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1	Control of the CDC48A segregase by the plant UBX-containing (PUX) protein family Zhang, Junrui 05 1900 (has links) In plants, AAA-adenosine triphosphatase (ATPase) Cell Division Control Protein 48 (CDC48) uses the force generated through ATP hydrolysis to pull, extract, and unfold ubiquitylated or sumoylated proteins from the membrane, chromatin, or protein complexes. The resulting changes in protein or RNA content are an important means for plants to control protein homeostasis and thereby adapt to shifting environmental conditions. The activity and targeting of CDC48 are controlled by adaptor proteins, of which the plant ubiquitin regulatory X (UBX) domain-containing (PUX) proteins constitute the largest and most versatile family. However, few PUX proteins have been structurally or functionally characterized and how they participate in the substrate processing of CDC48A is not fully understood. Here, we first performed a comparative bioinformatic analysis, in which we found that the PUX proteins can be functionally divided into six types. We used this classification as a guide for our experimental efforts to elucidate how PUX proteins mediate client recognition and delivery for CDC48A-mediated unfolding. As a first step in this experimental analysis, we cloned and expressed a number of PUX protein constructs, we assessed their interaction features, and obtained crystals for several PUX domains. These bioinformatic and experimental results provide a basis for the in-depth structural and functional analysis of how PUX proteins control the CDC48A segregase. Protein Cofactor Structure CDC48 PUX proteins
2	Investigation of the ubiquitin proteasome system in Schizosaccharomyces pombe Glover, James S. A. January 2010 (has links) Ubiquitin is an essential 76 amino acid protein which can be conjugated to lysine residues on a variety of substrates via its C-terminal diglycine motif. This conjugation allows the protein to act as a molecular tag in a range of processes, including regulation of chromatin compaction, signalling cascades and DNA repair. In addition, ubiquitin moieties are capable of forming chains through the successive conjugation to lysine residues within ubiquitin itself. One of the most well characterized functions of ubiquitin is its role in protein quality control and degradation. Tetra-ubiquitin chains, most commonly through a lysine-48 linkage, are responsible for directing proteins to the 26S proteasome for degradation. This process is of importance both in the removal of miss-folded proteins, and in the regulated destruction of specific targets, such as the cyclins. The 90kDa AAA-ATPase Cdc48/p97/VCP is an essential protein that forms a hexameric complex, which interacts with a wide variety of ubiquitinated substrates. The specificity of Cdc48 is modulated by a series of different cofactors, which together allow Cdc48 to operate in several different contexts, from removal of misfolded proteins from the ER, to regulating securin stability. The role of two Cdc48 cofactors, Ubx4 and Ubx5, was studied in an attempt to dissect their function and to determine how they may modulate the function of Cdc48. Neither protein was found to be essential, as knockouts of either were found to be viable with no major defect in growth rate. The work also describes the findings of a yeast two-hybrid screen to identify potential substrates for both cofactors. Delivery of ubiquitinated proteins to the proteasome is mediated by shuttling factors, which are able to bind to both ubiquitin and the proteasome, and hence mediate the interaction between both. The shuttling factor Dph1 binds ubiquitin via a C-terminal UBA domain, while its N-terminal UBL domain mediates its interaction with the proteasome. This work identified a novel interaction between the Sti1 domains of Dph1 and the N-terminal region of a mitochondrial localized AAA-ATPase, homologous to the Saccaromyces cerevisiae protein Msp1. In addition, cell fractionation experiments revealed the presence of Dph1 at the mitochondria. This interaction provides hints that Mlp1 may be involved in the removal of ubiquitinated proteins from the mitochondria, and their delivery to the proteasome. The thesis begins to try and attempt to identify possible substrates of this proposed mitochondria associated degradation pathway, and looks for ways in which the hypothesis may be tested. 572.6
