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Die Fähigkeit der spezifischen und kontextabhängigen zellulären Adaption auf intrinsische und/oder extrinsische Signale ist das Fundament zellulärer Homöostase. Verschiedene Signale werden von Membranrezeptoren oder intrazellulären Rezeptoren erkannt und ermöglichen die molekulare Anpassung zellulärer Prozesse. Komplexe, ineinandergreifende Proteinnetzwerke sind dabei elementar in der Regulation der Zelle. Proteine und deren Funktionen werden dabei nach Bedarf reguliert und unterliegen einem ständigen proteolytischen Umsatz.
Die stimulusabhängige Gentranskription und/oder Proteintranslation nimmt hier eine zentrale Stellung ein, da die zugrundeliegende Maschinerie die Komposition und Funktion der Proteinnetzwerke entsprechend anpassen kann. Zusätzlich zur Regulation der Proteinabundanz werden Proteine posttranslational modifiziert, um deren Eigenschaften rasch zu ändern. Zu posttranslationalen Modifikationen zählen die Ubiquitinierung und/oder Phosphorylierung, welche die Proteinfunktionen hochdynamisch regulieren. Deregulierte Proteinnetzwerke werden oft mit Neurodegeneration und Autoimmun- oder Krebserkrankungen assoziiert. Auch Infektionen mit humanpathogenen Bakterien greifen stark in den Regulierungsprozess von Proteinnetzwerken und deren Funktionen ein. Die zelluläre Homöostase wird dadurch herausgefordert.
Bakterien der Gattung Salmonella sind zoonotische, gramnegative, fakultativ intrazelluläre Pathogene, welche weltweit millionenfach Salmonellen-erkrankungen hervorrufen. Von besonderer Bedeutung ist dabei Salmonella enterica serovar Typhimurium (hiernach Salmonella), welches im Menschen, meist durch mangelnde Hygienemaßnahmen, Gastroenteritis auslöst.
Immunität in Epithelzellen wird über das angeborene Immunsystem vermittelt und dient der Pathogenerkennung und -bekämpfung. Die Toll-like Rezeptoren (TLR) gehören zu den Mustererkennungsrezeptoren (pattern recognition receptors), welche spezifische mikrobielle Strukturen detektieren und eine kontextabhängige zelluläre Antwort generieren. Danger-Rezeptoren erkennen hingegen nicht direkt das Pathogen, sondern zelluläre Perturbationen, welche durch Zellschäden oder bakterielle Invasionen verursacht werden. Die intrinsische Fähigkeit der Wirtszelle, sich gegen Infektionen/Gefahren zu wehren wird dabei als zellautonome Immunität bezeichnet. Dabei nehmen induzierte proinflammatorische Signalwege und zelluläre Stressantworten eine wichtige Stellung ein. Die zelluläre Stressantwort aktiviert unter anderem die selektive Autophagie. Diese kann spezifisch aberrante Organelle, Proteine und invasive Pathogene abbauen. Ein weiterer Stresssignalweg ist die integrated stress response (ISR), welche eine selektive Proteintranslation erlaubt und damit die Auflösung des proteintoxischen Stresses ermöglicht.
Zur Penetration von Epithelzellen benötigt Salmonella ein komplexes System an Virulenzfaktoren, welches die bakterielle Internalisierung und Proliferation in der Wirtszelle ermöglicht. Salmonella nutzt dazu ein Typ-III-Sekretionssystem. Das System sekretiert bakterielle Virulenzfaktoren in die Zelle, sodass eine hochspezifische Modulierung des Wirtes erzwungen wird.
Die Virulenzfaktoren SopE und SopE2 spielen dabei eine Schlüsselrolle, da sie die Pathogenität von Salmonella maßgeblich vermitteln. Durch molekulare Mimikry von Wirts GTP (Guanosintriphosphat) -Austauschfaktoren aktivieren SopE und SopE2 die Rho GTPasen CDC42 und Rac1. GTP-geladenes CDC42 und Rac1 wiederum aktivieren das Aktinzytoskelett und stimulieren die Polymerisierung von Aktinfilamenten über den Arp2/3-Komplex an der Invasionsstelle. Das Pathogen wird dadurch in ein membranumhülltes Vesikel, die sogenannte Salmonella-containing Vakuole (SCV), aufgenommen. Die SCV stellt eine protektive, replikative, intrazelluläre Nische des Pathogens dar und wird permanent durch verschiedene Virulenzfaktoren moduliert.
Im Allgemeinen führt die Aktivierung von Mustererkennungsrezeptoren und Danger-Rezeptoren also zu einer zellulären Stressantwort und Entzündungsreaktion, wodurch es zur Bekämpfung der Infektion kommt. Inflammatorische Signalwege werden meist über den zentralen Transkriptionsfaktor NF-κB (nuclear factor 'kappa-light-chain-enhancer' of activated B-cells) vermittelt. NF-κB bewirkt die Induktion von proinflammatorischen Effektoren und Stressgenen. Zellautonome Immunität wird zusätzlich durch antibakterielle Autophagie ermöglicht, wobei Salmonella selektiv über das lysosomale System abgebaut werden. Das bakterielle Typ-III-Sekretionssystem verursacht an einigen wenigen SCVs Membranschäden, sodass Salmonella das Wirtszytosol penetrieren. Zytosolische Bakterien werden dabei spezifisch ubiquitiniert. Dies erlaubt die Erkennung durch die Autophagie-Maschinerie.
In der vorliegenden Arbeit wurde die zellautonome Immunität von Epithelzellen während einer akuten Salmonella Infektion durch quantitative Proteomik untersucht...
5-Lipoxygenase (5-LO) catalysis is positively regulated by Ca2+ ions and phospholipids that both act via the N-terminal C2-like domain of 5-LO. Previously, we have shown that 1-oleoyl-2-acetylglycerol (OAG) functions as an agonist for human polymorphonuclear leukocytes (PMNL) in stimulating 5-LO product formation. Here we have demonstrated that OAG directly stimulates 5-LO catalysis in vitro. In the absence of Ca2+ (chelated using EDTA), OAG strongly and concentration-dependently stimulated crude 5-LO in 100,000 x g supernatants as well as purified 5-LO enzyme from PMNL. Also, the monoglyceride 1-O-oleyl-rac-glycerol and 1,2-dioctanoyl-sn-glycerol were effective, whereas various phospholipids did not stimulate 5-LO. However, in the presence of Ca2+, OAG caused no stimulation of 5-LO. Also, phospholipids or cellular membranes abolished the effects of OAG. As found previously for Ca2+, OAG renders 5-LO activity resistant against inhibition by glutathione peroxidase activity, and this effect of OAG is reversed by phospholipids. Intriguingly, a 5-LO mutant lacking tryptophan residues (Trp-13, -75, and -102) important for the binding of the 5-LO C2-like domain to phospholipids was not stimulated by OAG. We conclude that OAG directly stimulates 5-LO by acting at a phospholipid binding site located within the C2-like domain.
We report here the nuclear magnetic resonance 19F screening of 14 RNA targets with different secondary and tertiary structure to systematically assess the druggability of RNAs. Our RNA targets include representative bacterial riboswitches that naturally bind with nanomolar affinity and high specificity to cellular metabolites of low molecular weight. Based on counter-screens against five DNAs and five proteins, we can show that RNA can be specifically targeted. To demonstrate the quality of the initial fragment library that has been designed for easy follow-up chemistry, we further show how to increase binding affinity from an initial fragment hit by chemistry that links the identified fragment to the intercalator acridine. Thus, we achieve low-micromolar binding affinity without losing binding specificity between two different terminator structures.
The stem-loop (SL1) is the 5'-terminal structural element within the single-stranded SARS-CoV-2 RNA genome. It is formed by nucleotides 7–33 and consists of two short helical segments interrupted by an asymmetric internal loop. This architecture is conserved among Betacoronaviruses. SL1 is present in genomic SARS-CoV-2 RNA as well as in all subgenomic mRNA species produced by the virus during replication, thus representing a ubiquitous cis-regulatory RNA with potential functions at all stages of the viral life cycle. We present here the 1H, 13C and 15N chemical shift assignment of the 29 nucleotides-RNA construct 5_SL1, which denotes the native 27mer SL1 stabilized by an additional terminal G-C base-pair.
The SARS-CoV-2 (SCoV-2) virus is the causative agent of the ongoing COVID-19 pandemic. It contains a positive sense single-stranded RNA genome and belongs to the genus of Betacoronaviruses. The 5′- and 3′-genomic ends of the 30 kb SCoV-2 genome are potential antiviral drug targets. Major parts of these sequences are highly conserved among Betacoronaviruses and contain cis-acting RNA elements that affect RNA translation and replication. The 31 nucleotide (nt) long highly conserved stem-loop 5a (SL5a) is located within the 5′-untranslated region (5′-UTR) important for viral replication. SL5a features a U-rich asymmetric bulge and is capped with a 5′-UUUCGU-3′ hexaloop, which is also found in stem-loop 5b (SL5b). We herein report the extensive 1H, 13C and 15N resonance assignment of SL5a as basis for in-depth structural studies by solution NMR spectroscopy.
1H, 13C and 15N chemical shift assignment of the stem-loops 5b + c from the 5′-UTR of SARS-CoV-2
(2022)
The ongoing pandemic of the respiratory disease COVID-19 is caused by the SARS-CoV-2 (SCoV2) virus. SCoV2 is a member of the Betacoronavirus genus. The 30 kb positive sense, single stranded RNA genome of SCoV2 features 5′- and 3′-genomic ends that are highly conserved among Betacoronaviruses. These genomic ends contain structured cis-acting RNA elements, which are involved in the regulation of viral replication and translation. Structural information about these potential antiviral drug targets supports the development of novel classes of therapeutics against COVID-19. The highly conserved branched stem-loop 5 (SL5) found within the 5′-untranslated region (5′-UTR) consists of a basal stem and three stem-loops, namely SL5a, SL5b and SL5c. Both, SL5a and SL5b feature a 5′-UUUCGU-3′ hexaloop that is also found among Alphacoronaviruses. Here, we report the extensive 1H, 13C and 15N resonance assignment of the 37 nucleotides (nts) long sequence spanning SL5b and SL5c (SL5b + c), as basis for further in-depth structural studies by solution NMR spectroscopy.
1H, 13C, and 15N backbone chemical shift assignments of coronavirus-2 non-structural protein Nsp10
(2020)
The international Covid19-NMR consortium aims at the comprehensive spectroscopic characterization of SARS-CoV-2 RNA elements and proteins and will provide NMR chemical shift assignments of the molecular components of this virus. The SARS-CoV-2 genome encodes approximately 30 different proteins. Four of these proteins are involved in forming the viral envelope or in the packaging of the RNA genome and are therefore called structural proteins. The other proteins fulfill a variety of functions during the viral life cycle and comprise the so-called non-structural proteins (nsps). Here, we report the near-complete NMR resonance assignment for the backbone chemical shifts of the non-structural protein 10 (nsp10). Nsp10 is part of the viral replication-transcription complex (RTC). It aids in synthesizing and modifying the genomic and subgenomic RNAs. Via its interaction with nsp14, it ensures transcriptional fidelity of the RNA-dependent RNA polymerase, and through its stimulation of the methyltransferase activity of nsp16, it aids in synthesizing the RNA cap structures which protect the viral RNAs from being recognized by the innate immune system. Both of these functions can be potentially targeted by drugs. Our data will aid in performing additional NMR-based characterizations, and provide a basis for the identification of possible small molecule ligands interfering with nsp10 exerting its essential role in viral replication.
The SARS-CoV-2 genome encodes for approximately 30 proteins. Within the international project COVID19-NMR, we distribute the spectroscopic analysis of the viral proteins and RNA. Here, we report NMR chemical shift assignments for the protein Nsp3b, a domain of Nsp3. The 217-kDa large Nsp3 protein contains multiple structurally independent, yet functionally related domains including the viral papain-like protease and Nsp3b, a macrodomain (MD). In general, the MDs of SARS-CoV and MERS-CoV were suggested to play a key role in viral replication by modulating the immune response of the host. The MDs are structurally conserved. They most likely remove ADP-ribose, a common posttranslational modification, from protein side chains. This de-ADP ribosylating function has potentially evolved to protect the virus from the anti-viral ADP-ribosylation catalyzed by poly-ADP-ribose polymerases (PARPs), which in turn are triggered by pathogen-associated sensing of the host immune system. This renders the SARS-CoV-2 Nsp3b a highly relevant drug target in the viral replication process. We here report the near-complete NMR backbone resonance assignment (1H, 13C, 15N) of the putative Nsp3b MD in its apo form and in complex with ADP-ribose. Furthermore, we derive the secondary structure of Nsp3b in solution. In addition, 15N-relaxation data suggest an ordered, rigid core of the MD structure. These data will provide a basis for NMR investigations targeted at obtaining small-molecule inhibitors interfering with the catalytic activity of Nsp3b.
The ongoing pandemic caused by the Betacoronavirus SARS-CoV-2 (Severe Acute Respiratory Syndrome Coronavirus-2) demonstrates the urgent need of coordinated and rapid research towards inhibitors of the COVID-19 lung disease. The covid19-nmr consortium seeks to support drug development by providing publicly accessible NMR data on the viral RNA elements and proteins. The SARS-CoV-2 genome encodes for approximately 30 proteins, among them are the 16 so-called non-structural proteins (Nsps) of the replication/transcription complex. The 217-kDa large Nsp3 spans one polypeptide chain, but comprises multiple independent, yet functionally related domains including the viral papain-like protease. The Nsp3e sub-moiety contains a putative nucleic acid-binding domain (NAB) with so far unknown function and consensus target sequences, which are conceived to be both viral and host RNAs and DNAs, as well as protein-protein interactions. Its NMR-suitable size renders it an attractive object to study, both for understanding the SARS-CoV-2 architecture and drugability besides the classical virus’ proteases. We here report the near-complete NMR backbone chemical shifts of the putative Nsp3e NAB that reveal the secondary structure and compactness of the domain, and provide a basis for NMR-based investigations towards understanding and interfering with RNA- and small-molecule-binding by Nsp3e.
Although overexpression and hyperactivity of protein kinases are causative for a wide range of human cancers, protein kinase inhibitors currently approved as cancer drugs address only a limited number of these enzymes. To identify new chemotypes addressing alternative protein kinases, the basic structure of a known PLK1/VEGF-R2 inhibitor class was formally dissected and reassembled. The resulting 7-(2-anilinopyrimidin-4-yl)-1-benzazepin-2-ones were synthesized and proved to be dual inhibitors of Aurora A kinase and VEGF receptor kinases. Crystal structures of two representatives of the new chemotype in complex with Aurora A showed the ligand orientation in the ATP binding pocket and provided the basis for rational structural modifications. Congeners with attached sulfamide substituents retained Aurora A inhibitory activity. In vitro screening of two members of the new kinase inhibitor family against the cancer cell line panel of the National Cancer Institute (NCI) showed antiproliferative activity in the single-digit micromolar concentration range in the majority of the cell lines.
Two subvalent, redox-active diborane(4) anions, [3]4− and [3]2−, carrying exceptionally high negative charge densities are reported: Reduction of 9-methoxy-9-borafluorene with Li granules without stirring leads to the crystallization of the B(sp3)−B(sp2) diborane(5) anion salt Li[5]. [5]− contains a 2,2′-biphenyldiyl-bridged B−B core, a chelating 2,2′-biphenyldiyl moiety, and a MeO substituent. Reduction of Li[5] with Na metal gives the Na+ salt of the tetraanion [3]4− in which two doubly reduced 9-borafluorenyl fragments are linked via a B−B single bond. Comproportionation of Li[5] and Na4[3] quantitatively furnishes the diborane(4) dianion salt Na2[3], the doubly boron-doped congener of 9,9′-bis(fluorenylidene). Under acid catalysis, Na2[3] undergoes a formal Stone–Wales rearrangement to yield a dibenzo[g,p]chrysene derivative with B=B core. Na2[3] shows boron-centered nucleophilicity toward n-butyl chloride. Na4[3] produces bright blue chemiluminescence when exposed to air.
Publicly available compound and bioactivity databases provide an essential basis for data-driven applications in life-science research and drug design. By analyzing several bioactivity repositories, we discovered differences in compound and target coverage advocating the combined use of data from multiple sources. Using data from ChEMBL, PubChem, IUPHAR/BPS, BindingDB, and Probes & Drugs, we assembled a consensus dataset focusing on small molecules with bioactivity on human macromolecular targets. This allowed an improved coverage of compound space and targets, and an automated comparison and curation of structural and bioactivity data to reveal potentially erroneous entries and increase confidence. The consensus dataset comprised of more than 1.1 million compounds with over 10.9 million bioactivity data points with annotations on assay type and bioactivity confidence, providing a useful ensemble for computational applications in drug design and chemogenomics.
Persistent and, in particular, neuropathic pain is a major healthcare problem with still insufficient pharmacological treatment options. This triggered research activities aimed at finding analgesics with a novel mechanism of action. Results of these efforts will need to pass through the phases of drug development, in which experimental human pain models are established components e.g. implemented as chemical hyperalgesia induced by capsaicin. We aimed at ranking the various readouts of a human capsaicin–based pain model with respect to the most relevant information about the effects of a potential reference analgesic. In a placebo‐controlled, randomized cross‐over study, seven different pain‐related readouts were acquired in 16 healthy individuals before and after oral administration of 300 mg pregabalin. The sizes of the effect on pain induced by intradermal injection of capsaicin were quantified by calculating Cohen's d. While in four of the seven pain‐related parameters, pregabalin provided a small effect judged by values of Cohen's d exceeding 0.2, an item categorization technique implemented as computed ABC analysis identified the pain intensities in the area of secondary hyperalgesia and of allodynia as the most suitable parameters to quantify the analgesic effects of pregabalin. Results of this study provide further support for the ability of the intradermal capsaicin pain model to show analgesic effects of pregabalin. Results can serve as a basis for the designs of studies where the inclusion of this particular pain model and pregabalin is planned.
Organ-on-a-chip technology has the potential to accelerate pharmaceutical drug development, improve the clinical translation of basic research, and provide personalized intervention strategies. In the last decade, big pharma has engaged in many academic research cooperations to develop organ-on-a-chip systems for future drug discoveries. Although most organ-on-a-chip systems present proof-of-concept studies, miniaturized organ systems still need to demonstrate translational relevance and predictive power in clinical and pharmaceutical settings. This review explores whether microfluidic technology succeeded in paving the way for developing physiologically relevant human in vitro models for pharmacology and toxicology in biomedical research within the last decade. Individual organ-on-a-chip systems are discussed, focusing on relevant applications and highlighting their ability to tackle current challenges in pharmacological research.
Polo-like kinase 1 (PLK1) is a crucial regulator of cell cycle progression. It is established that the activation of PLK1 depends on the coordinated action of Aurora-A and Bora. Nevertheless, very little is known about the spatiotemporal regulation of PLK1 during G2, specifically, the mechanisms that keep cytoplasmic PLK1 inactive until shortly before mitosis onset. Here, we describe PLK1 dimerization as a new mechanism that controls PLK1 activation. During the early G2 phase, Bora supports transient PLK1 dimerization, thus fine-tuning the timely regulated activation of PLK1 and modulating its nuclear entry. At late G2, the phosphorylation of T210 by Aurora-A triggers dimer dissociation and generates active PLK1 monomers that support entry into mitosis. Interfering with this critical PLK1 dimer/monomer switch prevents the association of PLK1 with importins, limiting its nuclear shuttling, and causes nuclear PLK1 mislocalization during the G2-M transition. Our results suggest a novel conformational space for the design of a new generation of PLK1 inhibitors.
RcsF, a proposed auxiliary regulator of the regulation of capsule synthesis (rcs) phosphorelay system, is a key element for understanding the RcsC-D-A/B signaling cascade, which is responsible for the regulation of more than 100 genes and is involved in cell division, motility, biofilm formation, and virulence. The RcsC-D-A/B system is one of the most complex bacterial signal transduction pathways, consisting of several membrane-bound and soluble proteins. RcsF is a lipoprotein attached to the outer membrane and plays an important role in activating the RcsC-d-A/B pathway. The exact mechanism of activation of the rcs phosphorelay by RcsF, however, remains unknown. We have analyzed the sequence of RcsF and identified three structural elements: 1) an N-terminal membrane-anchored helix (residues 3-13), 2) a loop (residues 14-48), and 3) a C-terminal folded domain (residues 49-134). We have determined the structure of this C-terminal domain and started to investigate its interaction with potential partners. Important features of its structure are two disulfide bridges between Cys-74 and Cys-118 and between Cys-109 and Cys-124. To evaluate the importance of this RcsF disulfide bridge network in vivo, we have examined the ability of the full-length protein and of specific Cys mutants to initiate the rcs signaling cascade. The results indicate that the Cys-74/Cys-118 and the Cys-109/Cys-124 residues correlate pairwise with the activity of RcsF. Interaction studies showed a weak interaction with an RNA hairpin. However, no interaction could be detected with reagents that are believed to activate the rcs phosphorelay, such as lysozyme, glucose, or Zn(2+) ions.
Meat adulteration is a global problem which undermines market fairness and harms people with allergies or certain religious beliefs. In this study, a novel framework in which a one-dimensional convolutional neural network (1DCNN) serves as a backbone and a random forest regressor (RFR) serves as a regressor, named 1DCNN-RFR, is proposed for the quantitative detection of beef adulterated with pork using electronic nose (E-nose) data. The 1DCNN backbone extracted a sufficient number of features from a multichannel input matrix converted from the raw E-nose data. The RFR improved the regression performance due to its strong prediction ability. The effectiveness of the 1DCNN-RFR framework was verified by comparing it with four other models (support vector regression model (SVR), RFR, backpropagation neural network (BPNN), and 1DCNN). The proposed 1DCNN-RFR framework performed best in the quantitative detection of beef adulterated with pork. This study indicated that the proposed 1DCNN-RFR framework could be used as an effective tool for the quantitative detection of meat adulteration.
Computational oral absorption models, in particular PBBM models, provide a powerful tool for researchers and pharmaceutical scientists in drug discovery and formulation development, as they mimic and can describe the physiologically processes relevant to the oral absorption. PBBM models provide in vivo context to in vitro data experiments and allow for a dynamic understanding of in vivo drug disposition that is not typically provided by data from standard in vitro assays. Investigations using these models permit informed decision-making, especially regarding to formulation strategies in drug development. PBBM models, but can also be used to investigate and provide insight into mechanisms responsible for complex phenomena such as food effect in drug absorption. Although there are obviously still some gaps regarding the in silico construction of the gastrointestinal environment, ongoing research in the area of oral drug absorption (e.g. the UNGAP, AGE-POP and InPharma projects) will increase knowledge and enable improvement of these models.
PBBM can nowadays provide an alternative approach to the development of in vitro–in vivo correlations. The case studies presented in this thesis demonstrate how PBBM can address a mechanistic understanding of the negative food effect and be used to set clinically relevant dissolution specification for zolpidem immediate release tablets. In both cases, we demonstrated the importance of integrating drug properties with physiological variables to mechanistically understand and observe the impact of these parameters on oral drug absorption.
