@phdthesis{LiessneeEller2021, author = {Liess [n{\´e}e Eller], Anna Katharina Luise}, title = {Understanding the regulation of the ubiquitin-conjugating enzyme UBE2S}, doi = {10.25972/OPUS-20419}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-204190}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The ubiquitination of proteins serves as molecular signal to control an enormous number of physiological processes and its dysregulation is connected to human diseases like cancer. The versatility of this signal stems from the diverse ways by which ubiquitin can be attached to its targets. Thus, specificity and tight regulation of the ubiquitination are pivotal requirements of ubiquitin signaling. Ubiquitin-conjugating enzymes (E2s) act at the heart of the ubiquitination cascade, transferring ubiquitin from a ubiquitin-activating enzyme (E1) to a ubiquitin ligase (E3) or substrate. When cooperating with a RING-type E3, ubiquitin-conjugating enzymes can determine linkage specificity in ubiquitin chain formation. Our understanding of the regulation of E2 activities is still limited at a structural level. The work described here identifies two regulation mechanisms in UBE2S, a cognate E2 of the human RING-type E3 anaphase-promoting complex/cyclosome (APC/C). UBE2S elongates ubiquitin chains on APC/C substrates in a Lys11 linkage-specific manner, thereby targeting these substrates for degradation and driving mitotic progression. In addition, UBE2S was found to have a role in DNA repair by enhancing non-homologous end-joining (NHEJ) and causing transcriptional arrest at DNA damage sites in homologous recombination (HR). Furthermore, UBE2S overexpression is a characteristic feature of many cancer types and is connected to poor prognosis and diminished response to therapy. The first regulatory mechanism uncovered in this thesis involves the intramolecular auto-ubiquitination of a particular lysine residue (Lys+5) close to the active site cysteine, presumably through conformational flexibility of the active site region. The Lys+5-linked ubiquitin molecule adopts a donor-like, 'closed' orientation towards UBE2S, thereby conferring auto-inhibition. Notably, Lys+5 is a major physiological ubiquitination site in ~25\% of the human E2 enzymes, thus providing regulatory opportunities beyond UBE2S. Besides the active, monomeric state and the auto-inhibited state caused by auto-ubiquitination, I discovered that UBE2S can adopt a dimeric state. The latter also provides an auto-inhibited state, in which ubiquitin transfer is blocked via the obstruction of donor binding. UBE2S dimerization is promoted by its unique C-terminal extension, suppresses auto-ubiquitination and thereby the proteasomal degradation of UBE2S. Taken together, the data provided in this thesis illustrate the intricate ways by which UBE2S activity is fine-tuned and the notion that structurally diverse mechanisms have evolved to restrict the first step in the catalytic cycle of E2 enzymes.}, subject = {E2}, language = {en} } @phdthesis{Kasaragod2022, author = {Kasaragod, Vikram Babu}, title = {Biochemical and Structural Basis for the Moonlighting Function of Gephyrin}, doi = {10.25972/OPUS-14307}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-143077}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Neurons are specialized cells dedicated to transmit the nerve impulses throughout the human body across specialized structures called synapses. At the synaptic terminals, a crosstalk between multiple macromolecules regulates the structure and function of the presynaptic nerve endings and the postsynaptic recipient sites. Gephyrin is the central organizer at inhibitory postsynaptic specializations and plays a crucial role in the organization of these structures by anchoring GABAA receptors (GABAAR) and glycine receptors (GlyR) to the postsynaptic membrane. This 93 kDa protein features an N-terminal G domain and a C-terminal E domain and the latter interacts directly with the intracellular loop between transmembrane helices 3 and 4 of certain subunits of the GlyRs and GABAARs. Biochemical and structural analyses have already provided valuable insights into the gephyrin-GlyR interaction. Interestingly, biochemical studies on the gephyrin-GABAAR interaction demonstrated that the GABAARs also depend on the same binding site as the GlyRs for the interaction with the gephyrin, but the molecular basis for this receptor specific interaction of gephyrin was still unknown. Co-crystal structures of GephE-GABAAR α3- derived peptides with supporting biochemical data presented in this study deciphered the receptor-specific interactions of gephyrin in atomic detail. In its moonlighting function, gephyrin also catalyzes the terminal step of the evolutionarily conserved molybdenum cofactor biosynthesis. Molybdenum, an essential transition element has to be complexed with a pterin-based cofactor resulting in the formation