3	Molecular Insights into the A. thaliana CDC48-NPL4-UFD1 Complex Zahodnik-Huntington, Brandon D. 07 1900 (has links) The maintenance of protein homeostasis as a response to changing external conditions is crucial for cellular survival and proper function. Since plants cannot adapt by changing location, their need for a rapid intracellular response is accentuated. The AAA ATPase CDC48 maintains protein homeostasis in conjunction with NPL4 and UFD1 by coupling ATP hydrolysis with mechanical force to extract and unfold ubiquitylated proteins from organelle membranes, chromatin, or protein complexes. Our bioinformatic analysis revealed considerable domain and binding motif differences in A. thaliana NPL4 compared to its orthologs in animals and fungi. Using ITC, MST, and SEC-MALS, we found that NPL4 and UFD1 did not heterodimerize, NPL4 bound to CDC48A in the absence of UFD1, and the complex was not stable in vitro. Additionally, we provided the first medium-high-resolution reconstructions of CDC48A in both an AMP-PNP bound and apo state, using cryo-EM. AMP-PNP bound CDC48A was reconstructed in both a tense (3.3 Å) and relaxed (3.5 Å) conformation with the N domain was positioned above or coplanar with the D1 ring, respectively. Our heterogeneity analysis using CryoDRGN revealed continuous flexibility of the N domains between the two conformations. The apo state was reconstructed as a single conformation at 4.4 Å resolution. A cryo-EM reconstruction of the complex was also obtained at a resolution of ~6 Å, which showed expected cofactor stoichiometry and binding positions. Through our efforts, we have observed differences in the interaction between A. thaliana CDC48A and its cofactors UFD1 and NPL4 that may correspond to functional differences between kingdoms. CDC48 Cofactors cryo-EM Protein homeostasis UFDI NPL4
4	Etude du rôle de la protéine CDC48 dans l'immunité des plantes / Study of the role of the CDC48 chaperone protein in plant immunity Begue, Hervé 22 November 2018 (has links) La protéine chaperonne CDC48 (Cell division cycle 48) est un acteur important du contrôle qualité des protéines chez les eucaryotes et est associée à divers processus physio(patho)logiques chez les mammifères. En revanche, son rôle au sein du règne végétal a été peu appréhendé. Ce travail de thèse s’inscrit dans l’étude des fonctions de CDC48 chez les plantes et concerne plus particulièrement son implication dans la réponse immunité induite chez le tabac par cryptogéine produite par l’oomycète phytophthora cryptogea.Trois stratégies ont été adoptées. Premièrement, la dynamique d’accumulation de la protéine CDC48 ainsi que les événements intracellulaires sous-jacents à la réponse immunitaire ont été étudiés à la fois dans des cellules de tabac sauvages et des cellules sur-exprimant la protéine CDC48 (lignée CDC48-TAP). Deuxièmement, une liste de protéines interagissant avec CDC48 a été établie suite à des expériences d’immuno-précipitation de CDC48 suivit d’analyses de spectrométrie de masse. Parmi celles-ci, la forme cytosolique de l’ascorbate peroxydase (cAPX), une enzyme impliquée dans la détoxication du H2O2 intracellulaire, a fait l’objet d’une étude ciblée. Enfin, ces travaux ont été complétés par une analyse bio-informatique de l’ensemble des partenaires de CDC48 identifiés chez le tabac et d’établissement du réseau d’interaction protéique de CDC48 chez Arabidopsis thaliana.Les principaux résultats obtenus ont montré que l’activation de la réponse immunitaire s’accompagne de l’induction d’une accumulation des transcrits et la protéine CDC48. De plus, une mort cellulaire précoce a été observée chez les cellules CDC48-TAP, suggérant un rôle de cette dernière dans la régulation de la réponse hypersensible. L’interaction physique entre CDC48 et cAPX a été confirmée par différentes approches. De façon intéressante, il s’est avéré que l’activité et la dynamique d’accumulation de cAPX sont fortement impactées par la surexpression de CDC48. En accord avec ses résultats, le statut rédox s’est également révélé altéré dans la lignée surexpresseur. Enfin, l’analyse bio-informatique du réseau d’interaction protéique de CDC48 a permis de dégager de nouvelles protéines cibles, en particulier celles impliquées dans le métabolisme de la S-adenosylméthionine, une molécule substrat des réactions de trans-méthylation et précurseur de l’éthylène et de la nicotianamine. De plus, cette analyse a confirmé son rôle