Global ETD Search

11	Characterization of Structural and Binding Properties of 4E-BP2 Lukhele, Sabelo 10 July 2013 (has links) Eukaryotic initiation factor-4E (eIF4E) controls the rate of cap-dependent translation initiation and is in turn exquisitely regulated by 4E-BPs. 4E-BP2 binds eIF4E with the highest affinity and is implicated in cancer, and metabolic and neurological disorders. Herein we use NMR, ITC and fluorescence to characterize 4E-BP2 structural and binding properties. Isolated 4E-BP2 is intrinsically disordered, but possesses some transient secondary structural propensities. eIF4E, however, is folded but has a disordered N-terminus. The eIF4E:4E-BP2 interaction is tight (Kd = 10-9 nM) and involves 4E-BP2 C-terminal and canonical binding regions, and the disordered eIF4E N-terminus. 4E-BP2 remains largely disordered upon binding to eIF4E. Noteworthy, high affinity interactions are not necessarily mediated by static structures, and 4E-BP2 binding is not the simple “disorder-to-order” transition observed in many interactions involving disordered proteins. This study offers molecular insights into 4E-BP2 functionality, and lays a foundation for development of novel therapies for cancer and neurological disorders. Translation initiation Intrinsically disordered protein Eukaryotic initiation factor 4E 4E-BP2 NMR Fluorescence 0487
12	Intrinsic Disorder Where You Least Expect It: The Incidence and Functional Relevance of Intrinsic Disorder in Enzymes and the Protein Data Bank Deforte, Shelly 27 June 2016 (has links) Intrinsically disordered proteins (IDPs) and intrinsically disordered protein regions (IDPRs) exist as interconverting conformational ensembles, without a single fixed three-dimensional structure in vivo. The focus in the literature up to this point has been primarily on IDPs that are mostly or entirely disordered. Therefore, we have an incomplete understanding of the incidence and functional relevance of IDPRs in proteins that have regions of both order and disorder. This work explores these populations, by examining IDPRs in the Protein Data Bank (PDB) and in enzymes. By applying disorder prediction methods combined with an analysis of missing regions in crystal structure data, this work shows that enzymes have a similar incidence and length of IDPRs as do non-enzymes, and that these IDPRs are correlated with functions related to macromolecular metabolism, signaling, and regulation. Furthermore, extensive analyses of missing regions with conflicting information between multiple structures in the PDB show that, rather than experimental artifacts, this ambiguity most likely arises due to partially or conditionally disordered regions. This work documents the first proteome level study of protein intrinsic disorder in enzyme populations and demonstrates a novel way of analyzing missing regions in the PDB. Furthermore, an extensive literature search as part of this work provides information for 1127 IDPs with experimental evidence documented in the literature, 96 of which are enzymes. The results contained herein present a new model of the protein universe, where disorder is directed by evolution in both non-enzymes and enzymes to make the most of limited proteomes in complex organisms through complicated signaling networks and tightly controlled regulation. intrinsically disordered protein x-ray crystallography structural biology enzyme function Bioinformatics Medicine and Health Sciences Molecular Biology
13	The structural basis for lipid interactions of serum amyloid A Frame, Nicholas 07 October 2019 (has links) Serum amyloid A (SAA) is a small, evolutionarily well-conserved, acute-phase protein best known as the protein precursor for amyloid A amyloidosis. During acute injury, infection, or inflammation, SAA plasma concentration rapidly rises 1000-fold, but the benefit of this dramatic increase is unclear. SAA functions in the innate immune response, cell signaling, and lipid homeostasis. Most SAA circulates on plasma high-density lipoproteins (HDL), where it reroutes HDL for lipid recycling. The aim of this dissertation is to provide a structural basis for understanding SAA-lipid interactions and to elucidate the structure-function relationship in this ancient protein. SAA is an intrinsically