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Röntgenkristallographische Untersuchungen an der Tricorn-Protease aus Thermoplasma acidophilum und an der funktionell homologen Trilobed-Protease aus Pyrococcus furiosusBosch, Jürgen. Unknown Date (has links) (PDF)
Techn. Universiẗat, Diss., 2003--München.
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Protein-Protein-Wechselwirkungen der Untereinheiten der RNA-Polymerase von Pyrococcus furiosusGoede, Bernd. Unknown Date (has links) (PDF)
Universiẗat, Diss., 2004--Kiel.
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Etude des grands assemblages protéolytiques de la famille TET : processus d'oligomérisation et régulation fonctionnelle associée / Study of large proteolytic assembly of the TET family : oligomerization process and associated functional regulationAppolaire, Alexandre 15 December 2014 (has links)
La protéolyse est une fonction clé de la cellule pour le maintien de l'intégrité du protéome, pour le métabolisme et pour la régulation de nombreux processus physiologiques. Le travail présenté dans cette thèse porte sur une famille de complexes peptidases cytosoliques auto-compartimentés et énergie indépendants découverts chez les Archées, les aminopeptidases TET. Chez l'Archée hyperthermophile Pyrococcus horikoshii, organisme modèle de cette étude, il existe 3 peptidases TET présentant chacune des spécificités de substrats différentes. Les caractérisations structurales des différents membres connus de cette famille de peptidases ont révélé un assemblage dodécamériques creux en forme de tétraèdre d'environ 450 kDa. Des études récentes ont montré l'existence de complexes adoptant la même conformation que les TET dans les 3 domaines du vivant. La première partie du travail présenté a permis d'identifier des marqueurs structuraux caractéristiques de l'assemblage tétraédrique afin de déterminer sans ambiguïté l'appartenance de ces complexes à la famille des TET. La seconde partie de l'étude a conduit à élucider la question de la multiplicité des TET chez les Archées hyperthermophile mise en évidence grâce à une étude phylogénétique initiée pendant la thèse. L'étude en co-expression de PhTET2 et PhTET3 révèle que ces aminopeptidases sont capable de former un hétéro-oligomère présentant une activité enzymatique accrue vis-à-vis des homo-oligomères. La dernière partie du travail porte sur les relations oligomérisation-fonction chez les peptidases TET. L'étude d'un mutant de l'oligomérisation de PhTET2 via une stratégie intégrative alliant biochimie, enzymologie, biophysique (SAXS et AUC) et des études in vivo a permis de mettre en évidence un processus d'assemblage contrôlé permettant d'augmenter l'efficacité de la peptidase. Enfin, la méthode de variation de contraste en diffusion de neutrons aux petits angles (SANS) appliqué à l'étude de l'hétéro-oligomère a permis de révéler une topologie rationalise du complexe hétéro-oligomérique favorisant la formations de poches multi-catalytique. L'ensemble de ce travail contribue à mieux comprendre l'importance et le rôle physiologique des machines TETs dans les cellules. / Proteolysis is a key function in the cell for the maintenance of the proteome integrity, the metabolism and for the regulation of many physiological processes. The thesis work is focused on a family of self-compartmentalized energy-independent cytosolic peptidases discovered in Archaea, the TET aminopeptidases. Three different TET showing contrasted enzymatic specificities co-exist in the cytosol of the hyperthermophilic archaeon Pyrococcus horikoshii, which is the model organism for this study. The structural characterization of the known members of this family shows that they self-assemble in a unique 450 kDa hollow tetrahedral structure . Recent studies have revealed the existence of peptidases complexes that adopt the same conformation in the three domains of life. The first part of this work allowed identifying structural markers to assign without any ambiguity uncharacterized peptidases to the TET family. The second objective of the work was to understand the multiplicity of TET peptidases in hyperthermophilic archaeon that was highlighted by a phylogenomic study presented in this work . The co-expression of PhTET2 and PhTET3 in E. coli revealed that the two proteins form a hetero-oligomeric complex with enhanced enzymatic activity compared to the homo-oligomers. The last part of the work addressed the question of oligomerization-function relationship in TET particles. A mutagenesis strategy was used to slow down the oligomerization process of PhTET2, and, using an integrative strategy combining biochemistry, enzymology, biophysics (SAXS and AUC) and in vivo studies we were able to dissect the oligomerization pathway of the TET particles and to demonstrate that it is a highly controlled process aim to enhance the activity of the peptidases. Finally, the contrast variation technique in small angle neutron scattering studies (SANS) allowed us to unravel the rational topology of the TET hetero-oligomers that favored the formation of multi-catalytic enzymatic pockets in the complex. All theses studies contributed to specify the biological importance of the TET molecular machines in the cells.
