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Investigating Minor States of the Oncoprotein N-MYC, with Focus on Proline Cis/Trans Isomerisation using NMR SpectroscopyHaugskott, Frida January 2021 (has links)
MYC is a family of three regulator genes that codes for transcription factors. Expression of Myc proteins from MYC genes is found to be deregulated in 70 % of all cancer forms. The three human homologs C-Myc, N-Myc and L-Myc are mainly associated with cancer in the lymphatic system, nerve tissues and lung cancer, respectively. Even though N-Myc is associated with Neuroblastoma, the cancer variant that is most common among children, the field is focused towards C-Myc. The activation of C-Myc begins with phosphorylation of Serine 62, followed by trans-to-cis isomerisation of Proline 63. Then Threonine 58 becomes phosphorylated leading to that Serine 62 is dephosphorylated and subsequent cis-to-trans isomerisation of Proline 63, and C-Myc is marked for degradation. Cis-trans isomerisation is necessary for regulation of gene expression, and is therefore important to understand. Since N-Myc and C-Myc have identical sequences between residues 47 to residue 69, the hypothesis is that N-Myc is activated in the same manner, but this has not been confirmed. In this project the first 69 amino acids of N-Myc were analysed with NMR spectroscopy. This resulted in a near complete assignment of the major conformation, and of the alternative minor conformations as well. The traditional assignment experiments HNCACB, HN(CO)CACB, HNCO, HN(CA)CO in combination with CCH-TOCSY and HN(CCO)C revealed that the majority of the minor configurations can be explained by cis/trans isomerisation of prolines. In addition, the protein was analysed with direct carbon detected NMR spectroscopy to be able to detect the prolines.
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Structural and functional investigation of the C-terminal intrinsically disordered fragment of ErbB2 / Exploration structurale et fonctionnelle de la partie C-terminale intrinsèquement désordonnée de ErbB2Pinet, Louise 17 October 2019 (has links)
ErbB2/HER2 est un récepteur tyrosine kinase de la famille d'EGFR (ErbB1) surexprimé dans plus de 20% des cancers du sein et associé à une forme particulièrement agressive de la maladie. Les récepteurs ErbBs sont actifs seulement sous forme de dimères, permettant la phosphorylation de leur queue C-terminale par leur domaine tyrosine kinase. La phosphorylation entraine l'interaction avec des protéines adaptatrices et l'activation de voies de signalisation, Ras/MAPK et PI3K/Akt principalement. Ces voies contrôlent la prolifération, la motilité cellulaire et la résistance à l'apoptose. Contrairement à ErbB1/3/4, ErbB2 dimérise en l'absence de ligand. Comprendre les autres mécanismes de régulation de la phosphorylation de ses tyrosines et de ses interactions est donc particulièrement intéressant.ErbB2 a fait l'objet de nombreuses études structurales et fonctionnelles. Elles ont permis la mise au point de traitements ciblés efficaces mais sujets à l'apparition de résistance, dont l'anticorps Trastuzumab, ciblant sa partie extracellulaire. La queue C-terminale d'ErbB2 (CtErbB2) a été très souvent ignorée dans ces études. Cette partie étant intrinsèquement désordonnée, il a fallu attendre ces dernières années pour que les concepts et les outils permettant de l'étudier émergent.Dans cette thèse, j'ai d'abord effectué la caractérisation structurale et dynamique de CtErbB2. J'ai montré que bien qu'étant dépourvue de toute structure stable, cette région riche en prolines possède plusieurs structures secondaires transitoires et un contact longue-distance participant très probablement à la régulation de ses interactions intra- et inter-moléculaires. Dans une deuxième partie je me suis intéressée à la caractérisation de la protéine adaptatrice Grb2, partenaire essentiel de ErbB2 pour l'activation de la voie des MAP kinases. L'organisation en solution des domaines de cette protéine modulaire dans sa forme libre était jusque là inconnue. J'ai ensuite étudié l'interaction entre Grb2 et CtErbB2, et montré que CtErbB2 interagit non seulement avec le domaine SH2 de Grb2 (par l'intermédiaire d'une phosphotyrosine), mais aussi avec son domaine SH3 N-terminal (grâce à un motif polyproline). Enfin, j'ai mis en place plusieurs stratégies de phosphorylation des tyrosines de CtErbB2, dans le but d'étudier plus largement l'effet des phosphorylations sur l'ensemble de cette région. / ErbB2/HER2 is a receptor tyrosine kinase of the EGFR (ErbB1) family overexpressed in 20% of breast cancers and associated to a particularly aggressive form of the disease. ErbB receptors are only active upon dimerization that enables phosphorylation of their C-terminal tail by their tyrosine kinase domain. Phosphorylation then triggers interaction with adaptor proteins and activation of signaling pathways, mainly Ras/MAPK and Akt/PI3K. Those pathways control cell proliferation, motility and resistance to apoptosis. Contrary to ErbB1/3/4, ErbB2 can dimerize without any ligand. Understanding other mechanisms of regulation of its tyrosine phosphorylation and of its interactions is thus particularly interesting.ErbB2 structure and function have been extensively studied. This has led to the development of several FDA-approved targeted drugs, that are effective but to which resistance occurs, amongst which the Trastuzumab antibody that targets ErbB2 extracellular domain. The C-terminal tail of ErbB2 (CtErbB2) has been widely ignored in these studies. Since it is intrinsically disordered, the concepts and tools to study it have only emerged in the last few years.In the present work, I have performed the structural and dynamic study of CtErbB2. I showed that despite its lack of any stable structure, this proline-rich region exhibits several transient secondary structures and a long-range contact that might participate in the regulation of its intra- and inter-molecular interactions. Then, I characterized the adaptor protein Grb2, which is a partner of ErbB2 that is essential for the activation of the MAPK pathway. The solution organization of the domains of this modular protein in its apo-form was unknown so far. I also studied the interaction between Grb2 and CtErbB2, showing that in addition to the known SH2-phosphotyrosine interaction, a polyproline motif of CtErbB2 binds to the N-terminal SH3 domain of Grb2. Finally, I implemented several strategies to phosphorylate CtErbB2 tyrosines, to study more extensively the effect of phosphorylation on the whole tail.
