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Signal transduction via phosphorylated CheY towards the flagellum and the archaellum involves a conserved mechanism of CheY phosphorylation and subsequent conformational changes within CheY. This mechanism is conserved among bacteria and archaea, despite substantial differences in the composition and architecture of archaellum and flagellum, respectively. Phosphorylated CheY has higher affinity towards the bacterial C-ring and its binding leads to conformational changes in the flagellar motor and subsequent rotational switching of the flagellum. In archaea, the adaptor protein CheF resides at the cytoplasmic face of the archaeal C-ring formed by the proteins ArlCDE and interacts with phosphorylated CheY. While the mechanism of CheY binding to the C-ring is well-studied in bacteria, the role of CheF in archaea remains enigmatic and mechanistic insights are absent. Here, we have determined the atomic structures of CheF alone and in complex with activated CheY by X-ray crystallography. CheF forms an elongated dimer with a twisted architecture. We show that CheY binds to the C-terminal tail domain of CheF leading to slight conformational changes within CheF. Our structural, biochemical and genetic analyses reveal the mechanistic basis for CheY binding to CheF and allow us to propose a model for rotational switching of the archaellum.
Chapter I of this work addressed the piggyBac (PB) transposon system, a non-viral genome engineering tool that is capable of efficiently performing stable integration of DNA sequences into a target cells genome and has already been used in clinical trials. However, the PB transposase has the problematic property of preferentially integrating transposons near transcriptional start sites (TSSs). This increases the likelihood of causing genotoxic effects, limiting its potential use as a tool in clinical applications. It has been shown in the past that the PB transposase shows physical interactions with BET proteins (e.g. BRD4) through Co-IP experiments. Representatives of these proteins are part of the transcriptional activation complex and are abundant at TSSs. Accordingly, it was previously proposed that this interaction is the underlying cause for the biased integration preference. For the first chapter of this thesis, the goal was to disrupt this interaction potentially modifying said integration preference. A secondary structure hypothesized to be mainly responsible for said interaction was extensively mutated resulting in several PB variants that were analyzed for their interaction capacity through a series of Co-IP experiments with BRD4. In total, seven substitutions were identified (E380F, V390K, T392Y, M394R, K407C, K407Q, and K407V) which exhibited reduced interaction capacity with BRD4. Each of the aforementioned mutants were used to generate integration libraries and, through NGS, it was determined if the integration preferences of the respective mutants had changed. In the immediate range 200 base pairs up- and downstream from known TSSs all mutants used exhibited a reduced integration bias. At a wider observation window 3 kbp up- and downstream from TSSs, further mutants with the substitutions M394R, T392Y and V390K showed a reduction in integration frequency of 17.3%, 1.5% and 5.4%, respectively, compared to the wildtype. Of particular note was the M394R mutant, which showed a reduction in all window sizes analyzed with a maximum of 65% less integration preference in the immediate vicinity of TSSs, theoretically generating a safety advantage over the wildtype transposase.
Chapter II was dedicated to the overall safety improvement for transposon-based gene modification and addresses the time point after the transgene has already been integrated and serious side effects may not be preventable. With this in mind, the aim was to develop a novel suicide-switch that can be stably introduced into cells via transposition, and reliably leads to cell death of the modified cells once activated. A system based on CRISPR/Cas9 was developed, where single guide RNAs were used to guide the Cas9 nuclease to Alu elements. These are short, repetitive sequences, which are distributed over the human genome in more than one million copies. Inducing double strand breaks within these elements would lead to genomic fragmentation and cell death. To be inducible, a transcriptional as well as post- translational control mechanism was added. Transcription of the Cas9 nuclease was regulated using a tet-on system, making expression dependent on doxycycline (DOX) supplementation. Furthermore, a version of the Cas9 nuclease called arC9 was used that allows double strand break generation only in the presence of 4-Hydroxytamoxifen (4-HT). Together with an expression cassette for the Alu-specific guide RNA and an expression cassette for the reverse tetracycline controlled transactivator all components were arranged between transposase-specific recognition sequences on a plasmid to allow transposon-system based gene transfer. The system was tested in HeLa cells. First, conditional expression of the arC9 nuclease was confirmed by addition of 1 μg/ml DOX. Second, the suicide-switch was further induced by adding 200 nM 4-HT and protein extracts were assayed for the KAP1 phosphorylation. Only upon induction with DOX and 4-HT phosphorylated KAP1 was detected, indicating DNA damage. Further, extensive growth and survival experiments were conducted to determine the effect of suicide-switch induction on cell proliferation and survival. Between 24 and 48 hours after induction, a halt in cell division was detected, after which extensive cell death was observed. Within 5 days post induction, >99% of all cells were eliminated. In the absence of both inducers, no significant differences in survival were observed compared to control cells line lacking Alu-specific guide RNAs. Microscopic examinations of the <1% surviving cell fraction revealed a senescence-associated phenotype and showed no signs of resumption of the cell division process. Accordingly, the second chapter of this thesis also achieved its goal in developing a functional suicide-switch that can be inserted into human cells via transposition, is highly dependent on the necessary induction signals, and exhibits excellent elimination capabilities in the context tested.
The scope of this thesis is to elaborate on the use cases of the EEG in pain research. It has been submitted as a cumulative dissertation, meaning that the main part of this thesis has been previously published in international peer-reviewed journals. The first part of this thesis begins with an introduction which describes the general methodoligcal considerations and theoretical background information that is needed to perform pain research using the EEG. Then, I will give a summary of the results of all three studies and the subsequently published manuscripts. The discussion will give an outlook on two ongoing projects and elaborate how the methodology that has been compiled throughout my time as a PhD student can be further applied to scientific problems in pain research. I will conclude with the possibilities and the limitations of the EEG in pain research. The second part of this thesis consists of three publications that cover three individual studies, of which I am the lead/first author. These publications describe different use cases for the EEG in pain research. The first publication lays out the methodological backbone of this thesis, analyzing the exact EEG parameters that are needed to achieve the results in the following projects. Then, I present two additional studies. The first study describes the usefulness of pain-related evoked signatures after standardized noxious stimulation in the EEG in patients undergoing general anesthesia. The second study outlines differences in the pain processing of elite endurance athletes versus a normally active control group. Furthermore, it outlines how the function of the endogenous pain modulatory system can be measured in the EEG using CPM. All studys are discussed individually as per the journal guidelines.
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.
Locomotion, the way animals independently move through space by active muscle contractions, is one of the most apparent animal behaviors. However, in many situations it is more beneficial for animals to actively prevent locomotion, for instance to briefly stop before reorienting with the aim of avoiding predators, or to save energy and recuperate from stress during sleep. The molecular and cellular mechanisms underlying such locomotion inhibition still remain elusive. So, the aim of this study was to utilize the practical genetic model organism Caenorhabditis elegans to efficiently tackle relevant questions on how animals are capable of suppressing locomotion.
Nerve cells, mostly called neurons, are known to control locomotion patterns by activating some and inhibiting other muscle groups in a spatiotemporal manner via local secretion of molecules known as neurotransmitters. This study particularly focuses on whether neuropeptides modulate such neurotransmission to prevent locomotion. Neuropeptides are small protein-like molecules that are secreted by specific neurons and that act in the brain by activating G protein-coupled receptors (GPCRs) expressed in other target neurons. They can act as hormones, neuromodulators or neurotransmitters. DNA sequences coding for neuropeptides and their cognate receptors are similar across diverse species and thus indicate evolutionary conservation of their molecular signaling pathways. This could potentially also imply that regulatory functions of specific neuropeptides are also similar across species and are thus meaningful to unravel more general mechanisms for instance underlying locomotion inhibition.
Specifically, we find that the modulatory interneuron RIS constitutes a dedicated stop neuron of which the activity is sufficient to initiate rapid locomotion arrest in C. elegans while maintaining its body posture. Similar to its known function in larval sleep, RIS requires RFamide neuropeptides encoded by the flp 11 gene for this activity, in addition to GABA. Furthermore, we find that spontaneous calcium activity transients in RIS are compartmentalized and correlated with locomotion stop. These findings illustrate that a single neuron can regulate both stopping and sleeping phenotypes.
Secondly, we show that C. elegans RPamide neuropeptides encoded by nlp-22 and nlp-2 regulate sleep and wakefulness, respectively. We unexpectedly find that these peptides activate gonadotropin-releasing hormone (GnRH)-like receptors dose dependently and we highlight their sequence resemblance to other bilaterian GnRH-like neuropeptides. In addition, we show that these receptors are expressed in distinct subsets of neurons that are associated with motor behavior. Finally, we show that nlp 22 encoded peptides signal through GNNR 6 receptors to regulate larval sleep and that nlp 2 encoded peptides require both GNRR 3 and GNRR 6 receptors to promote wakefulness.
In sum, we find that locomotion inhibition in C. elegans is regulated by multiple, but evolutionary conserved RFamide and GnRH-like RPamide neuropeptidergic signaling pathways.
Diseases such as cardiac arrhythmias, CPVT and other issues of the human heart still remain largely unexplored. To contribute to this field of research, it is necessary to create tools to control the spatial and temporal release and reuptake of Ca2+ from the sarcoplasmic/endoplasmic reticulum (SR/ER). Ca2+ release and uptake by the ryanodine receptor (RyR) and Sarcoplasmic/endoplasmic reticulum calcium ATPase (SERCA), respectively, are essential for the function of excitable cells. In this process, the rapid Ca2+ release from the SR/ER and the associated contraction in muscle cells is modulated by RyR. However, diseases due to calcium leakage, such as cardiac arrhythmias, seizures and contractile dysfunction, are also caused by RyR. The resting Ca2+ concentration in the cytosol, which is important for the cell, is kept in balance by Ca2+ release and reuptake into the SR/ER. This reuptake is controlled quite considerably by SERCA. SERCA is important for development and muscle function in both nematodes such as C. elegans and mammals, though there is also a great need for tools that can help study precise function.
To advance towards the goal of developing tools for optogenetic stimulation of intracellular Ca2+ release from the SR/ER, the model organism C. elegans was chosen. Its advantages are the fully sequenced genome and the neural network connectome. In addition, the ease of maintenance, self-fertilisation, transparency and rapid generation cycles, as well as the fact that it is a eutelic animal, are advantages for the application of the optogenetic approach.
