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Certain electron-rich 1,4-diborabenzene derivatives efficiently activate single, double, and triple bonds and thereby increasingly compete with transition metals in homogeneous catalysis. This review compares the activation of three model substrates (H2, H2C=CH2, CO2) by (i) 9,10-dihydro-9,10-diboraanthracene dianions, (ii) their neutral carbene-stabilized congeners, (iii) 1,3,2,5-diazadiborinines, and (iv) 1,4,2,5-diazadiborinines. Distinct structure-properties relationships become apparent, the most influential factors being (i) the steric demands of the B-bonded substituents, (ii) the charges on the B-doped (hetero)arenes, (iii) charge polarization as a result of additional N-doping, and (iv) the energies and nodal structures of the frontier orbitals. The observed reactions are explained by a transition metal-like activation mechanism. If the two boron atoms are chemically inequivalent, contributions of a B(+I)/B(+III) mixed-valence state determine the observed regioselectivities when polar substrates are added. The lessons learned from the conversions of the model substrates are subsequently used to rationalize the behavior of the B2 heterocycles also toward more sophisticated substrate molecules. Finally, catalytic cycles based on H2- and H−-transfers, hydroboration reactions, and CO2 reductions will be covered.
Many processes in living cells involve interaction and cooperation of multiple proteins to fulfill a specific function. To understand biological processes in their full complexity, it is not sufficient to only identify the molecules being involved but also to understand the kinetic aspects of a reaction. Mass spectrometry (MS) is a very powerful tool which allows to precisely identify the molecules of a reaction. Usually this is done with tandem-MS experiments for purpose of de-novo peptide sequencing. However, since this involves protein digestion, a statement of the in-vivo constitution of non-covalently bound protein complexes is not possible. In order to detect an intact protein complex it is necessary to analyze the biological system softly and in a near-native environment with native MS. Native MS allows the non-destructive analysis of these non-covalent protein complexes as well as to detect their components. However, up to now native MS does not offer a possibility to resolve the timing of the constitution of protein complexes on a fast time-scale. Therefore, the progress of reactions on fast time-scales is invisible. However, a method which delivers both types of information - identification of the components of a protein complex, as well as time-resolving their interaction - would be of high interest.
A suitable ionization technique for native MS is laser-induced liquid-bead ion desorption (LILBID). LILBID employs well-defined droplets which are irradiated by IR laser pulses to generate gas phase ions. The not-continuous, repetitive nature of ion generation offers itself to the development of a time-resolved (TR) native MS system which is able to investigate protein complexes on a fast time scale. The LILBID-droplets can serve as reaction vessels if they are levitated in an electrodynamic Paul-trap. This new setup would allow sample manipulation and MS analysis on precise and fast reaction time-scales. The first part of this dissertation presents the construction and characterization of a setup for TR-LILBID-MS.
An example for a complex biological system is the self-assembly of beta-amyloid (Aβ). This small peptide is the major component in plaques related to Alzheimer’s disease. Clinically relevant is especially the 42 amino acid peptide Aβ42 which aggregates from monomers to oligomers through to fibrils. The oligomers are the neurotoxic species in this process and thus of high interest. Nevertheless, standard analytical techniques are unable to detect those oligomers which makes MS an optimal tool to study the oligomerization process of Aβ with the focus on disease relevant oligomers. TR-LILBID-MS allows to follow the oligomerization of Aβ enabling to study molecules which influence this kinetic. Combining MS with ion-mobility spectrometry adds an additional dimension - the collision cross section - to the mass-to-charge ratio obtained from MS. Therewith structural alterations induced by ligands can be correlated to differences in the aggregation kinetic. This allows to draw a picture of the aggregation process of Aβ for the development of disease-relevant small oligomers on a molecular level.
Die vorliegende Arbeit Zeitaufgelöste NMR-spektroskopische Untersuchung konformationeller Dynamiken in DNA G-Quadruplexen befasst sich mit der detaillierten biophysikalischen Untersuchung wichtiger strukturdynamischer Eigenschaften von nicht-kanonischen Nukleinsäure Sekundärstrukturelementen.
Im Genom aller eukaryotischer Lebewesen, insbesondere dem menschlichen Genom finden sich DNA-Sequenzabschnitte, die überdurchschnittlich Guanosin (G)-reich sind. Diese poly-G Abschnitte sind nicht zufällig im Genom verteilt, sondern häufen sich vermehrt in Genabschnitten, die besonders wichtig für die Regulation der Genexpression sind. G-reiche DNA-Sequenzen können unter geeigneten Umständen alternative Sekundärstrukturen ausbilden, die von der doppelsträngigen, kanonischen Watson-Crick Konformation abweichen. In Anwesenheit monovalenter Kationen können sich G-Nukleotide in einer Tetrade über Hoogsteen Interaktionen anlagern. Diese Tetraden können sich stapeln und dadurch sogenannte G-Quadruplexe (G4) ausbilden. Das menschliche cMYC Gen wird typischerweise als proto-Onkogen bezeichnet. Es kodiert für einen unspezifischen Transkriptionsfaktor, der bei einer Vielzahl von systematischen und soliden Tumorerkrankungen stark überexprimiert wird. Die zelluläre Konzentration des Genprodukts kann zu 90% über ein G4 cis-Element in der Promotorregion reguliert werden. Der cMYC G4 hat die Möglichkeit verschiedene Konformationen einzunehmen. Im Falle des cMYC G4 kann man zusätzliche, nicht-konventionelle Formen der konformationellen Isomerie finden. Zum einen gibt es die Möglichkeit, dass bei einem G4, der aus drei Tetraden und vier intramolekularen Strangabschnitten (dreistöckiger G4) besteht, einzelne Strangabschnitte mehr als drei konsekutive G-Nukleotide besitzen. Dadurch können sich Faltungs-Isomere bilden, die sich durch Verschieben des Strangs relativ zum verbleibenden dreistöckigen Tetradengerüst ergeben. Man spricht von G-Register Isomeren. Eine zweite Möglichkeit der Strukturisomerie ergibt sich, wenn in einer Nukleotidsequenz mehr als vier G-reiche Strangabschnitte aufeinander folgen. Jeweils vier dieser Strangabschnitte können in unterschiedlicher Weise kombiniert werden, um ein G4 Isomer auszubilden. In jedem dieser so zustande gekommenen G4 verbleibt ein (oder mehrere) G-reicher Strangabschnitt, der im konkreten Isomer nicht zur Faltung verwendet wird. Diese zusätzlichen G-Stränge werden daher auch Ersatzräder (engl. spare-tires) genannt; man erhält spare-tire Isomere.
