Global ETD Search

11	DCAF12 Is Required For Synaptic Function and Plasticity at the Drosophila Neuromuscular Junction Patrón, Lilian Adilene, Patrón, Lilian Adilene January 2017 (has links) We employed imaging, electrophysiological, and molecular techniques with the genetically tractable model organism Drosophila melanogaster to unravel fundamental biological and genetic underpinnings regulating synaptic function and plasticity. Using a forward genetic screen, we identified mutations in the Drosophila ortholog of a human WD40 repeat-containing protein termed DDB1 and CUL4 associated factor 12 (DCAF12). We show that DCAF12 likely serves as an adaptor protein for the DDB1-Cul4 E3 ubiquitin ligase complex by recruiting specific target proteins for ubiquitination. DCAF12 is expressed in neurons, muscles, and glia. In mitotically active cells such as muscles, DCAF12 is localized to nuclei and co-localizes in distinct foci with CUL4, suggesting that DCAF12 mediates a nuclear role for the CUL4 E3 ubiquitin ligase complex. In neurons, DCAF12 is localized to both cytoplasmic and nuclear compartments of motor neuron cell bodies, where it colocalizes with Cul4 in nuclei. DCAF12 is also expressed at the periactive zone of presynaptic terminals, but does not distinctly associate with DDB1 or Cul4 at this region. Evoked neurotransmitter release at larval NMJs is significantly reduced in DCAF12 mutants. These defects are rescued by presynaptic expression of wild-type DCAF12, demonstrating that DCAF12 is required presynaptically and serves as an important component of the machinery that facilitates evoked release. In addition, our studies show that DCAF12 is required for the differential expression of glutamate receptor subunits at the larval NMJ through transcriptional and post-translational mechanisms. GluRIID subunit mRNA levels and GluRIIA/C/D subunit protein levels are increased at DCAF12 mutant NMJs. Normal GluRIIA subunit levels can be restored by postsynaptic expression of wild-type DCAF12, but not with a truncated DCAF12 protein lacking a nuclear localization signal (∆NLS-DCAF12). Furthermore, DCAF12 overexpression in muscle nuclei reduces synaptic GluRIIA levels, an effect that can be suppressed by removing a copy of Cul4. These data strongly indicate that DCAF12 in muscle nuclei is required for GluRIIA expression and/or function in a Cul4-dependent manner. Moreover, homozygous DCAF12-GluRIIA double mutants show a strong synthetic lethality phenotype, providing further support for the hypothesis that GluRIIA directly or indirectly requires DCAF12. Mutations in glutamate receptors at larval NMJs trigger a retrograde trans-synaptic signal that leads to a compensatory increase in presynaptic release, which precisely restores the normal efficacy of synaptic transmission and muscle excitation. Reducing the gene dosage of DCAF12 by one gene copy suppresses the initiation and maintenance of GluRIIA-mediated synaptic homeostatic potentiation. This block of synaptic homeostatic potentiation can be rescued by presynaptic expression of DCAF12. In our studies, we determined that DCAF12 is critical for 3 distinct synaptic mechanisms: evoked neurotransmitter release, neurotransmitter reception by regulation of GluR subunit composition, and retrograde synaptic homeostatic signaling. Future research will strive to identify presynaptic and postsynaptic protein targets of DCAF12 and the Cul4 E3 ubiquitin ligase complex and the role of ubiquitination in regulating these synaptic processes. Cul4 E3 Ubiquitin Ligase DCAF12 DDB1 Glutamate Receptors Neurotransmitter Release Synaptic Homeostasis
12	Caractérisation des interactions moléculaires entre la GTPase Rac1 et son régulateur HACE1 : perspectives en infectiologie et en cancérologie / Characterization of molecular interactions between the E3 ubiquitin-ligase HACE1 and its target Rac1 Lotte, Romain 24 October 2017 (has links) La GTPase Rac1 est une protéine de signalisation intracellulaire qui joue notamment un rôle clé dans la prolifération cellulaire. Notre laboratoire a montré que la toxine CNF1, produite par les Escherichia coli pathogènes, catalyse l’activation de Rac1. Nous avons également identifié le rôle de la E3 ubiquitine-ligase HACE1, un suppresseur de tumeur avéré, dans la régulation par ubiquitylation de Rac1 actif. S’il est prouvé que la forme activée de Rac1 est une cible d’HACE1, le mode d’interaction de ces deux protéines reste à définir ainsi que le rôle de ces interactions dans l’infection et le cancer. L’objectif de mon travail a été de caractériser les interactions moléculaires entre HACE1 et Rac1. Nous avons testé