Various complex physiological processes are initiated upon food consumption, which can enhance or reduce a drug’s dissolution, solubility, and permeability and thus lead to changes in drug absorption. With improvements in modeling and simulation software and design of in vitro studies, PBBM modeling of food effects may eventually serve as a surrogate for clinical food effect studies for new doses and formulations or drugs. Furthermore, the application of these models may be even more critical in case of compounds where execution of clinical studies in healthy volunteers would be difficult (e.g., oncology drugs).
In the fourth chapter we have demonstrated the establishment of the link between biopredictive in vitro dissolution testing (QC or biorelevant method) PBBM coupled with PD modeling opens the opportunity to set truly clinically relevant specifications for drug release. This approach can be extended to other drugs regardless of its classification according to the BCS.
With the increased adoption of PBBM, we expect that best practices in development and verification of these models will be established that can eventually inform a regulatory guidance. Therefore, the application of Physiologically Based Biopharmaceutical Modelling is an area with great potential to streamline late-stage drug development and impact on regulatory approval procedures.
A toolbox for the generation of chemical probes for Baculovirus IAP Repeat containing proteins
(2022)
E3 ligases constitute a large and diverse family of proteins that play a central role in regulating protein homeostasis by recruiting substrate proteins via recruitment domains to the proteasomal degradation machinery. Small molecules can either inhibit, modulate or hijack E3 function. The latter class of small molecules led to the development of selective protein degraders, such as PROTACs (PROteolysis TArgeting Chimeras), that recruit protein targets to the ubiquitin system leading to a new class of pharmacologically active drugs and to new therapeutic options. Recent efforts have focused on the E3 family of Baculovirus IAP Repeat (BIR) domains that comprise a structurally conserved but diverse 70 amino acid long protein interaction domain. In the human proteome, 16 BIR domains have been identified, among them promising drug targets such as the Inhibitors of Apoptosis (IAP) family, that typically contain three BIR domains (BIR1, BIR2, and BIR3). To date, this target area lacks assay tools that would allow comprehensive evaluation of inhibitor selectivity. As a consequence, the selectivity of current BIR domain targeting inhibitors is unknown. To this end, we developed assays that allow determination of inhibitor selectivity in vitro as well as in cellulo. Using this toolbox, we have characterized available BIR domain inhibitors. The characterized chemical starting points and selectivity data will be the basis for the generation of new chemical probes for IAP proteins with well-characterized mode of action and provide the basis for future drug discovery efforts and the development of PROTACs and molecular glues.
Non-alcoholic steatohepatitis (NASH) - a hepatic manifestation of the metabolic syndrome - is a multifactorial disease with alarming global prevalence. It involves steatosis, inflammation and fibrosis in the liver, thus demanding multiple modes of action for robust therapeutic efficacy. Aiming to fuse complementary validated anti-NASH strategies in a single molecule, we have designed and systematically optimized a scaffold for triple activation of farnesoid X receptor (FXR), peroxisome proliferator-activated receptor (PPAR) α and PPARδ. Pilot profiling of the resulting triple modulator demonstrated target engagement in native cellular settings and in mice, rendering it a suitable tool to probe the triple modulator concept in vivo. In DIO NASH in mice, the triple agonist counteracted hepatic inflammation and reversed hepatic fibrosis highlighting the potential of designed polypharmacology in NASH.
The enzyme acetyl-CoA carboxylase (ACC) plays a fundamental role in the fatty acid metabolism. It regulates the first and rate limiting step in the biosynthesis of fatty acids by catalyzing the carboxylation of acetyl-CoA to malonyl-CoA and exists as two different isoforms, ACC1 and ACC2. In the last few years, ACC has been reported as an attractive drug target for treating different diseases, such as insulin resistance, hepatic steatosis, dyslipidemia, obesity, metabolic syndrome and nonalcoholic fatty liver disease. An altered fatty acid metabolism is also associated with cancer cell proliferation. In general, the inhibition of ACC provides two possibilities to regulate the fatty acid metabolism: It blocks the de novo lipogenesis in lipogenic tissues and stimulates the mitochondrial fatty acid β-oxidation. Surprisingly, the role of ACC in human vascular endothelial cells has been neglected so far. This work aimed to investigate the role of the ACC/fatty acid metabolism in regulating important endothelial cell functions like proliferation, migration and tube formation.
To investigate the function of ACC, the ACC-inhibitor soraphen A as well as an siRNA-based approach were used. This study revealed that ACC1 is the predominant isoform both in human umbilical vein endothelial cells (HUVECs) and in human dermal microvascular endothelial cells (HMECs). Inhibition of ACC via soraphen A resulted in decreased levels of malonyl-CoA and shifted the lipid composition of endothelial cell membranes. Consequently, membrane fluidity, filopodia formation and the migratory capacity were attenuated. Increasing amounts of longer acyl chains within the phospholipid subgroup phosphatidylcholine (PC) were suggested to overcompensate the shift towards shorter acyl chains within phosphatidylglycerol (PG), which resulted in a dominating effect on regulating the membrane fluidity. Most importantly, this work provided a link between changes in the phospholipid composition and altered endothelial cell migration. The antimigratory effect of soraphen A was linked to a reduced amount of PG and to an increased amount of polyunsaturated fatty acids (PUFAs) within the phospholipid cell membrane. This link was unknown in the literature so far. Interestingly, a reduced filopodia formation was observed upon ACC inhibition via soraphen A, which presumably caused the impaired migratory capacity.
This work revealed a relationship between ACC/fatty acid metabolism, membrane lipid composition and endothelial cell migration. The natural compound soraphen A emerged as a valuable chemical tool to analyze the role of ACC/fatty acid metabolism in regulating important endothelial cell functions. Furthermore, regulating endothelial cell migration via ACC inhibition promises beneficial therapeutic perspectives for the treatment of cell migration-related disorders, such as ischemia reperfusion injury, diabetic angiopathy, macular degeneration, rheumatoid arthritis, wound healing defects and cancer.
The enzyme acetyl-CoA carboxylase (ACC) plays a crucial role in fatty acid metabolism. In recent years, ACC has been recognized as a promising drug target for treating different diseases. However, the role of ACC in vascular endothelial cells (ECs) has been neglected so far. To characterize the role of ACC, we used the ACC inhibitor, soraphen A, as a chemical tool, and also a gene silencing approach. We found that ACC1 was the predominant isoform in human umbilical vein ECs as well as in human microvascular ECs and that soraphen A reduced the levels of malonyl-CoA. We revealed that ACC inhibition shifted the lipid composition of EC membranes. Accordingly, membrane fluidity, filopodia formation, and migratory capacity were reduced. The antimigratory action of soraphen A depended on an increase in the cellular proportion of PUFAs and, most importantly, on a decreased level of phosphatidylglycerol. Our study provides a causal link between ACC, membrane lipid composition, and cell migration in ECs. Soraphen A represents a useful chemical tool to investigate the role of fatty acid metabolism in ECs and ACC inhibition offers a new and valuable therapeutic perspective for the treatment of EC migration-related diseases.
The composition of cellular membranes is extremely complex and the mechanisms underlying their homeostasis are poorly understood. Organelles within a eukaryotic cell require a non-random distribution of membrane lipids and a tight regulation of the membrane lipid composition is a prerequisite for the maintenance of specific organellar functions. Physical membrane properties such as bilayer thickness, lipid packing density and surface charge are governed by the lipid composition and change gradually from the early to the late secretory pathway. As the endoplasmic reticulum (ER) is situated at the beginning of the cells secretory pathway, it has to accept and accommodate a great variety and quantity of secretory and transmembrane proteins, which enter the ER on their way to their final cellular destination. Secretory proteins can be translocated into the lumen of the ER co- or posttanslationally and membrane proteins are being inserted and released into the ER membrane. In the oxidative milieu of the ER-lumen, supported by a variety of chaperones, proteins can fold into their native form.
If the folding capacity of the ER-lumen is exceeded, an accumulation of mis- or unfolded proteins in the lumen of the ER occurs, consequently triggering the unfolded protein response (UPR). This highly conserved program activates a wide-spread transcriptional response to restore protein folding homeostasis. In fact, 7 – 8% of all genes in the yeast Saccharomyces cerevisiae (S. cerevisiae) are regulated by the UPR. The mechanism underlying the activation of the UPR by protein folding stress has been investigated thoroughly in the last decades and many of its mechanistic details have been elucidated. Recently, it became evident that aberrant lipid compositions of the ER membrane, collectively referred to as lipid bilayer stress, are equally potent in activating the UPR. The underlying molecular mechanism of this membrane-activated UPR, however, remained unclear.
This study focuses on the UPR in S. cerevisiae and characterizes the inositol requiring enzyme 1 (Ire1) as the sole UPR sensor in S. cerevisiae. Active Ire1 forms oligomers and, collaboratively with the tRNA ligase Rlg1, splices immature mRNA of the transcription factor HAC1, which results in the synthesis of mature HAC1 mRNA and the production of the active Hac1 protein, which binds to UPR-elements in the nucleus and activates the expression of UPR target genes. Here, the combination of in vivo and in vitro experiments is being used, which is supplemented by molecular dynamics (MD) simulations performed by Roberto Covino and Gerhard Hummer (MPI for Biophysics, Frankfurt), aiming to identify the molecular mechanism of Ire1 activation by lipid bilayer stress. This study focuses on the analysis of the juxta- and transmembrane region of Ire1. Bioinformatic analyses revealed a putative ER-lumenal amphipathic helix (AH) N-terminally of and partially overlapping with the transmembrane helix (TMH). This predicted AH contains a large hydrophobic face, which inserts into the ER membrane, forcing the TMH into a tilted orientation within the membrane. The resulting unusual architecture of Ire1’s AH and TMH constitutes a unique structural element required for the activation of Ire1 by lipid bilayer stress.
To investigate the function of the AH in the physiological context, different variants of Ire1 were produced under the control of their endogenous promoter and from their endogenous locus. The functional role of the AH was tested, by disrupting its amphipathic character by the introduction of charged residues into the hydrophobic face of the AH. The role of a conserved negative residue between the TMH and the AH (E540 in S. cerevisiae) was tested by substituting it by a unipolar, polar, or positively charged residue. These variants were intensively characterized using a series of assays:
This thesis provides evidence that the AH is crucial for the function of Ire1: Mutant variants with a disrupted (F531R, V535R) or otherwise modified AH (E540A) exhibited a lower degree of oligomerization and failed to catalyze the splicing of the HAC1 mRNA as the Wildtype control. Likewise, the induction of PDI1, a target gene of the UPR, was greatly reduced in mutants with a disrupted or defective AH. These data revealed an important functional role of the AH for normal Ire1 function.
An in vitro system was established to analyze the membrane-mediated oligomerization of Ire1. This system enabled the isolated functional analysis of the AH and TMH during Ire1 activation by lipid bilayer stress. A fusion construct, coding for the maltose binding protein (MBP) from Escherichia coli (E. coli), N-terminally to the AH and TMH of Ire1 was produced. The heterologous production in E. coli, the purification and reconstitution of this minimal sensor of Ire1 in liposomes was established as part of this study. To analyze the oligomeric status of the minimal sensor in different lipid environments, continuous wave electron paramagnetic resonance (cwEPR) spectroscopic experiments were performed. These experiments revealed that the molecular packing density of the lipids had a significant influence of the oligomerization of the spin-labeled membrane sensor: increasing packing densities resulted in sensor oligomerization. The AH-disruptive F531R mutant, in which the amphipathic character of the AH was destroyed, showed no membrane-sensitive changes in its oligomerization status.
Thus, the activation of Ire1 by lipid bilayer stress is achieved by a membrane-based mechanism. According to the current model, the AH induces a local membrane compression by inserting its large hydrophobic face into the membrane. As membrane thickness and acyl chain order are interconnected, this compression simultaneously results in an increased local disordering of lipid acyl chains. Supporting MD simulations performed by Roberto Covino and Gerhard Hummer revealed that the bilayer compression is significantly more pronounced in a densely packed lipid environment, than in a lipid environment of lower lipid packing density. Hence, the energetic cost of the local compression increases with the packing density of the membrane, but is compensated for by the oligomerization of Ire1. This minimization of energetic cost induced by the membrane deformation of Ire1 forms the basis for the activation of Ire1 by lipid bilayer stress.
Background and Purpose: Activation of hepatic thyroid hormone receptor β (THR-β) is associated with systemic lipid lowering, increased bile acid synthesis, and fat oxidation. In patients with non-alcoholic steatohepatitis (NASH), treatment with THR-β agonists decreased hepatic steatosis and circulating lipids, and induced resolution of NASH. We chose resmetirom (MGL-3196), a liver-directed, selective THR-β agonist, as a prototype to investigate the effects of THR-β activation in mice with diet-induced obesity (DIO) and biopsy-confirmed advanced NASH with fibrosis.
Experimental Approach: C57Bl/6J mice were fed a diet high in fat, fructose, and cholesterol for 34 weeks, and only biopsy-confirmed DIO-NASH mice with fibrosis were included. Resmetirom was administered at a daily dose of 3 mg·kg−1 p.o., for 8 weeks. Systemic and hepatic metabolic parameters, histological non-alcoholic fatty liver disease (NAFLD) activity and fibrosis scores, and liver RNA expression profiles were determined to assess the effect of THR-β activation.
Key Results: Treatment with resmetirom did not influence body weight but led to significant reduction in liver weight, hepatic steatosis, plasma alanine aminotransferase activity, liver and plasma cholesterol, and blood glucose. These metabolic effects translated into significant improvement in NAFLD activity score. Moreover, a lower content of α-smooth muscle actin and down-regulation of genes involved in fibrogenesis indicated a decrease in hepatic fibrosis.
Conclusion and Implications: Our model robustly reflected clinical observations of body weight-independent improvements in systemic and hepatic metabolism including anti-steatotic activity.
Lysosomes are major degradative organelles that contain enzymes capable of breaking down proteins, nucleic acids, carbohydrates, and lipids. In the last decade, new discoveries have traced also important roles for lysosomes as signalling hubs, affecting metabolism, autophagy and pathogenic infections. Therefore, maintenance of a healthy lysosome population is of utmost importance to the cell to respond to both stress conditions and also homeostatic signalling. For example, for minor perturbations to the lysosomal membrane, the cell activates repair processes which seal membrane nicks. For more extensive damage, autophagy is activated to remove damaged organelles from the cell. on the other hand, during pathogen invasion host cells have also evolved mechanisms to hijack the endolysosomal pathway to facilitate their own growth and replication in host cells.
The first part of the thesis work focuses on a lysosomal regeneration program which is activated under conditions where the entire lysosomal pool of the cell is damaged. Upon extensive membrane damage induced by the lysosomotropic drug LLOMe, the cell activates a regeneration pathway which helps in the formation of new functional lysosomes by recycling damaged membranes. I have identified the molecules important for this novel pathway of lysosomal regeneration and showed how the protein TBC1D15 orchestrates this process to regenerate functional organelles from completely damaged membrane masses in the first 2 hours following lysosomal membrane damage. This process resembles the process of auto- lysosomal reformation (ALR)- involving the formation of lysosomal tubules which are extended along microtubules and cleaved in a dynamin2 dependent manner to form proto-lysosomes which develop into fully functional mature lysosomes. These lysosomal tubules are closely associated with ATG8 positive autophagosomal membranes and require ATG8 proteins to bind to the lysophagy receptor LIMP2 on damaged membranes. This process is physiologically important under conditions of crystal nephropathy where calcium oxalate crystals induce damage to lysosomal membranes in nephrons in kidney disease.
The second part of the thesis shows how the endolysosomal system of the cell is hijacked by the bacteriaLegionella pneumophila. During Legionella infection the formation of conventional ATG8 positive autophagosomes are blocked due to the protease activity of the bacterial effector protein RavZ which cleaves lipidated ATG8 proteins from autophagosomal membranes. The SidE effectors of Legionella modify STX17 and SNAP29 by the process of non-canonical ubiquitination called phosphoribose-linked serine ubiquitination (PR-Ub). These proteins are essential for the formation of the autophagosomal SNARE complex which is used for fusion of the autophagosome with the lysosome. Upon Legionella infection, PR-UB of STX17 aids in formation of autophagosome-like replication vacuoles. ThesevacuolesdonotfusewiththelysosomebecauseSNAP29isalsoPR-Ubmodified. PR-UbofSTX17 and SNAP29 sterically blocks the formation of the autophagosomal-SNARE complex thereby preventing fusion of the autophagosome with the lysosome. As a result, Legionella can replicate in autophagosome- like vacuoles which do not undergo lysosomal degradation. In absence of PR-Ub modified STX17, bacterial replication is compromised when measured by bacterial replication assays in lung epithelial (A549) cells.
Taken together, this thesis highlights two important aspects of the autophagy-lysosomal system- how it responds to extensive membrane damage and its importance in Legionella pneumophila infection. Extensive damage to lysosomal membranes triggers a rapid regeneration process to partially restore lysosomal function before the effects of TFEB dependent lysosomal biogenesis becomes apparent. On the other hand, Legionella pneumophila infection segregates the lysosomes from the rest of the endo-lysosomal system by blocking autophagosome-lysosome fusion. Though lysosomes remain active, they are incapable of degrading pathogens since pathogen containing vacuoles do not fuse with the lysosome.
Two main types of methods are used in gene therapy: integrating vectors and nuclease-based genome engineering. Nucleases are site-specific and are efficient for knock-outs, but inefficient at inserting long DNA sequences. Integrating vectors perform this task with high efficiency, but their insertion occurs at random genomic positions. This can result in transformation of target cells, which leads to severe adverse events in a gene therapy context. Thus, it is of great interest to develop novel genome engineering tools that combine the advantages of both technologies. The main focus of this thesis is on generating such a targetable integrating vector.
The integrating vector used in this project is the Sleeping Beauty (SB) transposon, a DNA transposon characterized by high activity across a wide range of cells. The SB transposase was combined with an RNA-guided Cas9 nuclease domain. This nuclease component was meant to direct transposase integration to specific targets defined by RNAs. The SB transposase was fused to cleavage-inactivated Cas9 (dCas9) to tether it to the target sites. In addition, adapter proteins consisting of dCas9 and domains non-covalently interacting with SB transposase or the SB transposon were generated. All constituent domains of these fusion proteins were tested in enzymatic assays and almost all enzymatic activities could be verified.
Combining the fusion protein dCas9-SB100X with a gRNA binding a sequence from the AluY repetitive element resulted in a weak, but statistically significant enrichment around sites bound by the gRNA. This enrichment was ca. 2-fold and occurred within a 300 bp window downstream of target sites, or within the AluY element.
Targeting with adapter proteins and targeting of other targets (L1 elements or single-copy targets) did not result in statistically significant effects. Single-copy targets tested included the HPRT gene and three specifically selected GSH targets that were known to be receptive to SB insertions. The combination with a more sequence-specific transposase mutant also failed to increase specificity to a level allowing targeting of single-copy loci. Genome-wide analysis of insertions however demonstrated, that dCas9-SB100X has a different insertion profile than SB100X, regardless of the gRNA used.
As low efficiency of retargeting is likely a consequence of the high background activity of the SB100X transposase in the fusion constructs, a SB mutant with reduced DNA affinity, SB(C42), was generated. For this mutant, transposition activity was partly dependent on a dCas9 domain being supplied with a multi-copy target gRNA, specifically a 2-fold increase in the presence of a AluY-directed gRNA. Whether using this mutant results in improved targeting remains to be determined.
In a side project, an attempt was made to direct SB insertions to ribosomal DNA by fusing the transposase to a nucleolar protein. This fusion transposase partially localized to nucleoli and insertions catalyzed by this transposase were found to be enriched in nucleolus organizer regions (NORs) and nucleolus-associated domains (NADs).
The aim of a second side project was increasing the ratio between homology-directed repair (HDR) and non-homologous end-joining (NHEJ) at Cas9-mediated double-strand breaks (DSBs). To achieve this, Cas9 was fused to DNA-interacting domains and corresponding binding sequences were fused to the homology donors. While an increased HDR/NHEJ ration could be observed for the fusion proteins, it was not dependent on the presence on the binding sequences in the donor molecules.
Gram-negative bacteria maintain an intrinsic resistance mechanism against entry of noxious compounds by utilizing highly efficient efflux pumps. The E. coli AcrAB-TolC drug efflux pump contains the inner membrane H+/drug antiporter AcrB comprising three functionally interdependent protomers, cycling consecutively through the loose (L), tight (T) and open (O) state during cooperative catalysis. Here, we present 13 X-ray structures of AcrB in intermediate states of the transport cycle. Structure-based mutational analysis combined with drug susceptibility assays indicate that drugs are guided through dedicated transport channels toward the drug binding pockets. A co-structure obtained in the combined presence of erythromycin, linezolid, oxacillin and fusidic acid shows binding of fusidic acid deeply inside the T protomer transmembrane domain. Thiol cross-link substrate protection assays indicate that this transmembrane domain-binding site can also accommodate oxacillin or novobiocin but not erythromycin or linezolid. AcrB-mediated drug transport is suggested to be allosterically modulated in presence of multiple drugs.
Bacteria are true artists of survival, which rapidly adapt to environmental changes like pH shifts, temperature changes and different salinities. Upon osmotic shock, bacteria are able to counteract the loss of water by the uptake of potassium ions. In many bacteria, this is accomplished by the major K+ uptake system KtrAB. The system consists of the K+-translocating channel subunit KtrB, which forms a dimer in the membrane, and the cytoplasmic regulatory RCK subunit KtrA, which binds non-covalently to KtrB as an octameric ring. This unique architecture differs strongly from other RCK-gated K+ channels like MthK or GsuK, in which covalently tethered cytoplasmic RCK domains regulate a single tetrameric pore. As a consequence, an adapted gating mechanism is required: The activation of KtrAB depends on the binding of ATP and Mg2+ to KtrA, while ADP binding at the same site results in inactivation, mediated by conformational rearrangements. However, it is still poorly understood how the nucleotides are exchanged and how the resulting conformational changes in KtrA control gating in KtrB is still poorly understood.
Here,I present a 2.5-Å cryo-EM structure of ADP-bound, inactive KtrAB, which for the first time resolves the N termini of both KtrBs. They are located at the interface of KtrA and KtrB, forming a strong interaction network with both subunits. In combination with functional and EPR data we show that the N termini, surrounded by a lipidic environment, play a crucial role in the activation of the KtrAB system. We are proposing an allosteric network, in which an interaction of the N termini with the membrane facilitates MgATP-triggered conformational changes, leading to the active, conductive state.
The accumulation and distribution of characteristic secondary products in the different organs of an Aloe plant (A. succotrina Lam.) were studied by high performance liquid chromatography for the first time. In the leaves of the Aloe plant, only anthrone-C-glycosyls of the 7-hydroxyaloin type and, for the first time in plant material, the free anthraquinone 7-hydroxyaloeemodin were found. In contrast to previous reports on the distribution of secondary products in Aloe plants, anthrone-C-glycosyls were also detected in flowers, bracts and the inflorescence axis of the species examined. Aloesaponol I, a tetrahydroanthracene aglycone, was only present in the underground organs and in the stem. The 2-alkylchromone-C-glucosyl aloeresin B showed no specific occurrence as it was found in every type of organ. Based on these results and the findings of recent studies on Aloe roots and flowers, a distribution scheme of polyketide types in the Aloe plant was established. It suggests a separate and independent anthranoid metabolism for underground Aloe organs and stem on the one hand, and for leaves and inflorescence organs on the other hand. In the latter structures anthranoid metabolism seems to be additionally compartmentalized as the anthranoid pro files of inflorescence organs and leaves differ in two points relevant to anthranoid biosynthe sis: firstly, the occurrence of anthrone aglycones and secondly, the individual content of corresponding anthrone-C-glucosyl diastereomers.