dans du système de dégradation Ubiquitine/protéasome.Pour conclure, ce travail de thèse apporte de nouvelles informations quant au rôle de CDC48 dans la biologie des plantes. Il indique que celle-ci est mobilisée dans les cellules végétales exprimant une réponse immunitaire et impacte le statut rédox via la régulation du turnover de cAPX. De nouvelles pistes de recherche ont été dégagées, en particulier un rôle probable de CDC48 dans la régulation de la synthèse de la S-adenosylméthionine et de la réponse hypersensible suivant des mécanismes restant à déterminer. / The chaperone protein CDC48 (Cell division cycle 48) is a major regulator of the quality control of proteins and is involved in various cellular processes in animals and yeast. In contrast, the role of CDC48 in plants is poorly known. In the present work, we investigated the function of CDC48 in plant immunity thanks to the cryptogein/tobacco biological model, cryptogein being produced by the oomycete phytophthora cryptogea.Three strategies were carried out. First, the dynamic of accumulation CDC48 together with intracellular events inherent to the immune response were analyzed in both wild-type and CDC48 overexpressing tobacco cells (CDC48-TAP line). Second, a list if CDC48 partners was established based on immunoprecipitation assays followed by mass spectroscopy analysis. Among those partners the cytosolic form of acorbate peroxidase (cAPX), a central enzyme of the regulation of the redox status regulation, has been specifically studied. Finally, a computational analysis of the partner list of CDC48 and the subsequent generation of the protein-protein interaction (PPI) network of CDC48 in Arabidopsis thaliana were undertook.Our data indicated that the activation of the immune response is accompanied by an induction of the accumulation of both CDC48 transcript and protein. In addition, an early and exacerbated cell death was observed in the CDC48-TAP line, suggesting a role for CDC48 in the hypersensitive response. The interaction between CDC48 and cAPX was confirmed by different approaches. Interestingly, the activity of CDC48 and its dynamic of accumulation were strongly impacted in the CDC48 overexpressing line. Accordingly, a dysregulation of the redox status also occurred in this line. Finally, the computational analysis of the CDC48 PPI network highlighted new potential target proteins including proteins involved in the metabolism of S-adenosylmethionine, a substrate molecule of trans-methylation reactions and precursor of ethylene and nicotianamine.To summarize, this work provides new information about CDC48 in plant biology. It indicates that CDC48 is mobilized by plant cells undergoing an immune response and impacts the redox status through the regulation of the cAPX turnover. New research avenues emerged from our study, notably a putative role of CDC48 in the regulation of S-adenosylmethionine biosynthesis and in the establishment of hypersensitive response through process which remain to be investigated Cdc48 Immunité des plantes Biochimie Capx Cdc48 Plant immunity Biochemistry Capx Protein-Protein interaction network 572 571.6
5	Identification et étude du rôle des protéines cibles du monoxyde d'azote (NO) dans les réponses de défense chez le tabac / Identification an characterization of nitric oxyde (No) target proteins in tabacco defense responses Astier, Jérémy 30 May 2011 (has links) Les études entreprises depuis une douzaine d'années indiquent que le monoxyde d'azote (NO) est un médiateur physiologique impliqué dans de nombreux processus chez les plantes, incluant la germination, le développement des racines, la fermeture des stomates ou encore la réponse adaptative aux stress biotiques et abiotiques. Malgré cet important panel de fonctions, les mécanismes sous-jacents aux effets du NO ont été peu appréhendés et restent pour l'essentiel énigmatiques. Le travail présenté dans ce manuscrit s'inscrit dans cette problématique et a consisté en l’identification et la caractérisation de protéines cibles du NO chez le tabac dans le contexte de stress biotiques et abiotiques. Nous avons démontré que la cryptogéine, un éliciteur des réactions de défense, induit la S-nitrosylation rapide et transitoire de plusieurs protéines dans des suspensions cellulaires de tabac. Après purification, une douzaine de ces protéines ont été identifiées via une analyse par spectrométrie de masse. Celles-ci incluent notamment une