l’hypothèse que des mutations ponctuelles d’HACE1 identifiées dans les cancers pourraient interférer avec son interaction avec Rac1 et sa capacité de contrôle de la croissance cellulaire. J’ai ainsi pu mettre en évidence que 13 mutations somatiques d’HACE1 issues de tumeurs séquencées altèrent sa fonction de contrôle de la croissance cellulaire. De plus, l’étude de ces mutations nous a permis d’identifier un groupe d’acides aminés, situés sur les ankyrin-repeats 5 à 7 d’HACE1, qui contrôle l’interaction d’HACE1 avec Rac1 et de ce fait son ubiquitylation. Enfin dans cette étude nous précisons le rôle du domaine intermédiaire d’HACE1 (MID) dans la spécificité d’interaction de la ligase avec la forme active de Rac1. In fine, la caractérisation de mutants d’interaction entre HACE1 et Rac1 ainsi que l’effet de la toxine CNF1 sur cet axe de signalisation doit nous renseigner sur l’importance de cette voie de régulation dans le cancer et l’infection. / The small GTPase Rac1 plays a key role in various intracellular signaling pathways including cell proliferation. Our laboratory has shown that the CNF1 toxin, produced by pathogenic Escherichia coli, catalyzes the activation of Rac1. We also identified the role of the E3 ubiquitin-ligase HACE1, a tumor suppressor, in the regulation by ubiquitylation of active Rac1. If the activated form of Rac1 is proved to be a target of HACE1, the mode of interaction between these two proteins remains to be define as well as the role of these interactions in infection and cancer. The aim of my work was to characterize the molecular interactions between HACE1 and Rac1. We tested the hypothesis that HACE1 point mutations identified in cancers could interfere with its interaction with Rac1 and its ability to control cell growth. We showed that 13 cancer-associated somatic mutations of HACE1, led to a defective control of cell proliferation. Moreover, the study of these mutations allowed us to identify a group of amino acids, located on the ankyrin-repeats 5 to 7 of HACE1, which controls the interaction of HACE1 with Rac1 and thus its ubiquitylation. We also identified a role for the intermediate domain of HACE1 (MID) in conferring the specificity of association of HACE1 to the active form of Rac1. Ultimately, the characterization of interaction mutants between HACE1 and Rac1 as well as the effect of the CNF1 toxin on this signaling axis will give us more insight on this regulatory pathway in cancer and infection. HACE1 Rac1 E3 ubiquitine-ligase Escherichia coli CNF1 HACE1 Rac1 E3 ubiquitin-ligase Escherichia coli CNF1
13	Phosphorylation and mechanistic regulation of a novel IKK substrate, ITCH Perez, Jessica Marie 02 February 2018 (has links) No description available. Immunology Pathology Biomedical Research E3 ubiquitin ligase ITCH inflammation ubiquitination phosphorylation IKK substrate
14	Identifizierung neuer MuRF-Multiproteinkomplex assoziierter Proteine Nowak, Marcel 31 July 2014 (has links) Die Muscle-RING-finger (MuRF) Proteine sind E3-Ubiquitin-Ligasen, die im Muskelgewebe den Ubiquitin-Proteasom-System abhängigen Abbau von Proteinen vermitteln. MuRF1 wird in der Muskelatrophie verstärkt synthetisiert, was zu einem gesteigerten Proteinabbau und damit zum Verlust von Muskelmasse führt. Zudem sind Mäuse, denen MuRF1 fehlt vor Muskelatrophie geschützt. E3-Ubiquitin-Ligasen fungieren oftmals in Multiproteinkomplexen. Dies wurde für MuRF-Proteine bisher nicht gezeigt. Aufgrund dessen sollten neue MuRF-Multiproteinkomplex assoziierte Faktoren mittels Hefe-Zwei-Hybrid-System und SILAC AP-MS identifiziert und deren Einfluss auf die MuRF-Funktion charakterisiert werden. Es wurden sowohl neue als auch publizierte MuRF-Interaktionspartner (Iap) gefunden. Von den neu entdeckten MuRF-Iap wurde der Fokus auf WDR42A gelegt, da das Protein mit beiden Methoden identifiziert wurde und zudem funktionell hoch interessant ist. WDR42A homologe Proteine bilden zirkuläre β-Propeller Strukturen die Multiproteinkomplexe koordinieren. Die Interaktion zwischen MuRF-Proteinen und WDR42A wurde mittels Ko-IP Experimenten und Kolokalisationsstudien bestätigt. Cycloheximid-Abbau-Experimente deuten darauf hin, dass WDR42A kein MuRF1 Substrat-Protein ist. Da die MuRF-Proteine spezifisch im Muskel hergestellt werden, sollte überprüft werden ob WDR42A ebenfalls im Muskelgewebe synthetisiert wird. Es wurde gezeigt, dass WDR42A ubiquitär sowie im Muskelgewebe und in immortalisierten Muskelzellen hergestellt wird. Analog zu MuRF1 wird WDR42A in der Denervations-induzierten Skelettmuskelatrophie und der Muskelentwicklung verstärkt synthetisiert. Die Herunterregulation von