of the molybdenum cofactor (Moco). Moco is an essential component at the active site of all molybdenum-containing enzymes with the exception of nitrogenase. Mutations in enzymes involved in this pathway lead to a rare yet severe disease called Moco deficiency, which manifest itself in severe neurodevelopmental abnormalities and early childhood death. Moco biosynthesis follows a complex multistep pathway, where in the penultimate step, the N-terminal G domain of gephyrin activates the molybdopterin to form an adenylated molybdopterin intermediate. In the terminal step, this intermediate is then transferred to the C-terminal E domain of gephyrin, which catalyzes the metal insertion and deadenylation reaction to form active Moco. Previous biochemical and structural studies provided valuable insights into the penultimate step of the Moco biosynthesis but the terminal step remained elusive. Through the course of my dissertation, I crystallized the C-terminal E domain in the apo-form as well as in complex with ADP and AMP. These structures shed lightonto the deadenylation reaction and the formation of a ternary E-domain-ADP-Mo/W complex and thus provide structural insight into the metal insertion mechanism. Moreover, the structures also provided molecular insights into a mutation leading to Moco deficiency. Finally, ternary complexes of GephE, ADP and receptor-derived peptides provided first clues regarding the integration of gephyrin's dual functionality. In summary, during the course of the dissertation I was able to derive high resolution structural insights into the interactions between gephyrin and GABAARs, which explain the receptor-specific interaction of gephyrin and, furthermore, these studies can be extended in the future to understand GABAAR subunit-specific interactions of gephyrin. Finally, the understanding of Moco biosynthesis shed light on the molecular basis of the fatal Moco deficiency.}, subject = {Gephyrin}, language = {en} } @phdthesis{Carstensen2018, author = {Carstensen, Anne Carola}, title = {Identification of novel N-MYC interacting proteins reveals N-MYC interaction with TFIIIC}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-143658}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {N-MYC is a member of the human MYC proto-oncogene family, which comprises three transcription factors (C-, N- and L-MYC) that function in multiple biological processes. Deregulated expression of MYC proteins is linked to tumour initiation, maintenance and progression. For example, a large fraction of neuroblastoma displays high N-MYC levels due to an amplification of the N-MYC encoding gene. MYCN-amplified neuroblastoma depend on high N-MYC protein levels, which are maintained by Aurora-A kinase. Aurora-A interaction with N-MYC interferes with degradation of N-MYC via the E3 ubiquitin ligase SCFFBXW7. However, the underlying mechanism of Aurora-A-mediated stabilisation of N-MYC remains to be elucidated. To identify novel N-MYC interacting proteins, which could be involved in N-MYC stabilisation by Aurora-A, a proteomic analysis of purified N-MYC protein complexes was conducted. Since two alanine mutations in MBI of N-MYC, T58A and S62A (N-MYC mut), disable Aurora-A-mediated stabilisation of N-MYC, N-MYC protein complexes from cells expressing either N-MYC wt or mut were analysed. Proteomic analysis revealed that N-MYC interacts with two deubiquitinating enzymes, USP7 and USP11, which catalyse the removal of ubiquitin chains from target proteins, preventing recognition by the proteasome and subsequent degradation. Although N-MYC interaction with USP7 and USP11 was confirmed in subsequent immunoprecipitation experiments, neither USP7, nor USP11 was shown to be involved in the regulation of N-MYC stability. Besides USP7/11, proteomic analyses identified numerous additional N-MYC interacting proteins that were not described to interact with MYC transcription factors previously. Interestingly, many of the identified N-MYC interaction partners displayed a preference for the interaction with N-MYC wt, suggesting a MBI-dependent interaction. Among these were several proteins, which are involved in three-dimensional organisation of chromatin domains and transcriptional elongation by POL II. Not only the interaction of N-MYC with proteins functioning in elongation, such as the DSIF component SPT5 and the PAF1C components CDC73 and CTR9, was validated in immunoprecipitation experiments, but also with the POL III transcription factor TFIIIC and topoisomerases TOP2A/B. ChIP-sequencing analysis of N-MYC and TFIIIC subunit 5 (TFIIIC5) revealed a large number of joint binding sites in POL II promoters and intergenic regions, which are characterised by the presence of a specific motif that is highly similar to the CTCF motif. Additionally, N-MYC was shown to interact with the ring-shaped cohesin complex that is known to bind to CTCF motifs and to assist the insulator protein CTCF. Importantly, individual ChIP experiments demonstrated that N-MYC, TFIIIC5 and cohesin subunit RAD21 occupy joint binding sites comprising a CTCF motif. Collectively, the results indicate that N-MYC functions in two biological processes that have not been linked to MYC biology previously. Furthermore, the identification of joint binding sites of N-MYC, TFIIIC and cohesin and the confirmation of their interaction with each other suggests a novel function of MYC transcription factors in three-dimensional organisation of chromatin.