Obwohl diese Formen des Polymorphismus, deren biologischer Kontext und die biophysikalischen Konsequenzen in Arbeiten von C. Burrows (2015) und A. Mittermaier (2016) erstmals umfassend beschrieben wurden, gab es bis zum Ausgangspunkt dieser Arbeit keine Kenntnisse über deren strukturelle Dynamik, den Faltungswegen und den zugrundeliegenden molekularen Mechanismen. Zeitaufgelöste Kernspinresonanz (engl. nuclear magnetic resonance, NMR) Spektroskopie ist eine bestens geeignete Methode, um die Dynamik von Biomakromolekülen mit atomarer Auflösung zu studieren. Um solche Experimente durchführen zu können, braucht es geeignete Herangehensweisen für die Präparation eines Nicht-Gleichgewichtszustands. In dieser Arbeit wird eine neu erarbeitete Strategie vorgestellt, die es erlaubt, Einblick in die Faltungs- und Umfaltungskinetiken eines dynamischen Konformations-Ensembles nicht-konventioneller Strukturisomere der cMYC G4 DNA-Sequenz zu erhalten.
Hierzu wurden photolabile Schutzgruppen (engl. Photocages) positionsspezifisch an bestimmten G-Nukleobasen (O6-(R)-NPE) angebracht. Die Schutzgruppen blockieren die Basenpaar-Interaktionen des Nukleotids, wodurch dieses sich nicht mehr an einer Tetradenbildung beteiligen kann. Die Photocages wurden jeweils an den Nukleotiden eingeführt, die nur in jeweils einem der G-Register Isomere an der Tetradenbildung beteiligt sind. Durch diese gezielte Destabilisierung konnten die Isomere getrennt und im gefalteten Zustand isoliert werden. Die so erhaltenen Konformationen wurden umfassend spektroskopisch charakterisiert. Der Ansatz, das konformationelle Gleichgewicht durch Photocages transient zu stören, wurde daraufhin weiterentwickelt. Mehrere Photocages wurden an Nukleobasen in zentraler Position einzelner G-Strangabschnitte angebracht. Dadurch konnte eine ausreichende Destabilisierung erreicht werden, die die Faltung jedweder G4 Strukturen unterbindet. Somit wurde ein ungefalteter Zustand erzeugt, der unter ansonsten frei wählbaren, physiologischen Bedingungen besteht. Durch in situ Photolyse der Schutzgruppen konnte so die Licht-induzierte G4 Faltung unter konstanten Puffer- und Temperaturbedingungen untersucht werden. Dieser Ansatz wurde auf die Untersuchung der Faltungswege, die zu verschiedenen spare-tire Isomeren führen, fokussiert.
Zusammenfassend kann festgestellt werden, dass es insgesamt erstmalig gelungen ist, die Kinetiken der wesentlichen Faltungs- und Umfaltungswege entlang der konformationellen Energielandschaft des cMYC G4 Elements zu untersuchen. Das komplexe, dynamische Zusammenspiel aller relevanten, nicht-konventionellen isomeren G4 Strukturen konnte entworren und umfassend experimentell beschrieben werden. Der dafür weiterentwickelte Ansatz über konformationelle Selektion mit Hilfe photolabiler Schutzgruppen hat dabei experimentelle Einblicke erlaubt, die bislang nicht zugänglich waren. Die Strukturen und Faltungszustämde, die mit den chemisch modifizierten Oligonukleotiden erhalten und isoliert wurden, sind umfassend spektroskopisch untersucht worden. Die Anwendung verschiedener spektroskopischer Ansätze und deren Kombination mit weiteren biophysikalischen Methoden hat eine Methoden-unabhängige Validierung der erhaltenen kinetischen und thermodynamischen Daten ermöglicht.
Multidomain enzymes, such as fatty acid synthases (FASs) or polyketide synthases (PKSs), play a crucial role in the biosynthesis of important natural products. They have a high significance in the development of new pharmaceuticals and various research approaches focus on the engineering of these proteins. For example, human type I FAS is an interesting therapeutic target. Owing to its importance in lipogenesis, upregulation of human type I FAS expression has been observed in numerous cancers. Type I FAS is also regarded as important target in antiobesity treatment. Both multidomain enzyme classes - FASs and PKSs - show high structural and functional similarities. Particularly animal type I FAS is most relevant as evolutionary precursor of the PKS family. Therefore, the well characterized FASs are suitable model proteins for the poorly characterized PKSs, to gain deeper understanding in these megasynthases.