WDR42A mittels siRNA in C2C12 Myotuben schützte diese Zellen vor dem Auftreten von Atrophie. Diese Ergebnisse zeigen, dass WDR42A wie MuRF1 an der Entstehung von Muskelatrophie beteiligt ist. Aufgrund der WDR42A Domänenstruktur wird vermutet, dass WDR42A als Scaffolding-Protein MuRF1-Multiproteinkomplexe reguliert. / The muscle-RING-finger (MuRF) proteins are E3 ubiquitin ligases which coordinate the ubiquitin-proteasome system dependent protein degradation in muscle tissue. MuRF1 is up-regulated under muscle atrophy conditions. This leads to enhanced proteolysis and thereby to loss of muscle mass and strength. Furthermore are MuRF1 knockout mice resistant to muscle atrophy. E3 ubiquitin ligases often operate in multi-protein complexes. This has not been shown for MuRF proteins. Therefore we used yeast-two-hybrid and SILAC-AP-MS to identify and subsequently characterize new MuRF multi-protein complex associated proteins. We found new and also published MuRF interaction partners (Iap) with both methods. Amongst the new Iap, we focused on WDR42A, because it was found with both techniques and his interesting functional potential. WDR42A exhibits seven consecutive arranged WD40-repeat domains. This domain arrangement leads in homologues proteins to the formation of seven-bladed β-propeller structures, which act as protein interaction platforms that coordinate multi-protein complexes. The protein interaction between the MuRFs and WDR42A was confirmed with Co-IP and co-localization experiments. Cycloheximide decay experiments indicated that WDR42A is not a MuRF1 substrate protein. The MuRF proteins are muscle specific, therefore we tested if WDR42A is also synthetized in muscle tissue. We could show that WDR42A is ubiquitously, but also in muscle tissue as well as in immortalized muscle cells produced. WDR42A is similar to MuRF1 up-regulated under denervation-induced skeletal muscle atrophy as well as in muscle development. Furthermore are C2C12 myotubes resistant to muscle atrophy after siRNA down-regulation of WDR42A. These results demonstrate that WDR42A is like MuRF1 important for the development of muscle atrophy. Due to the domain structure of WDR42A, we hypothesize that WDR42A regulates MuRF1 multi protein complexes as scaffolding protein. UPS MuRF E3-Ubiquitin-Ligase Muskelatrophie Y2H SILAC-AP-MS Multiproteinkomplex PPI WDR42A UPS MuRF E3 ubiquitin ligase Muscle atrophy Y2H SILAC-AP-MS Multi-protein complex PPI WDR42A 570 Biowissenschaften, Biologie 32 Biologie YG 6200 ddc:570
15	Nouveau regard sur la signalisation AMPK : multiples fonctions de nouveaux interacteurs / A fresh look at AMPK signaling : multiple functions of novel interacting proteins Zorman, Sarah 08 November 2013 (has links) La protéine kinase activée par AMP (AMPK) est un senseur et régulateur central de l'état énergétique cellulaire, mais ces voies de signalisation ne sont pour le moment que partiellement comprises. Deux criblages non-biaisés pour la recherche de partenaires d'interaction et de substrats d'AMPK ont précédemment été réalisés dans le laboratoire. Ces derniers ont permis l'identification de plusieurs candidats (protéines), mais leur rôle fonctionnel et physiologique n'était pas encore établi. Ici nous avons caractérisé la fonction de la relation entre AMPK et quatre partenaires d'interaction : gluthation S-transferases (GSTP1 and GSTM1), fumarate hydratase (FH), l'E3 ubiquitine-ligase (NRDP1), et les protéines associées à la membrane (VAMP2 and VAMP3). Chacune de ces interactions parait avoir un rôle différent dans la signalisation AMPK, agissant en amont ou en aval de la protéine AMPK. GSTP1 et GSTM1 contribueraient à l'activation d'AMPK en facilitant la S-glutathionylation d'AMPK en conditions oxydatives moyennes. Cette régulation non-canonique suggère que l'AMPK peut être un senseur de l'état redox cellulaire. FH mitochondrial est l'unique substrat AMPK clairement identifié. Etonnamment le site de phosphorylation se trouve dans le peptide signal mitochondrial, ce qui pourrait affecter l'import mitochondrial. NRDP1, protéine pour laquelle nous avons pour la première fois développé un protocole de production de la protéine soluble, est faiblement phosphorylée par l'AMPK. L'interaction ne sert pas à l'ubiquitination d'AMPK, mais affecte le renouvellement de NRDP1. Finalement, l'interaction de VAMP2/3 avec AMPK n'implique pas d'évènement de phosphorylation ou d'activation d'un des partenaires. Nous proposons un mécanisme de recrutement d'AMPK par VAMP2/3 (" scaffold ") au niveau des vésicules en exocytose. Ce recrutement favoriserait la phosphorylation de substrats de l'AMPK à la