disordered protein that acquires ~50% helical structure when bound to lipids, and is ~80% helical in three available atomic-resolution x-ray crystal structures. We took advantage of these crystal structures of lipid-free SAA to propose the binding site for various lipids, including lipids in HDL. We postulated that SAA, as a monomer, binds lipids via two amphipathic helices, h1 and h3, that form a concave hydrophobic surface, and that the curvature of this surface defines the binding preference of SAA for HDL versus larger lipoproteins. Next, we used murine SAA1.1 and a membrane-mimicking model phospholipid, palmitoyl-oleoyl phosphocholine (POPC), to reconstitute SAA-lipid complexes and characterize their overall structure, stability and stoichiometry using an array of spectroscopic, electron microscopic, and biochemical methods. We observed preferential formation of ~10 nm particles that mimic HDL size, accompanied by the α-helical folding. To probe the local protein conformation and dynamics in these SAA-POPC particles, we used hydrogen-deuterium exchange mass spectrometry. Analysis of the amount and the kinetics of deuterium uptake clearly established h1 and h3 as the lipid-binding site. Moreover, we determined that SAA binding to lipid follows a mixed model that combines induced fit, promoting α-folding in h3, with conformational selection, stabilizing pre-existing conformations in h1 and around the h2-h3 linker. Taken together, our results provided the structural basis necessary for understanding SAA-lipid interactions, which are central to beneficial functions of SAA as a housekeeping molecule, and to its misfolding in amyloid. This research sets the stage for understanding SAA interactions with its numerous other functional ligands. Biophysics Intrinsically disordered protein Lipoprotein nanoparticle Protein-lipid binding Protein structure
14	Molecular Dynamics of Folded and Disordered Polypeptides in Comparison with Nuclear Magnetic Resonance Measurement Yu, Lei 15 August 2018 (has links) No description available. Biophysics Chemistry Physical Chemistry Molecular Dynamics Nuclear Magnetic Resonance Intrinsically Disordered Protein
15	Regulation of Palmitoylation Enzymes and Substrates by Intrinsically Disordered Regions Reddy, Krishna D. 15 November 2016 (has links) Protein palmitoylation refers to the process of adding a 16-carbon saturated fatty acid to the cysteine of a substrate protein, and this can in turn affect the substrate’s localization, stability, folding, and several other processes. This process is catalyzed by a family of 23 mammalian protein acyltransferases (PATs), a family of transmembrane enzymes that modify an estimated 10% of the proteome. At this point in time, no structure of a protein in this family has been solved, and therefore there is poor understanding about the regulation of the enzymes and their substrates. Most proteins, including palmitoylation enzymes and substrates, have some level of intrinsic disorder, and this flexibility can be important for signaling processes such as protein- protein interactions and post-translational modifications. Therefore, we assumed that examining intrinsic disorder in palmitoylation enzymes and substrates would yield insight into their regulatory mechanisms. First, we found that among other factors, utilizing intrinsic disorder predictions led to a palmitoylation predictor that significantly outperformed existing predictors. Next, we discovered a conserved region of predicted disorder-to-order transition in the disordered C-termini of the PAT family. In Erf2, the yeast Ras PAT, we developed a model where this region reversibly interacts with membranes, and we found that this region mediates interaction with Acc1, an enzyme involved in fatty acid metabolism processes. Finally, we found that an XLID-associated nonsense mutation in zDHHC9, the mammalian Ras PAT, removed a disordered region that was critical for enzyme localization. Future studies of palmitoylation utilizing the framework of intrinsic disorder may lead to additional insights about this important regulatory process. Acylation Protein Acyltransferase Intrinsically Disordered Protein Fatty Acid Metabolism Palmitoylation Predictor X-Linked Intellectual Disability Biochemistry Bioinformatics Neurosciences