Furthermore, fatty acids are considered to be strategically important platform chemicals accessible through sustainable microbial approaches. The recently acquired structural information on FASs provides an excellent understanding of the molecular basis of fatty acid synthesis. The specific understanding of chain-length control, the characterization of a multitude of substrate-specific thioesterases, and the emerging tools and means for metabolic engineering have fostered targeted approaches for modulating chain length. There is large interest in short-chain fatty acids, since these compounds are biotechnologically valuable platform chemicals and biofuel precursors, and attempts on the synthesis of short-chain fatty acids have been reported during the last years.
Primary focus of this thesis lies on the animal type I FASs, which exhibit large conformational variety, as seen in electron microscopy and high-speed atomic force microscopy. Conformational dynamics facilitate productive protein-protein interactions between catalytic domains within the enzyme and aid acyl carrier protein (ACP)-mediated substrate shuttling during the catalytic cycle of fatty acid biosynthesis. To gain deeper insight into the fundamental processes of ACP-mediated substrate shuttling and the underlying conformational dynamics, spectroscopic methods like Förster resonance energy transfer and electron paramagnetic resonance spectroscopy shall be employed. These spectroscopic methods demand site-specific labeling of proteins with fluorophore or spin labels, which can be accomplished with the amber codon suppression technology. Through amber codon suppression, a non-canonical amino acid (ncAA) with an orthogonal functional group is incorporated site-specifically into the protein sequence, which can be used in chemoselective reactions for protein labeling.
This thesis is at the forefront of employing the technology of amber codon suppression for addressing complex biological questions on megasynthases. The successful production of ncAA-modified FASs is challenging. With the aim of incorporating ncAAs into the multidomain 540 kDa large murine FAS, we by far exceed boundaries of documented application of amber codon suppression. Most of the proteins that are reported by Liu & Schultz in applications of amber codon suppression are in the range of 30kDa - for example the TE domain of human FAS. In the same review, the largest protein amber codon suppression was applied to is a potassium channel with roughly 80 kDa. Thus, to the best of my knowledge no protein exceeding 100 kDa has been used in amber codon suppression so far.
In this thesis a low-complex, well-plate based reporter assay is presented, based on an ACP-GFP fusion protein for fast and efficient screening of ncAA incorporation. Reliability and applicability of the reporter assay is demonstrated by successful upscaling to larger protein constructs and increased expression scale.
As outlined in this thesis, we have carefully set up methods for the modification of murine FAS and made several achievements:
(i) We have created our own toolbox with a multitude of suppressor plasmids and various orthogonal pairs. pACU and pACE plasmids are compatible for fast exchange of cassettes, and cloning procedures are optimized for modification of synthetases by site-directed mutagenesis. (ii) We have organic synthesis of several ncAAs stably running in the lab and synthesis of other ncAAs can be established when required. Therefore, extensive screening at moderate costs is possible. (iii) We have established a reporter assay for screening our own library of vectors for amber codon suppression and for optimizing incorporation of ncAAs. (iv) We successfully incorporated ncAAs into subconstructs and full-length murine FAS, and collected initial promising results for the application of these proteins in spectroscopic methods. Thus, laying the foundation for future studies to address fundamental questions of the ACP-mediated substrate shuttling and other conformational dynamics of these enzymes.
Fatty acid and polyketide synthases (FASs and PKSs) synthesize physiologically and pharmaceutically important products by condensation of acyl building blocks. The transacylation reaction catalyzed by acyl transferases (ATs) is responsible for the selection of acyl-CoA esters for further processing by FASs and PKSs. In this study, the AT domains of different multidomain (type I) PKS systems are kinetically described in their substrate selectivity, AT−Acyl carrier protein (ACP) domain-domain interaction and enzymatic kinetic properties. We observe that the ATs of modular PKSs, intricate protein complexes occurring in bacteria and responsible for the biosynthesis of bioactive polyketides, are significantly slower than ATs of mammalian FASs, reflecting the respective purpose of the biosynthetic pathways within the organism and their metabolic context. We further perform a mutational study on the kinetics of the AT−ACP interaction in the modular PKS 6-deoxyerythronolide B synthase (DEBS) and find a high plasticity in enzyme properties, which we explain by a high plasticity in AT−ACP recognition. Our study enlarges the understanding of ATs in its molecular properties and is similarly a call for thorough AT-centered PKS engineering strategies.
Transfer RNA fragments replace microRNA regulators of the cholinergic post-stroke immune blockade
(2020)
Stroke is a leading cause of death and disability. Recovery depends on a delicate balance between inflammatory responses and immune suppression, tipping the scale between brain protection and susceptibility to infection. Peripheral cholinergic blockade of immune reactions fine-tunes this immune response, but its molecular regulators are unknown. Here, we report a regulatory shift in small RNA types in patient blood sequenced two days after ischemic stroke, comprising massive decreases of microRNA levels and concomitant increases of transfer RNA fragments (tRFs) targeting cholinergic transcripts. Electrophoresis-based size-selection followed by RT-qPCR validated the top 6 upregulated tRFs in a separate cohort of stroke patients, and independent datasets of small and long RNA sequencing pinpointed immune cell subsets pivotal to these responses, implicating CD14+ monocytes in the cholinergic inflammatory reflex. In-depth small RNA targeting analyses revealed the most-perturbed pathways following stroke and implied a structural dichotomy between microRNA and tRF target sets. Furthermore, lipopolysaccharide stimulation of murine RAW 264.7 cells and human CD14+ monocytes upregulated the top 6 stroke-perturbed tRFs, and overexpression of stroke-inducible tRF-22-WE8SPOX52 using an ssRNA mimic induced downregulation of immune regulator Z-DNA binding protein 1 (Zbp1). In summary, we identified a “changing of the guards” between RNA types that may systemically affect homeostasis in post-stroke immune responses, and pinpointed multiple affected pathways, which opens new venues for establishing therapeutics and biomarkers at the protein- and RNA-level.