surface des vésicules en exocytoses. Une fois mis en commun, nos résultats enrichissent les connaissances sur les voies de signalisation AMPK, et suggèrent une grande complexité de ces dernières. Plus que les kinases en amont et des substrats en aval, la régulation de la signalisation d'AMPK se fait via des modifications secondaires autres que la phosphorylation, via des effets sur le renouvellement de protéines, et probablement via un recrutement spécifique de l'AMPK dans certains compartiments cellulaires. / AMP-activated protein kinase (AMPK) is a central energy sensor and regulator of cellular energy state, but the AMPK signaling network is still incompletely understood. Two earlier non-biased screens for AMPK interaction partners and substrates performed in the laboratory identified several candidate proteins, but functional and physiological roles remained unclear. Here we characterized the functional relationship of AMPK with four different protein interaction partners: gluthatione S-transferases (GSTP1 and GSTM1), fumarate hydratase (FH), an E3 ubiquitin-ligase (NRDP1), and vesicle-associated membrane proteins (VAMP2 and VAMP3). Each of these interaction partners seems to have a different function in AMPK signaling, either acting up- or down-stream of AMPK. GSTP1 and GSTM1 can contribute to AMPK activation by facilitating S-glutathionylation of AMPK under mildly oxidative conditions. This non-canonical regulation suggests AMPK as a sensor of cellular redox state. Mitochondrial FH was identified as the only clear AMPK downstream substrate, but surprisingly the phosphorylation site is present in the mitochondrial targeting prepeptide, possibly affecting mitochondrial import. NRDP1, whose expression as a full-length soluble protein was achieved here for the first time, is phosphorylated by AMPK only at low levels. The interaction does neither serve for AMPK ubiquitinylation, but rather affects NRDP1 turnover. Finally, interaction of VAMP2/3 with AMPK does not involve phosphorylation or activation events of one of the partners. Instead, we propose VAMP2/3 as scaffolding proteins that recruit AMPK to exocytotic vesicles which could favor phosphorylation of vesicular AMPK substrates for exocytosis. Collectively, our results add some new elements to the AMPK signaling network, suggesting that it is much more complex than anticipated. In addition to upstream kinases and downstream substrates, regulation of AMPK signaling occurs by second Protéine activé par AMP AMPK Fumarate hydratase Glutathion S transferase Vesicle associate membran protein E3 ubiquitin ligase NRDP1 AMP activated protein kinase Fumarate hydratase Glutathione S transferase E3 ubiquitin ligase NRDP1 AMPK Vesicle associate membran protein 570
16	Development of a new screening system for the identification of RNF43-related genes and characterisation of other PA-RING family members Merenda, Alessandra January 2017 (has links) The E3 ubiquitin ligase RNF43 (RING finger protein 43) is an important negative modulator of the WNT signalling pathway that acts at the plasma membrane by targeting Frizzled and its co-receptor LRP for degradation. In the small intestine, this prevents uncontrolled expansion of the stem cell compartment and so it is essential to the maintenance of normal tissue homeostasis. However, despite its crucial role in fine-tuning the WNT pathway and its role as a tumour suppressor, it is unclear whether RNF43 has further binding partners and what their functional relevance is to the modulation of WNT signalling. Here, I describe the development of a new screening strategy which combines CRISPR/Cas9 technology with 3D-intestinal organoid culture for the identification of novel molecular interactors of RNF43. Overall, this study and the technology developed provide a tool to enable the detailed description of the mechanism of action of RNF43, which is important not only in order to increase our understanding of WNT pathway regulation but also to gain potential new insights into RNF43 paralogs, by analogy. The investigation of paralogs is crucial as RNF43 belongs to a newly identified family of E3 ubiquitin ligases, named the PA-RING family, whose members are still poorly characterised. The majority of PA-RING family members have not been linked to any signalling pathway, most of their targets are still unknown and in many cases their in vivo function has not been addressed. In this context, my work has specifically focused on the investigation of the potential involvement of additional PA-RING family members in WNT pathway modulation and also on target identification for selected members. The