Global ETD Search

1	Structural and functional interactions between measles virus nucleocapsid protein and cellular heat shock protein Zhang, Xinsheng 09 March 2004 (has links) No description available. Hsp72 Morbillivirus Nucleocapsid protein Binding motif Reverse genetics Biacore
2	Analyse de la régulation du facteur de transcription E2F1 par cIAP1 / Analysis of E2F1 by clAP1 Allègre-Cultot, Jennifer 02 February 2017 (has links) CIAP1 (cellular Inhibitor of Apoptosis 1) possède une activité E3-ubiquitine ligase et présente des propriétés oncogéniques. Récemment, notre équipe a montré que cIAP1 pouvait réguler l’activité du facteur de transcription E2F1. L’objectif de mon travail de thèse était d’approfondir les mécanismes de cette régulation et d’évaluer l’importance de la coopération cIAP1-E2F1 dans l’activité oncogénique de cIAP1. J’ai démontré une interaction d’E2F1 avec la poche hydrophobe du domaine BIR3 de cIAP1. J’ai par ailleurs démontré l’importance de la première hélice α de ce domaine pour l’interaction de cIAP1 avec E2F1 et avec les autres protéines partenaires de cIAP1 capables de lier la poche hydrophobe du domaine BIR3. De plus, j’ai participé au travail montrant pour la première fois une régulation d’E2F1 par une ubiquitinylation non dégradative. cIAP1 permet la conjugaison de chaînes d’ubiquitines de type K63 sur les lysines 161 et 164 d’E2F1. Cette modification post-traductionnelle est indispensable à la stabilisation de la protéine lors d’un stress génotoxique et elle permet le recrutement du facteur de transcription sur les promoteurs des gènes cibles. Enfin, l’analyse des propriétés oncogéniques de cIAP1 n’ont pas permis, à ce jour, d’évaluer l’importance de la coopération cIAP1-E2F1. Cependant, nous avons montré l’importance du domaine BIR1 pour les propriétés oncogéniques de cIAP1 (domaine nécessaire à l’interaction de cIAP1 avec l’adaptateur moléculaire TRAF2). / The cellular inhibitor of Apoptosis 1 (cIAP1) behaves as an E3 ubiquitin ligase and has oncogenic properties. Previously, our team has shown that cIAP1 can regulate the E2F1 transcription factor activity. My research project has been focused on deepening our current knowledge on this interaction. Firstly, we characterized the E2F1-cIAP1 interaction, then we analyzed the regulation of E2F1 by cIAP1 and finally assessed the importance of the cIAP1-E2F1 interaction for the oncogenic properties of cIAP1. I have demonstrated a interaction of E2F1 with the hydrophobic pocket of the BIR3 domain of cIAP1. Moreover, I highlighted that the alpha 1 helix of the BIR3 domain is mandatory for the stability of this pocket. Moreover, we discovered an ubiquitination on lysine 161 and 164 of E2F1 by cIAP1. This ubiquitination is essential for the stability and transcriptional activity of E2F1. Finally, it appears that the cIAP1 BIR1 domain that is required for the interaction with TRAF2 is involved in its oncogenic properties. CIAP1 E2F1 Ubiquitinylation IBM CIAP1 E2F1 Ubiquitinylation IAP-Binding-Motif 571.6
3	The Structure and Function Study of Three Metalloenzymes That Utilize Three Histidines as Metal Ligands Chen, Yan 19 November 2013 (has links) The function of the metalloenzymes is mainly determined by four structural features: the metal core, the metal binding motif, the second sphere residues in the active site and the electronic statistics. Cysteamine dioxygenase (ADO) and cysteine dioxygenase (CDO) are the only known enzymes that oxidize free thiol containing molecules in mammals by inserting of a dioxygen molecue. Both ADO and CDO are known as non-heme iron dependent enzymes with 3-His metal binding motif. However, the mechanistic understanding of both enzymes is obscure. The understanding of the mechanistic features of the two thiol dioxygenases is approached through spectroscopic and metal substitution in this dissertation. Another focus of the dissertation is the understanding of the function of a second sphere residue His228 in a 3-His-1-carboxyl zinc binding decarboxylase α-amino-β-carboxymuconate-ε-semialdehyde decarboxylase (ACMSD). ACMSD catalyzes the decarboxylation through a hydrolase-like mechanism that is initialized by the deprotonation of metal bounded water molecule. Our study reveled that the second sphere residue His228 is responsible for the water deprotonation through hydrogen bonding. The spectroscopic and crystallographic data showed the H228Y mutation binds ferric iron instead of native zinc metal and the active site water is replaced by the Tyr228 residue ligation. Thus, we concluded that, H228Y not only plays a role of stabilizing and deprotonating the active site water but also is an essential residue on metal selectivity. Cysteamine dioxygenase Cysteine dioxygenase ACMSD Metal binding motif Metal selectivity Substrate specificity