So far, tools for light-induced Ca2+ release (LICR) have already been developed, involving the creation of ChR2 versions with higher Ca2+ conductivity based on the "CatCh" variant and further improving their conductivity through several established mutations. In addition, the pharynx of C. elegans was modified to produce an optogenetically stimulated muscle pump that resembles mammalian cardiac muscle cells. In this work, both optoUNC-68 (optically excitable RyR) and SERCA/LOV2 were generated in different variants by CRISPR/Cas9 and plasmid-based genome editing to achieve light-driven manipulation of calcium homeostasis in C. elegans. Here, LICR was triggered by LOV2 domains in an opto-mechanical manipulation of RyR as well as SERCA. This approach was made possible by recently published high-resolution cryoEM structural images. In addition, alternative approaches using Ca2+ conductance-optimised channelrhodopsin variants were tested in C. elegans body wall muscle cells.
By inserting ChR-XXM into C. elegans and subsequent fluorescence microscopy of the co-introduced GFP, an expression in body wall muscle cells could be detected. Furthermore, in contraction assays, ChR-XXM was demonstrated to induce contractions of the animals of up to 16% compared to the original body length in both medium (0.8mW/mm²) and high (1.4mW/mm²) stimulation at 470nm. ChR-XXM was thus identified as an excellent candidate for the development of an optogenetic tool, as it exhibits significantly increased Ca2+ conductivity compared to other ChR2 variants.
The use of CRISPR/Cas9 to insert AsLOV2 domains (L404-L546) into different insertion sites of RyR allowed the generation of a transgenic strain of C. elegans that could be stimulated to elongate during 0.3mW/mm² photostimulation. This demonstrated that RyR can be manipulated by photostimulation, spatiotemporally through conformational changes in the LOV2 domain and the resulting disruption of the pore region.
The CRISPR/Cas9 method was also used to insert LOV2 domains into SERCA. Here it could be demonstrated that a conformational change of the LOV2 domains induced by photostimulation leads to a stop or impairment of Ca2+ ion translocation by SERCA from the cytosol into the SR/ER. In contrast to LOV2 in RyR, this resulted in a contraction of C. elegans body length.
The data presented here indicate that the intracellular Ca2+ cycle involving the SR/ER and cytosol can be successfully manipulated by the introduction of optogenetic tools. It turned out that the manipulation/impairment of individual components of this system, such as RyR or SERCA, is usually insufficient to achieve a clear response. Therefore, simultaneous manipulation of the two main actors RyR and SERCA is arguably the best way to take another step towards creating optogenetic tools for light-stimulated manipulation of Ca2+ release and reuptake from the SR/ER.
A plethora of modified nucleotides extends the chemical and conformational space for natural occurring RNAs. tRNAs constitute the class of RNAs with the highest modification rate. The extensive modification modulates their overall stability, the fidelity and efficiency of translation. However, the impact of nucleotide modifications on the local structural dynamics is not well characterized. Here we show that the incorporation of the modified nucleotides in tRNAfMet from Escherichia coli leads to an increase in the local conformational dynamics, ultimately resulting in the stabilization of the overall tertiary structure. Through analysis of the local dynamics by NMR spectroscopic methods we find that, although the overall thermal stability of the tRNA is higher for the modified molecule, the conformational fluctuations on the local level are increased in comparison to an unmodified tRNA. In consequence, the melting of individual base pairs in the unmodified tRNA is determined by high entropic penalties compared to the modified. Further, we find that the modifications lead to a stabilization of long-range interactions harmonizing the stability of the tRNA’s secondary and tertiary structure. Our results demonstrate that the increase in chemical space through introduction of modifications enables the population of otherwise inaccessible conformational substates.
Rhizomes from Zingiber officinale Roscoe are traditionally used for the treatment of a plethora of pathophysiological conditions such as diarrhea, nausea, or rheumatoid arthritis. While 6-gingerol is the pungent principle in fresh ginger, in dried rhizomes, 6-gingerol is dehydrated to 6-shogaol. 6-Shogaol has been demonstrated to exhibit anticancer, antioxidative, and anti-inflammatory actions more effectively than 6-gingerol due to the presence of an electrophilic Michael acceptor moiety. In vitro, 6-shogaol exhibits anti-inflammatory actions in a variety of cell types, including leukocytes. Our study focused on the effects of 6-shogaol on activated endothelial cells. We found that 6-shogaol significantly reduced the adhesion of leukocytes onto lipopolysaccharide (LPS)-activated human umbilical vein endothelial cells (HUVECs), resulting in a significantly reduced transmigration of THP-1 cells through an endothelial cell monolayer. Analyzing the mediators of endothelial cell–leukocyte interactions, we found that 30 µM of 6-shogaol blocked the LPS-triggered mRNA and protein expression of cell adhesion molecules. In concert with this, our study demonstrates that the LPS-induced nuclear factor κB (NFκB) promoter activity was significantly reduced upon treatment with 6-shogaol. Interestingly, the nuclear translocation of p65 was slightly decreased, and protein levels of the LPS receptor Toll-like receptor 4 remained unimpaired. Analyzing the impact of 6-shogaol on angiogenesis-related cell functions in vitro, we found that 6-shogaol attenuated the proliferation as well as the directed and undirected migration of HUVECs. Of note, 6-shogaol also strongly reduced the chemotactic migration of endothelial cells in the direction of a serum gradient. Moreover, 30 µM of 6-shogaol blocked the formation of vascular endothelial growth factor (VEGF)-induced endothelial sprouts from HUVEC spheroids and from murine aortic rings. Importantly, this study shows for the first time that 6-shogaol exhibits a vascular-disruptive impact on angiogenic sprouts from murine aortae. Our study demonstrates that the main bioactive ingredient in dried ginger, 6-shogaol, exhibits beneficial characteristics as an inhibitor of inflammation- and angiogenesis-related processes in vascular endothelial cells.
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.
Malfunction of the actin cytoskeleton is linked to numerous human diseases including neurological disorders and cancer. LIMK1 (LIM domain kinase 1) and its paralogue LIMK2 are two closely related kinases that control actin cytoskeleton dynamics. Consequently, they are potential therapeutic targets for the treatment of such diseases. In the present review, we describe the LIMK conformational space and its dependence on ligand binding. Furthermore, we explain the unique catalytic mechanism of the kinase, shedding light on substrate recognition and how LIMK activity is regulated. The structural features are evaluated for implications on the drug discovery process. Finally, potential future directions for targeting LIMKs pharmacologically, also beyond just inhibiting the kinase domain, are discussed.
The peptide loading complex (PLC) is a central machinery in adaptive immunity ensuring antigen presentation by major histocompatibility complex class I (MHC I) molecules to immune cells. If nucleated cells present foreign antigenic peptides from various origins (e.g., viral infected or cancer cells) on their cell surface they are targeted and eliminated by effector cells of the immune system to protect the organism against the hazard. The antigen presentation process starts with proteasomal degradation. Peptide loading and quality control of most, if not all, MHC I is performed by the PLC. Despite the main components, architecture, and general functions of this labile and multi-subunit assembly have been described, knowledge about the inner mechanics of MHC I loading and quality control in the PLC is limited. Detailed structural insights into the interactions and functions of key elements are lacking. In this PhD thesis, structural and functional aspects of the PLC in peptide loading and quality control of MHC I are unraveled, and the PLC was analyzed from an evolutionary perspective.
First, composition and architecture of native PLC isolated from different mammalian species was analyzed. Comparison of detergent-solubilized PLC from cow and sheep spleens with PLC isolated from human source showed a compositional conservation in mammals, with the central components TAP, ERp57, tapasin, calreticulin, and the MHC I heterodimer were conserved in these species. Negative-stain electron microscopy (EM) analyses revealed an identical overall architecture of PLCs from human, sheep, and cow with two major densities at opposing sides of the plane of the detergent micelle corresponding to endoplasmic reticulum (ER) luminal and cytosolic domains. Interestingly, the glucose-regulated protein 78 (GRP78) was associated only with the PLC from sheep and cow as revealed by mass spectrometry. This ER chaperone is involved in initial folding steps of MHC I but was not co-purified with human PLC, rendering it an interesting target for future functional and in-depth structural studies.
The human PLC was stabilized by reconstitution in membrane mimicking systems that replace the detergent, which is necessary to solubilize the complex. This stabilization allowed detailed structural analysis by single-particle cryogenic electron microscopy (cryo-EM). The structure of the MHC I editing module in the PLC, composed of tapasin, ERp57, calreticulin, MHC I, and β-2-microglobulin (β2m), was solved at an overall resolution of 3.7 Å. Within the structure, two important features were visualized: (i) the editing loop of tapasin, which is directly involved in peptide proofreading of MHC I; (ii) the A-branch of the Asn86 tethered N-linked glycan on MHC I. Both features are crucial elements in the quality control and peptide editing process on MHC I. The editing loop interacts with the peptide binding groove in MHC I. It disturbs the interaction between a cargo peptide C terminus and the F-pocket in the binding groove by displacing Tyr84 and the helices α1 and α2. The helix displacement widens the F-pocket which allows a faster peptide exchange on MHC I. The glycan is bound in its monoglucosylated form (Glc1Man9GlcNAc2) by the lectin domain of calreticulin. The A-branch of this glycan is stretched between MHC I Asn86 and the lectin domain, leading to the hypothesis that the glycan will be released from calreticulin once MHC I is loaded with a favored peptide (pMHC I).
For investigation of the glycan status of MHC I, intact protein liquid chromatography coupled mass spectrometry (LC-MS) was performed under denaturating conditions. An allosteric coupling between peptide loading and removal of the terminal glucose by α-Glucosidase II (GluII) was discovered. In addition, the PLC remained fully intact after peptide loading, which demonstrated GluII action on the PLC once MHC I is loaded.
With establishing GluII as transient interaction partner, this work deepens the knowledge of the molecular sociology of the PLC and how the PLC is involved in the endoplasmic reticulum quality control (ERQC). Further investigation of the ER aminopeptidases ERAP1 and ERAP2 showed that these enzymes neither alone nor together stably interact with the PLC. In contrast, both work independent from the PLC on free peptides in the ER.
LC-MS analysis of the PLC components revealed a very unusual glycosylation pattern of tapasin. Tapasin was observed with N-linked glycans ranging from the full glycan (Man9GlcNAc2) to heavily trimmed glycans, where only a single GlcNAc remained attached to Asn233. In the PLC, tapasin is probably shielded from degradation by ERQC and can remain functional and intact without a full N-linked glycan.