Macrophages respond to the Th2 cytokine IL-4 with elevated expression of arachidonate 15-lipoxygenase (ALOX15). Although IL-4 signaling elicits anti-inflammatory responses, 15-lipoxygenase may either support or inhibit inflammatory processes in a context-dependent manner. AMP-activated protein kinase (AMPK) is a metabolic sensor/regulator that supports an anti-inflammatory macrophage phenotype. How AMPK activation is linked to IL-4-elicited gene signatures remains unexplored. Using primary human macrophages stimulated with IL-4, we observed elevated ALOX15 mRNA and protein expression, which was attenuated by AMPK activation. AMPK activators, e.g. phenformin and aminoimidazole-4-carboxamide 1-β-d-ribofuranoside inhibited IL-4-evoked activation of STAT3 while leaving activation of STAT6 and induction of typical IL-4-responsive genes intact. In addition, phenformin prevented IL-4-induced association of STAT6 and Lys-9 acetylation of histone H3 at the ALOX15 promoter. Activating AMPK abolished cellular production of 15-lipoxygenase arachidonic acid metabolites in IL-4-stimulated macrophages, which was mimicked by ALOX15 knockdown. Finally, pretreatment of macrophages with IL-4 for 48 h increased the mRNA expression of the proinflammatory cytokines IL-6, IL-12, CXCL9, and CXCL10 induced by subsequent stimulation with lipopolysaccharide. This response was attenuated by inhibition of ALOX15 or activation of AMPK during incubation with IL-4. In conclusion, limiting ALOX15 expression by AMPK may promote an anti-inflammatory phenotype of IL-4-stimulated human macrophages.
Alzheimer’s Disease (AD) is a progressive and irreversible neurodegenerative disorder, characterized by the accumulation of abeta-amyloid aggregates, which triggers tau hyperphosphorylation and neuronal loss. While the precise mechanisms underlying neurodegeneration in AD are not entirely understood, it is known that loss of proteostasis is implicated in this process. Maintaining neuronal proteostasis requires proper transfer RNA (tRNA) modifications, which are crucial for optimal translation. However, research into tRNA epitranscriptome in AD is limited, and it is not yet clear how alterations in tRNA modifying enzymes and tRNA modifications might contribute to disease progression. Here, we report that expression of the tRNA modifying enzyme ELP3 is reduced in the brain of AD patients and amyloid AD mouse models, suggesting ELP3 is implicated in proteostasis dysregulation observed in AD. To investigate the role of ELP3 specifically in neuronal proteostasis impairments in the context of amyloid pathology, we analyzed SH-SY5Y neuronal cells carrying the amyloidogenic Swedish familial AD mutation in the APP gene (SH-SWE) or the wild-type gene (SH-WT). Similarly to the amyloid mouse models, SH-SWE exhibited reduced levels of ELP3 which was associated with tRNA hypomodifications and reduced abundance, as well as proteostasis impairments. Furthermore, the knock-down of ELP3 in SH-WT recapitulated the proteostasis impairments observed in SH-SWE cells. Importantly, the correction of tRNA deficits due to ELP3 reduction rescued and reverted proteostasis impairments of SH-SWE and SH-WT knock-down for ELP3, respectively. Additionally, SH-WT exposed to the secretome of SH-SWE or synthetic amyloid aggregates recapitulate the SH-SWE phenotype, characterized by reduced ELP3 expression, tRNA hypomodification and increased protein aggregation. Taken together, our data suggest that amyloid pathology dysregulates neuronal proteostasis through the reduction of ELP3 and tRNA modifications. This study highlights the modulation of tRNA modifications as a potential therapeutic avenue to restore neuronal proteostasis in AD and preserve neuronal function.
NMR structure calculation using NOE-derived distance restraints requires a considerable number of assignments of both backbone and sidechains resonances, often difficult or impossible to get for large or complex proteins. Pseudocontact shifts (PCSs) also play a well-established role in NMR protein structure calculation, usually to augment existing structural, mostly NOE-derived, information. Existing refinement protocols using PCSs usually either require a sizeable number of sidechain assignments or are complemented by other experimental restraints. Here, we present an automated iterative procedure to perform backbone protein structure refinements requiring only a limited amount of backbone amide PCSs. Already known structural features from a starting homology model, in this case modules of repeat proteins, are framed into a scaffold that is subsequently refined by experimental PCSs. The method produces reliable indicators that can be monitored to judge about the performance. We applied it to a system in which sidechain assignments are hardly possible, designed Armadillo repeat proteins (dArmRPs), and we calculated the solution NMR structure of YM4A, a dArmRP containing four sequence-identical internal modules, obtaining high convergence to a single structure. We suggest that this approach is particularly useful when approximate folds are known from other techniques, such as X-ray crystallography, while avoiding inherent artefacts due to, for instance, crystal packing.
Additive manufacturing or 3D printing as an umbrella term for various materials processing methods has distinct advantages over many other processing methods, including the ability to generate highly complex shapes and designs. However, the performance of any produced part not only depends on the material used and its shape, but is also critically dependent on its surface properties. Important features, such as wetting or fouling, critically depend mainly on the immediate surface energy. To gain control over the surface chemistry post-processing modifications are generally necessary, since it′s not a feature of additive manufacturing. Here, we report on the use of initiator and catalyst-free photografting and photopolymerization for the hydrophilic modification of microfiber scaffolds obtained from hydrophobic medical-grade poly(ε-caprolactone) via melt-electrowriting. Contact angle measurements and Raman spectroscopy confirms the formation of a more hydrophilic coating of poly(2-hydroxyethyl methacrylate). Apart from surface modification, we also observe bulk polymerization, which is expected for this method, and currently limits the controllability of this procedure.
ABC transporters fulfill diverse physiological functions in different cellularlocalizations ranging from the plasma membrane to intracellular membranouscompartments. Several ABC transporters have been spotted in the endolyso-somal system, which consists of endosomes, autophagosomes, lysosomes, andlysosome-related organelles. In this review, we present an overview of lysoso-mal ABC transporters including ABCA2, ABCA3, ABCA5, ABCB6,ABCB9, and ABCD4, discussing their trafficking routes, putative substrates,potential physiological functions, and associated diseases. In addition, weoffer a critical evaluation of the literature linking ABC transporters to lyso-somal drug sequestration, examining pitfalls associated with in vitro modelsof drug resistance.
Catecholaminergic polymorphic ventricular tachycardia (CPVT) is an inherited disturbance of the heart rhythm (arrhythmia) that is induced by stress or that occurs during exercise. Most mutations that have been linked to CPVT are found in two genes, i.e., ryanodine receptor 2 (RyR2) and calsequestrin 2 (CASQ2), two proteins fundamentally involved in the regulation of intracellular Ca2+ in cardiac myocytes. We inserted six CPVT-causing mutations via clustered regularly interspaced short palindromic repeats (CRISPR)-Cas9 into unc-68 and csq-1, the Caenorhabditis elegans homologs of RyR and CASQ, respectively. We characterized those mutations via video-microscopy, electrophysiology, and calcium imaging in our previously established optogenetic arrhythmia model. In this study, we additionally enabled high(er) throughput recordings of intact animals by combining optogenetic stimulation with a microfluidic chip system. Whereas only minor/no pump deficiency of the pharynx was observed at baseline, three mutations of UNC-68 (S2378L, P2460S, Q4623R; RyR2-S2246L, -P2328S, -Q4201R) reduced the ability of the organ to follow 4 Hz optogenetic stimulation. One mutation (Q4623R) was accompanied by a strong reduction of maximal pump rate. In addition, S2378L and Q4623R evoked an altered calcium handling during optogenetic stimulation. The 1,4-benzothiazepine S107, which is suggested to stabilize RyR2 channels by enhancing the binding of calstabin2, reversed the reduction of pumping ability in a mutation-specific fashion. However, this depends on the presence of FKB-2, a C. elegans calstabin2 homolog, indicating the involvement of calstabin2 in the disease-causing mechanisms of the respective mutations. In conclusion, we showed for three CPVT-like mutations in C. elegans RyR a reduced pumping ability upon light stimulation, i.e., an arrhythmia-like phenotype, that can be reversed in two cases by the benzothiazepine S107 and that depends on stabilization via FKB-2. The genetically amenable nematode in combination with optogenetics and high(er) throughput recordings is a promising straightforward system for the investigation of RyR mutations and the selection of mutation-specific drugs.
Currently, a wide variety of complex non-oral dosage forms are entering the global healthcare market. Although many assays have been described in recent research, harmonized procedures and standards for testing their in vitro performance remain widely unexplored. Among others, dialysis-based techniques such as the Pharma Test Dispersion Releaser are developed for testing the release of drugs from nanoparticles, liposomes, or extracellular vesicle preparations. Here, we provide advanced strategies and practical advice for the development and validation of dialysis-based techniques, including documentation, analysis, and interpretation of the raw data. For this purpose, key parameters of the release assay, including the hydrodynamics in the device at different stirring rates, the selectivity for particles and molecules, as well as the effect of excipients on drug permeation were investigated. At the highest stirring rate, a more than twofold increase in the membrane permeation rate (from 0.99 × 10−3 to 2.17 × 10−3 cm2/h) was observed. Additionally, we designed a novel computer model to identify important quality parameters of the dialysis experiment and to calculate error-corrected release profiles. Two hydrophilic creams of diclofenac, Voltaren® Emulgel, and Olfen® gel, were tested and provide first-hand evidence of the robustness of the assay in the presence of semisolid dosage forms.
Cerumen was found to be a promising alternative specimen for the detection of drugs. In a pilot study, drugs of abuse were identified at a higher detection rate and a longer detection window in cerumen than in urine. In this study, cerumen from subjects was analyzed after they ingested the designer stimulant 4-fluoroamphetamine (4-FA) in a controlled manner. Methods: Twelve subjects ingested placebo and 100 mg of 4-FA. Five of them were also given 150 mg of 4-FA in 150 mL Royal Club bitter lemon drink at least after 7 days. Cerumen was sampled using cotton swabs at baseline, 1 h after the ingestion of the drug and at the end of the study day (12 h). After extraction with ethyl acetate followed by solid-phase extraction, the extracts were analyzed using liquid chromatography coupled with tandem mass spectrometry (LC–MS/MS). Results and discussion: In the cerumen of all 12 subjects, 4-FA was detected 12 h after its ingestion; in most subjects, cerumen was detected after 1 h of ingestion, ranging from 0.06 to 13.90 (median 1.52) ng per swab. The detection of 4-FA in cerumen sampled 7 days or more after the first dose suggested a long detection window of cerumen. Conclusions: Cerumen can be successfully used to detect a single drug ingestion even immediately after the ingestion when a sufficient amount of cerumen is used.
Extracts of frankincense, the gum resin of Boswellia species, have been extensively used in traditional folk medicine since ancient times and are still of great interest as promising anti-inflammatory remedies in Western countries. Despite their common therapeutic use and the intensive pharmacological research including studies on active ingredients, modes of action, bioavailability, pharmacokinetics, and clinical efficacy, frankincense preparations are available as nutraceuticals but have not yet approved as a drug on the market. A major issue of commercially available frankincense nutraceuticals is the striking differences in their composition and quality, especially related to the content of boswellic acids (BAs) as active ingredients, mainly due to the use of material from divergent Boswellia species but also because of different work-up and extraction procedures. Here, we assessed three frequently used frankincense-based preparations for their BA content and the interference with prominent pro-inflammatory actions and targets that have been proposed, that is, 5-lipoxygenase and leukotriene formation in human neutrophils, microsomal prostaglandin E2 synthase-1, and inflammatory cytokine secretion in human blood monocytes. Our data reveal striking differences in the pharmacological efficiencies of these preparations in inflammation-related bioassays which obviously correlate with the amounts of BAs they contain. In summary, high-quality frankincense extracts display powerful anti-inflammatory effectiveness against multiple targets which can be traced back to BAs as bioactive ingredients.
The membrane protein Green Proteorhodopsin (GPR), found in an uncultured marine γ-proteobacterium, is a retinal binding protein and contains a conserved structure of seven transmembrane helices (A-G). The retinal is bound to a conserved lysine residue (K231) in helix G via Schiff base linkage. It belongs to the widespread family of microbial rhodopsins and functions as a light dependent outward proton pump that bacteria may utilize for establishing a proton gradient across the cellular membrane. Proton pumping takes place after photon absorption, where GPR goes through a series of conformational changes, termed photocycle, causing the proton to be transported across the cellular membrane from the intra-cellular to the extracellular space. It is further mediated by the highly conserved functional residues D97 and E108, which function as the primary proton acceptor and primary proton donor for the protonated Schiff base, respectively. Another functionally important residue is the highly conserved H75 in helix B. It forms an intra-molecular cluster with D97 and is responsible for the high pKa value of the primary proton acceptor, stabilized by a direct interaction between D97 and H75.
Different Proteorhodopsin variants are globally distributed and colour tuned to their environment, depending on the water depth in which they occur. A single residue in the retinal binding pocket at position 105 is responsible for determining the absorption wavelength of the protein. GPR (from eBAC31A08) contains a leucine at position 105, while BPR (blue proteorhodopsin, from Hot75m4) in deeper waters possesses a glutamine. Although GPR shows 79% sequence identity with BPR, a single amino acid substitution (L105Q) in GPR is able to switch the absorption maximum to the one of BPR.
Protein oligomerisation describes the association of subunits (protomers) through non-covalent interactions, forming macromolecular complexes. It is an important structural characteristic of microbial rhodopsins, contributing to structural stability and promoting tight packing of the protomers in the bacterial membrane. GPR was shown to assemble into radially arranged oligomers, mainly pentamers and hexamers. No high resolution crystal structure of the whole GPR complex is available, but the structurally related BPR (Hot75m4) was successfully crystallized, showing pentameric oligomers.
The BPR crystal structure model reveals detailed information about complex assembly of the whole proteorhodopsin family. It reveals the oligomeric structures and shows residues that are part of the protomer interfaces, forming cross-protomer contacts, which is valuable information for the elaborate analysis of cross-protomer interactions of GPR oligomers.
Based on the knowledge of GPR and BPR oligomeric complexes, the aim of this study is to analyse specific cross-protomer contacts and to characterize the functional role of GPR oligomerisation. This includes the identification of residues, which are part of charged cross-protomer contacts and play an important role for the formation of the GPR oligomeric complex. Furthermore, this study deals with a detailed characterization of a potentially functional cross-protomer triad between the residues D97-H75-W34, which was detected in the BPR structural model. Hereby, the focus lies especially on the functional role H75, which is highly conserved and is positioned in between the primary proton acceptor D97 and W34 across the protomer interface. In summary, this study addresses GPR oligomerisation via specific cross-protomer contacts and its potential role for the functional mechanism of the protein.
The fundamental technique used in this study is solid-state NMR. Furthermore, an elaborate characterization of GPR oligomerisation was executed using a variety of biochemical methods and mutational approaches. Solid-state NMR is a powerful biophysical method to analyse membrane proteins in their native lipid environment and can be used to obtain diverse information about structure, molecular dynamics and orientation of the protein in the lipid bilayer.
Solid-state NMR naturally has a low sensitivity. In order to detect the low number of spins, DNP signal enhancement is of particular importance in this study. It is exhibited under cryogenic conditions and allows to drastically enhance the solid-state NMR signal by transferring magnetization from highly polarized electrons to the nuclear spins.
By applying these methods and techniques on GPR oligomers, this study reveals new insights in specific cross-protomer interactions in the complex. First the oligomeric states of GPR were determined for the specific experimental conditions used in this study. LILBID-MS, BN-PAGE and SEC analysis identified the pentameric state to be dominant for GPR. Furthermore, specific interactions across the protomer interface, which drive GPR oligomerisation, were identified. This was conducted by creating mixed 13C-15N labelled complexes. These mixed complexes show a unique isotope labelling pattern across their protomer interfaces. Solid-state NMR 13C-15N-correlation spectroscopy (TEDOR) was used to identify through-space dipole-dipole couplings, which indicate specific cross-protomer contacts. The results indicated that the residues R51, D52, E50 and T60 are important for GPR oligomerisation, and further analysis via single mutations of these residues showed a severe impact of the GPR oligomerisation behaviour.
The functional importance of GPR oligomerisation was analysed by DNP-enhanced solid-state NMR on the cross-protomer D97-H75-W34 triad. The DNP cryogenic conditions allowed to trap GPR in distinct stages of the photocycle. It could be shown that trapping GPR in a specific intermediate leads to a drastic conformational effect for the highly conserved H75 residue. Furthermore, DNP-enhanced solid-state NMR was used to characterize the cross-protomer contact between H75 and W34. Mutations of W34 could show that the cross-protomer interaction is highly important for the functionality of the protein, as negative mutants such as W34E showed a reverse proton transport across the bacterial membrane.
In summary this study represents a detailed analysis of GPR cross-protomer interactions and sheds light into the cause and functional importance of oligomeric complex formation in the microbial rhodopsin.
5‐Lipoxygenase (5‐LO) is the initial enzyme in the biosynthesis of leukotrienes, which are mediators involved in pathophysiological conditions such as asthma and certain cancer types. Knowledge of proteins involved in 5‐LO pathway regulation, including gene regulatory proteins, is needed to evaluate all options for therapeutic intervention in these diseases. Here, we present a mass spectrometric screening of ALOX5 promoter‐interacting proteins, obtained by DNA pulldown and label‐free quantitative mass spectrometry. Protein preparations from myeloid and B‐lymphocytic cell lines were screened for promoter DNA interactors. Through statistical analysis, 66 proteins were identified as specific ALOX5 promotor binding proteins. Among those, the 15 most likely candidates for a prominent role in ALOX5 gene regulation are the known ALOX5 interactors Sp1 and Sp3, the related factor Sp2, two Krüppel‐like factors (KLF13 and KLF16) and six other zinc finger proteins (MAZ, PRDM10, VEZF1, ZBTB7A, ZNF281 and ZNF579). Intriguingly, we also identified two helicases (BLM and DHX36) and the proteins hnRNPD and hnRNPK, which are, together with the protein MAZ, known to interact with DNA G‐quadruplex structures. As G‐quadruplexes are implicated in gene regulation, spectroscopic and antibody‐based methods were used to confirm their presence within the GC‐rich sequence of the ALOX5 promoter. In summary, we have systematically characterized the interactome of the ALOX5 promoter, identifying several zinc finger proteins as novel potential ALOX5 gene regulators. Further, we have shown that the ALOX5 promoter can form DNA G‐quadruplex structures, which may play a functional role in ALOX5 gene regulation.
As one of the most widespread infectious diseases in the world, it is currently estimated that approximately 296 million people globally are chronically infected with Hepatitis B virus (HBV), the consequences of HBV infection cause more than 620,000 deaths each year. Although safe and effective HBV vaccines have reduced the incidence of new HBV infections in most countries, there are still around 1.5 million new infections each year. HBV remains a major health problem because there is no large-scale effective vaccination strategy in many countries with a high burden of disease, many people with chronic HBV infection are not receiving effective and timely treatment, and a complete cure for chronic infection is still far from being achieved.
Since its discovery, HBV has been identified as an enveloped DNA virus with a diameter of 42 nm. For efficient egress from host cells, HBV is thought to acquire the viral envelope by budding into multivesicular bodies (MVBs) and escape from infected cells via the exosome release pathway. It is clear that HBV hijacks the host vesicle system to complete self-assembly and propagation by interacting with factors that mediate exosome formation. Consequently, the overlap with exosome biogenesis, using MVBs as the release platform, raises the possibility for the release of exosomal HBV particles. Currently, virus containing exosomal vesicles have been described for several viruses. In light of this, this study explored whether intact HBV-virions wrapped in exosomes are released by HBV-producing cells.
First, this study established a robust method for efficient separation of exosomes from HBV virions by a combination of differential ultracentrifugation and iodixanol density gradient centrifugation. Fractionation of the density gradient revealed that two populations of infectious viral particles can be separated from the culture fluids of HBV-producing cells. The population present in the low-density peak co-migrates with the exosome markers. Whereas the population that appeared in the high-density fractions was the classical HBV virions, which are rcDNA-containing nucleocapsids encapsulated by the HBV envelope.
Subsequently, the characterization of this low-density population was performed, namely the highly purified exosome fraction was systematically investigated. Relying on the detergent sensitivity of the exosome membrane and the outer envelope of the HBV virus, disruption of the exosome structure by treatment with limited detergent revealed the presence of HBsAg in the exosomes. At the same time, mild and limited NP-40 treatment of highly purified exosomes and a further combination of density gradient centrifugation resulted in the stepwise release of intact HBV virions and naked capsids from the exosomes generated by HBV-producing cells. This implies the presence of intact HBV particles encapsulated by the host membrane.
The presence of exosome-encapsulated HBV particles was consequently also verified by suppressing the morphogenesis of MVBs or exosomes. Impairment of MVB- or exosome-generation with small molecule inhibitors has significantly inhibited the release of host membrane-encapsulated HBV particles as well. Likewise, silencing of exosome-related proteins caused a diminution of exosome output, which compromised the budding efficiency of wrapped HBV.
Moreover, electron microscopy images of ultra-thin sections combined with immunogold staining visualized the hidden virus in the exosomal structure. Additionally, the presence of LHBs on the surface of exosomes derived from HBV-expressing cells was also observed.
As expected, these exosomal membrane-wrapped HBV particles can spread productive infection in differentiated HepaRG cells. In HBV-susceptible cells, as LHBs on the membrane surface, this type of exosomal HBV appeared to be uptaken in an NTCP receptor-dependent manner.
Taken together these data indicate that a fraction of intact HBV virions can be released as exosomes. This reveals a so far not described release pathway for HBV. Exosomes hijacked by HBV act as a transporter impacting the dissemination of the virus.
Mast cells are long-lived tissue-resident leukocytes, located most abundantly in the skin and mucosal surfaces. They belong to the first line of defence of the body, protecting against invading pathogens, toxins and allergens. Their secretory granules are densely packed with a plethora of mediators, which can be released immediately upon activation of the cell. Next to their role in IgE-mediated allergic diseases and in promoting inflammation, potential anti-inflammatory functions have been assigned to mast cells, depending on the biological setting. The aim of this thesis was to contribute to a better understanding of the role of mast cells during the resolution of a local inflammation. Therefore, in a first of step a suitable model of a local inflammation had to be identified. Since comparison of the two Toll-like receptor (TLR)-agonists zymosan and lipopolysaccharide (LPS), which are most commonly used to locally induce inflammation, revealed a systemic response after LPS-injection and a local inflammation after zymosan-injection, the TLR2 agonist zymosan was chosen for the subsequent experiments. Multi epitope ligand cartography (MELC) combined with statistical neighbourhood analysis showed that mast cells are located in an anti-inflammatory microenvironment next to M2 macrophages during resolution of inflammation, while neutrophils and M1 macrophages are located in the zymosan-filled core of the inflammation. Furthermore, infiltrating neutrophils during peak inflammation and an increasing population of macrophages phagocytosing neutrophils during resolution of inflammation could be observed. MELC as well as flow cytometry analysis of mast cell-deficient mice revealed a decreased phagocytosing activity of macrophages in the absence of mast cells. As an untargeted approach to identify mast cell-derived mediators induced by zymosan, mRNA sequencing of bone marrow-derived mast cells (BMMCs) was performed. Gene ontology term analysis of the sequencing data revealed the induction of the type I interferon (IFN) pathway as the dominant response. Contradicting previous studies, I could validate the production of IFN-β by mast cells in response to zymosan and LPS in vitro. Furthermore IFN-β expression by mast cells was also detected in vivo. In accordance with previous studies regarding other cell types the release of IFN-β by mast cells depends on endosomal signaling. The potential of IFN-β to enhance the phagocytosing activity of macrophages has been demonstrated recently. Besides IFN-β, various other mediators with reported enhancing effects on macrophage phagocytosis were also induced by zymosan in BMMCs, including Interleukin (IL)-1β, IL-4, IL-13, and Prostaglandin (PG) E2. Thus, either one of these mediators alone or a combination of them could promote macrophage phagocytosis.