}, subject = {Biologie}, language = {en} } @phdthesis{ScheideNoeth2021, author = {Scheide-N{\"o}th, Jan-Philipp}, title = {Activation of the Interleukin-5 receptor and its inhibition by cyclic peptides}, doi = {10.25972/OPUS-18250}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-182504}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The cytokine interleukin-5 (IL-5) is part of the TH2-mediated immune response. As a key regulator of eosinophilic granulocytes (eosinophils), IL-5 controls multiple aspects of eosinophil life. Eosinophils play a pathogenic role in the onset and progression of atopic diseases as well as hypereosinophilic syndrome (HES). Here, cytotoxic proteins and pro-inflammatory mediators stored in intracellular vesicles termed granula are released upon activation thereby causing local inflammation to fight the pathogen. However, if such inflammation persists, tissue damage and organ failure can occur. Due to the close relationship between eosinophils and IL-5 this cytokine has become a major pharmaceutical target for the treatment of atopic diseases or HES. As observed with other cytokines, IL-5 signals by assembling a heterodimeric receptor complex at the cell surface in a stepwise mechanism. In the first step IL-5 binds to its receptor IL-5Rα (CD125). This membrane-located complex then recruits the so-called common beta chain βc (CD131) into a ternary ligand receptor complex, which leads to activation of intracellular signaling cascades. Based on this mechanism various strategies targeting either IL-5 or IL-5Rα have been developed allowing to specifically abrogate IL-5 signaling. In addition to the classical approach of employing neutralizing antibodies against IL 5/IL-5Rα or antagonistic IL-5 variants, two groups comprising small 18 to 30mer peptides have been discovered, that bind to and block IL-5Rα from binding its activating ligand IL-5. Structure-function studies have provided detailed insights into the architecture and interaction of IL-5IL-5Rα and βc. However, structural information for the ternary IL-5 complex as well as IL-5 inhibiting peptides is still lacking. In this thesis three areas were investigated. Firstly, to obtain insights into the second receptor activation step, i.e. formation of the ternary ligand-receptor complex IL-5•IL-5Rα•βc, a high-yield production for the extracellular domain of βc was established to facilitate structure determination of the ternary ligand receptor assembly by either X-ray crystallography or cryo-electron microscopy. In a second project structure analysis of the ectodomain of IL-5Rα in its unbound conformation was attempted. Data on IL-5Rα in its ligand-free state would provide important information as to whether the wrench-like shaped ectodomain of IL-5Rα adopts a fixed preformed conformation or whether it is flexible to adapt to its ligand binding partner upon interaction. While crystallization of free IL-5Rα failed, as the crystals obtained did not diffract X rays to high resolution, functional analysis strongly points towards a selection fit binding mechanism for IL-5Rα instead of a rigid and fixed IL-5Rα structure. Hence IL-5 possibly binds to a partially open architecture, which then closes to the known wrench-like architecture. The latter is then stabilized by interactions within the D1-D2 interface resulting in the tight binding of IL-5. In a third project X-ray structure analysis of a complex of the IL-5 inhibitory peptide AF17121 bound to the ectodomain of IL-5Rα was performed. This novel structure shows how the small cyclic 18mer peptide tightly binds into the wrench-like cleft formed by domains D1 and D2 of IL-5Rα. Due to the partial overlap of its binding site at IL-5Rα with the epitope for IL-5 binding, the peptide blocks IL-5 from access to key residues for binding explaining how the small peptide can effectively compete with the rather large ligand IL-5. While AF17121 and IL-5 seemingly bind to the same site at IL-5Rα, functional studies however showed that recognition and binding of both ligands differ. With the structure for the peptide-receptor complex at hand, peptide design and engineering could be performed to generate AF17121 analogies with enhanced receptor affinity. Several promising positions in the peptide AF17121 could be identified, which could improve inhibition capacity and might serve as a starting point for AF17121-based peptidomimetics that can yield either superior peptide based IL-5 antagonists or small-molecule-based pharmacophores for future therapies of atopic diseases or the hypereosinophilic syndrome.