The phospholipid bilayers are the primary constituents of the membrane in living cells in which lipids are hold together in bilayer leaflets through a combination of different forces into the liquid crystalline (Lα) phase. Despite their thin fragile formations, the phospholipid bilayers are responsible for performing a variety of important tasks in the cells, some of which are carried out directly by the lipid bilayers and some by various integral proteins embedded within the bilayers. There have been continues efforts over the past decades to replicate the compound biophysical properties of living cell membranes in model lipid bilayers.
An important question remains unanswered: is it possible to replicate physical properties under “non-equilibrium” conditions as found in cell membranes in model lipid bilayers? In almost all previous studies, the model lipid bilayers were under static conditions – for instance, at zero lateral pressure. However, in living organisms, the cell membranes are involved in continuous (nonequilibrium) exchange and (or) transport of lipid species with the surrounding environment which consequently leads them to experience continuous lateral pressure variations. One suitable in vitro approach is to spatiotemporally control the model lipid bilayers over a time period during which they can be spatially stimulated at a level compatible to that found under in vivo conditions. This can be achieved with high spatiotemporal resolution by making lipids light-dependent through implementation of azobenzene photoswitch in their structures.
In this study, a specific azobenzene containing photolipid (AzoPC) is integrated into POPE:POPG bilayers (POPE: 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphoethanolamine, POPG: 1-palmitoyl-2-oleoyl-sn-glycero-3-phospho-(1'-rac-glycerol)) at ~14 mol% to construct a photo responsive model bilayers entitled as photoliposomes. Magic angle spinning solid-state NMR spectroscopy (MAS-NMR) at high field (850 MHz) is the measurement technique of choice by which it is possible to pursue the dynamics (fluidity) of the bulk lipids within the photoliposomes at atomistic resolution. It is shown that the AzoPCs undergo an efficient trans-to-cis isomerization (~85%) within the photoliposomes as the result of UV light absorption, and thermally relax back to the trans state during a period of ~65 h under the MAS measurement conditions. The order parameter measurements based on the C−H dipolar couplings reveal that the non-equilibrium cis-to-trans thermal isomerization impact of AzoPC on the fluidity of the bulk lipid is highly localized – the fluidity perturbations originate from specific order parameter changes in the middle section of the bulk lipid acyl chains. Further 1H NOESY measurements confirm the hypothesis that the azoswitch topologies in either cis and trans conformer of the photolipid is the key parameter in localized alteration of the C−H order parameters along the bulk lipid acyl chains.
Diacylglycerol kinase (DgkA) from E. coli is an enzyme responsible for the phosphorylation of diacylglycerol to phosphatidic acid, at the expense of adenosine triphosphate. Structurally, DgkA is a homo oligomer composed of three symmetric 14 kDa protomers, each of which has three transmembrane helices and one surface helix. Upon embedding within the photoliposomes, it is shown that DgkA enhances the AzoPC localization impact on the fluidity of the bulk lipids. In this regard, the results of a series of statistical simulations of lipid lateral diffusions along the bilayer leaflets in presence and absence of embedded proteins are accompanied with those of experimentally measured based upon which it is justified that membrane proteins markedly limit lipid lateral diffusions in the bilayers. In case of the DgkA proteo-liposomes with lipid-to-protein ratio of 50, it is estimated that the diffusion coefficient of lipids is above 2-fold lower compared to that of the protein free liposomes.
The cis-to-trans AzoPC isomerization and its following consequence in localized alteration of the bulk lipid fluidity is further investigated on the structural dynamics and enzymatic functionality of the embedded DgkA within the proteo-photoliposomes. It is revealed that DgkA structural dynamics are perturbated in a multi-scale, complex manner. The dynamics of residues located in different regions of DgkA changes with the light-induced AzoPC isomerization, but their time courses differ from residue to residue. For example, 29Ala, a residue on the hinge between the surface helix and membrane helix-1, exhibits the steepest time-dependent cross peak intensity changes in time-resolved NCA spectra. The impact of the lasting membrane fluidity perturbation on the enzymatic functionality of the embedded DgkA is subsequently measured which demonstrates a significant variation under cis- and trans-AzoPC conformations within the proteo-photoliposomes.
Ceramide synthase (CerS) is the enzyme responsible for the de novo synthesis of ceramide. In this process, the different CerS isoforms are substrate-specific and produce ceramides of different chain lengths. Ceramides form the backbone for other sphingolipids and are enriched in membrane microdomains called lipid rafts. Lipid rafts are important signaling platforms for many transmembrane proteins, but can also act as bioactive lipids. Depending on the chain length, the effects on signaling pathways can vary. The aim of this work was to further investigate the chain length-specific effects by CerS4 on the progression of inflammatory colon cancer. To understand the tissue-specific effects of CerS4 deficiency on the progression of acute colitis and colitis-associated cancer (CAC), CerS4 knockout models were used. Disease progression of wild-type CerS4 (WT) was compared with that of mice with global CerS4 knockout (CerS4 KO) and mice in which CerS4 deficiency was restricted to T cells (CerS4 LCK/Cre) or intestinal cells (CerS4 Vil/Cre). Acute colitis was induced with sodium dextran sulfate (DSS), whereas azoxymethane (AOM)/DSS combinations were used to induce CAC in mice. The results showed a different disease progression depending on the specific knockout. While CerS4 KO mice were sensitive to DSS. AOM/DSS treatment was lethal for these mice, indicating an important role of CerS4 in other tissues. CerS4 Vil/Cre mice were protected from tumor formation. In contrast, CerS4 LCK/Cre mice experienced increased tumor formation and pan-inflammation. The mechanism behind this is due to the absence of cytotoxic T cells and the increase of regulatory T cells in the CerS4 LCK/Cre mice, demonstrating that CerS4 is critical for T cell function and development. To understand the role of CerS in humans, organoids were prepared from patients and the CerS profile in the different organoids was elucidated. This work provides, for the first time, insights into the CerS profile in human organoids and demonstrates a link between differentiation markers and stem cell markers with CerS. In addition, the role of CerS4 was investigated in vitro using three different colon cell lines-Caco-2 cells, HCT116 cells, and HCT15 cells. Hypoxia induced downregulation of CerS4 in all cell lines. Using the luciferase promoter assay, hypoxia-induced downregulation could already be detected at the promoter. Downregulation of CerS4 and CerS5 in Caco-2 cells and HCT116 cells resulted in different metabolic changes and mitochondrial dynamics after hypoxia. In conclusion, the results show that the role of CerS4 depends on the tissue cell type and stage of colorectal carcinoma, which complicates the consideration of CerS4 as a target in patients.
To better understand the role of sphingolipids in the multifactorial process of inflammatory bowel disease (IBD), we elucidated the role of CerS4 in colitis and colitis-associated cancer (CAC). For this, we utilized the azoxymethane/dextran sodium sulphate (AOM/DSS)-induced colitis model in global CerS4 knockout (CerS4 KO), intestinal epithelial (CerS4 Vil/Cre), or T-cell restricted knockout (CerS4 LCK/Cre) mice. CerS4 KO mice were highly sensitive to the toxic effect of AOM/DSS, leading to a high mortality rate. CerS4 Vil/Cre mice had smaller tumors than WT mice. In contrast, CerS4 LCK/Cre mice frequently suffered from pancolitis and developed more colon tumors. In vitro, CerS4-depleted CD8+ T-cells isolated from the thymi of CerS4 LCK/Cre mice showed impaired proliferation and prolonged cytokine production after stimulation in comparison with T-cells from WT mice. Depletion of CerS4 in human Jurkat T-cells led to a constitutively activated T-cell receptor and NF-κB signaling pathway. In conclusion, the deficiency of CerS4 in T-cells led to an enduring active status of these cells and prevents the resolution of inflammation, leading to a higher tumor burden in the CAC mouse model. In contrast, CerS4 deficiency in epithelial cells resulted in smaller colon tumors and seemed to be beneficial. The higher tumor incidence in CerS4 LCK/Cre mice and the toxic effect of AOM/DSS in CerS4 KO mice exhibited the importance of CerS4 in other tissues and revealed the complexity of general targeting CerS4.
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.
BH3 mimetics are promising novel anticancer therapeutics. By selectively inhibiting BCL-2, BCL-xL, or MCL-1 (i.e. ABT-199, A-1331852, S63845) they shift the balance of pro- and anti-apoptotic proteins in favor of apoptosis. As Bromodomain and Extra Terminal (BET) protein inhibitors promote pro-apoptotic rebalancing, we evaluated the potential of the BET inhibitor JQ1 in combination with ABT-199, A-1331852 or S63845 in rhabdomyosarcoma (RMS) cells. The strongest synergistic interaction was identified for JQ1/A-1331852 and JQ1/S63845 co-treatment, which reduced cell viability and long-term clonogenic survival. Mechanistic studies revealed that JQ1 upregulated BIM and NOXA accompanied by downregulation of BCL-xL, promoting pro-apoptotic rebalancing of BCL-2 proteins. JQ1/A-1331852 and JQ1/S63845 co-treatment enhanced this pro-apoptotic rebalancing and triggered BAK- and BAX-dependent apoptosis since a) genetic silencing of BIM, BAK or BAX, b) inhibition of caspase activity with zVAD.fmk and c) overexpression of BCL-2 all rescued JQ1/A-1331852- and JQ1/S63845-induced cell death. Interestingly, NOXA played a different role in both treatments, as genetic silencing of NOXA significantly rescued from JQ1/A-1331852-mediated apoptosis but not from JQ1/S63845-mediated apoptosis. In summary, JQ1/A-1331852 and JQ1/S63845 co-treatment represent new promising therapeutic strategies to synergistically trigger mitochondrial apoptosis in RMS.