In conclusion, I herein present mast cells as a novel source for IFN-β induced by non-viral TLR ligands and demonstrate their enhancing effect on macrophage phagocytosis, thereby contributing to the resolution of inflammation.
Purpose: The quality testing and approval procedure for most pharmaceutical products is a streamlined process with standardized procedures for the determination of critical quality attributes. However, the evaluation of semisolid dosage forms for topical drug delivery remains a challenging task. The work presented here highlights confocal Raman microscopy (CRM) as a valuable tool for the characterization of such products.
Methods: CRM, a laser-based method, combining chemically-selective analysis and high resolution imaging, is used for the evaluation of different commercially available topical acyclovir creams.
Results: We show that CRM enables the spatially resolved analysis of microstructural features of semisolid products and provides insights into drug distribution and polymorphic state as well as the composition and arrangement of excipients. Further, we explore how CRM can be used to monitor phase separation and to study skin penetration and the interaction with fresh and cryopreserved excised human skin tissue.
Conclusion: This study presents a comprehensive overview and illustration of how CRM can facilitate several types of key analyses of semisolid topical formulations and of their interaction with their biological target site, illustrating that CRM is a useful tool for research, development as well as for quality testing in the pharmaceutical industry.
The DNA damage response (DDR) is a vast network of molecules that preserves genome integrity and allow the faithful transmission of genetic information in human cells. While the usual response to the detection of DNA lesions in cells involves the control of cell-cycle checkpoints, repair proteins or apoptosis, alterations of the repair processes can lead to cellular dysfunction, diseases, or cancer. Besides, cancer patients with DDR alterations often show poor survival and chemoresistance. Despite the progress made in recent years in identifying genes and proteins involved in DDR and their roles in cellular physiology and pathology, the question of the involvement of DDR in metabolism remains unclear. It remains to study the metabolites associated with specific repair pathways or alterations and to investigate whether differences exist depending on cellular origin. The identification of DDR-related metabolic pathways and of the pathways that cause metabolic reprogramming in DDR-deficient cells may produce new targets for the development of new therapies.
In this thesis, nuclear magnetic resonance spectroscopy (NMR) was used to assess the metabolic consequence of the loss of two central DNA repair proteins with importance in diseases context, ATM and RNase H2, in haematological cells. An increase in intracellular taurine was found in RNase H2- and ATM-deficient cells compared to wild-type cells for these genes and in cells after exposition to a source of DNA damage. The rise in taurine does not appear to result from an increase in its biosynthesis from cysteine, but more likely from other cellular processes such as degradation pathways.
Overall, evidence for metabolic reprogramming in haematological cells with faults in DNA repair resulting from ATM or RNase H2 deficiencies or upon exposition to a source of DNA damage is presented in this study.
Objectives: The objective of this review is to provide an overview of PK/PD models, focusing on drug-specific PK/PD models and highlighting their value-added in drug development and regulatory decision-making.
Key findings: Many PK/PD models, with varying degrees of complexity and physiological understanding, have been developed to evaluate the safety and efficacy of drug products. In special populations (e.g. pediatrics), in cases where there is genetic polymorphism and in other instances where therapeutic outcomes are not well described solely by PK metrics, the implementation of PK/PD models is crucial to assure the desired clinical outcome. Since dissociation between the pharmacokinetic and pharmacodynamic profiles is often observed, it is proposed that physiologically-based pharmacokinetic (PBPK) and PK/PD models be given more weight by regulatory authorities when assessing the therapeutic equivalence of drug products.
Summary: Modeling and simulation approaches already play an important role in drug development. While slowly moving away from “one-size fits all” PK methodologies to assess therapeutic outcomes, further work is required to increase confidence in PK/PD models in translatability and prediction of various clinical scenarios to encourage more widespread implementation in regulatory decision-making.
Objectives Supersaturating formulations hold great promise for delivery of poorly soluble active pharmaceutical ingredients (APIs). To profit from supersaturating formulations, precipitation is hindered with precipitation inhibitors (PIs), maintaining drug concentrations for as long as possible. This review provides a brief overview of supersaturation and precipitation, focusing on precipitation inhibition. Trial-and-error PI selection will be examined alongside established PI screening techniques. Primarily, however, this review will focus on recent advances that utilise advanced analytical techniques to increase mechanistic understanding of PI action and systematic PI selection.
Key Findings. Advances in mechanistic understanding have been made possible by the use of analytical tools such as spectroscopy, microscopy and mathematical and molecular modelling, which have been reviewed herein. Using these techniques, PI selection can instead be guided by molecular rationale. However, more work is required to see wide-spread application of such an approach for PI selection.
Conclusions PIs are becoming increasingly important in enabling formulations. Trial-and-error approaches have seen success thus far. However, it is essential to learn more about the mode of action of PIs if the most optimal formulations are to be realised. Robust analytical tools, and the knowledge of where and how they can be applied, will be essential in this endeavour.
We demonstrated previously that 5-lipoxygenase (5-LO), a key enzyme in leukotriene biosynthesis, can be phosphorylated by p38 MAPK-regulated MAPKAP kinases (MKs). Here we show that mutation of Ser-271 to Ala in 5-LO abolished MK2 catalyzed phosphorylation and clearly reduced phosphorylation by kinases prepared from stimulated polymorphonuclear leukocytes and Mono Mac 6 cells. Compared with heat shock protein 27 (Hsp-27), 5-LO was a weak substrate for MK2. However, the addition of unsaturated fatty acids (i.e. arachidonate 1-50 microm) up-regulated phosphorylation of 5-LO, but not of Hsp-27, by active MK2 in vitro, resulting in a similar phosphorylation as for Hsp-27. 5-LO was phosphorylated also by other serine/threonine kinases recognizing the motif Arg-Xaa-Xaa-Ser (protein kinase A, Ca(2+)/calmodulin-dependent kinase II), but these activities were not increased by fatty acids. HeLa cells expressing wild type 5-LO or S271A-5-LO, showed prominent 5-LO activity when incubated with Ca(2+)-ionophore plus arachidonate. However, when stimulated with only exogenous arachidonic acid, activity for the S271A mutant was significantly lower as compared with wild type 5-LO. It appears that phosphorylation at Ser-271 is more important for 5-LO activity induced by a stimulus that does not prominently increase intracellular Ca(2+) and that arachidonic acid stimulates leukotriene biosynthesis also by promoting this MK2-catalyzed phosphorylation.
Introns of human transfer RNA precursors (pre-tRNAs) are excised by the tRNA splicing endonuclease TSEN in complex with the RNA kinase CLP1. Mutations in TSEN/CLP1 occur in patients with pontocerebellar hypoplasia (PCH), however, their role in the disease is unclear. Here, we show that intron excision is catalyzed by tetrameric TSEN assembled from inactive heterodimers independently of CLP1. Splice site recognition involves the mature domain and the anticodon-intron base pair of pre-tRNAs. The 2.1-Å resolution X-ray crystal structure of a TSEN15–34 heterodimer and differential scanning fluorimetry analyses show that PCH mutations cause thermal destabilization. While endonuclease activity in recombinant mutant TSEN is unaltered, we observe assembly defects and reduced pre-tRNA cleavage activity resulting in an imbalanced pre-tRNA pool in PCH patient-derived fibroblasts. Our work defines the molecular principles of intron excision in humans and provides evidence that modulation of TSEN stability may contribute to PCH phenotypes.
Introns of human transfer RNA precursors (pre-tRNAs) are excised by the tRNA splicing endonuclease TSEN in complex with the RNA kinase CLP1. Mutations in TSEN/CLP1 occur in patients with pontocerebellar hypoplasia (PCH), however, their role in the disease is unclear. Here, we show that intron excision is catalyzed by tetrameric TSEN assembled from inactive heterodimers independently of CLP1. Splice site recognition involves the mature domain and the anticodon-intron base pair of pre-tRNAs. The 2.1-Å resolution X-ray crystal structure of a TSEN15–34 heterodimer and differential scanning fluorimetry analyses show that PCH mutations cause thermal destabilization. While endonuclease activity in recombinant mutant TSEN is unaltered, we observe assembly defects and reduced pre-tRNA cleavage activity resulting in an imbalanced pre-tRNA pool in PCH patient-derived fibroblasts. Our work defines the molecular principles of intron excision in humans and provides evidence that modulation of TSEN stability may contribute to PCH phenotypes.
ATP-binding cassette (ABC) systems translocate a wide range of solutes across cellular membranes. The thermophilic Gram-negative eubacterium Thermus thermophilus, a model organism for structural genomics and systems biology, discloses ∼46 ABC proteins, which are largely uncharacterized. Here, we functionally analyzed the first two and only ABC half-transporters of the hyperthermophilic bacterium, TmrA and TmrB. The ABC system mediates uptake of the drug Hoechst 33342 in inside-out oriented vesicles that is inhibited by verapamil. TmrA and TmrB form a stable heterodimeric complex hydrolyzing ATP with a Km of 0.9 mm and kcat of 9 s−1 at 68 °C. Two nucleotides can be trapped in the heterodimeric ABC complex either by vanadate or by mutation inhibiting ATP hydrolysis. Nucleotide trapping requires permissive temperatures, at which a conformational ATP switch is possible. We further demonstrate that the canonic glutamate 523 of TmrA is essential for rapid conversion of the ATP/ATP-bound complex into its ADP/ATP state, whereas the corresponding aspartate in TmrB (Asp-500) has only a regulatory role. Notably, exchange of this single noncanonic residue into a catalytic glutamate cannot rescue the function of the E523Q/D500E complex, implicating a built-in asymmetry of the complex. However, slow ATP hydrolysis in the newly generated canonic site (D500E) strictly depends on the formation of a posthydrolysis state in the consensus site, indicating an allosteric coupling of both active sites.
Atg8-family proteins - structural features and molecular interactions in autophagy and beyond
(2020)
Autophagy is a common name for a number of catabolic processes, which keep the cellular homeostasis by removing damaged and dysfunctional intracellular components. Impairment or misbalance of autophagy can lead to various diseases, such as neurodegeneration, infection diseases, and cancer. A central axis of autophagy is formed along the interactions of autophagy modifiers (Atg8-family proteins) with a variety of their cellular counter partners. Besides autophagy, Atg8-proteins participate in many other pathways, among which membrane trafficking and neuronal signaling are the most known. Despite the fact that autophagy modifiers are well-studied, as the small globular proteins show similarity to ubiquitin on a structural level, the mechanism of their interactions are still not completely understood. A thorough analysis and classification of all known mechanisms of Atg8-protein interactions could shed light on their functioning and connect the pathways involving Atg8-proteins. In this review, we present our views of the key features of the Atg8-proteins and describe the basic principles of their recognition and binding by interaction partners. We discuss affinity and selectivity of their interactions as well as provide perspectives for discovery of new Atg8-interacting proteins and therapeutic approaches to tackle major human diseases.
Alzheimer’s disease (AD) is characterized by the deposition of aggregated species of amyloid beta (Aβ) in the brain, which leads to progressive cognitive deficits and dementia. Aβ is generated by the successive cleavage of the amyloid precursor protein (APP), first by β-site APP cleaving enzyme 1 (BACE1) and subsequently by the γ-secretase complex. Those conditions which enhace or reduce its clearance predispose to Aβ aggregation and the development of AD. In vitro studies have demonstrated that Aβ assemblies spark a feed-forward loop heightening Aβ production. However, the underlying mechanism remains unknown. Here, we show that oligomers and fibrils of Aβ enhance colocalization and physical interaction of APP and BACE1 in recycling endosomes of human neurons derived from induced pluripotent stem cells and other cell types, which leads to exacerbated amyloidogenic processing of APP and intracellular accumulation of Aβ42. In cells that are overexpressing the mutant forms of APP which are unable to bind Aβ or to activate Go protein, we have found that treatment with aggregated Aβ fails to increase colocalization of APP with BACE1 indicating that Aβ-APP/Go signaling is involved in this process. Moreover, inhibition of Gβγ subunit signaling with βARKct or gallein prevents Aβ-dependent interaction of APP and BACE1 in endosomes, β-processing of APP, and intracellular accumulation of Aβ42. Collectively, our findings uncover a signaling mechanism leading to a feed-forward loop of amyloidogenesis that might contribute to Aβ pathology in the early stages of AD and suggest that gallein could have therapeutic potential.
F-type ATP synthases are multiprotein complexes composed of two separate coupled motors (F1 and FO) generating adenosine triphosphate (ATP) as the universal major energy source in a variety of relevant biological processes in mitochondria, bacteria and chloroplasts. While the structure of many ATPases is solved today, the precise assembly pathway of F1FO-ATP synthases is still largely unclear. Here, we probe the assembly of the F1 complex from Acetobacterium woodii. Using laser induced liquid bead ion desorption (LILBID) mass spectrometry, we study the self-assembly of purified F1 subunits in different environments under non-denaturing conditions. We report assembly requirements and identify important assembly intermediates in vitro and in cellula. Our data provide evidence that nucleotide binding is crucial for in vitro F1 assembly, whereas ATP hydrolysis appears to be less critical. We correlate our results with activity measurements and propose a model for the assembly pathway of a functional F1 complex.
Pancreatic cancer is a common malignant tumor with a high incidence and mortality rate. The prognosis of patients with pancreatic cancer is considerably poor due to the lack of effective treatment in clinically. Despite numerous studies have revealed that baicalein, a natural product, is responsible for suppressing multiple cancer cells proliferation, motility and invasion. The mechanism by which baicalein restraining pancreatic cancer progression remains unclear. In this study, we firstly verified that baicalein plays a critical role in inhibiting pancreatic tumorigenesis in vitro and in vivo. Then we analyzed the alteration of microRNAs (miRNAs) expression levels in Panc-1 cells incubated with DMSO, 50 and 100 μM baicalein by High-Throughput sequencing. Intriguingly, we observed that 20 and 39 miRNAs were accordingly up- and down-regulated through comparing Panc-1 cells exposed to 100 μM baicalein with the control group. Quantitative PCR analysis confirmed that miR-139-3p was the most up-regulated miRNA after baicalein treatment, while miR-196b-5p was the most down-regulated miRNA. Further studies showed that miR-139-3p induced, miR-196b-5p inhibited the apoptosis of Panc-1 cells via targeting NOB1 and ING5 respectively. In conclusion, we demonstrated that baicalein is a potent inhibitor against pancreatic cancer by modulating the expression of miR-139-3p or miR-196b-5p.
In der vorliegenden Arbeit wurde ein integrativer Netzwerkmodellierungsansatz gewählt, um die Rolle des Endothels im Kontext der Arteriosklerose zu untersuchen. Hierbei wurden bioinformatische Analysen, laborexperimentelle Versuche und klinische Daten vereinigt und aus dieser Synthese neue klinisch relevante Gene identifiziert und beschrieben.
Das Endothel trägt maßgeblich zur Homöostase des vaskulären Systems bei und eine Dysfunktion des Endothels fördert die Entstehung der Arteriosklerose. Im Zuge der Atherogenese entstehen vermehrt reaktive Sauerstoffspezies, die Lipide in der Membran von Plasma-Lipoprotein-Partikeln und in der zellulären Plasmamembran oxidieren. Eine Gruppe solcher oxidierter Membranlipide ist oxPAPC, das in erhöhter Konzentration in arteriosklerotischen Plaques und lokal an Orten chronischer Entzündung im vaskulären System vorkommt. Weitherhin findet sich diese Gruppe von oxidierten Phospholipiden in oxidierten LDL-Partikeln, in denen oxPAPC die Bindung an Makrophagen vermittelt und hierdurch maßgeblich zur Bildung der Schaumzellen und damit zum arteriosklerotischen Prozess beiträgt. Die durch oxPAPC verursachte Veränderung der Endothelzelle ist bisher wenig erforscht. Es ist jedoch bekannt, dass oxPAPC die Transkriptionslandschaft in Endothelzellen tiefgreifend verändert. Um der Komplexität der Endothelzellveränderung gerecht zu werden, wurde ein bayesscher Ansatz angewendet.
In einem ersten Schritt wurden Expressionsprofile von humanen Aortenendothelzellen (HAEC) aus 147 Herztransplantatspendern verwendet. Diese Expressionprofile enthalten Transkriptionsinformationen der 147 HAEC, die mit oxPAPC oder Kontrollmedium behandelt worden waren. Es wurden signifikant koexprimierte Gene identifiziert und hiervon Gen-Paare berechnet, die einen differentiellen Vernetzungsgrad zwischen Kontroll- and oxPAPC-Status aufweisen. Dieses Netzwerkmodell gibt darüber Aufschluss, welche Gene miteinander in Verbindung stehen. 26759 Gene-Paare, die differentiell verbunden und signifkant koexprimiert waren, wurden hierarchisch gruppiert. Es wurden neun Gen-Gruppen mit einer erhöhten und elf Gen-Gruppen mit einer verminderten Konnektivität nach oxPAPC identifiziert. Gruppe 6 der erhöhten Konnektvitäts-Gruppen wies hierbei die höchste kohärente Konnektivität von allen Gruppen auf. Eine Analyse signifikant überrepräsentierter kanonischer Gensätze ergab, dass diese Gruppe insbesondere Serin-Glycin-Aminosäuremetabolismus, tRNA- und mTOR-Aktivierung wiederspiegelte. Der hier gewählte Netzwerkmodellierungsansatz zeigte auf, dass der Aminosäuremetabolismus durch oxidizerte Phospholipide massiven Veränderungen unterworfen ist.
Um den Mechanismus der Veränderung des Aminosäuremetabolismus näher zu untersuchen, wurden bayessche Netzwerkmodelle verwendet. Dieses Netzwerkmodell enthält im Gegensatz zum differentiellen Koexpresssionsmodell gerichtete Informationen innerhalb des Netzwerkgraphes. Die Gen-Gen Verbindungen sind kausal, wodurch sich eine Hierarchie bildet und Schlüsselfaktoren innerhalb des Netzwerks bestimmt werden können. Durch die Integrierung von Expressionsprofilen und Genomprofilen derselben HAEC-Kohorte und der Inferenz von kausalen Gen-Gen-Verbindungen ergaben sich zwei bayessche Netze: Kontroll- und oxPAPC-Netzwerk. Permutationsuntersuchungen und systematische Beurteilung im Vergleich zu Gen-Gen-Verbindungen in Online-Datenbanken zeigten eine erhöhte Prognosefähigkeit der beiden HAEC bayesschen Netze. Es wurden die Schlüsselfaktoren und deren Teilnetzwerke berechnet und auf biologische Wege hin untersucht. Hierbei wurde das mitochondriale Protein MTHFD2 als ein Schlüsselfaktor für ein Teilnetzwerk des oxPAPC bayesschen Netzes identifiziert. Dieses Teilnetz zeigte eine ähnliche Gensatzanreicherung wie GOC-AA und überlappte mit diesem signifikant.
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Chemical language models enable de novo drug design without the requirement for explicit molecular construction rules. While such models have been applied to generate novel compounds with desired bioactivity, the actual prioritization and selection of the most promising computational designs remains challenging. Herein, we leveraged the probabilities learnt by chemical language models with the beam search algorithm as a model-intrinsic technique for automated molecule design and scoring. Prospective application of this method yielded novel inverse agonists of retinoic acid receptor-related orphan receptors (RORs). Each design was synthesizable in three reaction steps and presented low-micromolar to nanomolar potency towards RORγ. This model-intrinsic sampling technique eliminates the strict need for external compound scoring functions, thereby further extending the applicability of generative artificial intelligence to data-driven drug discovery.
Ginger (Zingiber officinale Roscoe) is widely used as medicinal plant. According to the Committee on Herbal Medicinal Products (HMPC), dried powdered ginger rhizome can be applied for the prevention of nausea and vomiting in motion sickness (well-established use). Beyond this, a plethora of pre-clinical studies demonstrated anti-cancer, anti-oxidative, or anti-inflammatory actions. 6-Shogaol is formed from 6-gingerol by dehydration and represents one of the main bioactive principles in dried ginger rhizomes. 6-Shogaol is characterized by a Michael acceptor moiety being reactive with nucleophiles. This review intends to compile important findings on the actions of 6-shogaol as an anti-inflammatory compound: in vivo, 6-shogaol inhibited leukocyte infiltration into inflamed tissue accompanied with reduction of edema swelling. In vitro and in vivo, 6-shogaol reduced inflammatory mediator systems such as COX-2 or iNOS, affected NFκB and MAPK signaling, and increased levels of cytoprotective HO-1. Interestingly, certain in vitro studies provided deeper mechanistic insights demonstrating the involvement of PPAR-γ, JNK/Nrf2, p38/HO-1, and NFκB in the anti-inflammatory actions of the compound. Although these studies provide promising evidence that 6-shogaol can be classified as an anti-inflammatory substance, the exact mechanism of action remains to be elucidated. Moreover, conclusive clinical data for anti-inflammatory actions of 6-shogaol are largely lacking.
Um sich an ändernde Umwelteinflüsse und metabolische Bedürfnisse anpassen zu können, ist es für Zellen essenziell, dass Boten-RNA (engl. messenger RNA, mRNA) stetig und schnell nach der Translation abgebaut wird. In Prokaryoten ist dafür der Proteinkomplex Degradosom verantwortlich, in dem Endo- und Exoribonukleasen RNase E und PNPase das RNA-Transkript in kleinere Fragmente und schließlich einzelne Nukleotide spalten. Die DEAD-Box Helikase RhlB im Komplex dient zusätzlich dazu, mögliche Sekundärstrukturen in der RNA zu entfalten, welche sonst die weitere Degradation behindern würden. Es konnte gezeigt werden, dass RhlB’s sehr geringe katalytische Aktivität – gemessen durch ATP-Verbrauch und Rate an entwundener RNA – signifikant durch die allosterische Bindung an Komplexpartner RNase E erhöht wird. Gleichzeitig deuten andere Studien darauf hin, dass RhlB eine mögliche Selektivität für doppelsträngige RNA-Substrate mit 5‘-Einzelstrang-Überhängen aufweist.
Diese Arbeit liefert neue Erkenntnisse in Bezug auf die Kommunikation zwischen den Degradosom-Komponenten RhlB und RNase E aus E. coli, indem das potenzielle Wechselspiel zwischen RhlBs RNA-Selektivität und der allosterischen Aktivierung durch RNase E untersucht wurde. Der vielseitige Einsatz NMR-spektroskopischer Techniken sowie die Verwendung kurzer RNA-Substrate mit spezifischen Strang-Eigenschaften ermöglicht es, mit einen ungewöhnlichen, RNA-zentrierten Ansatz an diese unzureichend verstandene Protein-Interaktion heranzugehen.