protéine chaperonne de la famille des AAA-ATPase nommée CDC48 (Cell Division Cycle 48). Cette dernière a fait l'objet d'une étude structure/fonction approfondie afin d'appréhender l'impact de sa S-nitrosylation. Après avoir vérifié que la protéine recombinante était S-nitrosylable in vitro, nous avons démontré que ce processus n'affecte pas la structure secondaire de la protéine mais induit des modifications locales de sa structure tertiaire et une inhibition de son activité ATPasique. Le résidu cystéine 526, localisé dans le second domaine ATPasique de la protéine, a été identifié comme site probable de S-nitrosylation. Cette localisation stratégique pourrait expliquer l'effet inhibiteur du NO sur l'activité enzymatique de CDC48. La dernière partie de ce travail a été centrée sur l'analyse des mécanismes par lesquels le NO active la protéine kinase NtOSAK (Nicotiana tabacum stress activated protein kinase) chez le tabac. Nous avons démontré que NtOSAK forme un complexe constitutif avec la glycéraldéhyde 3 phosphate deshydrogénase (GAPDH). En réponse à un stress salin, le NO promeut l'activation de NtOSAK via la phosphorylation de deux résidus serine localisés dans la boucle d'activation de l'enzyme. De plus, il induit une S-nitrosylation rapide de la GAPDH, ce processus n'affectant pas la formation du complexe. Notre hypothèse est que ce complexe constituerait une plateforme de signalisation régulée par le NO et pouvant recruter les protéines cibles de NtOSAK lors de la réponse au stress salin. / Studies conducted over the past ten years indicate that nitric oxide (NO) is a physiological mediator involved in many physiological processes in plants, including germination, root development, stomatal closure or responses against biotic or abiotic stresses. Despite this important range of functions, the mechanisms underlying the effects of NO in plants remain largely unknown. The present work aims at identifying and functionally characterizing NO target proteins in tobacco in the context of biotic and abiotic stresses. We demonstrated that cryptogein, an elicitor of defense responses, induces a rapid and transient S-nitrosylation of several proteins in tobacco cell suspensions. After purification, a dozen of these proteins have been identified through mass spectrometry analysis. These proteins include CDC48 (Cell Division Cycle 48), a chaperone-like protein belonging to the AAA-ATPase family. The regulation of CDC48 by NO was deeply investigated using a combination of structural and biochemical analyses. Once the in vitro S-nitrosylation of CDC48 was confirmed, we next demonstrated that this process does not affect the secondary structure of the protein but induces local changes in its tertiary structure together with an inhibition of its ATPase activity. The cysteine residue 526, located in the second ATPase domain of the protein, was identified as a probable S-nitrosylation site. This crucial localization may explain the inhibitory effect of NO on CDC48 enzymatic activity. The last part of this work was focused on the analysis of the mechanisms underlying the NO-dependent activation of the protein kinase NtOSAK (Nicotiana tabacum stress activated protein kinase) in tobacco. We demonstrated that NtOSAK forms a constitutive complex with glyceraldehyde 3-phosphate dehydrogenase (GAPDH). In response to salt stress, NO promotes the activation of NtOSAK via the phosphorylation of two serine residues located in the activation loop of the enzyme. Moreover, it induces a rapid S-nitrosylation of GAPDH. Interestingly, this latter process does not affect the complex formation. Our hypothesis is that once S-nitrosylated, GAPDH might act as a phosphorelay recruiting protein substrates for NtOSAK. Nicotiana tabacum Monoxyde d’azote Cryptogéine CDC48 NtOSAK Défenses des plantes Nicotiana tabacum Nitric oxide Cryptogein CDC48 NtOSAK Plant defenses. 572