Macroautophagy, herein referred to as autophagy, is an evolutionarily conserved homeostatic process that normally occurs inside eukaryotic cells which involves degradation of cytoplasmic substances via lysosomes. It can be induced by various conditions such as starvation and drug exposure, as well as be inhibited by numerous compounds. Under normal conditions, the doublemembrane autophagosomes engulf the cytosolic substrates and deliver them to lysosomes for digestion. These substrates include unnecessary or dysfunctional cell components, such as faulty macromolecules, organelles and even invading pathogens. Autophagosomes are formed through the co-operative work of various autophagy-related (ATG) proteins organized into complexes. Upon closure of the autophagosomes, they fuse with the acidic lysosomes, resulting in formation of autolysosomes and the delivery of lysosomal hydrolases to degrade the engulfed contents. The fusion of the autophagosome with lysosome is carried out by specific SNARE proteins, small GTPases and their effectors including tethers, adaptors and motor proteins. Autophagy is impaired in many human diseases including cancer, neurodegenerative diseases, aging and inflammation. Therefore, manipulation of autophagy pathway holds a great promise for new therapeutic applications ...
Die vorliegende Dissertationsarbeit behandelt eine umfangreiche Studie des nukleären Rezeptors (NR) TLX (engl. tailless homolog, TLX). Als ligandenaktivierbarer Transkriptionsfaktor ist TLX in Differenzierungs- und Proliferationsprozessen involviert und übernimmt somit eine tragende regulatorische Rolle in der Neurogenese von neuronalen Stammzellen87,88. Zahlreiche Studien haben gezeigt, dass eine fehlgesteuerte TLX-Expression mit gravierenden kognitiven, visuellen und neurodegenerativen sowie tumorigenen Erkrankungen assoziiert ist, sodass TLX ein vielversprechendes Wirkstofftarget mit hohem therapeutischem Potential darstellt94,95,99,100 105. Die pharmakologische Validierung von TLX als neues Wirkstofftarget befindet sich allerdings aufgrund limitierter Verfügbarkeit von validierten und potenten synthetischen und natürlichen kleinen organischen Molekülen in einer frühen Phase. Daher ist das Interesse sehr groß neuartige und wünschenswerterweise selektive TLX-Modulatoren zu generieren109,119-121.
Im Rahmen dieser Dissertationsarbeit wurden zu diesem Zweck mehrere Reportergenassays eingeführt, die die in vitro Aktivitätsstudie von TLX sowohl im Gal4-Hybridformat in Kombination mit Gal4-VP16 als starken Transkriptionsaktivator als auch als TLX-Volllängenprotein in HEK293T-Zellen (engl. human embryonic kidney, HEK293T) erlaubten. Zusätzlich wurde Gal4-TLX in Kombination mit VP16-RXRα untersucht, um bisherige unbekannte potentielle Heterodimer-vermittelte Effekte zu studieren. In einem primären Screeningansatz im Gal4-Format unter Verwendung einer kommerziell erhältlichen Wirkstofffragmentbibliothek und ausgewählter strukturähnlicher Wirkstoffe wurden mehrere Wirkstofffragmentkandidaten identifiziert (30, 34, 39, 45 und 47), die einen attraktiven Ausgangspunkt zur Darstellung von TLX-Modulatoren darstellten. Insgesamt wurden in vier Projekten vier strukturdiverse Chemotypen anhand von Struktur-Wirkungs-Beziehungs-Studien anhand der Aktivität an TLX untersucht. Ausgehend von Fragment 34 beinhaltete das erste Projekt die Identifizierung und Charakterisierung von Xanthinderivaten als inverse TLX-Agonisten. Eine systematische Struktur-Wirkungs-Beziehungs-Studie lieferte mehrere hochpotente Derivate, die auf das Grundgerüst von 8-Phenyltheophyllin (97) basierten. Parallel konnte Istradefyllin (116), welches aktuell zur Behandlung der Parkinson-Erkrankung in den USA und Japan Anwendung findet, als potenter inverser TLX-Agonist identifiziert werden. Mehrere orthogonale zelluläre und zellfreie Experimente klassifizierten die Xanthine als neue erste TLX-Modulatoren. Das zweite Projekt umfasste die Identifizierung und Charakterisierung des unselektiven β-Adrenorezeptorblockers Propranolol (54) ausgehend vom Wirkstofffragment 30. Durch eine vorläufige systematische Struktur-Wirkungs-Beziehungs-Untersuchung der aliphatischen Aminoalkoholseitenkette von 54 konnte die sekundäre Aminogruppe als determinierendes Strukturmotiv für eine Aktivität an TLX bestimmt werden. Weitere Migrations- und Zellviabilitätsexperimente demonstrierten erste phänotypische Effekte in T98G-Glioblastomzellen seitens 54, die TLX-vermittelt sein könnten. Das dritte Projekt behandelte die Darstellung eines potenten neuartigen TLX-Agonisten mit Hilfe eines ligandenbasierten Pharmakophormodells. Das verwendete Pharmakophormodell wurde hierbei unter Verwendung des publizierten Referenzliganden ccrp2 (2) und dem identifizierten Wirkstofffragment 45 aus dem vorherigen Screeningansatz generiert. Durch eine anschließende rationale Fragmentfusion von 45 mit weiteren TLX-Agonisten aus dem Wirkstofffragmentscreening konnte der neuartige potente TLX-Agonist 137h synthetisiert werden, welcher eine verbesserte mikrosomale Stabilität im Vergleich zu 45 und 2 aufwies. Das vierte Projekt beinhaltete die Darstellung neuartiger TLX-Modulatoren mit Hilfe eines Scaffold Hopping Ansatzes. Hierbei wurden essentielle Strukturmotive aus der Xanthin-Struktur-Wirkungs-Beziehung (erstes Projekt) auf weitere Wirkstofffragmente übertragen. Die Validierung dieses Scaffold Hoppings anhand der Verbindung 156 führte anhand eines darauf folgenden kombinatorisch-chemischen Ansatzes zur Darstellung einer Substanzbibliothek (255 Amidrohprodukte). Ein Aktivitätsscreening der Amidrohprodukte deutete in den Reportergenassays auf drei aktive TLX-Modulatoren hin (582, 611 und 629), welche nachträglich gezielt synthetisiert, isoliert und erneut auf Aktivität an TLX validiert wurden. Hierbei hob sich besonders 629 hervor, welches in drei orthogonalen zellulären Reportergenassays TLX-vermittelte Effekte aufwies und zusätzlich einen Bindungseffekt an rekombinanter exprimierter TLX-Ligandenbindedomäne zeigte.
Mit dieser Arbeit konnte mit Hilfe der Einführung diverser TLX-basierter Reportergenassays zur Aktivitätsstudie von TLX mehrere strukturdiverse Liganden als potentielle tool compounds identifiziert und charakterisiert werden. Alle abgeleiteten TLX-Modulatoren können somit als wertvolle neue Startpunkte zur Derivatisierung neuartiger potenter Liganden und somit zu einem Fortschritt in der pharmakologischen Validierung von TLX als Wirkstofftarget dienen.
Specialized surveillance mechanisms are essential to maintain the genetic integrity of germ cells, which are not only the source of all somatic cells but also of the germ cells of the next generation. DNA damage and chromosomal aberrations are, therefore, not only detrimental for the individual but affect the entire species. In oocytes, the surveillance of the structural integrity of the DNA is maintained by the p53 family member TAp63α. The TAp63α protein is highly expressed in a closed and inactive state and gets activated to the open conformation upon the detection of DNA damage, in particular DNA double-strand breaks. To understand the cellular response to DNA damage that leads to the TAp63α triggered oocyte death we have investigated the RNA transcriptome of oocytes following irradiation at different time points. The analysis shows enhanced expression of pro-apoptotic and typical p53 target genes such as CDKn1a or Mdm2, concomitant with the activation of TAp63α. While DNA repair genes are not upregulated, inflammation-related genes become transcribed when apoptosis is initiated by activation of STAT transcription factors. Furthermore, comparison with the transcriptional profile of the ΔNp63α isoform from other studies shows only a minimal overlap, suggesting distinct regulatory programs of different p63 isoforms.
The ability of some knotless phytochromes to photoconvert without the PHY domain allows evaluation of the distinct effect of the PHY domain on their photodynamics. Here, we compare the ms dynamics of the single GAF domain (g1) and the GAF-PHY (g1g2) construct of the knotless phytochrome All2699 from cyanobacterium Nostoc punctiforme. While the spectral signatures and occurrence of the intermediates are mostly unchanged by the domain composition, the presence of the PHY domain slows down the early forward and reverse dynamics involving chromophore and protein binding pocket relaxation. We assign this effect to a more restricted binding pocket imprinted by the PHY domain. The photoproduct formation is also slowed down by the presence of the PHY domain but to a lesser extent than the early dynamics. This indicates a rate limiting step within the GAF and not the PHY domain. We further identify a pH dependence of the biphasic photoproduct formation hinting towards a pKa dependent tuning mechanism. Our findings add to the understanding of the role of the individual domains in the photocycle dynamics and provide a basis for engineering of phytochromes towards biotechnological applications.
In Vorarbeiten wurde gezeigt, dass der Kaliumkanal Slack an der Verarbeitung neuropathischer Schmerzen funktionell beteiligt ist und dass das klassische Neuroleptikum Loxapin Slack-abhängig neuropathisches Schmerzverhalten im Mausmodell lindert (Lu et al. 2015).
Ausgehend von Loxapin als Leitstruktur wurden in der vorliegenden Arbeit im FluxOR™ Kaliumkanal-Assay an Slack-transfizierten HEK-Zellen insgesamt 68 neue Loxapin-Derivate gescreent. Hierbei wurden 23 Substanzen mit Slack-aktivierenden Eigenschaften identifiziert, von denen VHP93, VH408 und VH425 weiter in vivo untersucht wurden. Dabei zeigten Mäuse nach systemischer Gabe von VHP93 ein reduziertes Verhalten in einem Modell für neuropathische Schmerzen. Dem gegenüber wurde durch VH408 das Verhalten im neuropathischen Schmerzmodell nicht beeinflusst.
Des Weiteren konnte in dieser Arbeit gezeigt werden, dass durch eine Slack-Aktivierung nicht nur neuropathisches Schmerzverhalten gehemmt wird, sondern auch die Kratzreaktionen im Chloroquin-Modell des Histamin-unabhängigen Juckreizes reduziert werden können.