results summarised in this dissertation show that no other PA-RING family member plays a prominent role in WNT pathway modulation aside from Rnf43 and its homologue Znrf3, however, different classes of adhesion molecules are likely to be regulated by certain of these E3 ligases. In conclusion, my work has contributed to unravelling previously unexplored aspects of this protein family, with particular regard to RNF43 and its mechanism of action. Thanks to this original approach, it was possible to identify potential new players involved either in membrane clearance of Frizzled or in RNF43 maturation. In particular, my thesis focuses on the characterisation of the role of DAAM in RNF43-mediated Frizzled internalisation. 572
17	Regulation of the innate immune system McGlasson, Sarah Louise January 2015 (has links) The innate immune system is the first line of defence against pathogen invasion. The range of diseases that are caused by deficiencies in or deregulation of the innate immune system illustrates the importance of maintaining an effective balance between clearance of infectious agents and minimisation of inflammatory mediated tissue damage. This thesis explores the role of two proteins in the regulation of the innate immune system. Primarily, this work investigates the effect of human β-defensin 3 (hBD3) on the response to self-DNA and pathogenic DNA. HBD3 is an antimicrobial peptide (AMP), which has been shown to have a role in regulating the immune response; increased copy number of the region containing the gene for hBD3, DEFB103, is linked to an increased risk of psoriasis. Additionally, a similar cationic AMP, LL37, has been shown to exacerbate the pathogenesis of psoriasis by forming an immunogenic complex with self-DNA. This lead to the hypothesis that hBD3 may also affect the innate immune response to DNA. Therefore this project investigates what effect hBD3 has on the response of the innate immune system to self and pathogenic DNA. Flt-3 dendritic cells were used to show that whilst hBD3 increased cellular uptake of self-DNA, it did not convert self-DNA into an immune stimulus. However, hBD3 significantly exacerbated the response to bacterial DNA in a TLR9-dependent manner, also by increasing cellular uptake into FLDCs. The finding that hBD3 increased cellular uptake of both self- and pathogenic DNA suggests that at sites of infection or increased cell death, where DNA would be found in the extracellular environment, hBD3 may increase uptake into immune cells and could induce an increased immune response. Since increased hBD3 expression is induced by inflammatory stimuli, this process would cause a positive feedback loop of inflammation during bacterial infections. In conclusion, hBD3’s role in regulating the innate immune response to DNA is at the ligand-receptor level rather than affecting signalling pathways. Furthermore, hBD3 promotes the innate immune response to bacterial DNA by increasing the efficiency of cellular uptake possibly by inducing DNA aggregation. These results implicate a possible role for hBD3 in the earliest stages of psoriatic plaque development, which is often initiated or exacerbated by an infection, and this could be investigated further. Secondly, I investigated the innate immune function of an E3 ubiquitin ligase (E3L) not previously associated with human disease. Mutations in E3L have been identified in three microcephalic primordial dwarfism families; these patients also presented with recurrent respiratory illnesses. E3L has been implicated in the regulation of the innate immune system via interactions with signalling pathways downstream of the receptor, though its role is not clear. We hypothesised that E3L had a dual role both in regulating growth and cell division and in regulating the immune system. Primary patient fibroblasts did not demonstrate an altered cytokine response to bacterial or viral ligands, implying that E3L may have a specific function in immune cells. To investigate this further, and to provide a system to study E3L in vivo, two transgenic mouse lines were designed and engineered, firstly a conditional ‘knock-out’ designed to replicate some of the alternative isoforms of E3L seen in RT-PCRs, and secondly a ‘knock-in’ line to recapitulate the human mutation in exon 7 of E3L, R185X. These mouse lines should offer an insight into the developmental role for E3L, and contribute to establishing a potential role for E3L in the innate immune system. This thesis exemplifies the complexity of the innate immune system and the regulatory pathways that interact to maintain a delicate homeostasis preventing pathogenic inflammation. Understanding these regulatory mechanisms may shed light on the pathogenicity of diseases and identification of potential targets for therapeutics. 616.07