Zunächst wurden hierzu eine Reihe kurzer doppelsträngiger RNA-Konstrukte hergestellt, die sich nicht nur in ihren Einzelstrang-Merkmalen unterscheiden, sondern auch die thermodynamischen Anforderungen eines DEAD-Box Helikase Substrats erfüllen, und gleichzeitig eine ausreichende NMR-spektroskopische Signal-Zuordnung erlauben. Die thermale Stabilität, das Faltungsverhalten sowie die 1H Imino-protonen- und 13C HSQC-Zuordnungen aller geeigneten Konstrukte wurden erfolgreich bestimmt.
Um den Einfluss spezifischer RNA-Substrate sowie die Bindung zweier verschiedener RNase E Fragmente auf RhlBs ATP-Umsatzrate zu untersuchen, wurde sich zunächst eines photometrischen Phosphat-Assays bedient. Damit konnte deutlich gezeigt werden, dass RhlB in Abwesenheit des Komplex-Partners nicht in der Lage ist, signifikante Mengen an ATP umzusetzen, unabhängig davon, welches RNA-Konstrukt eingesetzt wird. Die Bindung der RNase E Fragmente erhöhte signifikant die ATP-Hydrolyse-Rate der Helikase, wobei die größte Aktivierung für den RNA-Duplex mit 5‘-Einzelstrang sowie ein einzelsträngiges Substrat zu beobachten ist. Da diese Ergebnisse deutlich eine RNA-Abhängigkeit beim ATP-Umsatz der Helikase zeigen, wurde untersucht, ob diese Unterschiede ihren Ursprung bereits in der Bindung der spezifischen RNA-Substrate haben. Mittels einer Mischapparatur, die es erlaubt die enzymatische Reaktion direkt im Spektrometer zu initiieren sowie zeitaufgelöster 31P NMR-Experimente konnte die allosterische Aktivierung der ATP-Hydrolyse-Rate von RhlB auch unter NMR-spektroskopischen Messbedingungen nachgewiesen werden.
Da die Ergebnisse des ATPase Assays deutlich eine RNA-Abhängigkeit bei der ATP-Umsatz-Rate der Helikase zeigen, wurde zusätzlich untersucht, ob diese Unterschiede ihren Ursprung in den Affinitäten für die verschiedenen RNA-Substrate haben und ob diese durch die Bindung von RNase E and RhlB beeinflusst werden. Um im gleichen Zuge zu überprüfen, ob die Bindung der RNA an RhlB die RNA-Konformation oder Basenpaarung ändert, werden 1H NMR-Titrationsexperimente durchgeführt. Es konnte erstmals gezeigt werden, dass RhlB eine inhärente Präferenz für Duplexe mit 5‘-Überhang gegenüber Konstrukten mit 3‘-Überhang oder stumpfen Enden besitzt, was sich in einer erhöhten Affinität zeigt. Zusätzlich offenbaren die Messungen, dass RNase Es allosterische Bindung selektiv die Affinität gegenüber Konstrukten mit Einzelstrang-Überhang erhöht, während die Affinität zu RNA Duplexen ohne Überhang sogar verringert wird. Diese Ergebnisse liefern erstmals einen Nachweis, dass RNase E aktiv Einfluss auf RhlBs RNA-Bindung nimmt. Weder die Bindung der RNA and RhlB noch an den RhlB/RNase E Komplex scheint die Basenpaarung oder Konformation der RNA-Substrate zu beeinflussen, da lediglich eine homogene Peak-Verbreitung aller Imino-Protonen-Signale im 1H NMR-Spektrum beobachtet werden konnte.
Die membranintegrierten, rotierenden F-Typ ATP-Synthasen zählen zu den essentiellen Komponenten der bakteriellen Energieversorgung. Ihre Rolle im zellulären Energiehaushalt bestehtin der Synthese von ATP unter Nutzung des transmembranen, elektrischen Ionengradienten (Mitchell 1961, Duncan et al. 1995, Noji et al. 1997, Kinosita et al. 1998). Die rotierenden ATP-Synthasen werden entsprechend der Kationenselektivität, die sie unter physiologischen Bedingungen zeigen, in zwei verschiedene Klassen eingeteilt, die H+-selektiven, sowiedie Na+-selektiven ATP-Synthasen. Hierbei bildet die Selektivität beider Klassen für einwertige Kationen (H+ oder Na+) eine essenzielle Grundlage für ihre Rolle im Energiehaushalt der bakteriellen Zellen. Jedoch gibt es nur eine begrenzte Anzahl von anaeroben Eubakterien und Archaeen, die noch einen auf Na+- Ionen basierenden Energiehaushalt besitzen. Gut charakterisierte Beispiele für Na+-selektive ATP-Synthasen bilden die F-Typ-Synthasen von I. tartaricus, P. modestum, sowie die V/A-Typ-Enzyme von E. hirae und A. woodii. Trotz der Unterschiede in der Kationenselektivitätder unterschiedlichen F-Typ ATP-Synthasen sind sie jedoch sowohl inihre Organisation, als auch hinsichtlich ihre Wirkungsweisen ähnlich. Das Ziel, der im Rahmen dieser Arbeit durchgeführten Forschung, bestand in der Identifizierung der Faktoren, die sowohl die hohen Selektivität, als auch die Affinität des in der Membran-eingebetteten Rotor-C-Rings der ATP-Synthasezu Protonen (H+) und Na+- Ionen beeinflussen. Die Untersuchungen wurden hierbei andem c11-Ring der F-Typ-ATP-Synthase aus dem anaeroben Bakterium Ilyobacter tartaricus durchgeführt, das hierbei als Modellsystem diente. Der untersuchte Ring zeigt unter physiologischen Bedingungen eine hohe Bindungsselektivität für Na+ Ionen, kann jedoch unter nicht-physiologischen Bedingungen auch Li+ und H+ Ionen binden und zur ATP-Synthese verwenden (Neumann et al. 1998).
Das Ziel, der im Rahmen dieser Arbeit durchgeführten Forschung, bestand in der Identifizierung der Faktoren, die sowohl die hohen Selektivität, als auch die Affinität des in der Membran-eingebetteten Rotor-C-Rings der ATP-Synthasezu Protonen (H+) und Na+- Ionen beeinflussen. Die Untersuchungen wurden hierbei andem c11-Ring der F-Typ-ATP-Synthase aus dem anaeroben Bakterium Ilyobacter tartaricus durchgeführt, das hierbei als Modellsystem diente. Der untersuchte Ring zeigt unter physiologischen Bedingungen eine hohe Bindungsselektivität für Na+ Ionen, kann jedoch unter nicht-physiologischen Bedingungen auch Li+ und H+ Ionen binden und zur ATP-Synthese verwenden (Neumann et al. 1998). Die Kd- und KM-Werte wurden verwendet, um die Na+ -Bindungsaffinität der C-Ringe bzw. ATP-Synthasen zu quantifizieren. Über die Selektivität wurdebeschrieben, welche Kationen an die C-Ringe und ATP-Synthasen binden können (z. B. H+/Na+/Li+, H+/Na+ - oder nur H+ Ionen).Das Verhältnis der absoluten Bindungsaffinitäten zwischen zwei Kationen (z. B. Kd (Na+)/Kd (H+)) wurde verwendet, um die Präferenz des Enzyms für eines der Ionen zu quantifizieren. Die Faktoren, dieder Kationenselektivität und der Affinität des I. tartaricus c-Rings zugrunde liegen, wurden mit Hilfe von Mutageneseexperimenten der Aminosäuren in der Ionenbindungsstelle untersucht. Im I. tartaricus-c-Ring erfolgt die Na+ Bindung an der Grenzfläche von zwei benachbarten c-Untereinheiten des c-Rings. An der Bindung der Na+-Ionen sind sowohl Aminosäuren aus Helix 1 (Gln32), sowie von Helix 2 (Val63, Ser66, Thr67 und Tyr70) beteiligt, die in der Nähe, des für den Mechanismusessentiellen Glu65 liegen. Insgesamt wurden 19 verschiedene, spezifische Einzel- und Doppelmutationen in die Sequenz des atpE-Gens eingeführt, die für die I. tarticus-ATP-Synthase-c-Untereinheit kodiert. Bei den Experimenten mit dem I. tartaricus c-Ring (Ser66, Thr67 und Tyr70) wurden drei polare Reste der Ionenbindungsstelle durch die polaren Reste (Ser67, Ile67 oder Leu67) oder hydrophobe Reste (Ala66, Gln67 und Phe70) ersetzt, während das geladene Glu65 durch die kürzere, aber immer noch geladene Seitenkette Asp65 ausgetauscht wurde. Zur Charakterisierung der monovalenten Kationenbindung durch die Wildtyp, sowie die mutierten C-Ringe von I.-tartaricus, wurde ein Ansatz verwendet, der biochemische (DCCD-Ionen-Kompetitionsassay) und biophysikalische (ITC) Methoden kombiniert.
Die Daten der in dieser Arbeit durchgeführten Experimente, zeigen, dass c-Ringe selektiv für H+ sind, solange in der Ionenbindungsstelle des c-Rings ein ionisierbarer Glu/Asp-Rest vorhanden ist. Die H+-Bindungsaffinität des c-Rings hängt von der Hydrophobizität der Reste ab, aus der die Ionenbindungsstelle aufgebaut ist.Jedoch ist die Zahl der Faktoren, die die Na+-Selektivität des C-Rings bestimmen, weitaus größer. Von den in dieser Arbeit untersuchten Faktoren war die Zahl der polaren Reste, die Wasserstoffbrücken zu Na+ bilden, die Co-Koordination von Na+ durch strukturell vorhandene Wassermoleküle und die Anwesenheit von negativ geladenen Resten besonders wichtig für die Bindung der Na+-Ionen an den Ring. Die hohe Bindungsaffinität des c-Rings für Na+-Ionen, wird sowohl durch Wechselwirkungen begünstigt die das gebundene Na+-Ion stabilisieren, als auch den gesamten atomaren Aufbau der Ionenbindestelle, der die enthalpiegetriebene Na+-Bindungan den c-Ring begünstigen. Im Rahmen dieser eingehenden Studien konnten zum ersten Mal die thermodynamischen Eigenschaften aufgeklärt werden, die der hohen Na+-Bindungsaffinität des c-Rings zugrunde liegen, sowie der Einfluss von Mutationen auf diese Parameter ermittelt werden. Durch zahlreiche Experimente mit ATP-Synthasen, die mit mutierten c-Ringen zusammengesetzt wurden, sollte eine Verbindung zwischen Veränderungen der H+- und der Na+-Bindungsaffinitäten und Unterschiede im Betrieb der ATP-Synthase aufgeklärt werden. Die wichtigste Schlussfolgerung, die sich aus dieser Arbeit ableiten lässt, ist, besteht darin, dass sich Na+/H+-selektiven ATP-Synthasen durch den Austausch von 1-2 Aminosäureresten innerhalb der rotierenden c-Ring-Ionenbindungsstelle in ausschließlich H+-selektive, vollfunktionelle ATP-Synthasen umwandeln lassen.
The genome of the halophilic archaeon Haloferax volcanii encodes more than 40 one-domain zinc finger µ-proteins. Only one of these, HVO_2753, contains four C(P)XCG motifs, suggesting the presence of two zinc binding pockets (ZBPs). Homologs of HVO_2753 are widespread in many euryarchaeota. An in frame deletion mutant of HVO_2753 grew indistinguishably from the wild-type in several media, but had a severe defect in swarming and in biofilm formation. For further analyses, the protein was produced homologously as well as heterologously in Escherichia coli. HVO_2753 was stable and folded in low salt, in contrast to many other haloarchaeal proteins. Only haloarchaeal HVO_2753 homologs carry a very hydrophilic N terminus, and NMR analysis showed that this region is very flexible and not part of the core structure. Surprisingly, both NMR analysis and a fluorimetric assay revealed that HVO_2753 binds only one zinc ion, despite the presence of two ZBPs. Notably, the analysis of cysteine to alanine mutant proteins by NMR as well by in vivo complementation revealed that all four C(P)XCG motifs are essential for folding and function. The NMR solution structure of the major conformation of HVO_2753 was solved. Unexpectedly, it was revealed that ZBP1 was comprised of C(P)XCG motifs 1 and 3, and ZBP2 was comprised of C(P)XCG motifs 2 and 4. There are several indications that ZBP2 is occupied by zinc, in contrast to ZBP1. To our knowledge, this study represents the first in-depth analysis of a zinc finger µ-protein in all three domains of life.
Glucokinase (GK) is a key enzyme of glucose metabolism in liver and pancreatic beta-cells, and small molecule activators of GK (GKAs) are under evaluation for the treatment of type 2 diabetes. In liver, GK activity is controlled by the GK regulatory protein (GKRP), which forms an inhibitory complex with the enzyme. Here, we performed isothermal titration calorimetry and surface plasmon resonance experiments to characterize GK-GKRP binding and to study the influence that physiological and pharmacological effectors of GK have on the protein-protein interaction. In the presence of fructose-6-phosphate, GK-GKRP complex formation displayed a strong entropic driving force opposed by a large positive enthalpy; a negative change in heat capacity was observed (Kd = 45 nm, DeltaH = 15.6 kcal/mol, TDeltaS = 25.7 kcal/mol, DeltaCp = -354 cal mol(-1) K(-1)). With k(off) = 1.3 x 10(-2) s(-1), the complex dissociated quickly. The thermodynamic profile suggested a largely hydrophobic interaction. In addition, effects of pH and buffer demonstrated the coupled uptake of one proton and indicated an ionic contribution to binding. Glucose decreased the binding affinity between GK and GKRP. This decrease was potentiated by an ATP analogue. Prototypical GKAs of the amino-heteroaryl-amide type bound to GK in a glucose-dependent manner and impaired the association of GK with GKRP. This mechanism might contribute to the antidiabetic effects of GKAs.
Die Zahl der gramnegativen Bakterien auf der WHO-Liste der Antibiotikaresistenzen hat in den letzten Jahrzehnten erheblich zugenommen. Schätzungen zufolge wird die Antibiotikaresistenz bis 2050 tödlicher sein als Krebs. Die äußere Membran gramnegativer Bakterien ist aufgrund ihres wichtigsten Strukturbestandteils, des Lipopolysaccharids (LPS), sehr anpassungsfähig an Umweltveränderungen. Das LPS macht gramnegative Bakterien von Natur aus resistent gegen viele Antibiotika und führt somit zu Antibiotikaresistenz. Der bakterielle ATP-bindende Kassettentransporter (ABC-Transporter) MsbA spielt eine entscheidende Rolle bei der Regulierung der bakteriellen Außenmembran, indem er das Kern-LPS durch ATP-Hydrolyse über die Innenmembran von gramnegativen Bakterien flockt. Darüber hinaus fungiert diese Floppase als Efflux-Pumpe, indem sie Medikamente durch die innere Membran transportiert, was sie zu einem interessanten Ziel für Medikamente macht. Vor kurzem wurden zwei verschiedene Klassen von MsbA-Inhibitoren entdeckt: (1) Tetrahydrobenzothiophene (TBT), die den LPS-Transport aufheben, und (2) Chinolinderivate, die sowohl die ATP-Hydrolyse als auch die LPS-Translokation blockieren. Darüber hinaus hat die Bestimmung der 3D-Struktur von MsbA durch Rontgen- und Kryo-EM mehrere interessante Zustände der Floppase ergeben. Die Kernspinresonanzspektroskopie ist eine hervorragende biophysikalische Methode zur Ergänzung der vorhandenen 3D-Strukturdaten. Insbesondere ermöglicht die Festkörper-NMR die Untersuchung von Membranproteinen in einer nativen Umgebung (z. B. in einer Lipiddoppelschicht). In der Vergangenheit hat unser Labor mithilfe der Festkörper-NMR einige detaillierte Mechanismen von MsbA aufgedeckt. Trotz der zahlreichen Fortschritte bei der Untersuchung der ABC-Transporterprotein-Superfamilie ist der spezifische Prozess der Substrattranslokation von MsbA noch immer unbekannt. Es wird angenommen, dass dieser Translokationsprozess über die Kopplungshelices (CHs) erfolgt, die sich zwischen der Transmembranregion (TMD) und der Nukleotidbindungsdomäne (NBD) befinden. Nukleotid-Bindungsdomäne (NBD). Zu diesem Zweck wird dem Zusammenspiel zwischen der TMD und der NBD über die CHs besondere Aufmerksamkeit gewidmet, mit dem Ziel, den Prozess der Substrattranslokation mithilfe von funktionellen Assays und Festkörper-NMR zu verstehen. Bei letzterem wurden spezifische Reporter in die CHs eingeführt, um Konformationsänderungen in 2D-spektroskopischen Daten zu verfolgen. Darüber hinaus wurde zeitaufgelöste NMR eingesetzt, um die Auswirkungen verschiedener Substrate in der TMD während der ATP-Hydrolyse in der NBD sichtbar zu machen. Die einzigartigen Reporter in den CHs haben Konformationsänderungen in bestimmten katalytischen Zuständen gezeigt. Darüber hinaus scheinen verschiedene Substrate die Kinetik der ATP-Hydrolyse zu beeinflussen. Die Ergebnisse zeigten, dass einige Substrate einen bevorzugten katalytischen Zustand innerhalb des ATP-Hydrolyse Zyklus aufweisen, der möglicherweise einen gekoppelten oder ungekoppelten Kinasemechanismus hat. Diese Ergebnisse könnten verschiedene Einblicke in die molekulare Struktur potenzieller neuer Antibiotika liefern.
RNA research is very important since RNA molecules are involved in various gene regulatory mechanisms as well as pathways of cell physiology and disease development.1 RNAs have evolved from being considered as carriers of genetic information from DNA to proteins, with the three major types of RNA involved in protein synthesis, including messenger RNA (mRNA), transfer RNA (tRNA), and ribosomal RNA (rRNA).2 In addition to the RNAs involved in protein synthesis numerous regulatory non-coding RNAs (ncRNAs) have been discovered in the transcriptome. The regulatory ncRNAs are classified into small ncRNAs (sncRNAs) with transcripts less than 200 nucleotides (nt) and long non-coding RNAs (lncRNAs) with more than 200 nt.3
LncRNAs represent the most diverse and versatile class of ncRNAs that can regulate cellular functions of chromatin modification, transcription, and post-transcription through multiple mechanisms.4 They are involved in the formation of RNA:protein, RNA:RNA and RNA:DNA complexes as part of their gene regulatory mechanism.4,5 The RNA:DNA interactions can be divided into RNA:DNA heteroduplex formation, also called R-loops, and RNA:DNA:DNA triplex formation. In triplex formation, RNA binds to the major groove of double-stranded DNA through Hoogsteen or reverse Hoogsteen hydrogen bonding, resulting in parallel or anti-parallel triplexes, respectively. In vitro studies have confirmed the formation of RNA:DNA:DNA triplexes.6 However, the extent to which these interactions occur in cells and their effects on cellular function are still not understood, which is why these structures are so exciting to study (Chapter I RNA:DNA:DNA Triplexes).
This cumulative thesis investigates several functional and regulatory important RNAs. The first project involves the improved biochemical and biophysical characterization of RNA:DNA:DNA triplex formation between lncRNAs of interest and their target genes. Triplex formation was confirmed by a series of experiments including electromobility shift assays (EMSA), thermal melting assays, circular dichroism (CD), and liquid state nuclear magnetic resonance (NMR) spectroscopy. The following is a summary of the main findings of these publications.
In research article 5.1, the oxygen-sensitive HIF1α-AS1 was identified as a functionally important triplex-forming lncRNA in human endothelial cells using a combination of bioinformatics techniques, RNA/DNA pulldown, and biophysical experiments. Through RNA:DNA:DNA triplex formation, endogenous HIF1α-AS1 decreases the expression of several genes, including EPH receptor A2 (EPHA2) and adrenomedullin (ADM), by acting as an adaptor for the repressive human silencing hub (HUSH) complex, which has been studied by our collaborators in the groups of Leisegang and Brandes.
2) Triplex formation between HIF1α-AS1 and the target genes EPHA2 and ADM was investigated in biochemical and biophysical studies. The EMSA results indicated that HIF1α-AS1 forms a low mobility RNA:DNA:DNA triplex complex with the EPHA2 DNA target sequence. The CD spectrum of the triplex showed distinct features compared to the EPHA2 DNA duplex and the RNA:DNA heteroduplex. Melting curve analysis revealed a biphasic melting transition for triplexes, with a first melting point corresponding to the dissociation of the RNA strand with melting of the Hoogsteen hydrogen bonds. The second, higher melting temperature corresponds to the melting of stronger Watson-Crick base pairing. Stabilized triplexes were formed using an intramolecular EPHA2 DNA duplex hairpin construct in which both DNA strands were attached to a 5 nucleotide (nt) thymidine linker. This approach allowed improved triplex formation with lower RNA equivalents and higher melting temperatures. By NMR spectroscopy, the triplex characteristic signals were observed in the 1H NMR spectrum, the imino signals in a spectral region between 9 and 12 ppm resulting from the Hoogsteen base pairing. To elucidate the structural and sequence specific Hoogsteen base pairs 2D 1H,1H-NOESY measurements of the EPHA2 DNA duplex and the HIF1α-AS1:EPHA2 triplex were performed. The 1H,1H-NOESY spectrum of the HIF1α-AS1:EPHA2 triplex with a 10-fold excess of RNA was semi-quantitatively analyzed for changes in the DNA duplex spectrum. We discovered, strong and moderate attenuation of cross peak intensities in the imino region of the NOESY spectrum. This attenuation was proposed to result from weakening of Watson-Crick base pairing by Hoogsteen hydrogen bonding induced by RNA binding. The Hoogsteen interactions can be mapped based on the analysis of the cross peak attenuation in the NOESY spectra, which we used to generate a structural model of the RNA:DNA:DNA triplex. These biophysical results support the physiological function of HIF1α as a triplex-forming lncRNA that recruits the HUSH-epigenetic silencing complex to specific target genes such as EPHA2 and ADM, thereby silencing their gene expression through RNA:DNA:DNA triplex formation.
Bleaching-independent, whole-cell, 3D and multi-color STED imaging with exchangeable fluorophores
(2018)
We demonstrate bleaching-independent STED microscopy using fluorogenic labels that reversibly bind to their target structure. A constant exchange of labels guarantees the removal of photobleached fluorophores and their replacement by intact fluorophores, thereby circumventing bleaching-related limitations of STED super-resolution imaging in fixed and living cells. Foremost, we achieve a constant labeling density and demonstrate a fluorescence signal for long and theoretically unlimited acquisition times. Using this concept, we demonstrate whole-cell, 3D, multi-color and live cell STED microscopy with up to 100 min acquisition time.
The introduction of a trigonal boron atom into a polyaromatic hydrocarbon (PAH) core is an extremely powerful tool to provide organic scaffolds with optoelectronic properties as well as optimal packing in the solid state. However, boron-doped PAHs (B-PAHs) often display low processability due to their poor solubility. The distortion of the molecular scaffold provides a suitable strategy to enhance the solubility properties of B-PAHs while maintaining good stacking properties and sufficient electronic conjugation.