Neben Slack wurde in dieser Arbeit auch die Gewebsexpression und funktionelle Bedeutung des eng mit Slack verwandten Kaliumkanals Slick charakterisiert. Expressionsanalysen ergaben, dass Slick überwiegend in dünn myelinisierten A-delta-Fasern und inhibitorischen Interneuronen im Dorsalhorn des Rückenmarks lokalisiert ist. Tierexperimentelle Untersuchungen zeigten, dass Slick-Knockout-Mäuse ein erhöhtes Schmerzverhalten nach thermischer Stimulation aufwiesen. Außerdem wurde bei Slick-Knockout-Mäusen in der späten Phase des Capsaicin- und Formalin-Tests ein signifikant erhöhtes Leckverhalten verzeichnet. Die Ergebnisse dieser Arbeit liefern somit Hinweise auf eine funktionelle Beteiligung von Slick bei der Detektion von Hitzeschmerzen und bei der TRPV1- und TRPA1-vermittelten Schmerzantwort. Zusammengefasst zeigen diese Daten, dass Slick vorrangig an der Verarbeitung thermischer und chemischer Noxen beteiligt ist und dabei eine antinozizeptive Funktion ausübt.
Riboswitch RNAs regulate gene expression by conformational changes induced by environmental conditions and specific ligand binding. The guanidine-II riboswitch is proposed to bind the small molecule guanidinium and to subsequently form a kissing loop interaction between the P1 and P2 hairpins. While an interaction was shown for isolated hairpins in crystallization and electron paramagnetic resonance experiments, an intrastrand kissing loop formation has not been demonstrated. Here, we report the first evidence of this interaction in cis in a ligand and Mg2+ dependent manner. Using single-molecule FRET spectroscopy and detailed structural information from coarse-grained simulations, we observe and characterize three interconvertible states representing an open and kissing loop conformation as well as a novel Mg2+ dependent state for the guanidine-II riboswitch from E. coli. The results further substantiate the proposed switching mechanism and provide detailed insight into the regulation mechanism for the guanidine-II riboswitch class. Combining single molecule experiments and coarse-grained simulations therefore provides a promising perspective in resolving the conformational changes induced by environmental conditions and to yield molecular insights into RNA regulation.
Membrane proteins are a diverse group of proteins that serve a multitude of purposes with one of the most important ones being transport. All kinds of substrates are shuffled over biological membranes with the help of dedicated proteins enabling the transport along and against a concentration gradient. Within the group of actively transporting proteins a diverse set of proteins that rely on an electrochemical gradient to facilitate transport of a substrate against its concentration gradient can be found. Those so-called secondary active
transporters are a group on integral membrane proteins ubiquitous to all cells. They allow the transport of all kinds of substrates like nutrients, ions, other metabolites and drugs over the hydrophobic barrier created by the cellular and organellar membrane. The gradients that provide the main driving force for most of the transporters are either sodium ions or protons, although transporters utilizing other ions or organic compounds are found as well. In case of exchangers two very similar substrates are transported in opposing direction over the membrane, one against its electrochemical gradient driven by the other.
Along with a structural diversity of the transporters concerning overall shape, oligomerization and number of transmembrane elements comes a mechanistic variety though still following the principle of alternating access. In humans the malfunction of secondary active transporters can lead to a physiological disorders such as epilepsy, depression or obesity.
The focus of this thesis was the structural and functional characterization of the secondary active transporter SeCitS from Salmonella enterica, a symporter of the 2-hydroxycarboxylate family. The transport of citrate as a bivalent ion is facilitated by the flux of sodium ions that have an inward-facing gradient over the inner membrane of Salmonella enterica. Transport experiments showed that the transport ratio is two sodium ions per citrate molecule, netting in an electroneutral transport. Compared to other members of the family the specificity of the transporter towards its main substrate is very high.
Structural information on the protein was initially obtained through 2D electron crystallography, which allowed the identification of the oval shaped dimer and a first hint towards a significant conformational change that the protein undergoes during its transport cycle. Using 3D crystallography, the X-ray structure of the transporter was solved. The protein crystalizes as a stable, but conformationally asymmetric dimer. As bound citrate can be readily identified in both protomers they can be assigned into an outward- and an inward-facing conformation, with the main citrate binding site in the outward-facing conformation.
One interesting feature of the crystal structure was the large surface available for multimerization, providing a platform for tight dimerization of the two protomers. On the other hand, SeCitS did not show a true cooperativity of transport. With those two aspects taken into account the question arose if any potential crosstalk between the monomers within the dimer takes place and influences transport (negative cooperativity) or the conformational distribution within the dimer (stabilization of the protein within the membrane).
The functional approach in answering this question was the use of mutated variants of the protein for cross-linking within one monomer. Two residues were chosen respectively to lock one of either conformation to be able to test for transport activity in the remaining protomer. The suitability of the residues was derived from the crystal structure (D112 – R205 to lock the inward-facing conformation and L337 – S412 for the outward-facing conformation). After initial promising results the final variants were not stable enough to be analyzed in transport assays.
To analyze the distribution of relative conformations within the dimer the protein was reconstituted into native-like lipid environment such as nanodiscs or saposin nanoparticles to be analyzed by cryo-electron microscopy. The first images were recorded and did yield promising 2D classes where the general features of the transporter were identified. Yet, an improved preparation is required to obtain a high resolution structure.
The key functional aspects of a transporter are its ability to bind and transport its substrates. In a set of experiments those features were investigated by a radioligand transport assay and by isothermal titration calorimetry (ITC). The transport properties of the protein were assessed in a filter assay using a radioactively labeled citrate as a read-out. The protein was reconstituted into proteoliposomes and subjected to different substrate conditions. Different ions were tested in its ability to drive or inhibit transport, but only sodium ions were able to drive transport and also not hindered by the presence of other ions...
Candida boidinii NAD+-dependent formate dehydrogenase (CbFDH) has gained significant attention for its potential applications in the production of biofuels and various industrial chemicals from inorganic carbon dioxide. The present study reports the atomic X-ray crystal structures of the wild-type CbFDH at cryogenic and ambient temperatures as well as Val120Thr mutant at cryogenic temperature determined at the Turkish Light Source "Turkish DeLight". The structures reveal new hydrogen bonds between Thr120 and water molecules in the mutant CbFDH's active site, suggesting increased stability of the active site and more efficient electron transfer during the reaction. Further experimental data is needed to test these hypotheses. Collectively, our findings provide invaluable insights into future protein engineering efforts that could potentially enhance the efficiency and effectiveness of CbFDH.
Im Rahmen dieser vorliegenden Thesis wurden verschiedene photosensitive Systeme anhand statischer und zeitaufgelöster optischer Spektroskopiemethoden charakterisiert. Das Hauptaugenmerk dieser Arbeit lag in der Entwicklung und Untersuchung neuer Quantenpunkt-basierter Hybridsysteme. Es war möglich die optischen Eigenschaften der Quantenpunkte über Optimierung der Syntheseschritte zu variieren und so auf geplante Projekte anzupassen.
Im Projekt „Quantenpunkte als Zwei-Photonen Antenne“ sollten die hohen Zwei-Photonen Einfangquerschnitte von Quantenpunkten ausgenutzt werden um in Kombination mit einer photolabilen Schutzgruppe, ein Uncaging im NIR-Bereich zu realisieren. Es wurden ZnSe/ZnS Partikel synthetisiert, die eine starke Emission im Bereich der Absorption der Schutzgruppe zeigen. Anhand von zeitaufgelösten transienten Absorptionsexperimenten mit einer Anregungswellenlänge bei 775 nm wurde eine Zwei-Photonen Absorption der Partikel nachgewiesen. Jedoch wurden starke Emissionsbeiträge aus Fallenzuständen und eine geringe Stabilität beobachtet. Die Synthese von CdS/ZnS Quantenpunkten lieferte stabile Partikel mit geringer trap state Emission. Diese Partikel wurden in einem Modellhybridsystem als Energiedonoren eingesetzt. Als Akzeptor wurde der Farbstoff Cumarin343 gewählt. In statischen Absorptions- und Emissionsmessungen, zeitkorrelierten Einzelphotonenmessungen sowie in fs-zeitaufgelösten transiente Absorptionsmessungen konnte ein ultraschneller Energietransfer nach Ein-Photonen Anregung des Hybridsystems beobachtet werden. Über TPiF Messungen wurde die Zwei-Photonen Absorption der Quantenpunkte detektiert. Ein Energietransfer nach Zwei-Photonen Anregung der Quantenpunkte wurde beobachtet. Schließlich wurde ein Hybridsystem aus CdS/ZnS und der photolabilen Schutzgruppe Az-NDBF (Synthese im AK Heckel, Goethe Universität, Frankfurt a. M.) untersucht. Auch in diesem System wurde ein Energietransfer von Quantenpunkt auf die Schutzgruppe nach Ein- und Zwei-Photonen Anregung beobachtet. Anhand von TA Experimenten wurde eine Zeitkonstante von <100 ps für den Energietransfer nach Ein-Photonen Anregung ermittelt. Es konnte anhand der vorgestellten Resultate gezeigt werden, dass sich Quantenpunkte, aufgrund der guten Anpassung ihrer optischen Eigenschaften generell sehr gut als Antennen für organische Verbindungen eigenen.
Des Weiteren wurde ein Hybridsystem aus CdSe/ZnS Quantenpunkten und einer Dyade (Verbindung eines DTE Photoschalters und BODIPY Derivats), entworfen und charakterisiert. Ein ultraschneller EET von BODIPY auf den geschlossenen DTE Schalter wurde in vorangegangenen Studien beobachtet. Dieser EET führte zur Löschung der BODIPY-Emission. Sobald der Photoschalter im offenen Zustand vorliegt, findet aufgrund des fehlenden spektralen Überlapps kein EET statt und es wird die BODIPY-Emission detektiert. Die Erweiterung der Dyade um einen Quantenpunkt zeigte nach Anregung des Quantenpunkts dessen Fluoreszenzlöschung. Da die Emissionsbande der Quantenpunkte im Absorptionsbereich des BODIPY Farbstoffes liegt, konnte über statische und zeitaufgelöste Experimente ein ultraschneller EET von CdS/ZnS auf den Farbstoff ermittelt werden. Dies führte zu der Erweiterung des Anregungsspektrums des BODIPY Farbstoffs. Die Kopplung der Dyade an die Quantenpunktoberfläche lieferte eine Verbindung mit dem breiten Anregungsspekrum des Quantenpunkts und der schaltbaren Fluoreszenz der Dyade.