6	Superexpressão de CDC48 e HSP104 na levedura Saccharomyces cerevisiae. / Overexpression of CDC48 e HSP104 in the yeast Saccharomyces cerevisiae. Franco, Letícia Veloso Ribeiro 19 December 2016 (has links) Este trabalho iniciou-se com o objetivo de superexpressar proteínas com atividade ATPase, como tentativa de alterar a conservação de energia livre na levedura S. cerevisiae, de maneira a aumentar o rendimento da fermentação alcoólica. Para isso, duas ATPases nativas de S. cerevisiae, as chaperonas codificadas pelos genes HSP104 e CDC48, foram superexpressas, individualmente, sob o controle de quatro promotores de diferentes forças, provocando diferentes gastos energéticos na levedura. Entretanto, não foi possível obter aumento no rendimento em etanol. Em seguida, foi feito um estudo que visou comparar essas linhagens em situação de estresse térmico, ácido ou osmótico, tipicamente encontrados no processo brasileiro de produção de etanol. A 40 °C, uma linhagem superexpressando CDC48 apresentou velocidade específica máxima de crescimento 17 % maior que a linhagem de referência, indicando maior tolerância ao estresse térmico. Finalmente, avaliou-se Hsp104 e Cdc48 em um contexto fisiológico no qual as atividades dessas proteínas pudessem ser mais requeridas. Como as chaperonas moleculares são conhecidas por agirem como primeira linha de defesa contra a formação de proteínas incorretamente enoveladas e agregados proteicos, estudaram-se a morfologia e a fisiologia da superexpressão de HSP104 e CDC48 em linhagens com desarranjo no controle de qualidade de proteínas intracelulares, causado por mutações no proteassomo 20S. A superexpressão de CDC48 ou HSP104 reverteu em parte a morfologia alterada de alguns desses mutantes de proteassomo. / The initial goal of this work was to overexpress proteins with ATPase activity in Saccharomyces cerevisiae, as an attempt to alter the conservation of free energy in this yeast, in order to increase alcoholic fermentation yield. Therefore, two native S. cerevisiae ATPases, the chaperones encoded by HSP104 and CDC48, were individually overexpressed under the control of four promoters with different strengths, in order to provoke different levels of energy expenditure. Increments in the ethanol yield could not be observed in any of the constructed strains. Subsequently, a study was carried out to compare these mutant strains with reference strains under heat, acid or osmotic stress, which are typically found in the industrial fuel ethanol production in Brazil. At 40 oC a strain overexpressing CDC48 displayed a maximum specific growth rate 17 % higher than that of the reference strain, indicating a greater tolerance to heat stress. Finally, Hsp104 and Cdc48 were evaluated in a physiological context in which the activity of these proteins would be required in a higher level. Since molecular chaperones are known to act as the first defense line against the formation of misfolded proteins and aggregates, the physiological and morphological effects of HSP104 or CDC48 overexpression were analyzed in strains with protein quality control disarrangements caused by mutations in proteasome 20S. The overexpression of either CDC48 or HSP104 partially reversed the altered morphology of some of these proteasome mutants. Alcoholic fermentation CDC48 CDC48 Fermentação alcoólica Fisiologia HSP104 HSP104 Leveduras Maximum specific growth rate Saccharomyces cerevisiae Saccharomyces cerevisiae
7	Superexpressão de CDC48 e HSP104 na levedura Saccharomyces cerevisiae. / Overexpression of CDC48 e HSP104 in the yeast Saccharomyces cerevisiae. Letícia Veloso Ribeiro Franco 19 December 2016 (has links) Este trabalho iniciou-se com o objetivo de superexpressar proteínas com atividade ATPase, como tentativa de alterar a conservação de energia livre na levedura S. cerevisiae, de maneira a aumentar o rendimento da fermentação alcoólica. Para isso, duas ATPases nativas de S. cerevisiae, as chaperonas codificadas pelos genes HSP104 e CDC48, foram superexpressas, individualmente, sob o controle de quatro promotores de diferentes forças, provocando diferentes gastos energéticos na levedura. Entretanto, não foi possível obter aumento no rendimento em etanol. Em seguida, foi feito um estudo que visou comparar essas linhagens em situação de estresse térmico, ácido ou osmótico, tipicamente encontrados no processo brasileiro de produção de etanol. A 40 °C, uma linhagem superexpressando CDC48 apresentou velocidade específica máxima de crescimento 17 % maior que a linhagem de referência, indicando maior tolerância ao estresse térmico. Finalmente, avaliou-se Hsp104 e Cdc48 em um contexto fisiológico no qual as atividades dessas proteínas pudessem ser mais requeridas. Como as chaperonas moleculares são conhecidas por agirem como primeira linha de defesa contra a formação de proteínas incorretamente enoveladas e agregados proteicos, estudaram-se a morfologia e a fisiologia da superexpressão de HSP104 e CDC48 em linhagens com desarranjo