18	NMR δομικός χαρακτηρισμός του RING τομέα της Ε3 λιγάσης ουβικιτίνης ARKADIA, με τροποποιημένο μοτίβο δέσμευσης ιόντων Ψευδαργύρου, του τύπου Cys3-His-Cys4 Βλάχου, Πολυτίμη-Μαρία 11 October 2013 (has links) Η αποικοδόμηση των πρωτεϊνών είναι μια διαδικασία απαραίτητη για τη διατήρηση της ομοιόστασης του κυττάρου. Ένας από τους κύριους μηχανισμούς αποικοδόμησης των βραχύβιων πρωτεϊνών καθώς και όσων εμφανίζουν λανθασμένη αναδίπλωση, χωρεί μέσω του μονοπατιού ουβικιτίνης- πρωτεασώματος. Η ουβικιτινίωση είναι μια μετα-μεταφραστική διαδικασία, η οποία έγκειται στη σηματοδότηση των υποψήφιων για αποικοδόμηση πρωτεϊνών με ουβικιτίνη και περιλαμβάνει τρεις ενζυμικές ενεργότητες: Ε1 (εκκινητής ουβικιτίνης), Ε2(μεταφορέας ουβικιτίνης) και Ε3 (λιγάση ουβικιτίνης). Η πρωτεΐνη Arkadia (Rnf11) είναι μια Ε3 λιγάση ουβικιτίνης με συνολικό μήκος 994 αμινοξέα. Σε μοριακό επίπεδο, ενισχύει το TGF-β σηματοδοτικό μονοπάτι, διαμεσολαβώντας την εξαρτώμενη από το πρωτεάσωμα αποικοδόμηση των αρνητικών ρυθμιστών του, c-Ski και Sno-N. Η δραστικότητα Ε3 λιγάσης ουβικιτίνης εδράζεται στον C΄-τελικό RING-H2 τομέα, που σχηματίζεται από τα τελευταία 60 περίπου αμινοξέα της ακολουθίας. Η δομή και η σταθερότητα του RING τομέα εξαρτώνται από την πρόσδεση δύο ιόντων Zn μέσω ενός χαρακτηριστικού μοτίβου, που περιλαμβάνει 6 κυστεϊνικά και 2 ιστιδινικά κατάλοιπα. Στην προσπάθεια αποσαφήνισης της σχέσης δομής-δράσης της πρωτεΐνης Arkadia, ένα από τα κατάλοιπα που συναρμόζονται με Zn -συγκεκριμένα η His965- αντικαταστάθηκε από κυστεΐνη μέσω κατευθυνόμενης μεταλλαξιγένεσης. Η μετάλλαξη αυτή, με την οποία, ουσιαστικά, μετατρέψαμε τον RING-H2 σε RING-HC τομέα, μελετήθηκε με χρήση πολυπυρηνικής/πολυδιάστατης φασματοσκοπίας πυρηνικού μαγνητικού συντονισμού (NMR). H NMR δομή του RING-H2 τομέα της Η965C Arkadia επιλύθηκε σε υψηλή διακριτικότητα (tf=0.94±7.5310-2, RMSD=0.75±0.20 και RMSD=1.45±0.24 για τα άτομα του πολυπεπτιδικού σκελετού και τα βαρέα άτομα αντίστοιχα) και αποκάλυψε μια ββαββ τοπολογία. Παράλληλα, πραγματοποιήθηκε μελέτη κινητικότητας, από την οποία προέκυψε ότι η εν λόγω μετάλλαξη υφίσταται ως μονομερές και διαθέτει έναν συμπαγή πυρήνα, που περικλείεται μεταξύ δύο ευκίνητων άκρων. / Protein degradation is necessary for the maintenance of cell homeostasis. A major mechanism for the degradation of short-lived as well as misfolded proteins involves the ubiquitin-proteasome pathway. Ubiquitination is a post translational modification, which targets the proteins to be degraded through the covalent attachment of a ubiquitin tag and consists of three enzyme activities: Ε1 (ubiquitin activator), E2 (ubiquitin carrier) and E3 (ubiquitin ligase). Arkadia (Rnf11) is a 994 amino acid protein, which acts as an E3 ubiquitin ligase. On a molecular level, Arkadia enhances TGF-β signaling by mediating the proteasome-dependent degradation of its negative regulators, c-Ski and Sno-N. Its E3 ubiquitin ligase activity lies on a C΄-terminal RING-H2 domain, formed by the last 60 residues. The structure as well as stability of the RING finger domain depend strongly on the binding of two zinc ions in a unique ΄΄cross-brace΄΄ arrangement through a defined motif of six cysteines and two histidines. Trying to elucidate the structure-activity relationship in the case of Arkadia, one of the amino acid ligands –specifically His965- was replaced by cysteine through site-directed mutagenesis. This particular mutation, which, in reality, transformed the RING-H2 to a RING-HC domain, was studied with the use of multinuclear/multidimensional nuclear magnetic resonance spectroscopy (NMR). The NMR solution structure of the H965 Arkadia RING-H2 domain was determined in high resolution (tf=0.94±7.5310-2, RMSD=0.75±0.20 και RMSD=1.45±0.24 for backbone and heavy atoms respectively) and revealed a ββαββ topology. Furthermore, a mobility study was conducted with the following results: the mutated protein is not expected to form dimers and shows a compact core region including the four metal binding motifs flanked by two flexibly disordered termini. NMR φασματοσκοπία RING finger τομέας Ε3 λιγάση ουβικιτίνης 612.398 NMR spectroscopy Structural characterization RING finger domain E3 ubiquitin ligase