Extreme distortion of the molecular structure can be achieved in helical-shaped PAHs, namely helicenes which are screw-shaped inherently chiral polycycles, formed by ortho-fused aromatic or heteroaromatic rings. The presence of a helical structure in B-PAHs is expected to strongly influence their physico-chemical properties leading to compounds characterized by peculiar features promising for applications in next generation functional materials. Despite the great potential of this class of compounds, only few examples of borahelicenes have been reported in the literature and those mainly consist of carbohelicene-based structures. However, the considerable structural diversity achievable by introducing different boraheterocycles (oxaborine, borole, borepin) and other heteroaromatic rings (thiophene, furan, pyrrole) into the same helical scaffold, suggests that a large variety of compounds with intriguing features could be accessible via currently unexplored synthetic routes. The design, synthesis, and properties investigation of new boraheterohelicenes (BHHs) is therefore a relevant research topic and is the object of this PhD project, aimed to obtain several BHHs with structural diversity, as well as to study their reactivity, electrochemical and photophysical features for better understanding their potential as building blocks for material science.
The thesis work was carried out in part at the University of Milan in the laboratories of Prof. Emanuela Licandro and in part at the Goethe Universität Frankfurt am Main under the supervision of Prof. Dr. Matthias Wagner, within a co-tutelle programme. Owing to the long-standing expertise of Prof. Licandro group in the synthesis of tetrathia helicenes and that of Prof. Dr. Wagner group in the synthesis of boron-doped PAHs (e.g. boron helicene 4BH; Figure 1), I conceived this PhD project designing a series of thiahelicenes containing one or more B-O bond into the helical scaffold.Tetrathia helicenes, consisting of thiophene and benzene rings fused in an alternating fashion, are configurationally stable heterohelicenes which exist as pair of enantiomers.
This class of molecules is particularly interesting since it merges the properties of oligothiophenes with those of helicenes, giving rise to systems with peculiar electronic and chiroptical properties which make them appealing building blocks for applications in manifold fields of science, including optoelectronics, catalysis and biology.
The introduction of trigonal boron atom into a thiahelicene scaffold gives rise to a novel class of unexplored boron π-conjugated molecules with potentially interesting features.
The present Ph.D. thesis was therefore intended to provide a meaningful contribution in the development of innovative and versatile syntheses of BO-doped tetrathia helicenes as well as the study of their stereochemical and optoelectronic properties to identify potential applications of these systems in material science. The first selected structures containing one or two oxaborine rings in the helical scaffold are shown in figure 2. The presence of the bulky mesityl group at the boron atom is necessary to ensure stability to the molecule.
It is noteworthy that compound 2 is the skeletal isomer of 1, as the direction of the B-O bond is opposite in the two molecules. In the course of the research work, after the evaluation of the photophysical properties of 1, helicene 2 was designed to get information on the structure-property relationship and evaluate how the position of the BO-bond into the helical scaffold can influence the electronic properties of BO-doped thiahelicenes.
Today, the term buchu refers to the two species in commerce, Agathosma betulina (P.J.Bergius) Pillans and Agathosma crenulata (L.) Pillans (Rutaceae). Its traditional use in urinary tract infections and related ailments made it a popular remedy, specifically in the US, in 19th century, but with the advent of antibiotics it became largely obsolete. Recent focus is on technological use and on the essential oil for use in the perfume and food-flavouring industry. A review of the scarce pharmacological research revealed moderate antimicrobial activity for a leaf extract but not the essential oil of both species in the MIC assay. In the 5-lipoxygenase (5-LO) assay the essential oil of both species revealed IC50 values of 50.37 ± 1.87 μg/ml and 59.15 ± 7.44 μg/ml, respectively. In another study 98% inhibitory activity was determined for 250 μg/ml of an ethanolic extract of A. betulina on cyclooxygenase (COX)-1 and a 25% inhibitory activity on COX-2. Analgesic activity of an ethanolic extract of A. betulina was shown in mice. Moderate antioxidant activity was determined for methanol:dichlormethane extracts of A. betulina and A. crenulata and an aqueous extract of A. betulina showed a Trolox equivalent antioxidant capacity (TEAC) of 11.8 µM Trolox. Recent in vitro studies with a commercial aqueous extract of buchu revealed increased uptake of glucose added to 3T3-L1 cell line, significant inhibition of the respiratory burst of neutrophils and monocytes, reduction in the expression of adhesion molecules and inhibition of the release of IL-6 and TNF-α. In diabetic rats the ingestion of aqueous buchu extract completely normalized the glucose level and in rats receiving a high fat diet the consumption of aqueous buchu extract resulted in less weight gain and less intraperitoneal fat gain as well as reduction of elevated blood pressure to normal associated with cardioprotective effects. Limitations in the hitherto conducted research lie in the undisclosed composition of the buchu extracts used and the difficulty in extrapolating data from animal studies to humans. Health claims for buchu products need to be substantiated by randomized, double-blind and placebo-controlled studies. Only then can they be promoted for their true therapeutic potential.
The exhaustive trichlorosilylation of hexachloro-1,3-butadiene was achieved in one step by using a mixture of Si2Cl6 and [nBu4N]Cl (7:2 equiv) as the silylation reagent. The corresponding butadiene dianion salt [nBu4N]2[1] was isolated in 36 % yield after recrystallization. The negative charges of [1]2− are mainly delocalized across its two carbanionic (Cl3Si)2C termini (α-effect of silicon) such that the central bond possesses largely C=C double-bond character. Upon treatment with 4 equiv of HCl, [1]2− is converted into neutral 1,2,3,4-tetrakis(trichlorosilyl)but-2-ene, 3. The Cl− acceptor AlCl3, induces a twofold ring-closure reaction of [1]2− to form a six-membered bicycle 4 in which two silacyclobutene rings are fused along a shared C=C double bond (84 %). Compound 4, which was structurally characterized by X-ray crystallography, undergoes partial ring opening to a monocyclic silacyclobutene 2 in the presence of HCl, but is thermally stable up to at least 180 °C.
The intriguing (μ-hydrido)diboranes(4) with their prominent pristine representative [B2H5]− have mainly been studied theoretically. We now describe the behavior of the planarized tetraaryl (μ-hydrido)diborane(4) anion [1H]− in cycloaddition reactions with the homologous series of heterocumulenes CO2, iPrNCO, and iPrNCNiPr. We show that a C=O bond of CO2 selectively activates the B−B bond of [1H]−, while the μ-H ligand is left untouched ([2H]−). The carbodiimide iPrNCNiPr, in contrast, neglects the B−B bond and rather adds the B-bonded H− ion to its central C atom to generate a formamidinate bridge across the B2 pair ([3]−). As a hybrid, the isocyanate iPrNCO combines the reactivity patterns of both its congeners and gives two products: one of them ([4H]−) is related to [2H]−, the other ([5]−) is an analog of [3]−. We finally propose a mechanistic scenario that rationalizes the individual reaction outcomes and combines them to a coherent picture of B–B vs. B–H bond activation.
Supersaturating formulations are widely used to improve the oral bioavailability of poorly soluble drugs. However, supersaturated solutions are thermodynamically unstable and such formulations often must include a precipitation inhibitor (PI) to sustain the increased concentrations to ensure that sufficient absorption will take place from the gastrointestinal tract. Recent advances in understanding the importance of drug-polymer interaction for successful precipitation inhibition have been encouraging. However, there still exists a gap in how this newfound understanding can be applied to improve the efficiency of PI screening and selection, which is still largely carried out with trial and error-based approaches. The aim of this study was to demonstrate how drug-polymer mixing enthalpy, calculated with the Conductor like Screening Model for Real Solvents (COSMO-RS), can be used as a parameter to select the most efficient precipitation inhibitors, and thus realise the most successful supersaturating formulations. This approach was tested for three different Biopharmaceutical Classification System (BCS) II compounds: dipyridamole, fenofibrate and glibenclamide, formulated with the supersaturating formulation, mesoporous silica. For all three compounds, precipitation was evident in mesoporous silica formulations without a precipitation inhibitor. Of the nine precipitation inhibitors studied, there was a strong positive correlation between the drug-polymer mixing enthalpy and the overall formulation performance, as measured by the area under the concentration-time curve in in vitro dissolution experiments. The data suggest that a rank-order based approach using calculated drug-polymer mixing enthalpy can be reliably used to select precipitation inhibitors for a more focused screening. Such an approach improves efficiency of precipitation inhibitor selection, whilst also improving the likelihood that the most optimal formulation will be realised.
Metastatic rhabdomyosarcoma (RMS) is one of the most challenging tumor entities in pediatric oncology caused by treatment resistances and immune escape. Novel chimeric antigen receptor (CAR) immunotherapies as specific, effective and safe treatment provide antitumor cytotoxicity by soluble factors and ligands/receptor signals. Besides its intrinsic potential as innate immune cell the ErbB2-sprecific CAR-engineered natural killer (NK)-92 cell line NK-92/5.28.z also provides CAR-mediated cytotoxicity, resulting in a high lytic capacity against 2D and 3D RMS cell structures in vitro. Also in a xenograft model using immune deficient NOD/Scid/IL2Rγ-/- (NSG) mice inhibited NK-92/5.28.z the tumor growth as long as the cells were administered and therefore prolonged the survival of the animals. The NK-92/5.28.z were distributed by the blood circulation and subsequently infiltrated the tumor tissue. Due to the malignant origin of the NK-92 cell line the cells must be irradiated prior to the use in patients. While the irradiation hampered the proliferation of NK-92/5.28.z cells, the cytotoxicity against RMS cells in vitro is retained for at least 24 hours. In the xenograft model irradiated NK-92/5.28.z cells inhibited the tumor growth but to a lower extent than untreated cells, as irradiated cells have only a limited life span in vivo no durable persistence and remission was achieved. Therefore, combinatorial approaches were focused and while blocking of the PD-1/PD-L1 axis did not resulted in a significantly enhanced tumor cell lysis, the combinatorial treatment with proteasome inhibitor bortezomib exhibited a significant enhanced cytotoxicity against RMS cells at least in vitro. Bortezomib itself induces caspase mediated apoptosis and also the upregulates the expression of TRAIL receptor DR5. The corresponding ligand TRAIL is expressed on the surface of the NK-92/5.28.z and pursuing experiments with purified TRAIL and bortezomib revealed a synergism. NK-92/5.28.z as an off-the-shelf product is therefore feasible for the therapy of metastatic RMS, but it might be necessary to support the cytotoxicity by additive agents like proteasome inhibitor bortezomib to archive durable remission.
Another cell population suitable for RMS CAR-immunotherapy are cytokine induced killer (CIK) cells, a heterogenous cell population generated from autologous PBMCs consisting of T, NK and T-NK cells. Lentivirally transduced ErbB2-specific CAR-CIK cells were previously shown to inhibit the tumor engraftment in a RMS xenograft model. However, lentiviral transduced adoptive immunotherapies bear risks for the transfer in patients, therefore the Sleeping Beauty Transposon System (SBTS) as a non-viral method, which integrates the CAR coding DNA by a cut-and-paste mechanism from a minicircle (MC) into the CIK cells genome is more feasible for the generation of CAR-CIK cells. The Sleeping beauty transposase mRNA and the MC were transferred in the cell by nucleofection, different factors influence the transfection efficiency and viability of the CIK cells in this harsh procedure. In preliminary experiments with MC Venus, a MC encoding eGFP, the highest transfection efficiency with the best proliferative capacity was achieved with cells on day 3 of CIK culture and without the addition of autologous monocytes as feeder cells. For the CAR construct the protocol was further improved by adjusting crucial factors, for this construct the best results were achieved on day 0, without irradiated PBMCs as feeder cells and cultivation in X-Vivo10 medium supplemented with human fresh frozen plasma. The X-Vivo10 medium enhanced the percentage of NK- and T-NK cells significantly compared to CAR-CIK cells cultured in RPMI. Since the gene transfer by SBTS resulted in CAR-CIK cells stably expressing a CAR in all subpopulations, resulting in a significantly enhanced cytotoxicity against RMS cells in vitro, these cells were compared to lentiviral transduced CAR-CIK cells in vitro and in vivo. While the SBTS CAR-CIK cells were superior to viral CAR-CIK cells in 2D short-term assays, the viral cells showed higher lytic capacity in 3D spheroid long-term assays. In a RMS xenograft model lentiviral CAR-CIK cells significantly prolonged the survival of mice and persisted, whereas SBTS CAR-CIKs did not favor the overall survival compared to untreated controls and also did not persist. Phenotypic analysis revealed a highly cytotoxic CD8+ and late effector memory dominant phenotype for SBTS CAR-CIK cells supporting short-term cytotoxicity but also more prone for exhaustion, while viral CAR-CIK cells showed a more balanced phenotype for memory and cytotoxicity. Therefore, the SBTS is feasible for the ErbB2-CAR gene transfer in CAR-CIK resulting in a stable CAR-expression with high short-term cytotoxicity, but these cells are also more prone to exhaustion and the protocol might be adapted further to prevent this limitation for in vivo application.
This work underlines the hard-to-treat characteristics of metastatic RMS, but also shows some approaches for further evaluation like the combination of NK-92/5.28.z cells with bortezomib and the feasibility of the generation of CAR-CIK cells via SBTS.
MKK7 (MEK7) is a key regulator of the JNK stress signaling pathway and targeting MKK7 has been proposed as a chemotherapeutic strategy. Detailed understanding of the MKK7 structure and factors that impact its activity is therefore of critical importance. Here, we present a comprehensive set of MKK7 crystal structures revealing insights into catalytic domain plasticity and the role of the N-terminal regulatory helix, conserved in all MAP2Ks, mediating kinase activation. Crystal structures harboring this regulatory helix revealed typical structural features of active kinase, providing exclusively a first model of the MAP2K active state. A small molecule screening campaign yielded multiple scaffolds, including type-II irreversible inhibitors a binding mode that has not been reported previously. We also observed an unprecedented allosteric pocket located in the N-terminal lobe for the approved drug ibrutinib. Collectively, our structural and functional data expand and provide alternative targeting strategies for this important MAP2K kinase.
Food allergies are defined as an adverse health effect arising from a specific immune response that occurs reproducibly on exposure to a given food. The prevalence of food allergies has increased in the past decade. Epidemiologic studies involving controlled food challenges for the diagnosis of food allergies indicated that between 1 % to 10.8 % of the population have immunemediated non-toxic food hypersensitivity.
Despite the increasing prevalence, no curative treatment has been established for food allergies so far except the complete avoidance of the elicited food. To establish safe and effective immunotherapy for food allergies, it is of crucially importance to elucidate pathological mechanism of such diseases.
Food allergies are classified into IgE-mediated and non-IgE mediated (T-cell mediated) allergies, depending on the immunologic pathways and the role of the IgE on the pathogenesis of the disease. Allergic enteritis (AE) is a gastrointestinal form of food allergy. It is classified as non-IgE-mediated food allergy. However, patients with AE often develop IgE and high levels of IgE have been associated with development of persistent AE. The gastrointestinal symptoms of AE are nonspecific, resulting in the fact that a broad differential diagnoses including diagnostic approaches for allergic diseases are necessary to rule out other gastrointestinal pathologies. Biopsies of patients with allergic enteritis have shown infiltration of inflammatory cells (e.g. mast cells, eosinophils, neutrophils, and T cells) in the lamina propria, disruption of intestinal villi, edema, and presence of goblet cells in the intestine...
G-protein coupled receptors (GPCRs) are a predominant class of cell-surface receptors in eukaryotic life. They are responsible for the perception of a broad range of ligands and involved in a multitude of physiological functions. GPCRs are therefore of crucial interest for biological and pharmaceutical research. Molecular analysis and functional characterisation of GPCRs is frequently hampered by challenges in efficient large-scale production, non-destructive purification and long-term stability. Cell-free protein synthesis (CFPS) provides new production platforms for GPCRs by extracting the protein synthesis machinery of the cell in an open system that allows target-oriented modulations of the synthesis process and direct access to the nascent polypeptide chain. CFPS is fast, reliable and highly adaptable. Unfortunately, highly productive cell-free synthesis of GPCRs is often opposed by low product quality. This thesis was aimed to adapt and improve some of the new possibilities for the cell-free production of GPCRs in high yield and quality for structural and pharmaceutical analysis. An E. coli based CFPS system was applied to synthesise various turkey and human Beta-adrenergic receptor (Beta1AR) derivatives as well as human Endothelin receptors type A and B (ETA and ETB) constructs. Both receptor families are important drug targets and pharmacologically addressed in the treatment of several cardiovascular diseases. CF-synthesis was mainly performed in presence of nanodiscs (ND), which are reconstituted high density lipoprotein particles forming discoidal bilayer patches with a diameter varyring from 6 to approx. 15 nm. The supplementation of ND in the CF-synthesis reaction caused the co-translational solubilisation of the freshly synthesised GPCRs. The fraction of the solubilised GPCR that was correctly folded was analysed by the competence to bind its ligand alprenolol or Endothelin-1, respectively. Both the solubilisation efficiency and the ability to fold in a ligand binding competent state was strongly affected by the lipid composition of the supplied ND. Best results were generally achieved with lipids having phosphoglycerol headgroups and unsaturated fatty acid chains with 18 carbon atoms. Furthermore, thermostabilisation by introduction of point mutations had a large positive impact on the folding efficiency of both Beta1AR and ETB receptor. Formation of a conserved disulphide bridge in the extracellular region was additionally found to be crucial for the function of the ETB receptor. Disulphide bridge formation could be enhanced by applying a glutathione-based redox system in the CFPS. Further improvements in the quality of ETB receptor could be made by the enrichment of heat-shock chaperones in the CF-reaction. Depending on the receptor type and DNA-template, roughly 10 – 30 nmol (350 – 1500 µg) of protein could be synthesised in 1 ml of CF-reaction mixture. After the applied optimisation steps, the fractions of correctly folded receptor could be improved by several orders of magnitude and were finally in between 35% for the thermostabilised turkey Beta1AR, 9% for the thermostabilised ETB receptor, 6.5% for the non-stabilised ETB receptor, 1 - 5% for non-stabilised turkey Beta1AR and for human Beta1AR isoforms and 0.1% for ETA receptor. Therefore, between 2 and 120 µg of GPCR could be synthesised in a ligand binding competent form, depending on the receptor and its modifications. Correctly folded turkey Beta1AR and ETB receptors were thermostable at 30°C and could be stored at 4°C for several weeks after purification. Yields of the thermostabilised turkey Beta1AR were sufficient to purify the receptor in a two-step process by ligand-binding chromatography to obtain pure and correctly folded receptor in the lipid bilayer of a ND. Furthermore, a lipid dependent ligand screen could be demonstrated with the turkey Beta1AR and significant alterations in binding affinities to currently in-use pharmaceuticals were found. The established protocols are therefore suitable and highly competetive for a variety of applications such as screening of GPCR ligands, analysis of lipid effects on GPCR function or for the systematical biochemical characterisation of GPCRs. Most promising for future approaches appears to address the suspected bottlenecks of intial insertion of the GPCR-polypeptide chain in the ND bilayer and the thermal stability of the receptors. Nevertheless, the estabilised protocols for the analysed targets in this thesis are already highly competitive to previously published production protocols either in cell-based or cell-free systems with regard to yield of functional protein, speediness and costs. Moreover, the direct accessibility and other general characteristics of cell-free synthesis open a large variety of possible applications and this work can therefore contribute to the molecular characterisation of this important receptor type and to the development of new pharmaceuticals.
Cell-free-synthesized voltage-gated proton channels: Approaches to the study of protein dynamics
(2018)
We often only realize how important health is when diseases manifest themselves through their symptoms and, ultimately, in a diagnosis. Over time, we suffer from many diseases starting with the first childhood disease to colds to gastrointestinal infections. Most diseases pass harmlessly and symptoms fade away. However, not all diseases are so harmless. Alzheimer’s disease, breast cancer, Parkinson’s disease, and colorectal cancer usually cause severe illness with high mortality rates. In pharmaceutical research, efforts are therefore being made to determine the molecular basis of them in order to provide patients with potential relief and, at best, healing. A special group of regulators, involved in the previously mentioned diseases, are voltage-gated proton channels. Thus, the understanding of their structure, function, and potential drug interaction is of great importance for humanity.
Voltage-gated proton channels are localized in the cell membrane. As their name indicates, they are controlled by voltage changes. Depolarization of the cell membrane induces conformational changes that open these channels allowing protons to pass through. Here, the transfer is based on a passive process driven by a concentration gradient between two individual compartments separated by the cell membrane. Voltage-gated proton channels are highly selective for protons and show a temperature- and pH-dependent gating behavior. However, little is known about their channeling mechanism. Previous experimental results are insufficient for understanding the key features of proton channeling.
In this thesis, for the first time, the cell-free production of voltage-sensing domains (VSD) of human voltage-gated proton channels (hHV1) and zebrafish voltage-sensing phosphatases (DrVSP) is described. Utilizing the cell free approach, parameters concerning protein stability, folding and labeling can be easily addressed. Furthermore, the provision of a membrane mimetic in form of detergent micelles, nanodiscs, or liposomes for co-translational incorporations of these membrane proteins is simple and efficient. Both VSDs were successfully produced up to 3 mg/ml. Furthermore, the cell-free synthesis enabled for the first time studies of lipid-dependent co-translational VSD insertions into nanodiscs and liposomes. Cell-free produced VSDs were shown to be active, and to exist mainly as dimers. In addition, also their activation was stated to be lipid-dependent, which has not been described so far. Solution-state NMR experiments were performed with fully and selectively labeled cell-free produced VSDs. With respect to the development of potential drug candidates, I could demonstrate the inhibition of the VSDs by 2-guanidinobenzimidazole (2GBI). Determined KD values were comparable to literature data for the human construct. For the first time, a low affinity for 2GBI of the zebrafish VSD could be described.
In future, the combination of a fast, easy and cheap cell-free production of fully or selectively labeled VSDs and their analysis by solution state NMR will enable structure determinations as well as inhibitor binding studies and protein dynamic investigations of those proteins. The results of these investigations will serve as a basis for example for the development of new drugs. In addition, a detailed description of the lipid-dependent activity might be helpful in controlling the function of voltage-gated proton channels in cancer cells and thereby reducing their growth or disturbing their cell homeostasis in general.
Protein kinases are key signalling molecules and transduce intracellular signals via the post-translational phosphorylation of substrate proteins, often other protein kinases. Dysregulation of this protein family has been linked to many diseases including neurodegenerative diseases, inflammation and cancer and amplifications of kinases play important roles as diagnostic biomarkers in a variety of cancers. Various strategies have been developed to treat dysregulated protein kinases. Most commonly, chemical small molecule inhibitors are used to modulate protein kinase activity in cancer cells. Many inhibitor and general research efforts have focused only on a small subset of protein kinases, resulting in a large portion of the kinome, the so-called “dark” kinome, remaining largely unexplored. As part of the strategy to develop inhibitors, it is crucial to understand the structure-activity-relationships (SAR) of small molecules to the activity towards the targets based on understanding small molecule-target affinities as determined by biophysical, biochemical, and cellular methods. However, not always do in vitro determined affinities, which are frequently used as basis for SAR considerations, correlate with the cellular affinity. For protein kinases in particular, it has been shown that the cellular concentration of the natural substrate adenosine-triphosphate (ATP) plays a critical role for the resulting small molecule affinity, as substrate and inhibitor frequently compete for the same binding site of the protein kinase. The cellular target engagement assay NanoBRET is a versatile assay that overcomes this problem and can be used to assess binding of a compound to the full-length protein kinase, in the presence of natural binding partners. Another important factor in inhibitor optimization is the selectivity of the molecule within the family of protein kinases. When comparing the selectivity profiles of small molecule kinase inhibitors in vitro and in cells, different profiles can be observed. Frequently, a compound, binds fewer protein kinases with high affinity in cells, indicating that cellular profiling of protein kinase inhibitors is necessary to understand the selectivity profile of an inhibitor.
