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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Estudos termodinâmicos e estruturais da interação cabeça-cauda da , alpha-tropomiosina muscular / Thermodynamic and structural studies of the head-to-tail complex of the muscular alpha-Tropomyosin

Fernando Corrêa 20 June 2008 (has links)
Tropomiosina (Tm) é uma das proteínas que compõe o filamento fino (actina, Tm, Troponina) do sistema muscular esquelético e desempenha um importante papel na regulação da contração muscular. Tm é um coiled-coil de 284 resíduos que forma longos homopolímeros lineares através da sobreposição de onze resíduos entre os terminais de Tms adjacentes (Interação cabeça-cauda) em condições de baixa força iônica. A presença de vários resíduos carregados (D2, K5, K6, K7, D275, H276 e D280) nas extremidades da Tm sugere que contatos intermoleculares eletrostáticos entre estes aminoácidos podem ter um importante papel na estabilidade dos polímeros. Entretanto, a estrutura do complexo cabeça-cauda demonstra que a maioria dos contatos intermoleculares na interface é de natureza hidrofóbica. A fim de analisarmos a contribuição dos grupos carregados para a estabilidade do complexo cabeça-cauda, construímos fragmentos recombinantes correspondentes à metade amino (ASTm1-142 ) e carboxi (Tm143-284(5OHW269)) terminais da proteína contendo mutações pontuais daqueles resíduos para alanina, e adicionalmente H276 para Glu. Medimos a afinidade entre todas as possíveis combinações destes fragmentos na ausência e presença de íons Mg2+, visto que este cátion está sempre presente em condições fisiológicas e é importante para estabilizar a interação entre Tm e actina. Os efeitos das mutações foram analisados por simulações de docking, desnaturações térmicas e ciclos de duplos mutantes. Os resultados demonstram que os aminoácidos K5, K7 e D280 presentes na interface formam contatos intermoleculares essenciais para a estabilidade do complexo. Enquanto, D2, K6, D275 e H276 não participam na formação de contatos intermoleculares, no entanto, contribuem para a estabilidade da interação cabeça- cauda através de suas interações intramoleculares que atuam na estabilidade das hélices individuais. Os aumentos na estabilidade da metade C-terminal da Tm (Tm143-284(5OHW)) induzidos por Mg2+ foram dependentes das mutações neste trecho da proteína sugerindo a presença de um sítio de ligação para este íon na extremidade carboxi terminal da molécula no trecho que forma a interação cabeça- cauda. Construímos um fragmento menor do C-terminal (Tm259-284(W269)) para acompanharmos mudanças no deslocamento químico induzidas pela ligação do íon usando ressonância magnética nuclear. Os resultados obtidos comprovaram nossa hipótese e nos permitiram definir pela primeira vez que a estrutura da Tm tem um ou mais sítios de ligação Mg2+ em uma região próxima ao resíduo H276 que está localizado entre vários resíduos carregados negativamente que participam da interação cabeça-cauda. Por último, estudamos os efeitos de solventes cosmótropicos (TFE e glicerol) nas estabilidades dos fragmentos da Tm, uma vez que a instabilidade (flexibilidade) da extremidade C-terminal é importante para a formação do complexo cabeça-cauda. Observamos que TFE, porém não glicerol, reduziu a afinidade entre os terminais. Ambos os co-solventes induziram aumentos na estabilidade dos fragmentos, no entanto, apenas TFE induziu um aumento no conteúdo de α-hélice e causou uma redução significativa na