19	Charakterisierung der MuRF2/MuRF3-Doppelknockout-Mauslinie hinsichtlich ihres Herz- und Skelettmuskel-Phänotyps Lodka, Dörte 11 June 2015 (has links) E3-Ubiquitin-Ligasen übertragen Ubiquitin auf die von ihnen gebundenen Substratproteine. Durch diese Ubiquitinierung werden Proteine für den kontrollierten Abbau im Ubiquitin-Proteasom-System markiert. Dieser Prozess beeinflusst aber auch die Aktivität verschiedener Signalwege, die Lokalisation von Proteinen oder die strukturelle Integrität zellulärer Komponenten. MuRF1, MuRF2 und MuRF3 sind E3-Ubiquitin-Ligasen, die hauptsächlich in quergestreifter Muskulatur exprimiert werden. Von MuRF1 ist bereits bekannt, dass es u. a. über die Ubiquitinierung von Myosinen und deren anschließender Degradation an der Entwicklung der Herz- und Skelettmuskelatrophie beteiligt ist. Da das Wissen über MuRF2 und MuRF3 in diesem Zusammenhang noch begrenzt ist, sollte die Auswirkung der kombinierten Keimbahndeletion von MuRF2 und MuRF3 in einem Mausmodell untersucht werden. Der Doppelknockout (DKO) von MuRF2 und MuRF3 führte zu Veränderungen der Morphologie und der Funktionsfähigkeit der Skelett- und Herzmuskulatur. In Skelettmuskelfasern kam es zur Ablagerung myosinhaltiger Proteinaggregate, zu einer Zunahme an langsam kontrahierenden Muskelfasern sowie zum Auftreten von Myozyten mit zentral gelegenen Nuclei als Anzeichen von Regenerationsprozessen. Isolierte Skelettmuskeln von DKO-Mäusen entwickelten eine geringere maximale spezifische Kraft als Muskeln aus Kontrolltieren. Ihre Herzen waren morphologisch unauffällig. Dennoch waren die Kontraktion des linken Ventrikels und das Schlagvolumen reduziert. Darüber hinaus zeigten isolierte Kardiomyozyten Beeinträchtigungen der Kontraktionsfähigkeit und der Kalziumströme in vitro. Eine massenspektrometrische Untersuchung ergab, dass in den Muskeln der MuRF2/3-DKO-Mäuse im Vergleich zu den Kontrollmäusen 12 Proteine in erhöhter Menge vorhanden waren. Eine Anreicherung von MAPKAP-K3, einem dieser Proteine, und von MAPKAP-K2 konnte im Western Blot von Proteinlysaten aus Skelettmuskeln und dem Herz der MuRF2/3-DKO-Mäuse detektiert werden. / E3 ubiquitin ligases attach the small modifier ubiquitin to their substrate proteins. This ubiquitin-tag not only marks proteins for the proteasome dependent degradation, but also influences the activity of signalling pathways, the localisation of proteins or the structural integrity of cellular components. MuRF1, MuRF2, and MuRF3 are E3 ubiquitin ligases predominantly expressed in striated muscles. MuRF1 is involved in cardiac and skeletal muscle atrophy by mediating proteasome-dependent degradation of myosins. The knowledge about MuRF2 and MuRF3 in this context is limited. Therefore, a mouse model was used to analyse the impact of the combined deletion of MuRF2 and MuRF3. The double knockout (DKO) of MuRF2 and MuRF3 influenced the structure and function of skeletal and cardiac muscle. Skeletal muscle fibres exhibited myosin-containing protein aggregates, a fibre-type shift towards slow fibres, and myoycytes with central nuclei which is an indication of regeneration. Maximal force development was reduced in isolated hindlimb muscles M. soleus and M. extensor digitorum longus of MuRF2/3-DKO mice. Hearts were morphologically normal. No protein aggregates or signs of fibrosis were detected. However, heart performance was impaired. The contractibility of the left ventricle and the ejection fraction were reduced. Isolated cardiomyocytes showed a diminished contractibility. Furthermore, their speed of contraction and relaxation was reduced and they had impaired calcium transients. Mass spectrometric analysis of muscle lysates identified 12 enriched proteins in MuRF2/3-DKO muscles. Western Blot analysis confirmed that MAPKAP-K3, one of these proteins, and MAPKAP-K2 were enriched in lysates of skeletal muscles and left ventricles of MuRF2/3-DKO mice. Further investigations will show how MAPKAP-K2- and MAPKAP-K3-signalling pathways are involved in the development of the MuRF2/3-DKO-phenotype. MuRF2 MuRF3 E3-Ubiquitin-Protein-Ligase Proteinaggregate spezifische Kraft E3 ubiquitin ligase MuRF2 MuRF3 protein aggregates specific force 570 Biowissenschaften, Biologie 32 Biologie YG 6204 ddc:570