The goal of this work was to understand cellular SARs of inhibitors for kinases and dark kinases in medicinal chemistry projects, and to understand the selectivity profiles of existing small molecules in cells, including already approved drugs and clinically used kinases inhibitors. The cellular potency and selectivity aspects guided optimization of the inhibitors towards selective small molecules ‘chemical probes’ or highly validated inhibitors with a narrow selectivity profile as part of ‘chemogenomic libraries’. One strategy to improve selectivity has been to use sterically restricted cyclic small molecules, called macrocycles, that allow fewer conformations of the molecule than their non-cyclic parent compound. In this thesis the dark kinase STK17A was investigated. Macrocyclization was used to develop a selective chemical probe molecule that is also selective in the cellular context. For another kinase, SIK2, a rational design approach was used to exclude off-targets bound by the lead structure, resulting in a chemical probe that selectively targets the SIK1/2/3 proteins. Assessing cellular potency of another series of inhibitors, a probe was developed for the PCTAIRE subfamily of the CDK kinases. This required co-expression of the binding partners of CDKs, the cyclins, in cells to obtain a functional assay. To identify new candidates for the neglected family of splicing kinases comprising the CLK, SRPK, DYRK and HIPK protein kinase subfamilies, a literature review was conducted, and the best small molecule candidates were compared for their target engagement in cells. This led to a series of small molecule inhibitors that may be used as a set or single agents to target the CLK proteins and SRPK proteins or in combination to target the remaining proteins. In search of new starting points for this subfamily of kinases, an initial screen with NanoBRET technology was performed using a library of over 2000 inhibitors, and new starting points were identified. Additionally, a set of clinical and approved small molecule kinase inhibitors was assessed for their selectivity in cells. Several highly selective molecules were identified that were much less selective in in vitro approaches. The set of data allowed for a comprehensive comparison of cellular potencies with published data using in vitro binding, in vitro activity and data obtained from cell lysates and identified several protein kinases that would need to be investigated in cells...
Central cholinergic function and metabolic changes in streptozotocin‐induced rat brain injury
(2020)
As glucose hypometabolism in the brain is an early sign of Alzheimer´s dementia (AD), the diabetogenic drug streptozotocin (STZ) has been used to induce Alzheimer‐like pathology in rat brain by intracereboventricular injection (icv‐STZ). However, many details of the pathological mechanism of STZ in this AD model remain unclear. Here, we report metabolic and cholinergic effects of icv‐STZ using microdialysis in freely moving animals. We found that icv‐STZ at a dose of 3 mg/kg (2 × 1.5 mg/kg) causes overt toxicity reflected in body weight loss. Three weeks after STZ administration, histological examination revealed a high number of glial fibrillary acidic protein reactive cells in the hippocampus, accompanied by Fluoro‐Jade C‐positive cells in the CA1 region. Glucose and lactate levels in microdialysates were unchanged, but mitochondrial respiration measured ex vivo was reduced by 9%–15%. High‐affinity choline uptake, choline acetyltransferase, and acetylcholine esterase (AChE) activities in the hippocampus were reduced by 16%, 28%, and 30%, respectively. Importantly, extracellular acetylcholine (ACh) levels in the hippocampus were unchanged and responded to behavioral and pharmacological challenges. In comparison, extracellular ACh levels and cholinergic parameters in the striatum were unchanged or slightly increased. We conclude that the icv‐STZ model poorly reflects central cholinergic dysfunction, an important characteristic of dementia. The icv‐STZ model may be more aptly described as an animal model of hippocampal gliosis.
Cyclic GMP (cGMP) is a second messenger that regulates numerous physiological and pathophysiological processes. In recent years, more and more studies have uncovered multiple roles of cGMP signalling pathways in the somatosensory system. Accumulating evidence suggests that cGMP regulates different cellular processes from embryonic development through to adulthood. During embryonic development, a cGMP-dependent signalling cascade in the trunk sensory system is essential for axon bifurcation, a specific form of branching of somatosensory axons. In adulthood, various cGMP signalling pathways in distinct cell populations of sensory neurons and dorsal horn neurons in the spinal cord play an important role in the processing of pain and itch. Some of the involved enzymes might serve as a target for future therapies. In this review, we summarise the knowledge regarding cGMP-dependent signalling pathways in dorsal root ganglia and the spinal cord during embryonic development and adulthood, and the potential of targeting these pathways.
LINKED ARTICLES
This article is part of a themed issue on cGMP Signalling in Cell Growth and Survival. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v179.11/issuetoc
Despite all advances in drug delivery, the limitations of the analytical technologies involved in the characterization of next-generation nanomedicines are still impeding further progress of an emerging market. Discriminating between different formulations and batches, drug release is one of the most important quality criteria in development and quality control of pharmaceutics. Unfortunately, there are only few methods available to sensitively measure this important parameter for nanosized carriers. With the development of the dispersion releaser (DR) technology our group has set up a dialysis-based technique that was tested with a number of nanocarrier and nanocrystal formulations such as liposomes and polymeric nanoparticles. By supporting formulation development with a more reliable methodology to assess the drug release from nanosized carriers, a first step has been made to improve future products.
Gram-negative Tripartite Resistance Nodulation and cell Division (RND) superfamily efflux pumps confer various functions, including multidrug and bile salt resistance, quorum-sensing, virulence and can influence the rate of mutations on the chromosome. Multidrug RND efflux systems are often characterized by a wide substrate specificity. Similarly to many other RND efflux pump systems, AcrAD-TolC confers resistance toward SDS, novobiocin and deoxycholate. In contrast to the other pumps, however, it in addition confers resistance against aminoglycosides and dianionic β-lactams, such as sulbenicillin, aztreonam and carbenicillin. Here, we could show that AcrD from Salmonella typhimurium confers resistance toward several hitherto unreported AcrD substrates such as temocillin, dicloxacillin, cefazolin and fusidic acid. In order to address the molecular determinants of the S. typhimurium AcrD substrate specificity, we conducted substitution analyses in the putative access and deep binding pockets and in the TM1/TM2 groove region. The variants were tested in E. coli ΔacrBΔacrD against β-lactams oxacillin, carbenicillin, aztreonam and temocillin. Deep binding pocket variants N136A, D276A and Y327A; access pocket variant R625A; and variants with substitutions in the groove region between TM1 and TM2 conferred a sensitive phenotype and might, therefore, be involved in anionic β-lactam export. In contrast, lower susceptibilities were observed for E. coli cells harbouring deep binding pocket variants T139A, D176A, S180A, F609A, T611A and F627A and the TM1/TM2 groove variant I337A. This study provides the first insights of side chains involved in drug binding and transport for AcrD from S. typhimurium.
Synaptic transmission is a fundamental process that involves the transfer of information from a presynaptic neuron to a target cell through the release of neurotransmitters. The SV cycle is a complex series of events that enables the recycling of SVs, allowing for the sustained release of neurotransmitters. This process is mediated by a variety of proteins and enzymes, and its regulation is critical for maintaining proper synaptic function. Despite extensive research efforts, many aspects of the SV cycle and the underlying synaptic proteins remain poorly understood, highlighting the need for continued investigation into this important process. During this work, multiple aspects of synaptic transmission were studied by performing
behavioural, pharmacological, optogenetic, electrophysiological and ultrastructural assays on Caenorhabditis elegans. First, the role of two proteins (ERP-1 and RIMB-1) were analysed in the synaptic vesicle cycle. Second, a new optogenetic tool, the pOpsicle assay was described, which enables the direct visualization of synaptic vesicle (SV) release.
Activity-dependent bulk endocytosis (ADBE) enables the endocytosis of SV membrane and proteins in a fast manner during intense stimulation, resulting in bulk endosomes (also so-called large vesicles, LVs). Recycling proteins can be characterized by its site of action, whether they act at the plasma membrane (participating at the LV formation), or at the LV membrane (participating at the SV formation). ERP-1 (the C. elegans ortholog of Endophilin B) was recently identified as a possible SV recycling factor, its contribution to synaptic transmission has not been analysed before. During this project the function and possible cooperation of three proteins, ERP-1, UNC-57 (the C. elegans ortholog of Endophilin A) and CHC-1 (the C. elegans ortholog clathrin heavy chain) were studied, with a special emphasis of the site of action. It has been confirmed that these proteins participate together in synaptic vesicle recycling. Endophilins (ERP-1 and UNC-57) act both at the PM and the LV level, but while UNC-57 has been identified as the main player, ERP-1 rather has a minor role and acts as a back-up protein. CHC-1 functions the LV level in the first place, but it can compensate for the loss of UNC-57 and acts as a back-up protein at the PM.
RIM-binding protein is an evolutionarily conserved active zone protein, which interacts directly with RIM and N, P/Q, as well as L-type Ca2+ channels. RIM-BP and RIM have redundant functions in different model organisms including C. elegans, however, while the loss of UNC-10 (the C. elegans ortholog of RIM) led to drastic behavioural defects, the loss of RIMB-1 (the C. elegans ortholog of RIM-BP) led only to mild phenotypes. During this work the synaptic function of RIMB-1 and its interaction with UNC-10 and UNC-2 (C. elegans ortholog of the CaV2 1 subunit) were extensively investigated. It has been shown that RIMB-1 contributes to the precise localization of VGCCs in cooperation with UNC-10. Furthermore, it has been demonstrated, that RIMB-1 plays different roles in cholinergic and GABAergic neurons, thus it contributes to maintain a proper excitation/inhibition balance.
There are numerous available assays, which enable the indirect analysis of synaptic transmission, however, a tool, that enables the direct visualization of SV release, is highly desired. pOpsicle is a method which combines the optogenetic stimulation of cholinergic neurons with real-time visualization of SV release. A pH-sensitive fluorescence protein, pHuji, was inserted into the second intravesicular loop of the synaptic vesicle membrane protein, synaptogyrin (SNG-1). The fluorescence of pHuji is quenched inside the vesicles, but once they are released, the pH increases and pHuji can be detected. pOpsicle enables not only the direct visualization of SV exo-, and endocytosis events, but also the identification of putative SV recycling proteins.
Riboswitches are regulatory RNA elements that undergo functionally important allosteric conformational switching upon binding of specific ligands. The here investigated guanidine-II riboswitch binds the small cation, guanidinium, and forms a kissing loop-loop interaction between its P1 and P2 hairpins. We investigated the structural changes to support previous studies regarding the binding mechanism. Using NMR spectroscopy, we confirmed the structure as observed in crystal structures and we characterized the kissing loop interaction upon addition of Mg2+ and ligand for the riboswitch aptamer from Escherichia coli. We further investigated closely related mutant constructs providing further insight into functional differences between the two (different) hairpins P1 and P2. Formation of intermolecular interactions were probed by small-angle X-ray scattering (SAXS) and NMR DOSY data. All data are consistent and show the formation of oligomeric states of the riboswitch induced by Mg2+ and ligand binding.
The Chikungunya virus (CHIKV) is a mosquito-transmitted alphavirus that causes high fever, rash, and recurrent arthritis in humans. The majority of symptoms disappear after about one week. However, arthritis can last for months or even years (in about 30% of cases), which makes people unable to work during this period. The virus is endemic in Sub-Saharan Africa, the Indian Ocean islands, India, and Southeast Asia. It has additionally caused several large outbreaks in the last few years, affecting millions of people. The mortality rate is very low (0.1%), but the infection rates are high (sometimes 30%) and the number of asymptomatic cases is rare (about 15%). The first CHIKV outbreak in a country with a moderate climate was detected in Italy in 2007. Furthermore, the virus has spread to the Caribbean in late 2013. Due to climate change, globalization, and vector switching, the virus will most likely continue to cause new worldwide outbreaks. Additionally, more temperate regions of the world like Europe or the USA, which have recently reported their first cases, will likely become targets. Alarmingly, there is no specific treatment or vaccination against CHIKV available so far.
The cell entry process of CHIKV is also not understood in detail, and was thusly the focus of study for this project. The E2 envelope protein is responsible for cell attachment and entry. It consists of the domain C, located close to the viral membrane, domain A, in the center of the protein, and domain B, at the distal end, prominently exposed on the viral surface.
In this work, the important role of cell surface glycosaminoglycans (GAGs) for CHIKV cell attachment was uncovered. GAGs consist of long linear chains of heavily sulfated disaccharide units and can be covalently linked to membrane associated proteins. They play an important role in different cell signaling pathways. So far, solely cell culture passage has revealed an increased GAG-dependency of CHIKV due to mutations in E2 domain A, which was associated with virus attenuation in vivo. However, in this work it could be shown that cell surface GAGs promote CHIKV entry using non-cell culture adapted CHIKV envelope (Env) proteins. Transduction and infection of cell surface GAG-deficient pgsA-745 cells with CHIKV Env pseudotyped vector particles (VPs) and with wild-type CHIKV revealed decreased transduction and replication rates. Furthermore, cell entry and transduction rates of GAG-containing cells were also dose-dependently decreased in the presence of soluble GAGs. In contrast, transduction of pgsA-745 cells with CHIKV Env pseudotyped VPs was enhanced by the addition of soluble GAGs. This data suggests a mechanism by which GAGs activate CHIKV particles for subsequent binding to a cellular receptor. However, at least one GAG-independent entry pathway might exist, as CHIKV entry could not be totally inhibited by soluble GAGs and entry into pgsA-745 was, albeit at a lower rate, still possible. Further binding experiments using recombinant CHIKV E2 domains A, B, and C suggest that domain B is responsible for the GAG binding, domain A possibly for receptor binding, and domain C is not involved in cell binding. These results are in line with the geometry of CHIKV Env on the viral surface. They altogether reveal that GAG binding promotes viral cell entry and that the E2 domain B plays a central role for this mechanism.
As no vaccine against CHIKV has been approved so far, another goal of this project was to test new vaccination approaches. It has been published that a single linear epitope of E2 is the target of the majority of early neutralizing antibodies against CHIKV in patients. Artificial E2-derived proteins were created, expressed in E.coli, and successfully purified. They consisted of 5 repeats of the mentioned linear epitope (L), the surface exposed regions of domain A linked by glycine-serine linkers (sA), the whole domain B plus a part of the β-ribbon connector (B+), or a combination of these 3 modules. Vaccination experiments revealed that B+ was necessary and sufficient to induce a neutralizing immune response in mice, with the protein sAB+ yielding the best results. sAB+, as a protein vaccine, efficiently and significantly reduced viral titers in mice upon CHIKV challenge, which was not the case for recombinant Modified Vaccinia virus Ankara (MVA; MVA-CHIKV-sAB+), as a vaccine platform expressing the same protein. These experiments show that a small rationally designed CHIKV Env derived protein might, after optimization of some vaccination parameters, be sufficient as a safe, easy-to-produce, and cheap CHIKV vaccine.
Epigallocatechin-3-gallate (EGCG) is a catechin found in green tea and was, in this work, found to inhibit the CHIKV life cycle at the entry state in in vitro experiments using CHIKV Env VPs and wild-type virus. EGCG was recently published to inhibit attachment of several viruses to cell surface GAGs, which is in line with the role for GAGs in CHIKV entry revealed in this work. EGCG might serve as a lead compound for the development of a small molecule treatment against CHIKV.
Zika-virus (ZIKV), a flavivirus mainly transmitted by Aedes mosquitoes, is a single-stranded, positive-sense RNA virus. The viral genome is surrounded by a nucleocapsid and a lipid bilayer, in which membrane and envelope proteins are embedded. ZIKV disease is mainly characterized by mild symptoms, such as fever, rash as well as pain in head and joints. However, after epidemics it caused in the Americas in 2015/16, ZIKV infections were also associated with severe neurological complications like the Guillain-Barré syndrome (GBS) and microcephaly in fetuses and newborns. So far there are no specific antiviral treatments or vaccines available against ZIKV. This strengthens the need for a detailed understanding of the viral life cycle and virus-host interactions.
The antiviral host factor tetherin (THN) is an interferon-stimulated protein and therefore part of the cellular innate immune response. It comprises an N-terminal cytoplasmic domain, followed by a transmembrane helix, an extracellular coiled-coil domain and a C-terminal glycosylphosphatidylinositol (GPI) anchor. Containing two sites for membrane insertion linked by a flexible structure, THN is able to integrate into the membrane of budding viruses, thereby attaching them to each other and to the cell membrane and preventing their further release and spread.
In this study, the crosstalk of ZIKV and THN was analyzed. Previous gene expression analyses by microarray and quantitative polymerase chain reaction (qPCR) had revealed a strong upregulation of the BST2 gene encoding for THN in ZIKV-infected cells. However, this enhanced expression did not correlate with an enhanced THN protein level. On the contrary, the amount of THN in THN-overexpressing cells was after infection even heavily reduced. Furthermore, immunofluorescence analyses revealed a loss of THN membrane localization in these cells. By performing a cycloheximide assay, this loss could be traced back to a reduced protein half-life of THN in infected versus uninfected cells. Treatment with inhibitors of different protein degradation pathways as well as colocalization analyses with markers of several subcellular compartments indicated an involvement of the endo-lysosomal route. A knock-down of the ESCRT-0 protein HRS however prevented the sorting of THN for lysosomal degradation and led to a stabilization of THN protein levels. After HRS depletion, the release and spread of viral particles was reduced in THN-overexpressing compared to wildtype cells.
Taken together, the data obtained in this study revealed the potential of THN to restrict ZIKV release and spread. The enhanced degradation of THN in ZIKV-infected cells via the endo-lysosomal pathway could therefore be explained as an effective viral escape strategy. This could be circumvented by knockdown of the ESCRT-0 protein HRS, which highlighted HRS as a potential target for the development of antiviral treatments.
The focus of this research was to understand the molecular mechanism that lies behind the insertion of tail-anchored membrane proteins into the ER membrane of yeast cells. State-of-art instruments such as LILBID, and Cryo-EM, combined with the introduction of direct electron detectors, were used to analyze the proteins that capture tail-anchored proteins near the ER membrane and help their releases from a chaperone, an ATPase named Get3. Get3 escorts TA proteins to the ER membrane, where both Get3 and the TA proteins interact sequentially to Get3 membrane bound receptors Get1 and Get2. Get1 and Get2 are homologs of mammalian WRB and CAML.
The native host was used to separately produce Get1, Get2, and the Get2/Get1 single chain constructs. The studies showed that when Get1 is expressed alone, Get1 does not seems to be located in the ER membrane but rather in microbodies like shape organelles (or peroxisome). Interestingly, Get1 seems to be located in the ER membrane when it is linked to Get2 as single chain construct.
The localization study of Get2/Get1 fused to GFP shows from the fluorescence intensity that Get2/Get1.GFP has a tube-like morphology or membrane-enclosed sacs (cisterna), implying that Get2/Get1 is actually targeted to the ER membrane and is likely functional. In other words, Get1 and Get2 stabilize each other in the ER membrane.
The expression of Get2/Get1 was found to be already optimum when expressed as single chain construct because the fluorescence counts did not improve when additives such as DMSO or histidine were added. However, when Get1 and Get2 are expressed separately, additives improve their protein production yield. In 1 liter culture, Get1 yield is increased by about 3 mg and Get2 by 1.8 mg. This can be explained by the space that Get1 and Get2 should occupy within the ER membrane as they must coexist with other membrane components to maintain the homeostasis of the cell. Hence, if there were no gain for single chain construct expression, it meant that Get2/Get1 was already well expressed on its own in ER membrane and has reached its optimum expression without the help of additives. The Get2/Get1 overexpression is more stable, tolerated and less toxic for the cells to express it at a high level.
DDM has proved to be the best detergent from the detergents tested to solubilize Get1, Get2, and Get2/Get1.
Thereafter, Get1, Get2 (data not shown), and Get2/Get1 were successfully purified in DDM micelles.
Furthermore, for the first time using LILBID, the actual study has shown that Get1 and Get2 are predominantly a heterotetramer (2xGet1 and 2xGet2) but higher oligomerization may exist as well.
Get3 binds to Get1 in a biphasic way with a specific strong binding of an affinity of 57 nM and the second of 740 nM nonspecific indicative of heterogeneity within the interaction between Get1 and Get3. This heterogeneity is caused by the presence of different conformation of either protein. However, in order to characterize a high-resolution structure model of a specific target one needs highly homogenous and identical molecules of the target protein or complex in solution. The homogeneity increases the chances of growing crystals during crystallography as the good homogeneity will likely generate a perfect packing of unit cells stack (also known as crystal lattice) in the three-dimensional spaces. The same truth goes for the single particles analysis Cryo-EM, especially for smaller complexes where having less or no conformation alterations of specific targets will enable the researcher to classify the particles in 2D and 3D, therefore improving the signal-to-noise-ratio that will ultimately lead to high-resolution structure determination.
Get1, Get2/Get1 and chimeric variants (tGet2/Get1, T4l.Get2/Get1, T4l.Get2.apocyte.Get1) were crystallized but none of the crystals could diffract due to heterogeneity.
This heterogeneity was not only occurring upon the binding of Get3 to its membrane receptors, but seems to be already present within the receptors themselves through possibly different conformation.
In this Ph.D. thesis, the heterogeneity of purified Get2 and Get1 as complex or individually in detergent is then, so far, the limiting factor for obtaining a high-resolution structure model of Get1 and Get2. As mentioned above, the heterogeneity observed was not due to the quality of the sample preparation but rather to the effect of different conformations that could have been native, or just because of the micelle used, as it was proven by the 3-D heterogeneity classification by Cryo-EM.
In general, crosslinking is one way to keep the integrity of protein complexes, however it appeared not to improve the sample quality when it was analyzed in micelles. Often the integrity of some membrane proteins is affected when they are solubilized and purified in detergents.
Finally, in this study, the structural map of Get2 and Get1 complex linked with chimeric protein T4 lysozyme and apocytochrome C b562RIL gene was obtained at 10 Å. However, this single chain construct has a density map corresponding to heterodimer species (one Get1 and Get2). Therefore, based on those data the tertiary structure of Get2/Get1 in micelle is poorly defined. It could be that the membrane extraction in DDM and the purification destabilizes the structure of the complex.
Paramyxo- and pneumoviruses include many pathogens with great relevance for human and animal health. To identify common host factors involved in the Paramyxo- and Pneumoviridae life cycle as a basis for new insights in the biology of these viruses and the development of rationally designed therapeutics, genome scale siRNA screens with wild-type measles, mumps, and respiratory syncytial viruses in A549 cells, a human lung adenocarcinoma cell line, were performed. A comparative bioinformatics analysis yielded different members of the coatomer complex I, the translation factors ABCE1 and eIF3A, and several RNA binding proteins as cellular proteins with proviral activity for all three viruses. The strongest common hit, ABCE1, an ATP-binding cassette transporter member, was chosen for further study. We found that ABCE1 supports replication of all three viruses, confirming its importance for both virus families. While viral protein kinetics showed that ABCE1 knockdown resulted in a drastic decrease of MeV protein expression, viral mRNA kinetics are not directly affected by a reduction of ABCE1.