cooperatividade de desenovelamento das proteínas. Estes resultados indicam que estes compostos orgânicos estabilizam as estruturas dos fragmentos individuais da Tm de maneiras diferentes e que estas diferenças podem estar relacionadas aos diferentes efeitos observados na formação da interação cabeça-cauda. / Tropomyosin (Tm) is a protein component of the skeletal muscle thin filament (actin, Tm, Troponin) which has an important role in the regulation of muscle contraction. Tm is a dimeric coiled-coil (284 aminoacids) which forms long linear homopolymers through the overlap of eleven residues of adjacent Tm termini (Head- to-tail interaction) in low ionic strength conditions. The presence of several charged amino acids (D2, K5, K6, K7, D275, H276 e D280) in Tm extremities suggests that electrostatic contacts among those residues may have an important role in the stability of the polymers. Nevertheless, the solution structure of the head-to-tail complex demonstrated that most of the contacts in the interface are hydrophobic. In order to study the contribution of these charged residues to the stability of the head- to-tail complex, we built recombinant fragments corresponding to the amino (ASTm1-142) and carboxy (Tm143-284(5OHW269)) termini containing single mutations of those amino acids to alanine, and additionally a substitution of H276 for Glu. We measured the binding affinities among all possible combinations of wild-type and mutant fragments in the absence or presence of Mg2+ ions. This cation is always physiologically present in the muscle and it is known to strengthen the binding of Tm to actin. The effects of the mutations were analyzed by protein-protein docking, thermodynamic cycles and thermal denaturations. The results show that residues K5, K7 and D280 are essential to the stability of the complex. Though D2, K6, D275 and H276 are exposed to the solvent and do not participate in intermolecular contacts in the NMR structure, they may contribute to the complex stability by modulating the stability of the helices at the Tm termini. Mg2+-induced increases in stability of the C- terminal were sensitive to mutations in residues located in the head-to-tail overlap region, suggesting that Mg2+ ions may bind specifically to the carboxy extremity of the protein. We produced a small peptide (Tm259-284(W269)) to follow amide chemical shift perturbations upon Mg2+ binding by nuclear magnetic resonance measurements. The results obtained with this peptide allowed us to define for the first time that the Tm structure has one or more Mg2+ binding sites in a region centered in the vicinity of H276 in which are located several negatively charged residues that participate in the head-to-tail interaction. We also studied the effects of kosmotropic co-solvents (TFE and glycerol) in the stability of Tm fragments, as the instability (flexibility) of the C- terminal region has been pointed as important for the formation of the head-to-tail complex. We observed that TFE, but not glycerol, reduces the affinity between the termini. Both TFE and glycerol increased the stability of the isolated N- and C- terminal fragments; however, only TFE caused an increase in the helical content and a significant reduction in the cooperativity of unfolding of the proteins. Our results show that these two co-solvents stabilize the structures of individual Tm fragments in different manners and that these differences may be related to their different effects on head-to-tail complex formation.
2