20	Le rôle de l’ubiquitination et des endomembranes dans l’activation du facteur de transcription NF-κB / The Role of Ubiquitinylation and Organelles During the Activation of the Transcription Factor NF-κB Zemirli, Naïma 24 November 2014 (has links) Le facteur de transcription NF-κB régule l’expression d’une pléthore de gènes impliqués dans divers processus physiologiques notamment la prolifération et la survie cellulaires, l’inflammation ainsi que les réponses immunes. Il intervient également dans de nombreux processus pathologiques à l’exemple de certains cancers et maladies auto-immunes.L’activation de NF-κB suite à l’engagement de différents immunorécepteurs requiert la mise en place de larges signalosomes formés suite au recrutement de différents adaptateurs au niveau des immunorécepteurs engagés. Ces adaptateurs subissent des ubiquitinations non-dégradatives nécessaires pour la transduction du signal. Nous avons démontré dans un précédent travail que ces protéines ubiquitinylées s’accumulent au niveau de la membrane du réticulum endoplasmique (RE) via la protéine réticulaire Métadhérine (MTDH). De plus, nos résultats suggèrent que l’ubiquitination est un prérequis nécessaire à l’adressage de ces protéines au RE. Afin d’évaluer la contribution des E3 ubiquitine ligases en charge de relayer NF-κB au niveau des organites, nous avons effectué le crible d’une banque de siRNAs dirigés contre les 46 E3 ligases transmembranaires en utilisant comme modèle la signalisation du TNF récepteur. Ce crible nous a permis d’identifier l’E3 ligase RNF121 comme régulateur positif de NF-κB. Bien que le mécanisme d’action de RNF121 ne soit pas complètement élucidé, nos données suggèrent qu’il agirait au niveau de la régulation de l’inhibiteur de NF-κB « IκBα ».Durant la deuxième partie de cette thèse, je me suis intéressée à la dynamique mitochondriale. Les mitochondries sont des organites dynamiques, dont la forme est maintenue grâce à une balance entre deux processus antagonistes appelés : fission et fusion. Il a été rapporté qu’en présence de certains stress modérés, les mitochondries hyperfusent, ce processus est appelé SIMH (Stress-Induced Mitochondrial Hyperfusion). Nous avons pu démontrer que la SIMH s’accompagne de l’activation de la voie canonique du facteur de transcription NF-κB via l’E3 ubiquitine ligase mitochondriale MULAN. Nos résultats suggèrent que durant le SIMH, MULAN forme un complexe avec TRAF2 et module son ubiquitination. Ces résultats suggèrent que la mitochondrie, de part sa dynamique, convertie un signal de stress en un signal de survie via l’activation de NF-κB. Pris dans leur ensemble, nos résultats illustrent la complexité de la régulation de NF-κB par ubiquitination et attribuent aux organites un nouveau rôle dans la transduction de la signalisation. / The transcription factor NF-κB regulates the expression of several genes implicated in various physiological processes such as cell proliferation and survival, inflammation and immune responses. Dysregulation of its activation is involved in diverse pathologies such as cancer and auto-immune diseases. Following the engagement of immunoreceptors, NF-κB signaling requires a large signalosome assembly containing different adaptor proteins. These adaptors undergo poly-ubiquitinylation in a non-degradative manner, which is essential for signal transduction. We demonstrated in previous work that these ubiquitinylated proteins accumulate at the surface of the endoplasmic reticulum (ER) via a reticular protein called “Methaderin” (MTDH). Furthermore, our results suggest that ubiquitinylation is a necessary prerequisite for protein addressing to the ER. To evaluate the contribution of E3 ubiquitin ligases in this process we performed a screen of a siRNA bank, targeting the 46 human transmembrane E3 ligases, using the TNF receptor signaling as a model. This screen enabled the identification of RNF121, a Golgi E3 ligase, as a positive regulator of NF-κB. Although the mechanism by witch RNF121 acts is not yet elucidated, our data suggest that it acts on the regulation of NF-κB inhibitor (IκBα). In the second part of this thesis, we investigated mitochondrial dynamics. Mitochondria are dynamic organelles; their shape is maintained due to a balance between two antagonist processes called: fusion and fission. It is known that moderate stress triggers mitochondrial hyperfusion, this process is called: SIMH (Stress-Induced Mitochondrial Hyperfusion). During this thesis, we demonstrated that SIMH is accompanied by NF-κB activation through the mitochondrial E3 ubiquitin ligase MULAN. Our results suggest that during SIMH, MULAN forms a complex with the protein TRAF2 and modulates its ubiquitinylation to allow NF-κB signaling transduction. This work shows that, through their dynamics, mitochondria convert stress signals into a prosurvival response via NF-κB activation.In summary, our results illustrate the complexity of the ubiquitin-dependant regulation of NF-κB and attribute a new role in signaling transduction to the organelles. NF-κB Ubiquitination Organites E3 ubiquitine ligase Dynamique mitochondriale Immunité innée NF-κB Ubiquitinylation Organelles E3 ubiquitin ligase Mitochondrial dynamic Innate immunity

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