}, subject = {Interleukin 5}, language = {en} } @phdthesis{Sander2014, author = {Sander, Bodo}, title = {Structural and biochemical characterization of gephyrin and various gephyrin-ligand complexes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-104212}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Efficient synaptic neurotransmission requires the exact apposition of presynaptic terminals and matching neurotransmitter receptor clusters on the postsynaptic side. The receptors are embedded in the postsynaptic density, which also contains scaffolding and regulatory proteins that ensure high local receptor concentrations. At inhibitory synapses the cytosolic scaffolding protein gephyrin assumes an essential organizing role within the postsynaptic density by the formation of self-oligomers which provide a high density of binding sites for certain -amino butyric acid type A (GABAA) and the large majority of glycine receptors (GlyR). Gephyrin contains two oligomerization domains: In isolation, the 20 kDa N-terminal G domain (GephG) and the 46 kDa E domain (GephE) trimerize and dimerize, respectively. In the full-length protein the domains are interconnected by a central ~150 amino acid linker, and only GephG trimerization is utilized, whereas GephE dimerization is prevented, thus suggesting the need for a trigger to release GephE autoinhibition, which would pave the way for the formation of higher oligomers and for efficient receptor clustering. The structural basis for this GephE autoinhibition has remained elusive so far, but the linker was reported to be sufficient for autoinhibition. This work dealt with the biochemical and structural characterization of apo-gephyrin and gephyrin in complexes with ligands which are known to promote the formation of synaptic gephyrin clusters (collybistin and neuroligin 2) and reorganize them (dynein light chain 1). For full-length gephyrin no structural information has been available so far. Atomic force microscopy (AFM) and small-angle X-ray scattering (SAXS) analyses described in this thesis disclosed that the gephyrin trimer forms a highly flexible assembly, which, due to the long linker, can switch between compact and extended conformational states in solution, with a preference for compact states. This partial compaction and potentially GephE autoinhibition are achieved by interactions of parts of the linker with the G and E domains, as suggested by circular dichroism spectroscopy. However, the linker on its own cannot account for GephE blockage, as size exclusion chromatography experiments coupled with multi angle light scattering detection (SEC-MALS) and SAXS analyses revealed that a gephyrin variant only encompassing the linker and GephE (GephLE) forms dimers and not monomers as suggested by an earlier study. The oligomeric state of GephLE and the observation that several gephyrin variants, in which linker segments of varying length were deleted, predominantly formed trimers, suggested the presence of a linker independent mechanism of GephE dimerization blockade. Taken together, the data indicated that linker-dependent and linker-independent mechanisms mediate gephyrin autoinhibition. In the second project gephyrin's interaction with DYNLL1 (Dynein LC8 Light Chain 1) was characterized. DYNLL1 is a 25 kDa dimer incorporated into the dynein motor and provides two binding sites, each of which can accommodate an octapeptide derived from gephyrin's linker region (referred to as GephDB). Originally, DYNLL1 was regarded as a cargo adaptor, linking gephyrin-GlyR complexes to the dynein motor, thus driving their retrograde transport and leading to a decrease of synaptic gephyrin-GlyR complexes. Building on these studies, this thesis assessed the cargo hypothesis as well as the so far unclear stoichiometry of the gephyrin-DYNLL1 complex. The cargo scenario would require ternary complex formation between gephyrin, DYNLL1 and the dynein intermediate chain (DIC) of the dynein motor. However, such a complex could not be detected by analytical size exclusion chromatography (aSEC) experiments - presumably because gephyrin and DIC competed for a common binding site in DYNLL1. This finding was consistent with a single DYNLL1 dimer capturing two linker segments of a single gephyrin trimer as suggested by a 26 kDa mass increase of the gephyrin species in the presence of DYNLL1 in SEC-MALS experiments. aSEC experiments at even higher concentrations (~20 µM gephyrin and ~80 µM DYNLL1) indicated that the affinity of GephDB was significantly impaired in the context of full-length gephyrin but also in a variant that bears only GephG and the first 39 residues of the linker (GephGL220). Presumably due to avidity effects two linkers stably associated