Significance Statement Ischemic stroke triggers peripheral immunosuppression, increasing the susceptibility to post-stroke pneumonia that is linked with poor survival. The post-stroke brain initiates intensive communication with the immune system, and acetylcholine contributes to these messages; but the responsible molecules are yet unknown. We discovered a “changing of the guards,” where microRNA levels decreased but small transfer RNA fragments (tRFs) increased in post-stroke blood. This molecular switch may re-balance acetylcholine signaling in CD14+ monocytes by regulating their gene expression and modulating post-stroke immunity. Our observations point out to tRFs as molecular regulators of post-stroke immune responses that may be potential therapeutic targets.
Transfer RNA fragments replace microRNA regulators of the cholinergic post-stroke immune blockade
(2020)
Stroke is a leading cause of death and disability. Recovery depends on balance between inflammatory response and immune suppression, which can be CNS-protective but may worsen prognosis by increasing patients’ susceptibility to infections. Peripheral cholinergic blockade of immune reactions fine-tunes this immune response, but its molecular regulators are unknown. Therefore, we sought small RNA balancers of the cholinergic anti-inflammatory pathway in peripheral blood from ischemic stroke patients. Using RNA-sequencing and RT-qPCR, we discovered in patients’ blood on day 2 after stroke a “change of guards” reflected in massive decreases in microRNAs (miRs) and increases in transfer RNA fragments (tRFs) targeting cholinergic transcripts. Electrophoresis-based size-selection followed by RT-qPCR validated the top 6 upregulated tRFs in a separate cohort of stroke patients, and independent small RNA-sequencing datasets presented post-stroke enriched tRFs as originating from lymphocytes and monocytes. In these immune compartments, we found CD14+ monocytes to express the highest amounts of cholinergic transcripts. In-depth analysis of CD14+ regulatory circuits revealed minimally overlapping subsets of transcription factors carrying complementary motifs to miRs or tRFs, indicating different roles for the stroke-perturbed members of these small RNA species. Furthermore, LPS-stimulated murine RAW264.7 cells presented dexamethasone-suppressible upregulation of the top 6 tRFs identified in human patients, indicating an evolutionarily conserved and pharmaceutically treatable tRF response to inflammatory cues. Our findings identify tRF/miR subgroups which may co-modulate the homeostatic response to stroke in patients’ blood and open novel venues for establishing RNA-targeted concepts for post-stroke diagnosis and therapeutics.
Transfer RNA fragments replace microRNA regulators of the cholinergic poststroke immune blockade
(2020)
Stroke is a leading cause of death and disability. Recovery depends on a delicate balance between inflammatory responses and immune suppression, tipping the scale between brain protection and susceptibility to infection. Peripheral cholinergic blockade of immune reactions fine-tunes this immune response, but its molecular regulators are unknown. Here, we report a regulatory shift in small RNA types in patient blood sequenced 2 d after ischemic stroke, comprising massive decreases of microRNA levels and concomitant increases of transfer RNA fragments (tRFs) targeting cholinergic transcripts. Electrophoresis-based size-selection followed by qRT-PCR validated the top six up-regulated tRFs in a separate cohort of stroke patients, and independent datasets of small and long RNA sequencing pinpointed immune cell subsets pivotal to these responses, implicating CD14+ monocytes in the cholinergic inflammatory reflex. In-depth small RNA targeting analyses revealed the most-perturbed pathways following stroke and implied a structural dichotomy between microRNA and tRF target sets. Furthermore, lipopolysaccharide stimulation of murine RAW 264.7 cells and human CD14+ monocytes up-regulated the top six stroke-perturbed tRFs, and overexpression of stroke-inducible tRF-22-WE8SPOX52 using a single-stranded RNA mimic induced down-regulation of immune regulator Z-DNA binding protein 1. In summary, we identified a “changing of the guards” between small RNA types that may systemically affect homeostasis in poststroke immune responses, and pinpointed multiple affected pathways, which opens new venues for establishing therapeutics and biomarkers at the protein and RNA level.
Transfer RNAs (tRNAs) are highly structured non-coding RNAs which play key roles in translation and cellular homeostasis. tRNAs are initially transcribed as precursor molecules and mature by tightly controlled, multistep processes that involve the removal of flanking and intervening sequences, over 100 base modifications, addition of non-templated nucleotides and aminoacylation. These molecular events are intertwined with the nucleocy- toplasmic shuttling of tRNAs to make them available at translating ribosomes. Defects in tRNA processing are linked to the development of neurodegenerative disorders. Here, we summarize structural aspects of tRNA processing steps with a special emphasis on intron-containing tRNA splicing involving tRNA splicing endonuclease and ligase. Their role in neurological pathologies will be discussed. Identification of novel RNA substrates of the tRNA splicing machinery has uncovered functions unrelated to tRNA processing. Future structural and biochemical studies will unravel their mechanistic underpinnings and deepen our understanding of neurological diseases.
Despite a high clinical need for the treatment of colorectal carcinoma (CRC) as the second leading cause of cancer-related deaths, targeted therapies are still limited. The multifunctional enzyme Transglutaminase 2 (TGM2), which harbors transamidation and GTPase activity, has been implicated in the development and progression of different types of human cancers. However, the mechanism and role of TGM2 in colorectal cancer are poorly understood. Here, we present TGM2 as a promising drug target.