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Characterization of two Protein Disulfide Oxidoreductases from Thermophilic Organisms Pyrococcus furiosus and Aquifex aeolicus : Characterization of two Protein Disulfide OxidoreductasesFürtenbach, Karin January 2008 (has links)
<p>Members of the thioredoxin superfamily of proteins catalyze disulfide bond reduction and oxidation using the active site C-X-X-C sequence. In hyperthermophilic organisms, cysteine side chains were expected in low abundance since they were not believed to endure the high temperatures under which they grow. Recently it has been found that disulfide bonds in hyperthermophiles are more frequent, the higher the growth temperature of the organism. This is perhaps used as an adaptation to high temperature in order to stabilize proteins under harsh conditions. A protein with sequence and structural similarities to mesophilic members of the thioredoxin superfamily, called protein disulfide oxidoreductases (PDO), has been found in the genomes of recently sequenced hyperthermophilic genomes. In this study PDOs from the hyperthermophiles Aquifex aeolicus (AaPDO) and Pyrococcus furiosus (PfPDO) have been investigated. The molecular weight is about 26 kDa and their structures are comprised of two homologous thioredoxin folds, referred to as the N-unit and the C-unit, each containing a C-X-X-C motif. The sequence identity between the two units and the two proteins is low, but they are still structurally very similar. The function of these proteins in vivo is unknown. As a first step in characterizing the activity of these proteins, the redox characteristics of these domains will be investigated. During this project, the genes for AaPDO and PfPDO have been cloned into overexpression vectors, expressed in E. coli and purified to homogeneity. To allow for individual study of the activities of two units, mutated proteins were prepared in which the cysteine residues of the N-unit (AaPDOnm and PfPDOnm) and of the C-unit (AaPDOcm and PfPDOcm) and purified. Circular dichroism spectra recorded of the wild type and mutants indicate that all purified proteins are folded and that the N- and C-unit active site mutants are structurally similar to the corresponding wild type proteins.</p>
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Characterization of two Protein Disulfide Oxidoreductases from Thermophilic Organisms Pyrococcus furiosus and Aquifex aeolicus : Characterization of two Protein Disulfide OxidoreductasesFürtenbach, Karin January 2008 (has links)
Members of the thioredoxin superfamily of proteins catalyze disulfide bond reduction and oxidation using the active site C-X-X-C sequence. In hyperthermophilic organisms, cysteine side chains were expected in low abundance since they were not believed to endure the high temperatures under which they grow. Recently it has been found that disulfide bonds in hyperthermophiles are more frequent, the higher the growth temperature of the organism. This is perhaps used as an adaptation to high temperature in order to stabilize proteins under harsh conditions. A protein with sequence and structural similarities to mesophilic members of the thioredoxin superfamily, called protein disulfide oxidoreductases (PDO), has been found in the genomes of recently sequenced hyperthermophilic genomes. In this study PDOs from the hyperthermophiles Aquifex aeolicus (AaPDO) and Pyrococcus furiosus (PfPDO) have been investigated. The molecular weight is about 26 kDa and their structures are comprised of two homologous thioredoxin folds, referred to as the N-unit and the C-unit, each containing a C-X-X-C motif. The sequence identity between the two units and the two proteins is low, but they are still structurally very similar. The function of these proteins in vivo is unknown. As a first step in characterizing the activity of these proteins, the redox characteristics of these domains will be investigated. During this project, the genes for AaPDO and PfPDO have been cloned into overexpression vectors, expressed in E. coli and purified to homogeneity. To allow for individual study of the activities of two units, mutated proteins were prepared in which the cysteine residues of the N-unit (AaPDOnm and PfPDOnm) and of the C-unit (AaPDOcm and PfPDOcm) and purified. Circular dichroism spectra recorded of the wild type and mutants indicate that all purified proteins are folded and that the N- and C-unit active site mutants are structurally similar to the corresponding wild type proteins.