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The Role of Intrinsically Disordered Thellungiella salsuginea dehydrins TsDHN-1 and TsDHN-2 in Stabilization of Membranes and Cytoskeletal Actin FilamentsRahman, Luna 11 May 2012 (has links)
The group 2 late embryogenesis abundant (LEA) proteins, also known as the dehydrins, are intrinsically disordered proteins that are expressed in plants experiencing extreme environmental conditions such as drought or low temperature. In this work, we study the potential roles that dehydrins may have in stabilizing membranes and actin microfilaments during cold stress. We have cloned and expressed in E. coli two dehydrins from Thellungiella salsuginea, denoted TsDHN-1 (acidic) and TsDHN-2 (basic). These proteins were expressed as SUMO-fusion proteins for in vitro phosphorylation by casein kinase II (CKII), and for structural analysis by CD and Fourier transform infrared (FTIR) spectroscopy. We show using transmission-FTIR spectroscopy that ordered secondary structure is induced and stabilized in these proteins by association with large unilamellar vesicles emulating the lipid compositions of plant plasma and organellar membranes. The increase in secondary structure by membrane association is further facilitated by the presence of Zn2+. Lipid composition and temperature have synergistic effects on the secondary structure. Our single molecule force spectroscopy studies also suggest tertiary folding of both TsDHN-1 and TsDHN-2 induced by association with lipids. From Langmuir-Blodgett monolayer compression studies, and from topographic studies using atomic force microscopy at variable temperature, we conclude that TsDHN-1 stabilizes the membrane at lower temperatures. Finally, we show that the conformations of TsDHN-1 and TsDHN-2 are affected by pH, interactions with cations and membranes, and phosphorylation. Actin assembly by these dehydrins was assessed by sedimentation assays, and viewed by transmission electron and atomic force microscopy. Phosphorylation enabled both dehydrins to polymerize actin filaments, a phenomenon that may occur in the cytosols of plant cells undergoing environmental stress. These results support the hypothesis that dehydrins stabilize plant organellar membranes and/or the cytoskeleton in conditions of stress, and further that phosphorylation may be an important feature of this stabilization. / NSERC
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Analyses structurales et fonctionnelles de la protéine non-structurale 5A (NS5A) du virus de l’hépatite C / Structural and functional analysis of the non structural protein 5A (NS5A) from hepatitis C virusBadillo, Aurélie 26 November 2012 (has links)
La protéine NS5A est essentielle pour la réplication et l'assemblage du virus de l'hépatite C (VHC), et elle constitue une cible thérapeutique prometteuse pour le développement d'antiviraux. Cependant, aucune fonction claire n'a encore été décrite pour NS5A, et les connaissances structurales restent limitées. Ainsi, nous avons caractérisé l'état intrinsèquement désordonné des domaines D2 et D3 de NS5A en décrivant leurs espaces conformationnels et leurs potentialités de repliement en combinant différentes méthodes biophysiques. Nous avons aussi mis en évidence la variabilité structurale du domaine D2 au sein des génotypes du VHC, ce qui pourrait être en rapport avec les différences de pathogénie et d'efficacité des thérapies observées selon les génotypes. L'interaction de D2 et D3 avec la cyclophiline humaine A (CypA) a été étudiée par résonance plasmonique de surface (SPR). Bien que des mutations au sein du domaine D2 rendent la réplication du VHC moins dépendante de la présence de CypA, ces mutations n'empêchent pas la liaison entre D2 et CypA. En revanche, elles induisent des perturbations structurales qui pourraient affecter la cinétique d'interconversion des conformères de D2. Nous avons montré par SPR que D2 et D3 interagissent avec le domaine de fixation à l'ADN du récepteur nucléaire FXR. Cette interaction pourrait inhiber la fixation de FXR sur sa cible ADN, suggérant une implication de NS5A dans la modulation de l'activité transcriptionnelle de ce récepteur nucléaire. L'ensemble de ces informations, nous a permis de proposer un modèle de la structure globale de NS5A permettant une meilleure compréhension des propriétés structurales et fonctionnelles de cette protéine énigmatique / NS5A is essential for HCV replication and particle assembly, and constitutes a very promising drug target. However, no clear function has yet been described for NS5A, and structural knowledge remains limited. We characterized the intrinsically disordered nature of NS5A domains D2 and D3, and describe their folding propensity and their overall conformational behaviour by combining different biophysical methods. We also highlighted the structural variability of D2 domain in HCV genotypes, which might be correlated with the disparities observed between genotypes in terms of pathogenesis and efficiency of therapies. The interactions between D2 and D3 with human cyclophilin A (CypA) was analysed by surface plasmon resonance (SPR). We showed that mutations in the D2 domain conferring resistance of HCV replication to CypA inhibitors did not prevent the interaction between D2 and CypA. However, they induce structural perturbations that may affect the kinetics of conformers interconversion of D2. We also showed by SPR that D2 and D3 interact with the of DNA-binding domain of the nuclear receptor FXR (farnesoid X receptor alpha). This interaction reduce the binding of FXR to its DNA target, suggesting an involvement of NS5A in the modulation of the transcriptional activity of FXR. All this data led us to propose a model of the overall structure of NS5A, which provides a useful template for a better understanding of structural and functional properties of this enigmatic protein
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