no controle de qualidade de proteínas intracelulares, causado por mutações no proteassomo 20S. A superexpressão de CDC48 ou HSP104 reverteu em parte a morfologia alterada de alguns desses mutantes de proteassomo. / The initial goal of this work was to overexpress proteins with ATPase activity in Saccharomyces cerevisiae, as an attempt to alter the conservation of free energy in this yeast, in order to increase alcoholic fermentation yield. Therefore, two native S. cerevisiae ATPases, the chaperones encoded by HSP104 and CDC48, were individually overexpressed under the control of four promoters with different strengths, in order to provoke different levels of energy expenditure. Increments in the ethanol yield could not be observed in any of the constructed strains. Subsequently, a study was carried out to compare these mutant strains with reference strains under heat, acid or osmotic stress, which are typically found in the industrial fuel ethanol production in Brazil. At 40 oC a strain overexpressing CDC48 displayed a maximum specific growth rate 17 % higher than that of the reference strain, indicating a greater tolerance to heat stress. Finally, Hsp104 and Cdc48 were evaluated in a physiological context in which the activity of these proteins would be required in a higher level. Since molecular chaperones are known to act as the first defense line against the formation of misfolded proteins and aggregates, the physiological and morphological effects of HSP104 or CDC48 overexpression were analyzed in strains with protein quality control disarrangements caused by mutations in proteasome 20S. The overexpression of either CDC48 or HSP104 partially reversed the altered morphology of some of these proteasome mutants. CDC48 Fermentação alcoólica Fisiologia HSP104 Leveduras Saccharomyces cerevisiae Alcoholic fermentation CDC48 HSP104 Maximum specific growth rate Saccharomyces cerevisiae
8	In vitro reconstitution of the ubiquitylation and disassembly of the eukaryotic replisome Mukherjee, Progya January 2018 (has links) Maintenance of genomic integrity is dependent on the duplication of chromosomes, only once per cell cycle. Highly conserved mechanisms for the regulation of chromosome replication exists to ensure that the genome is copied only once. The Cdc45-MCM-GINS (CMG) DNA helicase which is the core of the eukaryotic replication complex, has been shown to be extensively regulated by post translational modifications, during its assembly. Therefore, it is not inconceivable that the process to unload the replication complex would also be a conserved and regulated process. In 2014, our lab discovered that the CMG complex undergoes post-translational modification in the form of ubiquitylation on one of the subunits of CMG, leading to its disassembly from the chromatin. Though the main players in the disassembly of CMG were known, viz the E3 ligase SCFDia2 and segregase Cdc48, very little was known about the mechanism of CMG disassembly. In the process of learning more about the disassembly of the replicative helicase from chromatin, I reconstituted the ubiquitylation of CMG and thereafter the disassembly of CMG helicase in vitro. My work resulting in the reconstitution of CMG disassembly in vitro is the first example of the disassembly of a multi-subunit physiological substrate of Cdc48. Though CMG is ubiquitylated in yeast extracts in vitro, it does not lead to its disassembly and therefore led me to find conditions necessary for the efficient ubiquitylation of CMG. I have further shown that purifying the E3 ligase associated CMG can be efficiently ubiquitylated in a semi-reconstituted system consisting of purified factors, necessary for the ubiquitylation of substrate. I investigated whether this efficiently ubiquitylated CMG can be disassembled by purified Cdc48 and associated co-factor Ufd1/Npl4 in vitro and found that disassembly is dependent on K48 linked poly-ubiquitylation of CMG. I have found that the reconstituted poly-ubiquitylation of CMG is restricted to the Mcm7 subunit of CMG, recapitulating the ubiquitylation of CMG in vivo, and my data points out that there are multiple sites of ubiquitylation on Mcm7. Through this work, I have also found that ubiquitylated Mcm7 no longer associates with the rest of the CMG components after disassembly of CMG. My assays and findings, open the door towards dissecting the molecular mechanism of the disassembly of CMG in greater detail.