Das Hybridsystem aus CdSe Quantenpunkten und PDI zeigte vom Verhältnis der Quantenpunkte zu gekoppelten PDI Molekülen abhängige Fluoreszenzsignale. In TA Experimenten wurde ein ultraschneller EET ermittelt. Für hohe PDI Konzentrationen wurde ein weiterer EET von höher angeregten Elektronen auf das PDI identifiziert. Neben der EET Charakterisierung konnte ein zusätzlicher Prozess innerhalb des Hybridsystems mit hoher PDI Konzentration beobachtet werden. Auf den EET von Quantenpunkt auf PDI folgt ein ET aus dem Valenzband des Quantenpunkts in das HOMO des PDI*. In vorangegangene Arbeiten zu Hybridsystemen aus CdSe/ZnS und PDI wurde kein ET beobachtet. In dem beschriebenen Projekt konnte der Einfluss einer passivierenden Schale auf die elektronischen Eigenschaften von CdSe Quantenpunkten gezeigt werden.
Im letzten Teil dieser Thesis wurde die spektroskopische Charakterisierung einer NVOC und zweier NDBF Schutzgruppen beschrieben. Es konnten anhand statischer Absorptionsmessungen eine Freisetzungsquantenausbeute für NVOC-Adenin von 1,1 % ermittelt werden. Die Charakterisierung der Schutzgruppen mit einer NDBF Grundstruktur (DMA-NDBF und Az-NDBF) ergab eine Abhängigkeit der Freisetzungs- und Fluoreszenzausbeute von der Polarität des Lösungsmittels. In polarer Umgebung reduzierten sich die Quantenausbeuten deutlich...
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.
Protein biosynthesis is a fundamental process across all domains of life. Polypeptides are produced by translating the genetic information of the messenger RNA (mRNA) into amino acids. This elaborate procedure is divided into the four distinct phases: initiation, elongation, termination, and ribosome recycling. The phases are controlled and regulated by a multitude of translation factors. During initiation, the ribosome assembles on the mRNA. Initiation factors (IFs) bind to the small ribosomal subunit (SSU) and assist the recruitment of mRNA and initiator transfer RNA (tRNA), which delivers the first amino acid methionine. After positioning the SSU at the start codon of the mRNA, additional IFs support the joining of the large ribosomal subunit (LSU). Next, elongation factors (EFs) deliver amino-acylated tRNAs (aa-tRNAs) to the translating ribosome and assist kinetic proofreading and ribosome subunit translocation after the catalytic transfer of the polypeptide onto the aa-tRNA. When a stop codon is reached, translation is terminated by release factors (RFs) that hydrolyze the peptidyl-tRNA to release the nascent protein chain. Afterwards, the ribosome is recycled in Eukaryotes and Archaea by the conserved and essential factor ABCE1, which splits the ribosome into the LSU and SSU. ABCE1 remains bound to the SSU forming the post-splitting complex (post-SC). mRNA translation closes into a cycle by recruitment of IFs to the post-SC and the start of a new round of initiation. The post-SC presents the platform for translation initiation. However, the role of ABCE1 in initiation remains elusive. Therefore, the main goal of my thesis was to unravel the molecular mechanism of ABCE1 on the post-SC and during initiation complex (IC) assembly.
Using a reconstituted system, the high-resolution structure of the archaeal post-SC was solved by cryogenic electron microscopy (cryo-EM) following the native splitting route. It was the first complete model of an archaeal SSU at atomic resolution and revealed a previously undescribed ribosomal protein, which we termed eS21. The hinge 2 region of ABCE1 was identified to be the major interaction interface that anchors to the SSU. Functional characterization of single residue mutations in hinge 2 unraveled essential interactions with the ribosomal RNA backbone of the SSU. Sensing of SSU-binding was found to be allosterically transmitted to the nucleotide-binding sites (NBSs) for integration into the ATPase cycle of ABCE1.
Reconstitution of the archaeal translation apparatus allowed for dissection of IC assembly in the presence of ABCE1. Three different ICs were resolved by cryo-EM. The results were in accordance with recent structural findings of eukaryotic translation initiation and highlighted that the involvement of ABCE1 is conserved.
In a semi-native approach, recombinant ABCE1 was pulled-down from crenarchaeal cell lysates. Mass spectrometric analysis of co-immunoprecipitated ribosomal complexes identified the association of numerous translation factors to the post-SC in a cellular context. The establishment of the genetic toolbox of the acidothermophilic Sulfolobus acidocaldarius allowed the homologous expression of ABCE1. Pull-down of native ABCE1 revealed similar ribosomal complexes as the semi-native and reconstituted approaches. Together, my results gave first physiological relevance of ABCE1 involvement in mRNA translation initiation in Archaea. Native archaeal ABCE1-ICs were vitrified for structural analysis by cryo-EM. Thereby, future structural analysis will allow to analyze the interactions of ABCE1 on native ICs and identify its role in IC assembly.
To address the molecular process of IC assembly, the binding affinity of aIF1 to the SSU was determined by fluorescence polarization. Similar studies will allow for a detailed functional analysis on IF recruitment to the SSU in presence of ABCE1.
mRNA surveillance and ribosome-associated quality control (RQC) mechanisms evolved to ensure cell viability. The pathways overcome ribosome stalling and defective translation components. Stalled ribosomes are terminated by special RFs, which do not hydrolyze the peptidyl-tRNA, but allow dissociation of the ribosome by ABCE1. Faulty messages are degraded via mRNA decay pathways and the LSU is rescued by RQC factors. Recently, the bacterial RQC factor MutS2 was identified to specifically target collided di- and polysomes but its molecular mechanism remains unknown. In this thesis, initial functional analyses showed tri-phosphate specific nucleotide binding of MutS2. While the dissociation of collided disomes by MutS2 could not be observed, the results pave the way for future in vitro studies of bacterial RQC factors acting on specific ribosome populations.
In the future, mRNA translation research must focus on complex quality control processes to comprehensively understand this fundamental cellular process in a holistic context.
Structural Biology has moved beyond the aim of simply identifying the components of a cellular subsystem towards analysing the dynamics and interactions of multiple players within a cell. This focal shift comes with additional requirements for the analytical tools used to investigate these systems of increased size and complexity, such as Native Mass Spectrometry, which has always been an important tool for structural biology. Scientific advance and recent developments, such as new ways to mimic a cell membrane for a membrane protein, have caused established methods to struggle to keep up with the increased demands. In this review, we summarize the possibilities, which Laser Induced Liquid Bead Ion Desorption (LILBID) mass spectrometry offers with regard to the challenges of modern structural biology, like increasingly complex sample composition, novel membrane mimics and advanced structural analysis, including next neighbor relations and the dynamics of complex formation.
Electronic circular dichroism unravels atropisomers of a broadly absorbing fulgide derivative
(2022)
We prepared and studied six atropisomers with different chiroptical properties emerging from a single, robust, broadly-absorbing fulgide photoswitch. After separation of the different atropisomers via HPLC on a chiral column, their isomerization processes at room temperature and the energy barriers of the different species were investigated in detail using spectroscopic and theoretical methods.
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.
Quinone methide precursors protected with alkyldithiomethyl groups have been synthesized and converted into PNA conjugates. Stable in the absence of reducing agents, the electrophilic quinone methide is released by glutathione in concentrations typical for the cytosol. Self-alkylation then occurs or crosslinking of RNA when hybridized with complementary strands. Fastest reactions are seen for the sterically least hindered compound.
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.
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.
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.
tRNAs are L-shaped RNA molecules of ~ 80 nucleotides that are responsible for decoding the mRNA and for the incorporation of the correct amino acid into the growing peptidyl-chain at the ribosome. They occur in all kingdoms of life and both their functions, and their structure are highly conserved. The L-shaped tertiary structure is based on a cloverleaf-like secondary structure that consists of four base paired stems connected by three to four loops. The anticodon base triplet, which is complementary to the sequence of the mRNA, resides in the anticodon loop whereas the amino acid is attached to the sequence CCA at the 3′-terminus of the molecule. tRNAs exhibit very stable secondary and tertiary structures and contain up to 10% modified nucleotides. However, their structure and function can also be maintained in the absence of nucleotide modifications. Here, we present the assignments of nucleobase resonances of the non-modified 77 nt tRNAIle from the gram-negative bacterium Escherichia coli. We obtained assignments for all imino resonances visible in the spectra of the tRNA as well as for additional exchangeable and non-exchangeable protons and for heteronuclei of the nucleobases. Based on these assignments we could determine the chemical shift differences between modified and non-modified tRNAIle as a first step towards the analysis of the effect of nucleotide modifications on tRNA’s structure and dynamics.
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.
Focused electron and ion beam induced deposition (FEBID/FIBID) methods have gained significant attention in recent years because of their unique ability for the maskless fabrication of arbitrary three-dimensional shapes. Both techniques enable material deposition down to the nanoscale for applications in materials science and condensed matter physics. However, the number of suitable precursor molecules, especially for high purity deposits, is usually still very limited to date. Additionally, both the FEBID and FIBID process are very complex when assessed in detailed and the development of process-optimize, tailored precursor molecules is not yet possible.
In the first part of this work hexacarbonyl vanadium (V(CO)6) and dimanganese decacarbonyl (Mn2(CO)10) are investigated for their use in FEBID in order to complement the already existing data on transition metal carbonyl precursors. In addition, chemical vapor deposition (CVD) has been carried out to compare compositional differences for electron induced and purely thermal processes. FEBID using V(CO)6 resulted in the formation of a vanadium (oxy)carbide material with a V:C ratio of approx. 0.6-0.9. The material shows a temperature-dependent normalized electrical conductance typical for granular metals in agreement with TEM analysis. Additionally, characterization of the crystalline fractions reveals a cubic VC1-xOx phase in agreement with the phase observed in CVD thin films. Thermal decomposition using CVD yielded material of higher purity with V:C ratios of 1.1-1.3. In contrast, an insulating material with approx. 40 at% Mn is obtained for FEBID using Mn2(CO)10 as precursor with very similar compositions being observed for CVD thin films.