16	Production, purification et caractérisation de la protéine Hsp 12 de Saccharomyces cerevisiae, une protéine impliquée dans la sucrosité du vin. / Production, purification and characterization of the Hsp12 protein of Saccharomyces cerevisiae, a protein involved in the sweetness of wine. Léger, Antoine 19 November 2019 (has links) La protéine Hsp12 est une protéine de choc thermique (12 kDa) exprimée par la levure Saccharomyces cerevisiae et associée à la réponse au stress. En effet, il a été montré que les transcrits du gène HSP12 sont exprimés en réponse à différents stress. De plus, la protéine Hsp12 serait responsable de la sucrosité du vin observée au cours de l’autolyse des levures lors de la vinification. Cependant, le goût sucré pourrait provenir de la protéine Hsp12 entière, ou, d’un ou plusieurs peptides issus de la protéine Hsp12. L’objectif de cette étude était d’obtenir la protéine Hsp12 native pure à partir de culture de Saccharomyces cerevisiae afin de comprendre son rôle, d’une part dans la réponse au stress chez la levure et, d’autre part dans la sucrosité du vin.Des cultures de la souche œnologique Fx10 de Saccharomyces cerevisiae ont été réalisées afin d’étudier la protéine Hsp12 native. La production de la protéine Hsp12 en réponse à différents stress a été étudiée au cours des cultures, grâce à un dosage ELISA développé lors de cette étude. Il a ainsi été mis en évidence que la protéine Hsp12 est produite en quantités significativement supérieures en réponse à des stress thermiques et osmotiques. Le stress éthanolique quant à lui entraine une diminution de la quantité de protéine Hsp12. La protéine Hsp12 native extraite à partir des cultures a été purifiée. Un procédé de purification en 3 étapes a été développé. Plusieurs résines et conditions chromatographiques ont été criblées en microplaques. La résine en mode mixte PPA HyperCel a permis d’éliminer des contaminants majeurs grâce à sa sélectivité. La chromatographie d’exclusion stérique a permis d’éliminer les contaminants restants et ainsi d’obtenir la protéine Hsp12 native avec une pureté de 99%. Différentes techniques biophysiques et calorimétriques ont permis de caractériser la protéine Hsp12 native purifiée, en présence de membranes modèles. Il a ainsi été démontré que la protéine Hsp12 est une protéine intrinsèquement non ordonnée (intrinsically disordered protein - IDP). Elle est caractérisée par l’absence de structures secondaires en solution aqueuse et par la formation d’hélices α en présence de SDS et du phospholipide PiP2. La liaison avec le PiP2 suggère un rôle dans la stabilisation de la membrane plasmique des levures. La protéine Hsp12 pourrait ainsi avoir un rôle de chaperonne de membrane. Une caractérisation organoleptique de la protéine Hsp12 native purifiée a également été réalisée. Il apparait que la protéine Hsp12 entière n’est pas responsable de la sucrosité mais plutôt un ou des peptides issus sa digestion enzymatique. / Hsp12 is a heat shock protein (12 kDa) expressed by the yeast Saccharomyces cerevisiae and associated with the stress response. Indeed, it has been shown that transcripts of the HSP12 gene are expressed in response to different stresses. In addition, the protein Hsp12 would be responsible for the sweetness of wine observed during the autolysis of yeasts during vinification. However, the sweet taste could come from the entire Hsp12, or from one or more peptides derived from Hsp12. The objective of this study was to obtain the pure native Hsp12 protein from Saccharomyces cerevisiae culture in order to understand its role, on the one hand in the stress response in yeast and on the other hand in the sweetness of wine.Cultures of the Saccharomyces cerevisiae Fx10 enological strain were made to study the native Hsp12 protein. The production of the Hsp12 protein in response to different stresses was studied during the cultures, thanks to an ELISA assay developed during this study. It has thus been demonstrated that the Hsp12 protein is produced in significantly greater quantities in response to thermal and osmotic stress. Ethanol stress causes a decrease in the amount of Hsp12 protein. The native Hsp12 protein extracted from the cultures was purified. A 3-step purification process