with a single DYNLL1 dimer, whereas the third DYNLL1 binding motif remained predominantly unoccupied unless high concentrations of GephGL220 (50 µM) and DYNLL1 (200 µM) were used. These findings indicate that an interplay between GephG and the N-terminal linker segment mediates the attenuation of GephDB affinity towards DYNLL1 and that preventing DYNLL1 from the induction of higher gephyrin oligomers is either advantageous for DYNLL1-mediated reorganization of gephyrin-GlyR clusters or that DYNLL1 exerts possibly two (concentration-dependent) actions on gephyrin. The gephyrin-collybistin-neuroligin 2 complex was the subject of the third project. Previously, collybistin and gephyrin were observed to mutually trigger their translocation to the postsynaptic membrane, where the disordered cytoplasmic tail of the postsynaptic cell adhesion molecule NL2 (NL2cyt) causes the anchoring of collybistin 2 (CB2) by binding to its SH3 domain, thereby releasing SH3 domain mediated autoinhibiton of CB2 binding to the membrane phospholipid phosphatidylinositol-3-phosphate. Critical for this event is the binding of gephyrin to both CB2 and NL2, presumably via GephE. Following up on these previous studies biochemical data presented in this thesis confirm the formation of the ternary complex. Unexpectedly, analyses by means of native polyacrylamide gel electrophoresis pointed to: (1) The existence of a complex containing NL2cyt and CB2 lacking the SH3 domain and consequently an additional NL2 binding site in CB2. (2) Attenuated gephyrin-collybistin complex formation in the presence of the SH3 domain. (3) A requirement for high NL2cyt concentrations (> 30 µM) during the formation of the ternary complex. This might allow for the regulation by other factors such as additional binding partners or posttranslational modifications. Although of preliminary character, these results provide a starting point for future studies, which will hopefully elucidate the interplay between gephyrin, collybistin, NL2 and certain GABAA receptors.}, subject = {Gephyrin}, language = {en} } @phdthesis{Delto2015, author = {Delto, Carolyn Francesca}, title = {Structural and Biochemical Characterization of the GABA(A) Receptor Interacting Protein Muskelin}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-115922}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {In a study from 2011, the protein muskelin was described as a central coordinator of the retrograde transport of GABA(A) receptors in neurons. As muskelin governs the transport along actin filaments as well as microtubules, it might be the first representative of a novel class of regulators, which coordinate cargo transport across the borders of these two independent systems of transport paths and their associated motorproteins. To establish a basis for understanding the mode of operation of muskelin, the aim of this thesis was an in-depth biochemical and structural characterization of muskelin and its interaction with the GABA(A) receptor. One focus of the work was the analysis of the oligomerization of muskelin. As could be demonstrated, the oligomerization is based on two independent interactions mediated by different domains of the protein: a known interaction of the N-terminal discoidin domain with the C-terminal portion, termed head-to-tail interaction, and a dimerization of the LisH motif in muskelin that was so far neglected in the literature. For the detailed studies of both binding events, the solution of a crystal structure of a fragment of muskelin, comprising the Discoidin domain and the LisH motif, was an important basis. The fragment crystallized as a dimer, with dimerization being mediated solely by the LisH motif. Biochemical analysis corroborated that the LisH motif in muskelin serves as a dimerization element, and, moreover, showed that the C-terminal domain of the protein substantially stabilizes this dimerization. In addition, the crystal structure revealed the molecular composition of the surface of the head in the head-to-tail interaction, namely the discoidin domain. This information enabled to map the amino acids contributing to binding, which showed that the binding site of the head-to-tail interaction coincides with the generic ligand binding site of the discoidin domain. As part of the analyses, residues that are critical for LisH-dimerization and the head-to-tail binding, respectively, were identified, whose mutation specifically interfered with each of the interactions separately. These mutations allowed to investigate the interplay of these interactions during oligomerization. It could be shown that recombinant muskelin assembles into a tetramer to which both interactions, the LisH-dimerization and the head-to-tail binding, contribute independently. When one of the two interactions was disturbed, only a dimer mediated via the respective other interaction could be formed; when both interactions were disturbed, the