The second part of this work deals with the deposition of defined alloy materials by focused charged particle beam deposition. Three silyl substituted transition metal carbonyl complexes have been synthesized and tested for FEBID, FIBID and CVD. The three precursors investigated were: H3SiMn(CO)5, H3SiCo(CO)4, and H2Si(Co(CO)4)2. FEBID experiments with the manganese derivative show the selective loss of silicon, and metal/metalloid contents of up to 49 at%. Contrary, material derived from both cobalt derivatives did retain the 1:1 and 2:1 Co:Si ratios respectively, resulting in metal/metalloid contents of up to 62 at%. Temperature-dependent normalized electrical conductance measurements of as-grown and post-growth electron beam irradiated samples reveal behavior typical for granular metals except for the as-grown CoSi material which is located on the insulating side of the metal-insulator transition. Ga+-FIBID revealed H2Si(Co(CO)4)2 to be a very suitable precursor, retaining the predefined Co:Si ratio in the deposits, while significant loss of silicon was observed for H3SiCo(CO)4 derived deposits. Contrary to FEBID high metal/metalloid contents of up to 90 at% are obtained. Additionally, temperature dependent electrical properties of dicobalt silicide and the expected ferromagnetic behavior have been observed for the Co2Si-FIBID material. Further analysis enables the proposition of different dominating decomposition channels in FEBID and FIBID based on microstructural features such as bubble formation in FIBID materials.
5-Lipoxygenase (5-LO) is the key enzyme in the formation of pro-inflammatory leukotrienes (LT) which play an important role in a number of inflammatory diseases. Accordingly, 5-LO inhibitors are frequently used to study the role of 5-LO and LT in models of inflammation and cancer. Interestingly, the therapeutic efficacy of these inhibitors is highly variable. Here we show that the frequently used 5-LO inhibitors AA-861, BWA4C, C06, CJ-13,610 and the FDA approved compound zileuton as well as the pan-LO inhibitor nordihydroguaiaretic acid interfere with prostaglandin E2 (PGE2) release into the supernatants of cytokine-stimulated (TNFα/IL-1β) HeLa cervix carcinoma, A549 lung cancer as well as HCA-7 colon carcinoma cells with similar potencies compared to their LT inhibitory activities (IC50 values ranging from 0.1–9.1 µM). In addition, AA-861, BWA4C, CJ-13,610 and zileuton concentration-dependently inhibited bacterial lipopolysaccharide triggered prostaglandin (PG) release into human whole blood. Western Blot analysis revealed that inhibition of expression of enzymes involved in PG synthesis was not part of the underlying mechanism. Also, liberation of arachidonic acid which is the substrate for PG synthesis as well as PGH2 and PGE2 formation were not impaired by the compounds. However, accumulation of intracellular PGE2 was found in the inhibitor treated HeLa cells suggesting inhibition of PG export as major mechanism. Further, experiments showed that the PG exporter ATP-binding cassette transporter multidrug resistance protein 4 (MRP-4) is targeted by the inhibitors and may be involved in the 5-LO inhibitor-mediated PGE2 inhibition. In conclusion, the pharmacological effects of a number of 5-LO inhibitors are compound-specific and involve the potent inhibition of PGE2 export. Results from experimental models on the role of 5-LO in inflammation and pain using 5-LO inhibitors may be misleading and their use as pharmacological tools in experimental models has to be revisited. In addition, 5-LO inhibitors may serve as new scaffolds for the development of potent prostaglandin export inhibitors.
Inflammation or injury to the somatosensory nervous system may result in chronic pain conditions, which affect millions of people and often cause major health problems. Emerging lines of evidence indicate that reactive oxygen species (ROS), such as superoxide anion or hydrogen peroxide, are produced in the nociceptive system during chronic inflammatory and neuropathic pain and act as specific signaling molecules in pain processing. Among potential ROS sources in the somatosensory system are NADPH oxidases, a group of electron-transporting transmembrane enzymes whose sole function seems to be the generation of ROS. Interestingly, the expression and relevant function of the Nox family members Nox1, Nox2, and Nox4 in various cells of the nociceptive system have been demonstrated. Studies using knockout mice or specific knockdown of these isoforms indicate that Nox1, Nox2, and Nox4 specifically contribute to distinct signaling pathways in chronic inflammatory and/or neuropathic pain states. As selective Nox inhibitors are currently being developed and investigated in various physiological and pathophysiological settings, targeting Nox1, Nox2, and/or Nox4 could be a novel strategy for the treatment of chronic pain. Here, we summarize the distinct roles of Nox1, Nox2, and Nox4 in inflammatory and neuropathic processing and discuss the effectiveness of currently available Nox inhibitors in the treatment of chronic pain conditions.
Pulsed dipolar (PD) EPR spectroscopy is an established and reliable tool for the investigation of biomolecules. In terms of long distance and orientation measurements, it is one of the leading methods and further fields of application are constantly being explored. The distances that can be detected with PD EPR also correspond to the range in which almost all important biomolecule interactions occur. In the transition from in vitro spectroscopy to in-cell spectroscopy, the power of PD EPR spectroscopy is particularly evident. It is non-invasive, more sensitive than NMR, and does not exhibit background signals from diamagnetic molecules. In particular, the absence of background signals is of great importance given the high density of molecules within cellular environment. However, like any other spectroscopic method, PD EPR has certain limitations. Owing to the intrinsically fast electron spin echo dephasing at higher temperature, these experiments are commonly carried out in frozen solutions at about 50 K. This temperature is far away from the physiological conditions and the freezing additives used, e.g. glycols, can further influence the structure. To enable measurements with and within living organisms, it is therefore necessary to ascend from the cold depths of the frozen state. At the same time, one has to adapt the spin tags for the desired application. Established nitroxides commonly used for EPR studies are typically susceptible to reduction. Thus, for studies under physiological conditions, e.g. in the cell, one has to fight against the reductive environment in the cell and somehow protect the spin labels. Initial published in-cell experiments within the research group and investigations of homogeneously distributed labeled double-stranded (ds) ‐DNA samples in solid matrices showed promising results and enabled pulsed measurement in the temperature range of 50‐ 295 K. It could also be demonstrated that spherical shielded nitroxides have a significantly longer life span in cellular environments than non-protected ones and first nuclear acids were measured in cell. Based on these results, we have gone further to overcome the standing limitations and developed the use of PD EPR spectroscopy. This work addresses these challenges with the overall goal of advancing the applications of PD EPR spectroscopy for studying biomolecules under physiological conditions.
We have focused on four different approaches. The results of these studies were published in various publications. They are presented and discussed together with further studies and put into the context of research conducted before and after the authors' publications.
In approach 1, we fought against the two main obstacles for using pulsed dipolar spectroscopy at ambient conditions – minimizing phase memory time T2 and averaging of the anisotropic dipolar coupling by rotational diffusion. We focused on an immobilization approach, while using rigid spin labels at same time. Besidesto the distance information, the incorporated rigid spin labels will give additional angular constrains and information about the molecular dynamics.
In approach 2, we focused on the on-site and on-demand formation of nitroxide spin labels using light-sensitive alkyl protection groups. This a very mild and efficient procedure that will hardly interfere with sensitive functional groups present in oligonucleotides or peptides. By establishing this method and using coumarin protecting groups plus two-photon excitation, this property may offer the potential to generate spin labels with very high levels of spatial and temporal resolution.
For approach 3, we used paramagnetic Gd3+ -ions as intrinsically stable labels, which are not reducible within a cellular environment. Easy to mix and bound to encodable lanthanide binding tags within the molecule Interleucin 1β, we were able to measure distances between two tags with PELDOR spectroscopy. We tested the extent to which this system is suitable for in-cell measurements.
Finally, we focus on methods for easier labeling by using non-covalentlabeling techniques. One of these is the novel nitroxide G´ for site-directed spin labeling of nucleic acids, especially for RNA. This spin label is sterically hindered, easy to build and binding occurs in seconds by simply mixing the spin label with the target. For large RNAs, another easy-to-mix and noncovalent spin-labeling strategy will be experimentally accompanied and presented.
The approaches and results described here are intended to demonstrate that the study of the biological functions of biomolecules under physiological conditions by pulsed EPR spectroscopy is feasible and operational. In combination, they will enable the life sciences to make further and faster progress in the search for the molecular master plan.
We synthesized two green-light activatable 5’-caps for oligonucleotides based on the BODIPY and coumarin scaffold. Both bear an alkyne functionality allowing their use in numerous biological applications. They were successfully incorporated in oligonucleotides via solid-phase synthesis. Copper-catalyzed alkyne-azide cycloaddition (CuAAC) using a bisazide photo-tether gave cyclic oligonucleotides that could be relinearized by activation with green light and were shown to exhibit high stability against exonucleases. Chemical ligation as another example for bioconjugation yielded oligonucleotides with an internal strand break site. Irradiation at 530 nm or 565 nm resulted in complete photolysis of both caging groups.
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.
The most versatile tool for visualizing endogenous RNA is molecular beacons (MBs). MBs are modified oligonucleotides that consist of a stem-loop structure equipped with a fluorophore and a quencher at the opposite ends. They only give a fluorescent signal when hybridized to the target RNA. Here we present our recent efforts to enhance the spatiotemporal resolution of RNA visualization by refining MBs.
We first asked if we could refine MBs to visualize defined subcellular populations of RNA in living neurons. To achieve this, we utilize visible light-activatable Q-dye MBs to allow only a subcellular fraction to be activated. Here, the fluorophore at the 5’-end was linked to a second quencher via a photolabile coumarin protecting group. Therefore, the MB only gives a fluorescent signal, when activated with visible light and hybridized to the target. This architecture allowed local activation of a hybridized subpopulation in a defined area of the cell. Knowing the exact origin of the activated RNA, we were able to increase the available monitoring time for neuronal mRNA from several minutes (literature known MBs) to more than 14 hours.
We next asked if it would be possible to gain spatiotemporal control over where the MB hybridization events occur. Therefore, we developed photo-tethered MBs where two phosphates in the loop backbone are covalently linked to each other via two photocages. This prevents the MB from hybridization to the target RNA. Only when light is applied, the photo-tethers are cleaved, and the inherent hybridization function of the MB is activated. This architecture allowed us to control the hybridization of photo-tethered MBs in primary cultured neurons.
In the development of photolabile protecting groups, it is of high interest to selectively modify photochemical properties with structural changes as simple as possible. In this work, knowledge of fluorophore optimization was adopted and used to design new coumarin- based photocages. Photolysis efficiency was selectively modulated by inactivating competitive decay channels, such as twisted intramolecular charge transfer (TICT) or hydrogen-bonding, and the photolytic release of the neurotransmitter serotonin was demonstrated. Structural modifications inspired by the fluorophore ATTO 390 led to a significant increase in the uncaging cross section that can be further improved by the simple addition of a double bond. Ultrafast transient absorption spectroscopy gave insights into the underlying solvent-dependent photophysical dynamics. The chromophores presented here are excellently suited as new photocages in the visible wavelength range due to their simple synthesis and their superior photochemical properties.