has been developed. Several resins and chromatographic conditions were screened in microplates. PPA HyperCel mixed-mode resin has eliminated major contaminants due to its selectivity. Steric exclusion chromatography allowed the removal of remaining contaminants and thus obtain the native Hsp12 protein with a purity of 99%. Various biophysical and calorimetric techniques were used to characterize the purified native Hsp12 protein in the presence of model membranes. It has thus been demonstrated that the Hsp12 protein is an intrinsically disordered protein (IDP). It is characterized by the absence of secondary structures in aqueous solution and by the formation of α helices in the presence of SDS and phospholipid PiP2. The binding with PiP2 suggests a role in the stabilization of the plasma membrane of yeasts. The Hsp12 protein could thus act as a membrane chaperone. Organoleptic characterization of the purified native Hsp12 protein was also performed. It appears that the entire Hsp12 protein is not responsible for the sweetness but rather one or more peptides resulting from its enzymatic digestion. Hsp12 Chromatographie multimodale Protéine intrinsèquement non ordonnée Saccharomyces cerevisiae Sucrosité Stress Hsp12 Chromatography Intrinsically disordered protein Saccharomyces cerevisiae Sweetness Stress
17	Investigating Minor States of the Oncoprotein N-MYC, with Focus on Proline Cis/Trans Isomerisation using NMR Spectroscopy Haugskott, 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. Myc N-Myc Intrinsically Disordered protein (IDP) Proline cis-trans isomerisation minor conformation NMR cancer Structural Biology Strukturbiologi
18	Conformation of Y145Stop Prion Protein in Solution and Amyloid Fibrils Probed by Nuclear Magnetic Resonance Spectroscopy Xia, Yongjie 12 October 2017 (has links) No description available. Chemistry Physical Chemistry Biochemistry Biophysics
19	Etudes fonctionnelles et biophysiques de Hug1 ; une protéine intrinsèquement désordonnée impliquée dans le métabolisme des nucléotides / Hug1, an intrinsically disordered protein involved in nucleotide metabolism ; functional and biophysical insights Meurisse, Julie 18 September 2012 (has links) Face aux agressions constantes que subit l’ADN, les cellules ont développé des mécanismes de protection, nommés checkpoints pour maintenir l’intégrité de leur génome. Chez Saccharomyces cerevisiae, la kinase Rad53 joue un rôle central dans ces voies et son activation conduit à de nombreux effets cellulaires tels que le ralentissement du cycle cellulaire, le ralentissement de la réplication, l’activation de la transcription de certains gènes, l’activation de la réparation… Lors d’un crible transcriptomique, utilisant une souche exprimant une forme hyperactive de Rad53, nous avons identifié le gène HUG1 comme l’un des gènes les plus transcrits suite à l’activation de la voie RAD53. Cependant les fonctions de Hug1 demeurent énigmatiques.Pour mieux comprendre les fonctions de Hug1 dans la réponse aux dommages de l’ADN, nous avons recherché ses partenaires physiques et avons identifié les protéines Rnr2 et Rnr4, les deux composants de la petite sous-unité de la Ribonucléotide Réductase (RNR). La RNR est un complexe enzymatique qui catalyse l’étape limitante de synthèse des nucléotides. Nous avons alors cherché à caractériser cette interaction par diverses méthodes. Nous avons ainsi montré que Hug1 est une protéine intrinsèquement désordonnée capable d’interagir physiquement avec la petite sous-unité de la RNR et qu’au moins onze acides aminés de Hug1 sont impliqués dans son interaction avec la RNR. Lors de nos investigations, nous avons observé que le fait d’étiqueter Rnr2 en position C-terminale sensibilisait les souches aux stress génotoxiques et que cette sensibilité était supprimée si on abrogeait la fonction de HUG1, faisant de Hug1 un nouvel inhibiteur de la RNR. Ainsi nous sommes parvenus à proposer un modèle de régulation de la RNR par Hug1. / To maintain genome integrity, cells have developed protection mechanisms, called checkpoints, in response to DNA damage insults. In Saccharomyces cerevisiae, Rad53 protein kinase is one of the major actors in these mechanisms, and its activation triggers several cellular responses such as cell cycle