protein was present as monomer. Furthermore, Frank Heisler in the group of Matthias Kneussel was able to show the drastic impact of an impaired LisH-dimerization on muskelin in cells using these mutations. Disturbing the LisH-dimerization led to a complete redistribution of the originally cytoplasmic muskelin to the nucleus which was accompanied by a severe impairment of its function during GABA(A) receptor transport. Following up on these results in an analysis of muskelin variants, for which alterations of the subcellular localization had been published earlier, the crucial influence of LisH-dimerization to the subcellular localization and thereby the role of muskelin in the cell was confirmed. The biochemical studies of the interaction of muskelin and the alpha1 subunit of the GABA(A) receptor demonstrated a direct binding with an affinity in the low micromolar range, which is mediated primarily by the kelch repeat domain in muskelin. For the binding site on the GABA(A) receptor, it was confirmed that the thirteen most C-terminal residues of the intracellular domain are critical for the binding of muskelin. In accordance with the strong conservation of these residues among the alpha subunits of the GABA(A) receptor, it could be shown that an interaction with muskelin in vitro is also possible for the alpha2 and alpha5 subunits. Based on the comparison of the binding sites between the homologous subunits, tentative conclusions can be drawn about the details of the binding, which may serve as a starting point for follow-up studies. This thesis thereby makes valuable contributions to the understanding of muskelin, in particular the significance of its oligomerization. It furthermore provides an experimental framework for future studies that address related topics, such as the characterization of other muskelin interaction partners, or the questions raised in this work.}, subject = {Oligomerisation}, language = {en} } @phdthesis{Ganesan2014, author = {Ganesan, Jayavarshni}, title = {The role of microRNA-378 in cardiac hypertrophy}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-100918}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {MicroRNAs are endogenous ≈22 nt long non coding RNA molecules that modulate gene expression at the post transcriptional level by targeting mRNAs for cleavage or translational repression. MicroRNA-mRNA interaction involves a contiguous and perfect pairing within complementary sites usually in the 3' UTR of the target mRNA. Heart failure is associated with myocyte hypertrophy and death, due to compensatory pathological remodeling and minimal functional repair along with microRNA deregulation. In this study, we identified candidate microRNAs based on their expression strength in cardiomyocytes and by their ability to regulate hypertrophy. Expression profiling from early and late stages of heart failure showed several deregulated microRNAs. Of these microRNAs, miR-378 emerged as a potentially interesting microRNA that was highly expressed in the mouse heart and downregulated in the failing heart. Antihypertrophic activity of miR-378 was first observed by screening a synthetic miR library for morphologic effects on cardiomyocytes, and validated in vitro proving the tight control of hypertrophy by this miR. We combined bioinformatic target prediction analysis and microarray analysis to identify the targets of miR-378. These analyses suggested that factors of the MAP kinase pathway were enriched among miR-378 targets, namely MAPK1 itself (also termed ERK2), the insulin-like growth factor receptor 1 (IGF1R), growth factor receptor bound protein 2 (GRB2) and kinase suppressor of ras 1 (KSR1). Regulation of these targets by miR-378 was then confirmed by mRNA and protein expression analysis. The use of luciferase reporter constructs with natural or mutated miR-378 binding sites further validated these four proteins as direct targets of miR-378. RNA interference with MAPK1 and the other three targets prevented the prohypertrophic effect of antimiR-378, suggesting that they functionally relate to miR-378. In vivo restoration of disease induced loss of miR-378 in a pressure overload mouse model of hypertrophy using adeno associated virus resulted in partial attenuation cardiac hypertrophy and significant improvement in cardiac function along with reduced expression of the four targets in heart. We conclude from these findings that miR-378 is an antihypertrophic microRNA in cardiomyocytes, and the main mechanism underlying this effect is the suppression of the MAP kinase-signaling pathway on four distinct levels. Restoration of disease-associated loss of miR-378 through cardiomyocyte-targeted AAV-miR-378 may prove as an effective therapeutic strategy in myocardial disease.