4	Analysis of RBM5 and RBM10 expression throughout H9C2 skeletal and cardiac muscle cell differentiation. Loiselle, Julie Jennifer 31 July 2013 (has links) RNA Binding Motif (RBM) domain proteins RBM5 and RBM10 have been shown to influence apoptosis, cell cycle arrest and splicing in transformed cells. In this study, RBM5 and RBM10 were examined in non-transformed cells in order to gain a wider range of knowledge regarding their function. Expression of Rbm5 and Rbm10, as well as select splice variants, was examined at the mRNA and protein level throughout H9c2 skeletal and cardiac myoblast differentiation. Results suggest that Rbm5 and Rbm10 may (a) be involved in regulating cell cycle arrest and apoptosis during skeletal myoblast differentiation and (b) undergo post-transcriptional or translational regulation throughout myoblast differentiation. All in all, the expression profiles obtained in the course of this study will help to suggest a role for Rbm5 and Rbm10 in differentiation, as well as possible differentiation-specific target genes with which they may interact. RNA Binding Motif (RBM) domain proteins RBM5 RBM10 Myoblast differentiation H9c2 Alternative Splicing
5	Computational bioinformatics on three-dimensional structures of ribosomes using multiresolutional analysis Hsiao, Chiaolong 25 August 2008 (has links) RNA is amazing. We found that without changing the backbone connectivity, RNA can maintain structural conservation in 3D via topology switches, at a single residue level. I developed a method of representing RNA structure in multiresolution, called the PBR approach (P stands for Phosphate; B stands for Base; R stands for Ribose). In this method, structural data is viewed through a series of resolutions from finest to coarsest. At a single nucleotide resolution (fine resolution), RNA is abstruse and elaborate with structural insertions/deletions, strand clips, and 3,2-switches. The compilation of structural deviations of RNA, called DevLS (Deviations of Local Structure), provides a new descriptive language of RNA structure, allowing one to systematize and investigate RNA structure. Using PBR analysis, a total of 103 tetraloops within the crystal structures of the 23s rRNA of H. marismortui and the 70s rRNA of T. thermophilus are found and classified. Combining them, I constructed a 'tetraloop family tree', using a tree formalism, to unify and re-define the tetraloop motif and to represent relationships between tetraloops, as grouped by DevLS. To date, structural alignment of very large RNAs remains challenge due to the large size, intricate backbone choreography, and tertiary interactions. To overcome these obstacles, I developed a concept of structural anchors along with a 'Divide and Conquer' strategy for performing superimposition of 23s rRNAs. The successful alignment and superimpositions of the 23s rRNAs of T. thermophilus and H. marismortui gives an overall RMSD of atomic positions of 1.2 Å, as utilized 73% of RNA backbone atoms (~ 2129 residues). By using principles of inorganic chemistry along with structural alignment technique as described above, a recurrent magnesium-binding motif in large RNAs is revealed. These magnesium-binding motifs play a critical role in the framework of the ribosomal PTC by their locations, topologies, and coordination geometries. Common features of Mg2+-mc's include direct phosphate chelation of two magnesium ions in the form of Mg2+(i)-(O1P-P-O2P)-Mg2+(j), phosphate groups of adjacent RNA residues as ligands of a given Mg2+, and undulated RNA surfaces with unpaired and unstacked bases. Magnesium-binding motif Superimposition Structural alignment Multiresolution Ribosome Tetraloop Bioinformatics Ribosomes RNA Image processing
6	Structure-function Relationship of the β-hairpin Loop in the N-terminal Domain and the Zinc-binding Motif of Thermolysin / サーモライシンのN末端領域のβヘアピンループと亜鉛結合モチーフの構造活性相関 Menach Evans Pkemoi 24 March 2014 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第18316号 / 農博第2041号 / 新制\|\|農\|\|1020(附属図書館) / 学位論文\|\|H26\|\|N4823(農学部図書室) / 31174 / 京都大学大学院農学研究科食品生物科学専攻 / (主査)教授保川清, 教授安達修二, 教授伏木亨 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM β-hairpin loop metalloproteinase site-directed mutagenesis thermolysin zinc-binding motif 610
7	Biochemical properties and substrate reactivities of Aquifex Aeolicus Ribonuclease III Shi, Zhongjie January 2012 (has links) Ribonuclease III is a highly-conserved bacterial enzyme that cleaves double-stranded (ds) RNA structures, and participates in diverse RNA maturation and decay pathways. Essential insight on the RNase III mechanism of dsRNA cleavage has been provided by crystallographic studies of the enzyme from the hyperthermophilic bacterium, Aquifex aeolicus. However, those crystals involved complexes containing either cleaved RNA, or a mutant RNase III that is catalytically inactive. In addition, neither the biochemical properties of A. aeolicus (Aa)-RNase III, nor the reactivity epitopes of its cognate substrates are known. The goal of this project