9	Identification et étude du rôle des protéines cibles du monoxyde d'azote (NO) dans les réponses de défense chez le tabac Astier, Jérémy 30 May 2011 (has links) (PDF) Les études entreprises depuis une douzaine d'années indiquent que le monoxyde d'azote (NO) est un médiateur physiologique impliqué dans de nombreux processus chez les plantes, incluant la germination, le développement des racines, la fermeture des stomates ou encore la réponse adaptative aux stress biotiques et abiotiques. Malgré cet important panel de fonctions, les mécanismes sous-jacents aux effets du NO ont été peu appréhendés et restent pour l'essentiel énigmatiques. Le travail présenté dans ce manuscrit s'inscrit dans cette problématique et a consisté en l'identification et la caractérisation de protéines cibles du NO chez le tabac dans le contexte de stress biotiques et abiotiques. Nous avons démontré que la cryptogéine, un éliciteur des réactions de défense, induit la S-nitrosylation rapide et transitoire de plusieurs protéines dans des suspensions cellulaires de tabac. Après purification, une douzaine de ces protéines ont été identifiées via une analyse par spectrométrie de masse. Celles-ci incluent notamment une protéine chaperonne de la famille des AAA-ATPase nommée CDC48 (Cell Division Cycle 48). Cette dernière a fait l'objet d'une étude structure/fonction approfondie afin d'appréhender l'impact de sa S-nitrosylation. Après avoir vérifié que la protéine recombinante était S-nitrosylable in vitro, nous avons démontré que ce processus n'affecte pas la structure secondaire de la protéine mais induit des modifications locales de sa structure tertiaire et une inhibition de son activité ATPasique. Le résidu cystéine 526, localisé dans le second domaine ATPasique de la protéine, a été identifié comme site probable de S-nitrosylation. Cette localisation stratégique pourrait expliquer l'effet inhibiteur du NO sur l'activité enzymatique de CDC48. La dernière partie de ce travail a été centrée sur l'analyse des mécanismes par lesquels le NO active la protéine kinase NtOSAK (Nicotiana tabacum stress activated protein kinase) chez le tabac. Nous avons démontré que NtOSAK forme un complexe constitutif avec la glycéraldéhyde 3 phosphate deshydrogénase (GAPDH). En réponse à un stress salin, le NO promeut l'activation de NtOSAK via la phosphorylation de deux résidus serine localisés dans la boucle d'activation de l'enzyme. De plus, il induit une S-nitrosylation rapide de la GAPDH, ce processus n'affectant pas la formation du complexe. Notre hypothèse est que ce complexe constituerait une plateforme de signalisation régulée par le NO et pouvant recruter les protéines cibles de NtOSAK lors de la réponse au stress salin. Nicotiana tabacum Monoxyde d'azote Cryptogéine CDC48 NtOSAK Défenses des plantes
10	Regulation of chromosome condensation in Saccharomyces cerevisiae during mitosis Thattikota, Yogitha 05 1900 (has links) No description available. Condensine Smc4 Cdk1 Cdc48 Ufd1-Npl4 Phosphorylation Cycle cellulaire Ubiquitination Chaperon Condensin Chaperone Cell cycle

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