In primary patient material of CRC patients, we detected an increased expression and enzymatic activity of TGM2 in colon cancer tissue in comparison to matched normal colon mucosa cells. The genetic ablation of TGM2 in CRC cell lines using shRNAs or CRISPR/Cas9 inhibited cell expansion and tumorsphere formation. In vivo, tumor initiation and growth were reduced upon genetic knockdown of TGM2 in xenotransplantations. TGM2 ablation led to the induction of Caspase-3-driven apoptosis in CRC cells. Functional rescue experiments with TGM2 variants revealed that the transamidation activity is critical for the pro-survival function of TGM2. Transcriptomic and protein–protein interaction analyses applying various methods including super-resolution and time-lapse microscopy showed that TGM2 directly binds to the tumor suppressor p53, leading to its inactivation and escape of apoptosis induction.
We demonstrate here that TGM2 is an essential survival factor in CRC, highlighting the therapeutic potential of TGM2 inhibitors in CRC patients with high TGM2 expression. The inactivation of p53 by TGM2 binding indicates a general anti-apoptotic function, which may be relevant in cancers beyond CRC.
Ribosomes catalyze protein synthesis by cycling through various functional states. These states have been extensively characterized in vitro, yet their distribution in actively translating human cells remains elusive. Here, we optimized a cryo-electron tomography-based approach and resolved ribosome structures inside human cells with a local resolution of up to 2.5 angstroms. These structures revealed the distribution of functional states of the elongation cycle, a Z tRNA binding site and the dynamics of ribosome expansion segments. In addition, we visualized structures of Homoharringtonine, a drug for chronic myeloid leukemia treatment, within the active site of the ribosome and found that its binding reshaped the landscape of translation. Overall, our work demonstrates that structural dynamics and drug effects can be assessed at near-atomic detail within human cells.
Transport mechanism of a multidrug resistance protein investigated by pulsed EPR spectroscopy
(2019)
In human several diseases result from malfunctions of ATP-binding cassette (ABC) systems, which form one of the largest transport system superfamily. Many ABC exporters contain asymmetric nucleotide-binding sites (NBSs) and some of them are inhibited by the transported substrate.1 For the active transport of diverse chemically substrates across biological membranes, ABC transport complexes use the energy of ATP binding and subsequent hydrolysis. In this thesis, the heterodimeric ABC exporter TmrAB2,3 from Thermus thermophilus, a functional homolog of the human antigen translocation complex TAP, was investigated by using pulsed electron-electron double resonance (PELDOR/DEER) spectroscopy. In the presence of ATP, TmrAB exists in an equilibrium between inward- and outward-facing conformations. This equilibrium can be modulated by changing the ATP concentration, showing asymmetric behaviour in the open-to-close equilibrium between the consensus and the degenerate NBSs. At the degenerate NBS the closed conformation is more preferred and closure of one of the NBSs is sufficient to open the periplasmic gate at the transmembrane domain (TMD).3 By determining the temperature dependence of this conformational equilibrium, the thermodynamics of the energy coupling during ATP-induced conformational changes in TmrAB were investigated. The results demonstrate that ATP-binding alone drives the global conformational switching to the outward-facing state and allows the determination of the entropy and enthalpy changes for this step. With this knowledge, the Gibbs free energy of this ATP induced transition was calculated. Furthermore, an excess of substrate, meaning trans-inhibition of the transporter is resulting mechanistically in a reverse transition from the outward-facing state to an occluded conformation predominantly.3 This work unravels the central role of the reversible conformational equilibrium in the function and regulation of an ABC exporter. For the first time it is shown that the conformational thermodynamics of a large membrane protein complex can be investigated. The presented experiments give new possibilities to investigate other related medically important transporters with asymmetric NBSs or other similar protein complexes.
Protein quality control (PQC) machinery is in charge of ensuring protein homeostasis in the cell, i.e. proteostasis. Chaperones assist polypeptides throughout their maturation until functionality is achieved. This process might be disrupted in the presence of mutations or external damaging agents that affect the folding and stability of proteins. In this case, proteins can be efficiently recognized and targeted for degradation in a controlled manner. Ubiquitylation refers to the covalent attachment of one or more ubiquitin moieties to faulty proteins, thus triggering their degradation by the 26S proteasome.
More than 30% of proteins need cofactor molecules. Lack of cofactors renders proteins non-functional. We wanted to understand how the PQC deals with wild-type proteins in the absence of their cofactors. Several studies have indicated the importance of the riboflavin-derived cofactor FAD in the stability of individual flavoproteins, and hence we assumed that loss of flavin should mediate a targeted degradation of this group of proteins. Indeed, our mass spectrometry experiments showed that flavoproteome levels decreased under riboflavin starvation. The oxidoreductase NQO1 was used as a model enzyme to further investigate the mechanism of flavoproteome targeting by the PQC. We showed that cofactor loading determines ubiquitylation of NQO1 by the co-chaperone CHIP, both in vivo and in vitro. Furthermore, subtle changes in the C-terminus of NQO1 in the absence of FAD seemed to be crucial for this recognition event. ApoNQO1 interactome differed from holoNQO1. Chaperones and degradation factors were enriched on NQO1 upon cofactor withdrawal, probably to support maturation and prevent aggregation of the enzyme.
Loss of protein folding and stability, even to a small extent, can enhance the aggregating behavior of proteins. Proper loading with FAD reduced the co-aggregation of NQO1 with Aβ1-42 peptide. We assumed that the flavoproteome might represent aggregating-prone species under riboflavin deprivation. Supportingly, reversible apoNQO1 aggregates were observed in vivo in the absence of cofactor. General amyloidogenesis in vivo also increased under these conditions, apparently as a result of flavoproteome destabilization. In this context, we think that our data might have important implications considering the onset and development of conformational diseases.