is to use Aa-RNase III, for which there is atomic-level structural information, to determine how RNase III recognizes its substrates and selects the target site. I first purified recombinant Aa-RNase III and defined the conditions that support its optimal in vitro catalytic activity. The catalytic activity of purified recombinant Aa-RNase III exhibits a temperature optimum of 70-85°C, a pH optimum of 8.0, and with either Mg2+ or Mn2+ supports efficient catalysis. Cognate substrates for Aa-RNase III were identified and their reactivity epitopes were characterized, including the specific bp sequence elements that determine processing reactivity and selectivity. Small RNA hairpins, based on the double-stranded structures associated with the Aquifex 16S and 23S rRNA precursors, are cleaved in vitro at sites that are consistent with production of the immediate precursors to the mature rRNAs. Third, the role of the dsRBD in scissile bond selection was examined by a mutational analysis of the conserved interactions of RNA binding motif 1 (RBM1) with the substrate proximal box (pb). The individual contributions towards substrate recognition were determined for conserved amino acid side chains in the RBM1. It also was shown that the dsRBD plays key dual roles in both binding energy and selectivity, through RBM1 responsiveness to proximal box bp sequence. The dsRBD is specifically responsive to an antideterminant (AD) bp in pb position 2. The relative structural rigidity of both dsRNA and dsRBD rationalizes the strong effect of an inhibitory bp at pb position 2: disruption of one RBM1 side chain interaction can effectively disrupt the other RBM1 side chain interactions. Finally, a cis-acting model was developed for subunit involvement in substrate recognition by RNase III. Structurally asymmetric mutant heterodimers of Escherichia coli (Ec)-RNase III were constructed, and asymmetric substrates were employed to reveal how RNase III can bind and deliver hairpin substrates to the active site cleft in a pathway that requires specific binding configurations of both enzyme and substrate. / Chemistry Biochemistry Aquifex Aeolicus Dsrna-binding Domain Nuclease Domain Proximal Box Ribonuclease Iii Rna Binding Motif
8	Studies on HIV-1 nucleocapsid chaperone role in protein/nucleic acid interactions by single molecule spectroscopy approaches Ma, Xiaojing, 1982- 20 August 2010 (has links) HIV-NC is a multifunctional protein which plays an important role in almost every step of the retroviral life cycle. NC is essential in catalyzing stand transfers of HIV-1 reverse transcription, including the annealing of the transactivation response element (TAR) of the viral genome to the complementary TAR DNA in minus-strong-stop DNA. In this dissertation, the research starts with focus on elucidating the reaction mechanism of NC-facilitated TAR DNA/RNA annealing using single molecule spectroscopy (SMS) approaches. The results indicate that nucleation of TAR DNA/RNA annealing occurs in an encounter complex form in which one or two DNA/RNA strands in the partially open “Y” form associated with multiple NC molecules. This encounter complex leads to annealing through the 3’/5’ termini, namely “zipper” pathway and the annealing through the hairpin loop region, namely “kissing” pathway. By employing target oligonucleotides for specific TAR regions, we directly probed kinetic reversibility and the chaperone role of NC. Concentration-dependence of NC chaperoned melting and annealing of TAR hairpins was investigated and the results further support the proposed reaction mechanism. Additionally, we used a single-stranded DNA (ssDNA) as model to study ssDNA conformational change upon NC binding. Here we present observation of NC binding to d(TG)n and d(T)n, including NC effect on flexibility and conformation of these oligonucleotides chains. Our results reveal that the rigidity of ssDNA chain is dramatically reduced through interaction with NC. Meanwhile the results of NC dissociation experiments indicate the interaction of NC/ssDNA is complex and heterogeneous. Finally, we used SMS in vitro to systematically compare and contrast the RNA/protein interactions for the zinc-finger-binding-motif protein (NC) and the arginine-rich-binding-motif (ARM) protein (Tat) encoded by HIV-1. Tat and NC use different RNA binding motifs to recognize and interact with RNA hairpin, giving rise to very different changes in the RNA secondary structure upon protein binding. Competition experiments show that the presence of Tat can effectively inhibit the NC binding-induced local melting of TAR RNA hairpins. These results indicate that Tat specifically binds and stabilizes the TAR RNA hairpin structure, which likely inhibits the local melting of the hairpin induced by NC. / text HIV-1 nucleocapsid Protein Nucleic acid chaperone Single molecule spectroscopy Arginine rich binding motif