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Recombinant Pyrococcus Furiosus ExtracellularBoy, Erdem 01 December 2011 (has links) (PDF)
Pyrococcus furiosus extracellular &alpha / -amylase is a hyperthermostable glucosyl hydrolyzing enzyme which shows unique biochemical properties that may have impact on improving starch hydrolysis process / however, it is insignificantly expressed in its native archaeal host. In this study, it was aimed to express the P. furiosus extracellular alpha-amylase (PFA) in Pichia pastoris, which is a well-recognized overexpression host used in production of heterologous proteins. In this context, first, P. furiosus was grown under anaerobic conditions in capped bottles for t= 12 h at T=90° / C and then its genomic DNA was isolated. PFA coding cDNA frame was amplified using two specifically designed oligonucleotides and cloned into pPICZ&alpha / A expression vector. Then wild type P. pastoris X-33 cells were transfected with pPICZ&alpha / A::PFA construct. In shake flask production medium, existence of recombinant PFA activity was tested and biochemical characterization of the recombinant product was done. This was the first time PFA is expressed in an eukaryotic host. Optimum working temperature and pH of the rPFA were found to be 95 ° / C and within the range of 4.5-6.5, respectively. rPFA is independent to metal ions and inhibition by production medium of P. pastoris was observed, in presence of divalent metal ions. Although Saccharomyces cerevisiae &alpha / -factor secretion signal was fused to the N terminal of rPFA, minute amount of extracellular secretion was detected but the majority of the enzymatic activity remained in the intracellular medium. The best producer strain was selected by measuring &alpha / -amylase activity in cell extracts by DNS method. Effects of pH on cell growth and recombinant protein production were determined by shake flask experiments and maximum of 4800 U/l rPFA was detected with 7.30 g/l wet cell density in pH=6 buffered medium. In order to achieve higher rPFA production, two bioreactor experiments were designed at two different pH operation conditions, namely pH=4 and pH=5, in a working volume of 1 L. The dissolved oxygen tension was kept over 20% and predetermined exponential methanol feeding strategy was employed in order to fix specific cell growth rate, µ / , at 0.03 h-1. At pH=4 operation, maximum of 73,400 U/l &alpha / -amylase activity was detected at the t=27 h of production phase when the wet cell density was 209 g/l.
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Analyses of the archaeal transcription cycle reveal a mosaic of eukaryotic RNA polymerase II and III-like featuresSpitalny, Patrizia January 2008 (has links)
Regensburg, Univ., Diss., 2008
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Analyse von hybriden eukaryotisch-archaeellen RNA-Polymerasen unter besonderer Berücksichtigung der Untereinheiten Rpb5, RpoH und Rpb12, RpoPReich, Christoph January 2009 (has links)
Regensburg, Univ., Diss., 2009.