delay, replication delay, transcription modifications, activation of DNA repair pathways… Using an hyperactivative allele of RAD53, we identified HUG1, as one of the most induced gene in a transcriptomic analysis upon RAD53 pathway activation. However Hug1’s functions remains elusive.To better understand Hug1’s functions in DNA damage response, we searched for physical partners and identified Rnr2 and Rnr4 proteins, which are the two small subunits of Ribonucleotide Reductase (RNR). The RNR is an enzymatic complex that catalyses nucleotide reduction, a step limiting for dNTPs synthesis. We next experimentally tackled the Hug1-RNR interaction using various methods. We showed so that Hug1 is a small intrinsically disordered protein able to interact physically with the small RNR subunit and that at least eleven amino acids in Hug1 are involved in this interaction. During our investigations, we observed that C-terminal tagging of Rnr2 sensitizes strains to genotoxics stress and that this sensitivity was suppressed when HUG1’s function is abrogated. Hence, we showed that Hug1 is a negative RNR regulator and propose a model for Hug1’s function. HUG1 Ribonucléotide réductase Protéine intrinsèquement désordonnée Saccharomyces cerevisiae Réponses aux dommages de l’ADN HUG1 Ribonucleotide Reductase Intrinsically Disordered Protein Saccharomyces cerevisiae DNA damage response
20	Degradation mechanisms of TTP/TIS11 proteins, major effectors of the AU-rich element-mediated mRNA decay in eukaryotes Vo Ngoc, Long 25 September 2014 (has links) Regulation of gene expression occurs at several levels in a cell. While control of transcription is often viewed as the main source of regulation, it is now clear that post-transcriptional processes are essential to fine-tune protein availability. The presence of AU-rich elements (ARE) in the 3’ untranslated region (3’UTR) of many important mRNAs exemplifies one such process. AREs alter the mRNA translation or degradation status by recruiting ARE-binding proteins (ARE-BP). ARE-BPs of the TTP/TIS11 family bind to their cognate ARE-RNAs using their conserved tandem zinc-finger domain and induce rapid decay of their targets. This allows for proper regulation of cell proliferation, cell death and inflammation. In this regard, TTP/TIS11 are main regulators of gene expression, and as such are put under strict transcriptional, post-transcriptional as well as several layers of post-translational control.<p>In this work, we aimed at elucidating the degradation mechanisms affecting TTP/TIS11. Using Drosophila as a model, we found that dTIS11 protein turnover is rapid due to continuous degradation by the proteasome. However, proteasomal recognition did not require ubiquitination of dTIS11 as non-ubiquitinable mutants were efficiently degraded by the proteasome. In addition, dTIS11 was digested by the 20S proteasome that lacks ubiquitin-recognition domains. Our results further indicate that intrinsically disordered regions (IDR) in dTIS11 may be responsible for proteasomal recognition. In fact, dTIS11 is predicted as disordered and possesses the main characteristics of intrinsically disordered proteins (IDP). We also identified dTIS11 N- and C-terminal domains as functional signals for degradation, potentially due to their destructuration. This ubiquitination-independent, disorder-dependent degradation process is conserved throughout evolution as dTIS11 mammalian counterpart, TTP, undergoes the same degradation by default pathway. In addition, we established that phosphorylation prevents degradation of TTP/TIS11 by the proteasome. <p>Together, our results pinpoint a new essential characteristic for TTP/TIS11 that may redefine the identity of these proteins. In addition, we unraveled a novel and conserved mechanism of regulation of TTP/TIS11. This control is essential for cell physiology as defects in this process can lead to defects in the inflammatory response, increased radiation-induced lung toxicity and tumorigenesis.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Biologie Proteins -- Metabolism Ubiquitin Protéines -- Métabolisme Ubiquitine Proteasome Ubiquitin-independent Intrinsically disordered protein AU-rich element Tristetraprolin TIS11

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