This work has shed some light on the therapeutic implications of riboflavin deficiency as well. The sensitivity of melanoma cells towards the alkylating agent methyl methanesulfonate (MMS) increased under riboflavin starvation. Subsequent analyses indicated that a complex metabolic reorganization, mostly affecting proliferation and energy metabolism, occurs in response to starvation. What we suggest to call “flavoaddiction” can be understood as the dependence of melanoma cells on the flavoproteome structural and functional intactness to survive chemotherapy. Understanding this cellular reprogramming in detail might reveal new possibilities for future therapies.
Two salts of the 6,6-difluoro-6H-dibenzo[c,e][1,2]oxaborinin-6-ide anion with different cations
(2020)
The crystal structures are reported of the 6,6-difluoro-6H-dibenzo[c,e][1,2]oxaborinin-6-ide (or 9,9-difluoro-10-oxa-9-boraphenanthren-9-ide) anion with two different cations, namely, potassium 6,6-difluoro-6H-dibenzo[c,e][1,2]oxaborinin-6-ide, K+·C12H8BF2O−, (II), featuring a polymeric structure, and bis(tetraphenylphosphonium) bis(6,6-difluoro-6H-dibenzo[c,e][1,2]oxaborinin-6-ide) acetonitrile trisolvate, 2C24H20P+·2C12H8BF2O−·3CH3CN, (III), which is composed of discrete cations, anions and acetonitrile solvent molecules linked by C—H...O, C—H...N and C—H...F hydrogen bonds. There are only minor differences in the geometrical parameters of the anions in these structures.
De novo fatty acid biosynthesis in humans is accomplished by a multidomain protein, the type I fatty acid synthase (FAS). Although ubiquitously expressed in all tissues, fatty acid synthesis is not essential in normal healthy cells due to sufficient supply with fatty acids by the diet. However, FAS is overexpressed in cancer cells and correlates with tumor malignancy, which makes FAS an attractive selective therapeutic target in tumorigenesis. Herein, we present a crystal structure of the condensing part of murine FAS, highly homologous to human FAS, with octanoyl moieties covalently bound to the transferase (MAT) and the condensation (KS) domain. The MAT domain binds the octanoyl moiety in a novel (unique) conformation, which reflects the pronounced conformational dynamics of the substrate binding site responsible for the MAT substrate promiscuity. In contrast, the KS binding pocket just subtly adapts to the octanoyl moiety upon substrate binding. Besides the rigid domain structure, we found a positive cooperative effect in the substrate binding of the KS domain by a comprehensive enzyme kinetic study. These structural and mechanistic findings contribute significantly to our understanding of the mode of action of FAS and may guide future rational inhibitor designs.
In the last twenty years, there has been splendid progress in energy conversion technologies to have sustainable energy sources. For example, solar cells contribute significantly to energy production as the sun is an enormous source for renewable energy. Currently, the most common commercialized photovoltaic devices are silicon-based. The scientists' main targets are high efficiency, low cost, environmentally friendly, and easy to synthesize new semiconductor materials to replace silicon. Furthermore, understanding the photophysical properties of these materials is very important for designing high efficient photoconversion systems.
This thesis investigates the photophysics of lead-based wide-bandgap perovskites with different dimensionality (2D, 3D) and how they can be optimized for optoelectronic applications. In chapter 1, we present the background and progress in perovskite research. The basic concepts of semiconductor and spectroscopic methods of the applied techniques in this work are discussed in chapter 2.
In the first project (chapter 3.1), we used our time-resolved techniques to study the ultrafast dynamics of energy transfer from the inorganic to the organic layer in a series of three lead-based mixed-halide 2D perovskites containing benzyl ammonium (BA), 1-naphthyl methyl ammonium (NMA), and 1-pyrene methyl ammonium (PMA) thin films.
In the second project (chapter 3.2), we used time-resolved spectroscopic techniques to study the effect of adding 5% of Cs on the dynamics of a mixed-cation wide bandgap bromide-based 3D perovskite.
In another side project (chapter 4), we present the photophysics properties of newly synthesized new Schiff bases containing indole moieties using piperidine as an organic base catalyst and Au@TiO2 as a heterogeneous catalyst. Finally, the results of this work are summarized in Chapter 5 with an outlook and a discussion of open questions for further research.
The family of phytochrome photoreceptors contains proteins with different domain architectures and spectral properties. Knotless phytochromes are one of the three main subgroups classified by their distinct lack of the PAS domain in their photosensory core module, which is in contrast to the canonical PAS-GAF-PHY array. Despite intensive research on the ultrafast photodynamics of phytochromes, little is known about the primary kinetics in knotless phytochromes. Here, we present the ultrafast Pr ⇆ Pfr photodynamics of SynCph2, the best-known knotless phytochrome. Our results show that the excited state lifetime of Pr* (~200 ps) is similar to bacteriophytochromes, but much longer than in most canonical phytochromes. We assign the slow Pr* kinetics to relaxation processes of the chromophore-binding pocket that controls the bilin chromophore’s isomerization step. The Pfr photoconversion dynamics starts with a faster excited state relaxation than in canonical phytochromes, but, despite the differences in the respective domain architectures, proceeds via similar ground state intermediate steps up to Meta-F. Based on our observations, we propose that the kinetic features and overall dynamics of the ultrafast photoreaction are determined to a great extent by the geometrical context (i.e., available space and flexibility) within the binding pocket, while the general reaction steps following the photoexcitation are most likely conserved among the red/far-red phytochromes.