9	Statistical models of TF/DNA interaction Fouquier d'Herouel, Aymeric January 2008 (has links) <p>Gene expression is regulated in response to metabolic necessities and environmental changes throughout the life of a cell.</p><p>A major part of this regulation is governed at the level of transcription, deciding whether messengers to specific genes are produced or not.</p><p>This decision is triggered by the action of transcription factors, proteins which interact with specific sites on DNA and thus influence the rate of transcription of proximal genes.</p><p>Mapping the organisation of these transcription factor binding sites sheds light on potential causal relations between genes and is the key to establishing networks of genetic interactions, which determine how the cell adapts to external changes.</p><p>In this work I review briefly the basics of genetics and summarise popular approaches to describe transcription factor binding sites, from the most straight forward to finally discuss a biophysically motivated representation based on the estimation of free energies of molecular interactions.</p><p>Two articles on transcription factors are contained in this thesis, one published (Aurell, Fouquier d'Hérouël, Malmnäs and Vergassola, 2007) and one submitted (Fouquier d'Hérouël, 2008).</p><p>Both rely strongly on the representation of binding sites by matrices accounting for the affinity of the proteins to specific nucleotides at the different positions of the binding sites.</p><p>The importance of non-specific binding of transcription factors to DNA is briefly addressed in the text and extensively discussed in the first appended article:</p><p>In a study on the affinity of yeast transcription factors for their binding sites, we conclude that measured in vivo protein concentrations are marginally sufficient to guarantee the occupation of functional sites, as opposed to unspecific emplacements on the genomic sequence.</p><p>A common task being the inference of binding site motifs, the most common statistical method is reviewed in detail, upon which I constructed an alternative biophysically motivated approach, exemplified in the second appended article.</p> gene expression regulation transcription factor binding motif matrix representations gibbs sampling binding affinity non-specific binding Biological physics Biologisk fysik
10	The MHC-glycopeptide-T cell interaction in collagen induced arthritis : a study using glycopeptides, isosteres and statistical molecular design in a mouse model for rheumatoid arthritis Holm, Lotta January 2006 (has links) <p>Rheumatoid arthritis (RA) is an autoimmune disease affecting approximately 1% of the population in the western world. It is characterised by a tissue specific attack of cartilage in peripheral joints. Collagen induced arthritis (CIA) is one of the most commonly used animal models for (RA), with similar symptoms and histopathology. CIA is induced by immunisation of mice with type II collagen (CII), and the immunodominant part was previously found to be located between residues 256-270. This thesis describes the interaction between the MHC molecule, glycopeptide antigens from CII and the T cells that is essential in development of CIA. The glycopeptide properties for binding to the mouse MHC molecule Aq have been studied, as well as interaction points in the glycopeptide that are critical for stimulation of a T-cell response.</p><p>The thesis is based on five studies. In the first paper the minimal glycopeptide core, that is required for binding to the Aq molecule while still giving a full T cell response was determined. The second paper studied the roles of amino acid side-chains and a backbone amide bond as T-cell contact points. In the third paper the hydrogen bond donor-acceptor characteristics of the 4-OH galactose hydroxyl group of the glycopeptide was studied in detail. In the fourth paper we established a structure activity relationship (QSAR model) for (glyco)peptide binding to the Aq molecule. Finally, the stereochemical requirements for glycopeptide binding to the Aq molecule and for T-cell recognition was studied in the fifth paper.</p><p>The study was performed using collagen glycopeptide analogues, which were synthesised on solid phase. Amide bond and hydroxyl group isosteres were introduced for study of hydrogen bond donor-acceptor characteristics. Statistical methods were used to design a representative peptide test set and in establishing a QSAR model.</p><p>The results give a deeper understanding of the interactions involved in the ternary MHC-glycopeptide-T cell complex. This information contributes to research directed towards finding new treatments for RA.</p> Rheumatoid arthritis collagen T-cell class II MHC solid phase peptide synthesis glycopeptide peptide isostere PCA statistical molecular design PLS QSAR sequence binding motif Organic chemistry Organisk kemi

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