The impact of ABCE1 on viral and global cellular translation was investigated using both 35S metabolic labelling and non radioactive fluorescent protein labelling. ABCE1 knockdown strongly inhibited the production of MeV proteins, while only modestly affecting global cellular protein synthesis and showed that ABCE1 is specifically required for efficient viral, but not general cellular, protein synthesis, indicating that paramyxoand pneumoviral mRNAs may exploit specific translation mechanisms.
In a second approach the efficacy of the small-molecule polymerase inhibitor ERDRP-0519 against MeV was assessed in squirrel monkeys. Animals treated with the drug experienced less severe clinical disease compared to untreated controls, and this effect correlated with the onset of drug treatment.
We observed a reduction of levels of PBMC-associated viremia and virus release in the upper airways, illustrating effective inhibition of virus replication by the drug treatment. ERDRP-0519 drug treatment also alleviated MeV-induced immunosuppression. In addition to providing proof-of-concept for the support of MeV eradication efforts by preventing disease and transmission with a small-molecule polymerase inhibitor, this dissertation provides a novel perspective on cellular proteins that impact the replication of MeV, MuV and HRSV and highlights the role of ABCE1 as host factor that is required for efficient paramyxo- and pneumovirus translation.
The multistep-processes leading to the formation of tumors have been extensively studied in the past decades, leading to the identification of “hallmarks of cancer”. They are characteristic changes in biological processes that discriminate tumor cells from healthy cells. Increasing knowledge on the molecular structures associated with tumorigenesis allowed their specific inhibition in targeted anti-cancer therapy. However, successful targeted anti-cancer therapy is only available for a limited subset of diseases, so the continuous investigation of tumorigenic mechanisms is required to tackle the immense diversity of neoplastic entities.
AVEN and FUSE binding protein 1 (FUBP1) display the ability to regulate apoptosis and cell cycle progression. Thus, the proteins are associated with hallmarks of cancer (resisting cell death and uncontrolled proliferation). Indeed, aberrant expression of AVEN and FUBP1 could be demonstrated in multiple cancers. In contrast, there is only little knowledge on the physiological function of AVEN and FUBP1. The lack of knowledge results in part from the embryonic lethality of the homozygous knockout of Aven and Fubp1 in mouse models, limiting the gain of information by analyzing these animals.
In this study, I generated conditional Aven and Fubp1 knockout mice to investigate their physiological function.
By analyzing reporter mice expressing β-galactosidase under the control of the endogenous Aven promoter, I identified Aven promoter activity to be both tissue- and cell type-specific and dependent on the developmental stage. Detecting apoptotic cell death by immunohistochemistry did not reveal increased apoptosis in Aven knockout mice, suggesting a functional role of AVEN besides apoptosis inhibition during embryogenesis.
Basing on the significant Aven promoter activity detected in the adult brain and in the mammary gland, I generated and characterized conditional Aven knockout mice with Aven deletion restricted to cells within the brain or the mammary gland. AVEN depletion in these tissues was not embryonic lethal and the affected tissues displayed a normal histology.
Since aberrant Aven expression had been associated with hematologic malignancies, I also analyzed mice with an Aven knockout in the hematopoietic system. Depletion of AVEN in the blood cells had no effect on hematopoietic stem and progenitor cell frequencies. Consequently, AVEN seems to be dispensable for the maintenance and differentiation of stem, progenitor and mature blood cells, at least as far as the expression of particular differentiation markers was concerned.
As loss of AVEN in the analyzed tissues did not affect the viability of mice and did not produce any other obvious phenotype, the exact role of AVEN that is essential for embryo survival remains to be identified.
To study the oncogenic potential of AVEN, I investigated the role of AVEN in a mouse model for breast carcinogenesis. While AVEN expression seemed to be increased in breast tumors, tumor onset and progression were not altered in mice with depleted AVEN expression in the mammary gland. Consistently, Aven knockout tumor cells were neither less proliferative nor more prone to undergo apoptosis than Aven wildtype tumor cells. Cell culture experiments demonstrated that AVEN expression is upregulated by estrogen. Knockdown of AVEN in the breast cancer cell line MCF-7 slightly increased UV irradiation-induced apoptosis and accelerated metabolism. So while AVEN does not promote development or progression of breast tumors, enhanced AVEN expression in ER+ breast cancers might contribute to chemotherapy resistance.
To study the physiological role of FUBP1, I generated a conditional Fubp1 knockout mouse model. While the insertion of loxP sites into the Fubp1 locus was occasionally embryonic lethal, some mice with a cell type-specific deletion of Fubp1 in hematopoietic cells or EPO receptor expressing cells were born alive. In these mice, frequencies of hematopoietic stem and progenitor cells as well as erythrocytes were unaltered. These results conflict with previous publications. However, compensating mechanisms might be responsible for the discrepancies between the observed phenotypes and reported FUBP1 function.
In cell culture studies, I could demonstrate that the previously reported upstream regulation of FUBP1 by TAL1 depended on an intact GATA motif in the FUBP1 promoter and that binding of GATA1 to the FUBP1 promoter increased during erythropoiesis.
To identify new FUBP1 target genes with relevance for erythropoiesis, I performed differential gene expression analysis in cells with wildtype and depleted FUBP1 expression. RNA-sequencing and PCR-arrays revealed only moderate differences in the expression of genes that are components of the EPO receptor signaling pathway as well as genes associated with apoptosis and proliferation of hematopoietic cells. By regulating the transcription of these genes, FUBP1 could contribute to efficient erythropoiesis.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8’s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein’s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8’s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein’s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8’s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein’s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8′s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein′s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8’s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein’s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Interferon-stimulated gene-15 (ISG15) is an interferon-induced protein with two ubiquitin-like (Ubl) domains linked by a short peptide chain, and the conjugated protein of the ISGylation system. Similar to ubiquitin and other Ubls, ISG15 is ligated to its target proteins with a series of E1, E2, and E3 enzymes known as Uba7, Ube2L6/UbcH8, and HERC5, respectively. Ube2L6/UbcH8 plays a literal central role in ISGylation, underscoring it as an important drug target for boosting innate antiviral immunity. Depending on the type of conjugated protein and the ultimate target protein, E2 enzymes have been shown to function as monomers, dimers, or both. UbcH8 has been crystalized in both monomeric and dimeric forms, but the functional state is unclear. Here, we used a combined approach of small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) spectroscopy to characterize UbcH8′s oligomeric state in solution. SAXS revealed a dimeric UbcH8 structure that could be dissociated when fused with an N-terminal glutathione S-transferase molecule. NMR spectroscopy validated the presence of a concentration-dependent monomer-dimer equilibrium and suggested a backside dimerization interface. Chemical shift perturbation and peak intensity analysis further suggest dimer-induced conformational dynamics at ISG15 and E3 interfaces - providing hypotheses for the protein′s functional mechanisms. Our study highlights the power of combining NMR and SAXS techniques in providing structural information about proteins in solution.
Throughout their life cells of eukaryotic organisms can be confronted with a variety of proteotoxic stresses and in order to survive, corresponding resistance mechanisms had to evolve. Proteotoxic stresses can cause misfolding of proteins and accumulation of toxic protein aggregates. Failure to remove aggregates of misfolded proteins compromises cellular function and can ultimately cause cell death and disease. To deal with this challenge, cells utilize a complex network of protein quality control pathways, including chaperones, the ubiquitin-proteasome system and the autophagy system.
Another mechanism to cope with proteotoxic stresses is the stalling of translation initiation in order to save valuable resources and prevent faulty translation. Upon stress, intrinsically disordered RNA-binding proteins such as TIA-1 or G3BP1/2 are recruited to stalled preinitiation complexes and a network of multivalent interactions between RNAs and proteins is formed. These mRNP networks can merge with each other and phase separate into membraneless liquid-like structures called stress granules (SGs). Once stress is released, SGs are quickly resolved and translation continues. Yet, chronic stress or mutations of SG-associated proteins can cause persistent SGs, which can sequester misfolded proteins and have been linked to neurodegenerative diseases such as amyotrophic lateral sclerosis or frontotemporal dementia.
In mammalian cells, three isoforms of the small ubiquitin-related modifier (SUMO), SUMO1, SUMO2 and SUMO3 are covalently attached to lysine residues of target proteins. SUMO conjugation is catalyzed via an enzymatic cascade of an heteromeric E1 activating enzyme, the E2 conjugating enzyme Ubc9 and in some cases one of a limited number of E3 SUMO ligases. SUMOylation is a dynamic modification and can be reversed by SUMO isopeptidases, the best characterized of which belong to the SENP family. Cellular stresses such as heat or oxidative stress strongly induce SUMOylation resulting in increased numbers of poly-SUMOylation (formation of SUMO2/3 chains) on nuclear proteins.
The SUMO-targeted ubiquitin ligase (STUbL) RNF4 harbors four SUMO interaction motifs in its N-terminal domain. This feature allows RNF4 to specifically bind poly-SUMOylated proteins and catalyze their proteolytic or non-proteolytic ubiquitylation.
A variety of substrate proteins have been shown to undergo SUMO-primed ubiquitylation by RNF4 in response to stress or DNA damage. RNF4-mediated ubiquitylation is often a signal for proteolytic degradation of these substrates.
In this work we aimed by identify novel RNF4 targets, in heat-stressed cells in order to gain a wider understanding of the nuclear proteotoxic stress response. Analysis by mass spectrometry revealed that a large fraction of RNF4-interacting proteins in heatstressed cells are nuclear RNA-binding proteins, many of which shuttle outside the nucleus and associate with SGs upon stress. We validated, that nuclear RNA-binding proteins, such as TDP-43 and hnRNP M are indeed heat-induced targets of SUMOprimed ubiquitylation by RNF4.
These initial results led us to further investigate the links between the SUMO/RNF4-mediated, nuclear protein quality control and the dynamics of cytosolic heat- or arsenite-induced SGs. SUMO2/3 and RNF4 are mainly nuclear proteins and we confirmed that they do not associate with SGs. Yet, we could demonstrate that depletion of SUMO2/3, the E3 SUMO ligase PML or RNF4 as well as chemical inhibition of SUMOylation strongly delayed SG clearance upon stress release, indicating that a functional STUbL pathway is essential for the timely clearance of SGs.
Next, we investigated how stress-induced poly-SUMOylation is regulated. Our data shows that SENP levels and activities are reduced in response to heat and arsenite stress, which allows the buildup of poly-SUMO chains on nuclear proteins. Limitation of poly-SUMOylation by overexpression of the SUMO chain-specific isopeptidases SENP6 and SENP7 induced SG formation. In contrast, poly-SUMO-priming by chemical depletion of SENP6 with the drug hinokiflavone drastically limited SG formation upon stress treatment. These results indicate a clear role of chain-specific SENPs in the regulation of stress-induced poly-SUMOylation and SG dynamics.
Last, we investigated whether the STUbL pathway could affect the phase separation of FUSP525 (an ALS-linked mutant of the SG-associated protein FUS) and observed that perturbations of the STUbL pathway lead to an increased phase separation of FUSP525L.
Thus, our work connects the SUMO/RNF4 protein quality control mechanism to the dynamics of SGs supporting the hypothesis that release of proteotoxic stress in the nucleus facilitates the clearance of cytosolic SGs. Thereby, we discovered a previously unknown link between the nuclear and cytosolic axis of proteotoxic stress response.
Large international airports were identified as sources of ultrafine particles (UFPs) (Hu et al., 2009; Yu et al., 2012; Hsu et al., 2013; Keuken et al., 2015; Hudda and Fruin, 2016). Since September 2017 UFP emissions originating from the Frankfurt International Airport, Germany are monitored by the Hessian Agency for Nature Conservation, Environment and Geology (HLNUG) showing elevated UFP concentrations during airport operating hours (05:00–23:00 CET) (Ditas et al., 2022). Referring to that, the organic chemical composition of aviation-related UFPs emerging from the Frankfurt Airport was analysed by performing a comprehensive non-target screening of UFP filter samples.
Aluminium-filter samples were collected at an air quality monitoring station 4 km north of the Frankfurt Airport, using a 13-stage impactor system (Nano-MOUDI). The chemical
characterization of UFPs in the size range of 10-18 nm, 18-32 nm and 32-56 nm was accomplished by ultra-high-performance liquid chromatography, heated electrospray ionisation and mass analysis using an Orbitrap high-resolution mass spectrometer. Non-target screening revealed that the majority of detected compounds belong to homologous series of two different types of organic esters, which are base stocks of aircraft lubrication oils.
In reference to five different jet engine lubrication oils of various manufacturers, the corresponding lubricant base stocks and their additives, two amines and one organophosphate, were identified in the UFPs by the use of matching retention time, exact mass and MS/MS fragmentation pattern of single organic molecules. The quantitative analysis of the jet engine oil constituents in the aviation-related UFPs with diameters < 56 nm was accomplished by standard addition. By characterizing the Nano-MOUDI, loss factors for each size stage were determined and used for correction accordingly. Particle-number size distribution measurements, conducted parallel to the filter sampling, enabled the determination of the jet engine oil contribution to the UFP mass.
Furthermore, the nucleation and particle formation potential of a commonly used synthetic jet engine lubrication oil was investigated in the laboratory. Thermodenuder experiments at 20 °C and 300 °C were carried out to monitor the gas-to-particle partitioning behaviour of jet engine oils. At 300 °C a significantly higher number of particles with a mean diameter of ~10 nm are formed, leading to a more than fivefold increase in total particle numbers compared to 20 °C. Particle diameters of the newly formed oil particles in the laboratory experiment appeared in the same size region as UFPs emerging from Frankfurt Airport. Particles originating from the Frankfurt city centre direction showed larger diameters.
Results indicate that aircraft emissions strongly influence the total mass of 10-18 nm particles. The jet oil fraction decreases for bigger particles (e.g., 18-56 nm), implying that these oils form new particles in the cooling exhaust gases of aircraft engines. In addition, non-target screening and in vitro bioassays on aviation-related PM2.5 filter samples were combined to provide indications for potential toxicologically relevant compounds in dependence of different wind directions and airport operations. Most recently, the applied non-target screening method was also used to identify seasonal variations in the organic aerosol composition in Beijing.
This cumulative dissertation examines learning in chemistry laboratories, focusing on the challenges and benefits of problem-based learning (PBL) for novices in the lab. It addresses the lack of consistent understanding about what should be learned in labs and why it's important. The research aims to understand what students learn, how they learn, and how lab learning can be improved.
A central concept in PBL labs is Information Literacy, defined as a sociocultural practice enabling learners to identify and use information sources within a specific context as legitimized by the practice community.
The first publication, Wellhöfer and Lühken (2022a), investigates the relationship between PBL and learner motivation. It identifies factors that can foster students' intrinsic motivation in a PBL lab. Autonomy is found to be a key factor, increasing student motivation and presenting a model of the autonomous scientific process. This model involves four steps: information acquisition, designing and applying experimental procedures, experimental feedback, and autonomous process optimization. The results suggest that intrinsic motivation in PBL labs can be enhanced by enabling students to independently execute these steps.
The second publication, Wellhöfer and Lühken (2022b), examines the information process students undergo during their first PBL lab. Using a sociocultural framework, it explores Information Literacy to understand students' handling of information and their perceptions of the information process. The findings reveal that in PBL labs, developing a practical, applicable experimental procedure is crucial for problem-solving and significantly shapes the information-acquisition process. This process is iterative, influenced by new information, leading to more precise information needs. Students assess information quality based on its usefulness for their problem, implementability (considering cognitive understanding, available equipment, and psychomotor skills), and safety.
Furthermore, the role of privileged knowledge forms in evaluating the quality of text sources is explored. Students viewed non-scientific sources as "poor" and scientific sources as "good," yet used both for information gathering. There were discrepancies between their assessment of source quality and actual use, indicating that perception of source quality doesn't always affect their practical decisions.
The third publication, Wellhöfer, Machleid, and Lühken (2023), investigates students' information practices in the lab, focusing on discourse between novice learners and experienced assistants. It shows that theoretical knowledge isn't sufficient for independent practical action, and students need actionable social information from experienced community members. The results highlight that information literacy in the lab for newcomers to a community of practice has distinctive features, and physical experience and tacit knowledge are crucial for learning the methods and group-specific knowledge of the practice community. The article demonstrates how learning information literacy in a practice community requires a social and physical experience and provides insights on how educators can support this process.
Hepatocyte nuclear factor 4α (HNF4α) is a ligand-sensing transcription factor and presents as a potential drug target in metabolic diseases and cancer. In humans, mutations in the HNF4α gene cause maturity-onset diabetes of the young (MODY), and the elevated activity of this protein has been associated with gastrointestinal cancers. Despite the high therapeutic potential, available ligands and structure–activity relationship knowledge for this nuclear receptor are scarce. Here, we disclose a chemically diverse collection of orthogonally validated fragment-like activators as well as inverse agonists, which modulate HNF4α activity in a low micromolar range. These compounds demonstrate the druggability of HNF4α and thus provide a starting point for medicinal chemistry as well as an early tool for chemogenomics.
Cardiolipin, the mitochondria marker lipid, is crucially involved in stabilizing the inner mitochondrial membrane and is vital for the activity of mitochondrial proteins and protein complexes. Directly targeting cardiolipin by a chemical-biology approach and thereby altering the cellular concentration of “available” cardiolipin eventually allows to systematically study the dependence of cellular processes on cardiolipin availability. In the present study, physics-based coarse-grained free energy calculations allowed us to identify the physical and chemical properties indicative of cardiolipin selectivity and to apply these to screen a compound database for putative cardiolipin-binders. The membrane binding properties of the 22 most promising molecules identified in the in silico approach were screened in vitro, using model membrane systems finally resulting in the identification of a single molecule, CLiB (CardioLipin-Binder). CLiB clearly affects respiration of cardiolipin-containing intact bacterial cells as well as of isolated mitochondria. Thus, the structure and function of mitochondrial membranes and membrane proteins might be (indirectly) targeted and controlled by CLiB for basic research and, potentially, also for therapeutic purposes.
Dimerization of Taspase1 activates an intrinsic serine protease function that leads to the catalytic Thr234 residue, which allows to catalyze the consensus sequence Q−3X−2D−1⋅G1X2D3D4, present in Trithorax family members and TFIIA. Noteworthy, Taspase1 performs only a single hydrolytic step on substrate proteins, which makes it impossible to screen for inhibitors in a classical screening approach. Here, we report the development of an HTRF reporter assay that allowed the identification of an inhibitor, Closantel sodium, that inhibits Taspase1 in a noncovalent fashion (IC50 = 1.6 μM). The novel inhibitor interferes with the dimerization step and/or the intrinsic serine protease function of the proenzyme. Of interest, Taspase1 is required to activate the oncogenic functions of the leukemogenic AF4-MLL fusion protein and was shown in several studies to be overexpressed in many solid tumors. Therefore, the inhibitor may be useful for further validation of Taspase1 as a target for cancer therapy.
Rhabdomyosarcoma (RMS) is the most frequent pediatric soft-tissue sarcoma comprising two major subtypes – the alveolar and the embryonal rhabdomyosarcoma. The current therapeutic regime is multimodal including surgery, radiation and chemotherapy with cytostatic drugs. Although the prognosis for RMS patients has steadily improved to a 5-year overall survival rate of 70% for ERMS and 50% for ARMS, prognosis for subgroups with primary metastases or relapsed patients is still less than 25%, highlighting the need for development of new therapies for these subgroups. Since cancer cells are addicted to their cancer promoting transcriptional program, remodeling transcription by targeting bromodomain and extraterminal (BET) proteins has emerged as compelling anticancer strategy. However, in many cancer types BET inhibition was proved cytostatic but not cytotoxic emphasizing the need for combination protocols.
In this study we identify a novel synergistic interaction of the BET inhibitor JQ1 with p110α-isoform-specific Phosphoinositid-3-Kinase (PI3K) inhibitor BYL719 (Alpelisib) to induce mitochondrial apoptosis and global reallocation of BRD4 to chromatin. At first, we showed that JQ1 single treatment had cytostatic effects at nanomolar concentrations and inhibited MYC and Hedgehog (Hh) signaling in RMS known to promote proliferation of RMS. However, JQ1 single treatment barely induced cell death in RMS cells even at concentrations of up to 20 µM (< 20% cell death). Thus, we next tested combination approaches to elicit cell death. Since we previously identified synergistic cell death induction of Hh inhibition and PI3K inhibition in RMS cells we tested JQ1 in combination with the pan-PI3K/mTOR inhibitor PI-103 and the p110α-isoform-specific PI3K inhibitor BYL719. In addition, we tested JQ1 in combination with distinct HDAC inhibitors namely JNJ-26481585, SAHA (Vorinostat), MS-275 (Entinostat) and LBH-589 (Panobinostat) since the synergistic interaction of BET and HDAC inhibition has previously been described for other tumor entities.
Interestingly the synergism of cell death induction of JQ1/BYL719 co-treatment is superior to the synergism of JQ1 with pan-PI3K/mTOR inhibitor PI-103 or the tested HDAC inhibitors as confirmed by calculation of combination index. To investigate the molecular mechanisms underlying the synergy of JQ1/BYL719 co-treatment, we performed RNA-Seq and BRD4 ChIP-Seq experiments. RNA-Seq exhibited, that JQ1/BYL719 co-treatment shifted the overall balance of BCL-2 family gene expression towards apoptosis and increased gene expression of proapoptotic BMF, BCL2L11 (BIM) and PMAIP1 (NOXA) while decreasing gene expression of antiapoptotic BCL2L1 (BCL xL). These changes were verified by qRT-PCR and Western blot. Notably, BRD4 is phosphorylated upon JQ1/BYL719 co-treatment and globally reallocates BRD4 to chromatin. This BRD4 reallocation includes enrichment of BRD4 at the super-enhancer site of BMF, at the super-enhancer, typical enhancer and promoter regions of BCL2L11 (BIM) and at the PMAIP1 (NOXA) promoter, while JQ1 alone, as expected, reduces global chromatin binding of BRD4. Integration of RNA-Seq and BRD4 ChIP-Seq data underlines the transcriptional relevance of reallocated BRD4 upon JQ1/BYL719 co-treatment. Immunopreciptation studies showed, that RMS cells are initially primed to undergo mitochondrial apoptosis since BIM is constitutively bound to antiapoptotic BCL-2, BCL xL and MCL-1. JQ1/BYL719 co-treatment increased BIM expression and its neutralization of antiapoptotic BCL-2, BCL-xL and MCL-1 thereby rebalancing the ratio of pro- and antiapoptotic BCL-2 proteins in favor of apoptosis. This promotes activation of BAK and BAX resulting in caspase-dependent apoptosis. The functional relevance of proapoptotic re-balancing for the execution of JQ1/BYL719-mediated apoptosis was confirmed by individual silencing of BMF, BIM, NOXA or overexpression of BCL-2 or MCL-1, which all significantly rescued JQ1/BYL719-induced cell death. Execution of cell death by mitochondrial caspase-dependent apoptosis was veryfied by individual knockdown of BAK and BAX or caspase inhibitor N-Benzyloxycarbonyl-Val-Ala-Asp(O-Me) fluoromethylketone (zVAD.fmk), which all significantly rescued JQ1/BYL719-induced cell death.
In summary, combined BET and PI3Kα inhibition cooperatively induces mitochondrial apoptosis by proapoptotic re-balancing of BCL-2 family proteins accompanied by reallocation of BRD4 to transcriptional regulatory elements of BH3-only proteins.