}, subject = {Hypertrophie}, language = {en} } @phdthesis{Bothe2021, author = {Bothe, Sebastian Helmut}, title = {Fragmentbasiertes Design von p97-Liganden: Identifizierung von Startstrukturen zur Entwicklung von Protein-Protein-Interaktionsinhibitoren f{\"u}r die SHP-Bindestelle der AAA+ ATPase p97}, doi = {10.25972/OPUS-23911}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-239112}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {Die AAA+ ATPase p97 ist ein essenzielles Protein, das an einer Vielzahl zellul{\"a}rer Prozesse beteiligt ist und eine Schl{\"u}sselrolle in der Protein-Hom{\"o}ostase spielt. Die funktionale Diversit{\"a}t von p97 beruht auf der Interaktion zahlreicher unterschiedlicher Kofaktoren, die vorwiegend an die N-Dom{\"a}ne von p97 binden. Aufgrund seiner Bedeutung in der Regulierung diverser physiologischer und pathologischer Prozesse stellt p97 eine interessante Zielstruktur f{\"u}r die Entwicklung neuer Wirkstoffe dar, die insbesondere in der Krebstherapie von Bedeutung sein k{\"o}nnte. Bekannte p97-Inhibitoren greifen vor allem die ATPase-Funktion des Proteins an. Ein neuer pharmakologischer Ansatz stellt die Inhibierung der Kofaktorbindung an die N-Dom{\"a}ne dar. Ein solcher Protein-Protein-Interaktionsinhibitor w{\"a}re nicht nur von therapeutischem Interesse, sondern h{\"a}tte auch einen besonderen Nutzen f{\"u}r die Entschl{\"u}sselung molekularer und zellul{\"a}rer Funktionen von p97-Kofaktoren. In dieser Arbeit wurde ein fragmentbasierter Ansatz f{\"u}r die Identifizierung von chemischen Startstrukturen f{\"u}r die Entwicklung eines Protein-Protein- Interaktionsinhibitors verfolgt. Als Zielstruktur wurde die SHP-Bindestelle in der N-Dom{\"a}ne gew{\"a}hlt. Die Identifizierung von Liganden erfolgte sowohl durch computergest{\"u}tzte Methoden (insbesondere virtuelles Screening und Molekulardynamik-Simulationen) als auch experimentell durch biophysikalische Techniken (wie Biolayer-Interferometrie, R{\"o}ntgenstrukturanalyse und ligandbasierte NMR-Techniken). Die Grundlage des computerbasierten Designs stellte eine Analyse der bekannten Kristallstrukturen der p97-Komplexe mit den SHP-Motiven der Kofaktoren UFD1 und Derlin-1 dar. Dar{\"u}ber hinaus dienten Molekulardynamik-Simulationen der Analyse der Wassereigenschaften innerhalb der SHP-Bindestelle. Darauf aufbauend wurden verschiedene Pharmakophormodelle entwickelt, die die Grundlage des im Anschluss durchgef{\"u}hrten virtuellen Screenings und Dockings bildeten. Anhand der Ergebnisse von Molekulardynamik-Simulationen wurden zehn Verbindungen f{\"u}r die experimentelle Validierung ausgew{\"a}hlt. Hiervon konnten zwei Fragmente in STD-NMR- und Biolayer-Interferometrie-Experimenten als Liganden best{\"a}tigt werden. In einem parallel durchgef{\"u}hrten biophysikalischen Fragmentscreening mittels Biolayer-Interferometrie wurden unter mehr als 650 Verbindungen 22 identifiziert, die an die N-Dom{\"a}ne binden. 15 dieser Fragmente wurden durch einen orthogonalen STD-NMR-Assay best{\"a}tigt. F{\"u}nf dieser Verbindungen zeigten Affinit{\"a}ten mit KD-Werten kleiner 500μMund g{\"u}nstigen Ligandeffizienzen. Des Weiteren konnte die Bindungskinetik und Affinit{\"a}t des in der Literatur als p97-Inhibitor berichteten Naturstoffes Xanthohumol bestimmt und eine Bindung an die N-Dom{\"a}ne best{\"a}tigt werden. Zur Identifizierung m{\"o}glicher Bindestellen dieser f{\"u}nf Fragmente wurden mixed-solvent Molekulardynamik-Simulationen durchgef{\"u}hrt. Diese ergaben, dass alle Verbindungen die SHP-Bindestelle in der N-Dom{\"a}ne adressieren. Die Regionen fielen mit hot spots der Kofaktorwechselwirkungen zusammen und stellen somit m{\"o}gliche Ankerpunkte f{\"u}r die Weiterentwicklung dar. F{\"u}r zwei Fragmente konnten die postulierten Bindestellen mittels R{\"o}ntgenstrukturanalyse bzw. STD-NMR-Messungen an p97-Alanin-Mutanten best{\"a}tigt werden. Die erhaltene R{\"o}ntgenstruktur ist die erste p97-Struktur, die ein gebundenes Fragment an der N-Dom{\"a}ne zeigt.}, subject = {Arzneimitteldesign}, language = {de} } @phdthesis{TrujilloViera2022, author = {Trujillo Viera, Jonathan}, title = {Protein kinase D2 drives chylomicron-mediate lipid transport in the intestine and promotes obesity}, doi = {10.25972/OPUS-26509}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-265095}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {Obesity and associated metabolic syndrome are growing concerns in modern society due to the negative consequences for human health and well-being. Cardiovascular diseases and type 2 diabetes are only some of the pathologies associated to overweight. Among the main causes are decreased physical activity and food availability and composition. Diets with high content of fat are energy-dense and their overconsumption leads to an energy imbalance, which ultimately promotes energy storage as fat and obesity. Aberrant activation of signalling cascades and hormonal imbalances are characteristic of this disease and members of the Protein Kinase D (PKD) family have been found to be involved in several mechanisms mediating metabolic