Uncaging approach, native membrane dynamics and lipidic cubic phases in biomolecular solid-state NMR
(2019)
It was previously shown for the Escherichia coli diacylglycerol kinase (DgkA) that enzyme-reactions at the membrane interface can be monitored by solid-state NMR. However, such studies can face problems due to limited accessibility of the active sites: Natural substrates for membrane enzymes, but also ligands for membrane proteins or lipid mediators, are either partitioning into the membrane and cannot be added easily, or if soluble exhibit accessibility restrictions, as they cannot freely pass through lipid bilayers. This situation complicates quantitative kinetic analysis of biochemical processes such as enzyme activity, ligand binding, but also oligomerization or folding reactions in the membrane or at its interface under MAS NMR conditions.
To overcome these limitations the feasibility and possible advantages of the uncaging approach as a new tool for biomolecular solid-state NMR to trigger reactions by light have been explored. DgkA’s enzymatic activity, exemplary of a biochemical process on the membrane interface, was thereby triggered in situ during MAS by light-induced release of its substrates that were rendered inactive with photolabile protecting groups. To be capable of uncaging sufficient amounts of substrate during MAS to follow the enzymatic reaction via 31P real-time NMR measurements, several illumination variants including an existing illumination setup to study retinal proteins under cryogenic conditions via DNP enhanced NMR were tested. As uncaging of micromole amounts of substrates requires a higher flux compared to initiation of a photocycle in retinal proteins, a new illumination setup was built with Bruker Biospin and Leoni Fibertech. It consists of a modified MAS probe and a suitable fiber bundle, allowing to efficiently couple light from high power LEDs into a sapphire rotor containing the sample, without disturbing the magnetic field homogeneity or sample rotation. By reducing the sample volume to the illuminated area up to 60 mM ATP were released by uncaging NPE ATP to initiate DgkA’s activity in several tested membrane mimetics. These mimetics included liposomes and bicelles, which are well established in the field of biomolecular solid state NMR as well as the optically transparent lipidic cubic phase of monoolein, widely used in membrane protein crystallography, but not yet well characterized as membrane mimetic under MAS conditions. A unique and powerful but compared to time and spatial resolution often underrepresented advantage of the uncaging approach for biophysical studies has been demonstrated by successful uncaging of a non-miscible lipid substrate to trigger DgkA’s kinase reaction: Initiation of processes that cannot easily be triggered by mixing. Examples of these are reactions involving highly hydrophobic, membrane partitioning compounds including lipid substrates, ligands or interaction partners, but also oligomerization or folding of biomacromolecules. The herein performed experiments therefore serve as a first demonstration of the uncaging approach’s feasibility and compatibility with a wide variety of membrane mimetics and give a first indication of its potential for a variety of biomolecular solid state NMR experiments.
As high accessibility for solutes has been a second focus for the choice of membrane mimetics, DgkA’s activity in the lipidic cubic phases of monoacylglycerols with its two continuous networks of water channels has been further characterized. Kinetic parameters obtained from 31P real time solid state NMR experiments revealed that DgkA’s activity is similar to activities obtained in swollen cubic phases in a bath solution with wider water channels. Diffusion of ATP in a non swollen cubic phase was however strongly reduced compared to ATP in solution as diffusion measurements showed. Therefore, saturation of the enzyme required distinctly higher ATP concentrations. These results thereby underline the advantage of a non invasive and label free method like NMR to directly gain information about enzymatic reactions of immobilized enzymes in porous materials. The obtained wealth of information from 31P real time NMR experiments and biochemical assays in different membrane mimetics in presence and absence of lipid substrates and activators also provided further insight into DgkA’s enzymatic activity. It confirms ATP binding and hydrolysis in the absence of a lipid substrate, in agreement with the proposed mode of substrate binding, and allowed to estimate the in vivo relevance of previously observed ATPase activity in liposomes.
Further exploration of the cubic phase as membrane mimetic for protein solid state NMR revealed its high stability under MAS at elevated temperatures and capacity to reconstitute sufficient amounts of DgkA. Unlike monoolein, DgkA was cross-polarizable in a cubic phase and exhibited similar dynamics compared to DgkA reconstituted into liposomes, allowing to acquire the herein shown dipolar coupling based 2D protein spectra. As lipidic cubic phases are not containing phospholipids, monoacylglycerols could be especially useful as membrane mimetics for 31P correlation spectra. Initial experiments under DNP conditions, where in liposomes line broadening causes severe overlap of phospholipid signals and unspecific cross polarization highlight this aspect.
In summary, herein reported results of the experiments performed with lipidic cubic phases demonstrate that they are robust and versatile membrane mimetics. They could be of advantage for a variety of solid-state NMR experiments where either optical transparency for efficient illumination is desired, accessibility for solutes and membrane components under MAS is required, or interference of phosphorous signals of other membrane mimetics must be avoided.