Estudos termodinâmicos e estruturais da interação cabeça-cauda da , alpha-tropomiosina muscular / Thermodynamic and structural studies of the head-to-tail complex of the muscular alpha-Tropomyosin

Corrêa, Fernando 20 June 2008 (has links)
Tropomiosina (Tm) é uma das proteínas que compõe o filamento fino (actina, Tm, Troponina) do sistema muscular esquelético e desempenha um importante papel na regulação da contração muscular. Tm é um coiled-coil de 284 resíduos que forma longos homopolímeros lineares através da sobreposição de onze resíduos entre os terminais de Tms adjacentes (Interação cabeça-cauda) em condições de baixa força iônica. A presença de vários resíduos carregados (D2, K5, K6, K7, D275, H276 e D280) nas extremidades da Tm sugere que contatos intermoleculares eletrostáticos entre estes aminoácidos podem ter um importante papel na estabilidade dos polímeros. Entretanto, a estrutura do complexo cabeça-cauda demonstra que a maioria dos contatos intermoleculares na interface é de natureza hidrofóbica. A fim de analisarmos a contribuição dos grupos carregados para a estabilidade do complexo cabeça-cauda, construímos fragmentos recombinantes correspondentes à metade amino (ASTm1-142 ) e carboxi (Tm143-284(5OHW269)) terminais da proteína contendo mutações pontuais daqueles resíduos para alanina, e adicionalmente H276 para Glu. Medimos a afinidade entre todas as possíveis combinações destes fragmentos na ausência e presença de íons Mg2+, visto que este cátion está sempre presente em condições fisiológicas e é importante para estabilizar a interação entre Tm e actina. Os efeitos das mutações foram analisados por simulações de docking, desnaturações térmicas e ciclos de duplos mutantes. Os resultados demonstram que os aminoácidos K5, K7 e D280 presentes na interface formam contatos intermoleculares essenciais para a estabilidade do complexo. Enquanto, D2, K6, D275 e H276 não participam na formação de contatos intermoleculares, no entanto, contribuem para a estabilidade da interação cabeça- cauda através de suas interações intramoleculares que atuam na estabilidade das hélices individuais. Os aumentos na estabilidade da metade C-terminal da Tm (Tm143-284(5OHW)) induzidos por Mg2+ foram dependentes das mutações neste trecho da proteína sugerindo a presença de um sítio de ligação para este íon na extremidade carboxi terminal da molécula no trecho que forma a interação cabeça- cauda. Construímos um fragmento menor do C-terminal (Tm259-284(W269)) para acompanharmos mudanças no deslocamento químico induzidas pela ligação do íon usando ressonância magnética nuclear. Os resultados obtidos comprovaram nossa hipótese e nos permitiram definir pela primeira vez que a estrutura da Tm tem um ou mais sítios de ligação Mg2+ em uma região próxima ao resíduo H276 que está localizado entre vários resíduos carregados negativamente que participam da interação cabeça-cauda. Por último, estudamos os efeitos de solventes cosmótropicos (TFE e glicerol) nas estabilidades dos fragmentos da Tm, uma vez que a instabilidade (flexibilidade) da extremidade C-terminal é importante para a formação do complexo cabeça-cauda. Observamos que TFE, porém não glicerol, reduziu a afinidade entre os terminais. Ambos os co-solventes induziram aumentos na estabilidade dos fragmentos, no entanto, apenas TFE induziu um aumento no conteúdo de α-hélice e causou uma redução significativa na cooperatividade de desenovelamento das proteínas. Estes resultados indicam que estes compostos orgânicos estabilizam as estruturas dos fragmentos individuais da Tm de maneiras diferentes e que estas diferenças podem estar relacionadas aos diferentes efeitos observados na formação da interação cabeça-cauda. / Tropomyosin (Tm) is a protein component of the skeletal muscle thin filament (actin, Tm, Troponin) which has an important role in the regulation of muscle contraction. Tm is a dimeric coiled-coil (284 aminoacids) which forms long linear homopolymers through the overlap of eleven residues of adjacent Tm termini (Head- to-tail interaction) in low ionic strength conditions. The presence of several charged amino acids (D2, K5, K6, K7, D275, H276 e D280) in Tm extremities suggests that electrostatic contacts among those residues may have an important role in the stability of the polymers. Nevertheless, the solution structure of the head-to-tail complex demonstrated that most of the contacts in the interface are hydrophobic. In order to study the contribution of these charged residues to the stability of the head- to-tail complex, we built recombinant fragments corresponding to the amino (ASTm1-142) and carboxy (Tm143-284(5OHW269)) termini containing single mutations of those amino acids to alanine, and additionally a substitution of H276 for Glu. We measured the binding affinities among all possible combinations of wild-type and mutant fragments in the absence or presence of Mg2+ ions. This cation is always physiologically present in the muscle and it is known to strengthen the binding of Tm to actin. The effects of the mutations were analyzed by protein-protein docking, thermodynamic cycles and thermal denaturations. The results show that residues K5, K7 and D280 are essential to the stability of the complex. Though D2, K6, D275 and H276 are exposed to the solvent and do not participate in intermolecular contacts in the NMR structure, they may contribute to the complex stability by modulating the stability of the helices at the Tm termini. Mg2+-induced increases in stability of the C- terminal were sensitive to mutations in residues located in the head-to-tail overlap region, suggesting that Mg2+ ions may bind specifically to the carboxy extremity of the protein. We produced a small peptide (Tm259-284(W269)) to follow amide chemical shift perturbations upon Mg2+ binding by nuclear magnetic resonance measurements. The results obtained with this peptide allowed us to define for the first time that the Tm structure has one or more Mg2+ binding sites in a region centered in the vicinity of H276 in which are located several negatively charged residues that participate in the head-to-tail interaction. We also studied the effects of kosmotropic co-solvents (TFE and glycerol) in the stability of Tm fragments, as the instability (flexibility) of the C- terminal region has been pointed as important for the formation of the head-to-tail complex. We observed that TFE, but not glycerol, reduces the affinity between the termini. Both TFE and glycerol increased the stability of the isolated N- and C- terminal fragments; however, only TFE caused an increase in the helical content and a significant reduction in the cooperativity of unfolding of the proteins. Our results show that these two co-solvents stabilize the structures of individual Tm fragments in different manners and that these differences may be related to their different effects on head-to-tail complex formation.
3