During evolution of an RNA world, the development of enzymatic function was essential. Such enzymatic function was linked to RNA sequences capable of adopting specific RNA folds that possess catalytic pockets to promote catalysis. Within this primordial RNA world, initially evolved self-replicating ribozymes presumably mutated to ribozymes with new functions. Schultes and Bartel (Science 2000, 289, 448–452) investigated such conversion from one ribozyme to a new ribozyme with distinctly different catalytic functions. Within a neutral network that linked these two prototype ribozymes, a single RNA chain could be identified that exhibited both enzymatic functions. As commented by Schultes and Bartel, this system possessing one sequence with two enzymatic functions serves as a paradigm for an evolutionary system that allows neutral drifts by stepwise mutation from one ribozyme into a different ribozyme without loss of intermittent function. Here, we investigated this complex functional diversification of ancestral ribozymes by analyzing several RNA sequences within this neutral network between two ribozymes with class III ligase activity and with self-cleavage reactivity. We utilized rapid RNA sample preparation for NMR spectroscopic studies together with SHAPE analysis and in-line probing to characterize secondary structure changes within the neutral network. Our investigations allowed delineation of the secondary structure space and by comparison with the previously determined catalytic function allowed correlation of the structure-function relation of ribozyme function in this neutral network.
Acute myeloid leukemia (AML) is one of the most frequently occurring and fatal types of leukemia. Initiated by genetic alterations in hematopoietic stem and progenitor cells, rapidly proliferating cancer cells (leukemic blasts) infiltrate the bone marrow and damage healthy hematopoiesis. Subgroups of AML are defined by underlying molecular and cytogenetic abnormalities, which are decisive for treatment and prognosis. For AML patients that can be intensively treated, the first line treatment remains a combination of cytarabine and anthracycline, which was developed in the 1970s. While this treatment regimen clears the disease and reinstates normal hematopoiesis (complete remission, CR) in 60% to 80% of patients below the age of 60, CR rates in patients above the age of 60 are only 40% to 50%. Relapse and refractory disease are the major cause of death of AML patients, despite large efforts to improve risk-adjusted post-remission therapy with further chemotherapy cycles and, if possible, allogeneic bone marrow transplantation. Elderly patients are particularly difficult to treat because of age-related comorbidities and because their disease tends to relapse more often than the disease of younger patients. Thus, the cure rates of AML vary with age, with 5-year survival rates of about 50% in young patients, and less than 20% in patients above the age of 65 years. With the median age of AML patients being 68 years, the need for novel therapeutic options is immense. The recent approval of eight new agents (venetoclax, midostaurin, gilteritinib, glasdegib, ivosidenib, enasidenib, gemtuzumab ozogamicin and CPX-351 (liposomal cytarabine and daunorubicin)) has added considerably to the therapeutic armamentarium of AML and has increased cure rates in specific subgroups of AML. However, the high heterogeneity among patients, clonal evolution and commonly occurring drug resistance, which cause the high relapse rates, remain a substantial problem in the treatment of AML. Therefore, a better understanding of currently used therapeutics and further development of novel therapeutics is urgently needed.
In recent years, attention has increasingly focused on therapeutic strategies to interfere with the metabolic requirements of cancer cells. The last three decades have provided extensive insights into the diversity and flexibility of AML metabolism. AML cells use different sources of nutrients compared to normal hematopoietic progenitor cells and reprogram their metabolic pathways to fulfill their exquisite anabolic and energetic needs. As a result, they develop high metabolic plasticity that enables them to thrive in the bone marrow microenvironment, where oxygen and nutrient availability are subject to constant change.
Cancer cells, specifically AML cells, have a strong dependency for the amino acid glutamine. Glutamine serves in energy production, redox control, cell signaling as well as an important nitrogen source. The only enzyme capable of de novo glutamine synthesis is glutamine synthetase (GS). GS catalyzes glutamine production from glutamate and ammonium. In AML, the metabolic role and dependency of GS is poorly understood. Here, we investigated the effects of GS deletion on AML growth, and its functional relevance in AML metabolism. Genetic deletion of GS resulted in a significant decrease of cell growth in vitro, and impaired leukemia progression in vivo in a xenotransplantation mouse model. Interestingly, the dependency of AML cell growth on GS was shown to be independent of its functional role in glutamine synthesis. Glutamine starvation did not increase the dependency of the AML cells on GS, nor did increased glutamine availability rescue the GS-knockout-associated growth disadvantage. Instead, functional studies revealed the role of GS in the detoxification of ammonium. GS-deficient cells showed elevated ammonium secretion as well as a higher sensitivity towards the toxic metabolite. Exogenous provision of 15N-labeled ammonium was detoxified by GS-driven incorporation into glutamine. Studies on cells that had gained resistance to GS-knockout-mediated growth inhibition indicated enzymes involved in the urea cycle and the arginine biogenesis pathway to compensate for a loss of GS. Together, these findings unveiled GS as an important ammonium scavenger in AML.
Clinical studies on AML patients revealed increased ammonium concentrations in the blast-infiltrated bone marrow compared to peripheral blood. In line with this finding, proteome and transcriptome analysis of AML blasts showed a significant upregulation of GS in AML compared to healthy progenitors, further indicating its importance in ammonium detoxification.
Analyzing pathways that contribute to ammonium production revealed protein uptake followed by amino acid catabolism as a yet not identified mechanism supporting AML growth. Protein endocytosis and subsequent proteolytic degradation were shown to rescue AML cells from otherwise growth-inhibiting glucose or amino acid depletion. Furthermore, protein metabolization led to the reactivation of the mammalian target of rapamycin (mTOR) signaling pathway, which was deactivated upon leucine and glutamine depletion, revealing protein consumption as an important alternative source of amino acids in AML.
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Human 5-lipoxygenase (5-LO) is the key enzyme of leukotriene biosynthesis, mostly expressed in leukocytes and thus a crucial component of the innate immune system.
In this study, we show that 5-LO, besides its canonical function as an arachidonic acid metabolizing enzyme, is a regulator of gene expression associated with euchromatin. By Crispr-Cas9-mediated 5-LO knockout (KO) in MonoMac6 (MM6) cells and subsequent RNA-Seq analysis, we identified 5-LO regulated genes which could be clustered to immune/defense response, cell adhesion, transcription and growth/developmental processes. Analysis of differentially expressed genes identified cyclooxygenase-2 (COX2, PTGS2) and kynureninase (KYNU) as strongly regulated 5-LO target genes. 5-LO knockout affected MM6 cell adhesion and tryptophan metabolism via inhibition of the degradation of the immunoregulator kynurenine. By subsequent FAIRE-Seq and 5-LO ChIP-Seq analyses, we found an association of 5-LO with euchromatin, with prominent 5-LO binding to promoter regions in actively transcribed genes. By enrichment analysis of the ChIP-Seq results, we identified potential 5-LO interaction partners. Furthermore, 5-LO ChIP-Seq peaks resemble patterns of H3K27ac histone marks, suggesting that 5-LO recruitment mainly takes place at acetylated histones.>
In summary, we demonstrate a noncanonical function of 5-LO as transcriptional regulator in monocytic cells.
Photoresponsive hydrogels can be employed to coordinate the organization of proteins in three dimensions (3D) and thus to spatiotemporally control their physiochemical properties by light. However, reversible and user-defined tethering of proteins and protein complexes to biomaterials pose a considerable challenge as this is a cumbersome process, which, in many cases, does not support the precise localization of biomolecules in the z direction. Here, we report on the 3D patterning of proteins with polyhistidine tags based on in-situ two-photon lithography. By exploiting a two-photon activatable multivalent chelator head, we established the protein mounting of hydrogels with micrometer precision. In the presence of photosensitizers, a substantially enhanced two-photon activation of the developed tool inside hydrogels was detected, enabling the user-defined 3D protein immobilization in hydrogels with high specificity, micrometer-scale precision, and under mild light doses. Our protein-binding strategy allows the patterning of a wide variety of proteins and offers the possibility to dynamically modify the biofunctional properties of materials at defined subvolumes in 3D.
KMT2A-rearrangements are causative for 70-80% all infant acute lymphoblastic leukemias (Pieters et al., 2019, 2007). Among these, the translocation t(4;11)(q21;23) generating the oncogenic fusion genes KMT2A::AFF1 and AFF1::KMT2A is the most frequent one, accounting for almost every second case of KMT2A-r infant ALL (Meyer et al., 2018). Despite passing a multimodal chemotherapy, 64% of patients achieve an event including relapse or death within four years from diagnosis, and overall survival three years from relapse remains poor with only 17% (Driessen et al., 2016; Pieters et al., 2019, 2007). Vari-ous studies have shown that relapse and therapy resistance were not mediated by chemotherapy-induced mutagenesis as there was no accumulation of secondary mutations in the dominant leukemic clone between diagnosis and relapse (Agraz-Doblas et al., 2019; Andersson et al., 2015; Bardini et al., 2011; Dobbins et al., 2013; Driessen et al., 2013; Mullighan et al., 2007).
Intriguingly, exclusively infant t(4;11) ALL patients were reported to subdivide in two groups depending on the level of HOXA gene cluster expression (Trentin et al., 2009). The HOXAlo group displayed a high expression of IRX1 and the HOXAhi group a low expression of IRX1 (Symeonidou and Ottersbach, 2021; Trentin et al., 2009). Importantly, the HOXAlo/IRX1hi group was characterized to possess a strongly ele-vated relapse incidence compared to the HOXAhi/IRX1lo group (Kang et al., 2012; Stam et al., 2010). IRX1 was identified to upregulate the Early growth response genes EGR1, EGR2 and EGR3 (Kühn et al., 2016).
The doctoral project “EGR-mediated relapse mechanisms in infant t(4;11) acute lymphoblastic leuke-mia” aimed to investigate a potential correlation between the HOXAlo-IRX1-EGR axis and relapse development in infant t(4;11) ALL. The primary objective was to clarify through which molecular mechanism(s) relapse development despite continuous chemotherapy could be achieved. In this context, the role of the EGR genes has been investigated. In addition, this project aimed to disclose molecular targets which could offer novel therapeutic interventions to interfere with therapy resistance and relapse formation.