homeostasis. Therefore, we aimed to investigate the role of Protein Kinase D2 (PKD2) in the regulation of metabolism. Our investigation initiated with a mice model for global PKD2 inactivation, which allowed us to prove a direct involvement of this kinase in lipids homeostasis and obesity. Inactivation of PKD2 protected the mice from high-fat diet-induced obesity and improved their response to glucose, insulin and lipids. Furthermore, the results indicated that, even though there were no changes in energy intake or expenditure, inactivation of PKD2 limited the absorption of fat from the intestine and promoted energy excretion in feces. These results were verified in a mice model for specific deletion of intestinal PKD2. These mice not only displayed an improved metabolic fitness but also a healthier gut microbiome profile. In addition, we made use of a small-molecule inhibitor of PKD in order to prove that local inhibition of PKD2 in the intestine was sufficient to inhibit lipid absorption. The usage of the inhibitor not only protected the mice from obesity but also was efficient in avoiding additional body-weight gain after obesity was pre-established in mice. Mechanistically, we determined that PKD2 regulates lipids uptake in enterocytes by phosphorylation of Apolipoprotein A4 (APOA4) and regulation of chylomicron-mediated triglyceride absorption. PKD2 deletion or inactivation increased abundance of APOA4 and decreased the size of chylomicrons and therefore lipids absorption from the diet. Moreover, intestinal activation of PKD2 in human obese patients correlated with higher levels of triglycerides in circulation and a detrimental blood profile. In conclusion, we demonstrated that PKD2 is a key regulator of dietary fat absorption in murine and human context, and its inhibition might contribute to the treatment of obesity.}, subject = {Chylomicrons}, language = {en} } @phdthesis{Zink2023, author = {Zink, Christoph}, title = {Biochemische und strukturbiologische Charakterisierung der Inhibition der Pyridoxal 5´-Phosphat Phosphatase durch 7,8-Dihydroxyflavon}, doi = {10.25972/OPUS-25151}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-251511}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2023}, abstract = {Die Pyridoxal-5'-Phosphat Phosphatase (PDXP), auch bekannt als Chronophin (CIN), ist eine HAD-Phosphatase, die beim Menschen ubiquit{\"a}r exprimiert wird und eine entscheidende Rolle im zellul{\"a}ren Vitamin-B6-Metabolismus einnimmt. PDXP ist in der Lage Pyridoxal-5'-Phosphat (PLP), die co-enzymatisch aktive Form von Vitamin B6, zu dephosphorylieren. In-vivo Studien mit M{\"a}usen zeigten, dass die Abwesenheit von PDXP mit verbesserten kognitiven Leistungen und einem verringerten Wachstum von Hirntumoren assoziiert ist. Dies begr{\"u}ndet die gezielte Suche nach einem pharmakologischen Inhibitor f{\"u}r PDXP. Ein Hochdurchsatz-Screen legte nahe, dass 7,8-Dihydroxyflavon (7,8-DHF) hierf{\"u}r ein potenzieller Kandidat ist. Zahlreiche Studien beschreiben bereits vielf{\"a}ltige positive neurologische Effekte nach in-vivo Administration von 7,8-DHF, allerdings bleibt der genaue Wirkmechanismus umstritten und wird bis dato nicht mit PDXP in Zusammenhang gebracht. Ziel dieser Arbeit ist es, die Inhibition von PDXP durch 7,8-DHF n{\"a}her zu charakterisieren und damit einen Beitrag zur Beantwortung der Frage zu leisten, ob PDXP an den 7,8-DHF-induzierten Effekten beteiligt ist. Hierzu wurde der Effekt von 7,8-DHF auf die enzymatische Aktivit{\"a}t von rekombinant hergestelltem, gereinigtem PDXP in in-vitro Phosphatase-Assays charakterisiert. Um die Selektivit{\"a}t von 7,8-DHF gegen{\"u}ber PDXP zu untersuchen, wurden f{\"u}nf weitere HAD-Phosphatasen getestet. Unter den analysierten Phosphatasen zeigte einzig die dem PDXP nah verwandte Phosphoglykolat Phosphatase (PGP) eine geringer ausgepr{\"a}gte Sensitivit{\"a}t gegen 7,8-DHF. Ein Vergleich von 7,8-DHF mit sechs strukturell verwandten, hydroxylierten Flavonen zeigte, dass 7,8-DHF unter den getesteten Substanzen die h{\"o}chste Potenz und Effektivit{\"a}t aufwies. Außerdem wurde eine Co-Kristallisation von PDXP mit 7,8-DHF durchgef{\"u}hrt, deren Struktur bis zu einer Aufl{\"o}sung von 2,0 {\AA} verfeinert werden konnte. Die in der Kristallstruktur identifizierte Bindungsstelle von 7,8-DHF an PDXP wurde mittels verschiedener, neu generierter PDXP-Mutanten enzymkinetisch best{\"a}tigt. Zusammenfassend zeigen die hier beschriebenen Ergebnisse, dass 7,8-DHF ein direkter, selektiver und vorwiegend kompetitiver Inhibitor der PDXP-Aktivit{\"a}t ist, mit einer IC50 im submikromolaren Bereich. Die Ergebnisse dieser in-vitro Untersuchungen motivieren zu weiterer Forschung bez{\"u}glich der 7,8-DHF-vermittelten Inhibition der PDXP-Aktivit{\"a}t in Zellen, um die Frage beantworten zu k{\"o}nnen, ob PDXP auch in-vivo ein relevantes Target f{\"u}r 7,8-DHF darstellt.}, subject = {Pyridoxalphosphat}, language = {de} }