Biochemical and Bioinformatics Analysis of CVAB C-Terminal Domain

Guo, Xiangxue 12 January 2006 (has links)
Cytoplasmic membrane proteins CvaB and CvaA and the outer membrane protein TolC form the bacteriocin colicin V (ColV) secretion system in Escherichia coli. CvaB functions as an ATP-binding cassette transporter with nucleotide-binding motifs in the C-terminal domain (CTD). To study the role of CvaB-CTD in the ColV secretion, a truncated construct of this domain was made and over-expressed. Different forms of CvaB-CTD were obtained during purification, and were identified as monomer, dimer, and oligomer on gel filtration. Nucleotide binding was shown critical for the CvaB-CTD dimerization: oligomers could be converted into dimers by nucleotide bindings; the removal of nucleotide from dimers resulted in transient monomers followed by CTD oligomerization and aggregation; no dimer form could be cross-linked from the nucleotide-binding deficient mutant D654H. The spatial proximity of the Walker A site and ABC signature motif in CTD dimer was identified through disulfide cross-linking of mixed CvaB-CTD with mutants A530C and L630C, while mutations did not dimerize individually. Those results indicated that the CvaB-CTD formed a nucleotide-dependent head-to-tail dimer. Molecular basis of differential nucleotide bindings was also studied through bioinformatics prediction and biochemical verification. Through sequence alignment and homology modeling with bound ATP or GTP, it was found that the Ser503 and Gln504 on aromatic stacking region (Y501DSQ-loop) of CvaB-CTD provided two additional hydrogen-bonds to GTP, but not to ATP. Site-directed mutations of the S503A and/or Q504L were designed based on the model. While site-directed mutagenesis studies of Walker A&B sites or the ABC signature motif affected little on the GTP-binding preference, the double mutation (S503A/Q504L) on the Y501DSQ-loop increased both ATP-binding and ATPase activity at low temperatures. The double mutant showed slight decrease of GTP-binding and about 10-fold increase of the ATP/GTP-binding ratio. Similar temperature sensitivity in nucleotide-binding and activity assays were identified in the double mutant at the same time. Mutations on the Y501DSQ-loop did not affect the ColV secretion level in vivo. Together, the Y501DSQ-loop is structurally involved in the differential binding of GTP over ATP.
4

Organogels et aérogels obtenus à partir de phénylalanine : étude de l'organisation supramoléculaire et élaboration d'un nouveau type de super-isolant thermique / Organogels and aerogels obtained from phenylalanine : Study of the supermolecular organization and elaboration of a new kind of super heat insulator

Son, Sébastien 23 January 2015 (has links)
Depuis 1973, l’un des objectifs principaux de la France est la diminution de la consommation des énergies de chauffage des bâtiments du résidentiel et du tertiaire qui représentent plus de 40% de la consommation énergétique totale du pays. Le développement des isolants thermiques a été par conséquent un sujet de recherche qui a abouti à de nouveaux matériaux : les super-isolants thermiques de conductivité thermique inférieure à 25 mW.m-1.K-1. Les aérogels organiques de faible densité de Z-Phe-NH-Napht étudiés au LCPM présentent une structure fibrillaire qui leur confère des propriétés thermiques intéressantes malgré une résistance mécanique faible. Une étude fondamentale de l’organisation supramoléculaire nous a permis d’une part de démontrer l’existence de deux modes d’empilement des molécules organogélatrices : tête-à-tête (monocristaux) et tête-à-queue (gels), caractérisées par une signature infrarouge propre à des pseudo-cycles respectivement en C12 et C10/C14. D’autre part, nous avons étudié le mécanisme de formation séquentiel de ces gels et abouti à un modèle complet d’organisation de la molécule isolée à la fibre basé sur une symétrie hexagonale. En vue d’une commercialisation d’un isolant à base d’aérogel organique, nous avons tout d’abord optimisé le protocole d’obtention des aérogels pour ensuite travailler à l’amélioration des propriétés thermiques et mécaniques. Nous sommes parvenus à un nouvel isolant hydrophobe présentant une conductivité thermique de l’ordre de celles des super-isolants et de bonnes propriétés mécaniques compatibles avec les pré-requis industriels pour une application dans le bâtiment / Since 1973, France's main objective in this domain has been to reduce the consumption of energy in heating residential and industrial buildings, which represents more than 40% of the national consumption. Consequently, the development of heat insulators has been the subject of research which has resulted in new materials: super thermal insulators with a thermal conductivity of less than 25 mW.m-1.K-1. Organic aerogels with a low density of Z-Phe-NH-Napht have been studied at LCPM for the past 10 years. Despite their very weak mechanical resistance they present a fibrillar structure which gives them very interesting thermal properties. A fundamental study of the supermolecular self-assembly allowed us to demonstrate the existence of two stacking methods of gelling molecules: head-to-head (monocrystals) and head-to-tail (gels) which are characterized by a specific infrared signature to the pseudo-cycles respectively on C12 and C10/C14. In addition, we also studied the sequential formation mechanism of these gels which resulted in a full model of their molecular organization from the single molecule to the fiber and based on a hexagonal packing symmetry. In aim of commercializing an insulator made from organic aerogels, we firstly optimized the protocol for obtaining aerogels to then work on improving their thermal and mechanical properties. We created a new hydrophobic insulator which has both a thermal conductivity in the range of the super heat insulators' and good mechanical properties that are compatible with industrial prerequisites for the construction of buildings

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