In the second chapter of this thesis 1H solid-state NMR as a label free method to probe membrane order and dynamics directly within a cellular and disease relevant context was used to observe the effects of soluble epoxide hydrolase (sEH) encoding gene knock-outs on membrane dynamics. Knock-out of the sEH encoding gene changed the overall membrane dynamics in the physiological temperature range of native membranes derived from mouse brains, making the bulk membrane more dynamic. To confirm that these effects are related to the enzymatic activity of sEH, substrates and products of sEH were added to evaluate their effects on membrane dynamics. 19,20 dihydroxydocosapentaenoic acid (DHDP), a product of sEH, partially reversed the knock out phenotype in a concentration dependent manner whereas the substrate 19,20 epoxydocosapentaenoic acid did not cause any effects. As both polyunsaturated fatty acids did not show differences in phase behavior in a simple phospholipid bilayer these results provide evidence that the previously observed concentration dependent DHDP induced relocation of cholesterol away from detergent resistant lipid raft fractions is associated with alteration of membrane dynamics. Therefore, also the effect of cholesterol removal via cyclodextrin on membrane dynamics was analyzed. Removal of cholesterol led to a similar temperature profile of wild type and knock out membranes thereby supporting the hypothesis that DHDP induced relocation of cholesterol is causing altered membrane dynamics. These alterations have been shown by the lead authors of the collaborative research project to induce relocation of various membrane proteins and are involved in the development of diabetic retinopathy. Furthermore, in this context inhibition of sEH has been shown to inhibit diabetic retinopathy and proposed as target for prevention of one of the leading causes of blindness in the developed world.
Unraveling the activation mechanism of taspase1 which controls the oncogenic AF4–MLL fusion protein
(2015)
We have recently demonstrated that Taspase1-mediated cleavage of the AF4–MLL oncoprotein results in the formation of a stable multiprotein complex which forms the key event for the onset of acute proB leukemia in mice. Therefore, Taspase1 represents a conditional oncoprotein in the context of t(4;11) leukemia. In this report, we used site-directed mutagenesis to unravel the molecular events by which Taspase1 becomes sequentially activated. Monomeric pro-enzymes form dimers which are autocatalytically processed into the enzymatically active form of Taspase1 (αββα). The active enzyme cleaves only very few target proteins, e.g., MLL, MLL4 and TFIIA at their corresponding consensus cleavage sites (CSTasp1) as well as AF4–MLL in the case of leukemogenic translocation. This knowledge was translated into the design of a dominant-negative mutant of Taspase1 (dnTASP1). As expected, simultaneous expression of the leukemogenic AF4–MLL and dnTASP1 causes the disappearance of the leukemogenic oncoprotein, because the uncleaved AF4–MLL protein (328 kDa) is subject to proteasomal degradation, while the cleaved AF4–MLL forms a stable oncogenic multi-protein complex with a very long half-life. Moreover, coexpression of dnTASP1 with a BFP-CSTasp1-GFP FRET biosensor effectively inhibits cleavage. The impact of our findings on future drug development and potential treatment options for t(4;11) leukemia will be discussed.
Ubiquitination is regarded as one of the key post-translational modifications in nearly all biological processes, endowed with numerous layers of complexity. Deubiquitinating enzymes (DUBs) dynamically counterbalance ubiquitination events by deconjugating ubiquitin signals from substrates. Dysregulation of the ubiquitin code and its negative regulators drive various pathologies, such as neurological disorders and cancer.
The DUB ubiquitin-specific peptidase 22 (USP22) is well-known for its essential role in the human Spt-Ada-Gcn5 acetyltransferase (SAGA) complex, mediating the removal of monoubiquitination events from Histone 2A and 2B (H2A and -B), thereby regulating gene transcription. In cancer, USP22 was initially described as a part of an 11-gene expression signature profile, predicting tumor metastasis, reoccurrence and death after therapy in a wide range of tumor cells. However, novel roles for USP22 have emerged recently, accrediting USP22 essential roles in regulating tumor development as well as apoptotic cell death signaling.
One of the hallmarks of cancer is the evasion of cell death, especially apoptosis, a form of programmed cell death (PCD). Necroptosis, a regulated form of necrosis, is regarded as an attractive therapeutic strategy to overcome apoptosis-resistance in tumor cells, although a profound understanding of the exact signaling cascade still remains elusive. Nevertheless, several ubiquitination and deubiquitination events are described in fine-tuning necroptotic signaling.
In this study, we describe a novel role for USP22 in regulating necroptotic cell death signaling in human tumor cell lines. USP22 depletion significantly delayed TNFa/Smac mimetic/zVAD.fmk (TBZ)-induced necroptosis, without affecting TNFa-induced nuclear factor-kappa B (NF-KB) signaling or TNFa-mediated extrinsic apoptosis. Intriguingly, re-expression of USP22 wildtype in the USP22 knockout background could re-sensitize HT-29 cells to TBZ-induced necroptosis, whereas re-constitution with the catalytic inactive mutant USP22 Cys185Ser did not rescue susceptibility to TBZ-induced necroptosis, confirming the USP22 DUB-function a pivotal role in regulating necroptotic cell death. USP22 depletion facilitated ubiquitination and unexpectedly also phosphorylation of Receptor-interacting protein kinase 3 (RIPK3) during necroptosis induction, as shown by Tandem Ubiquitin Binding Entities (TUBE) pulldowns and in vivo (de)ubiquitination immunoprecipitations. To substantiate our findings, we performed mass-spectrometric ubiquitin remnant profiling and identified the three novel USP22-regulated RIPK3 ubiquitination sites Lysine (K) 42, K351 and K518 upon TBZ-induced necroptosis. Further assessment of these ubiquitination sites unraveled, that mutation of K518 in RIPK3 reduced necroptosis-associated RIPK3 ubiquitination and additionally affected RIPK3 phosphorylation upon necroptosis induction. At the same time, genetic knock-in of RIPK3 K518R sensitizes tumor cells to TNFa-induced necroptotic cell death and amplified necrosome formation.
In summary we identified USP22 as a new regulator of TBZ-induced necroptosis in various human tumor cell lines and further unraveled the distinctive role of DUBs and (de)ubiquitination events in controlling programmed cell death signaling.