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Etude de l'activité de l'enzyme de réparation NucS à l'échelle de la molécule uniqueRezgui, Rachid 11 June 2013 (has links) (PDF)
Les enzymes de réparation de l'ADN sont des facteurs essentiels pour assurer l'intégrité du génome. Ainsi, la compréhension de la dynamique de leurs mécanismes d'interaction est capitale. NucS est une nucléase récemment découverte chez l'archée Pyrococcus abyssi, qui interagit avec des structures branchées de l'ADN à simple brin libre, appelées flaps. Sa caractérisation biochimique a mis en évidence une affinité nanomolaire pour l'ADN simple brin, avec l'existence de deux sites de liaison (site I et II) ainsi qu'une activité bidirectionnelle caractérisée par la capacité à cliver les flaps 5' et 3'. Les mécanismes qui sont à l'origine de cette activité, notamment ses modalités de chargement, de localisation et de dissociation, restent toutefois peu connus. Afin de sonder la dynamique des interactions de NucS avec son substrat, nous avons mis en place un microscope à illumination en onde évanescente permettant la détection et le suivi des événements d'interaction individuels entre la protéine marquée avec un fluorophore et un substrat d'ADN attaché à la surface. Nous avons ensuite développé une nouvelle technique de colocalisation qui permet de positionner une protéine individuelle par rapport à son substrat avec une précision de 50 nm pour des durées arbitraires. Nous avons alors étudié la cinétique d'association et de dissociation des complexes NucS-ADN individuels afin de résoudre les mécanismes qui régulent l'activité de l'enzyme dans différentes conditions. Dans des conditions où le clivage est inhibé, nous avons montré que l'association était dépendante du site I, bidirectionnelle et symétrique pour les flaps 3' et 5' et que la dissociation était orientée avec une affinité supérieure pour les flap 5'. Nous avons également montré que la dissociation suivait une cinétique du premier ordre indépendante de la diffusion de NucS sur le flap. Ceci indique que, dans ces conditions non clivantes, NucS s'associe et/ou se dissocie à des positions arbitraires sur le flap. Par la suite, nous avons étudié la cinétique d'association et de dissociation du complexe NucS-ADN à 45 ◦ C en présence du cofacteur de la réparation PCNA. Nous avons démontré que PCNA augmente la vitesse d'association de NucS avec les substrats 3' et 5'. Ceci indique que PCNA agit comme une plateforme qui facilite la reconnaissance de la lésion, avec un chargement ciblé de NucS à la jonction. De plus, nous avons montré que PCNA déstabilise le complexe NucS-ADN, vraisemblablement en exerçant une force pour plier l'ADN afin d'amener l'extrémité du flap vers le site II. Dans le cas de flaps 5', nous avons montré que la dissociation suit un mécanisme en deux étapes, qui est indépendant de la longueur du flap. Ceci nous a permis de proposer un modèle où NucS se charge par son site I directement à la jonction, courbe le substrat pour capturer l'extrémité simple brin par le site II pour le cliver. Dans le cas d'un flap 3', nous avons montré que la dissociation suit un mécanisme du premier ordre ce qui est probablement dû à la rapidité de la seconde étape dans le mécanisme proposé pour les flaps 5'. Nos résultats constituent ainsi une nouvelle contribution à la caractérisation intramoléculaire des interactions NucS-ADN. Les méthodes que nous avons développées constituent en outre un moyen original pour sonder la cinétique des interactions entre biomolécules et pourront être appliquées à de multiples systèmes.
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The P. furiosus Mre11/Rad50 complex facilitates 5’ strand resection by the HerA helicase and NurA nuclease at a DNA double-strand breakHopkins, Ben Barrett 26 January 2011 (has links)
The Mre11/Rad50 complex has been implicated in the early steps of DNA double-strand break (DSB) repair through homologous recombination in several organisms. However, the enzymatic properties of this complex are incompatible with the generation of 3’ single-stranded DNA for recombinase loading and strand exchange. In thermophilic Archaea, the mre11 and rad50 genes cluster in an operon with genes encoding a bidirectional DNA helicase, HerA, and a 5’ to 3’ exonuclease, NurA, suggesting these four enzymes function in a common pathway. I show that purified Mre11 and Rad50 from Pyrococcus furiosus act cooperatively with HerA and NurA to resect the 5’ strand at a DNA end under physiological conditions in vitro where HerA and NurA alone do not show detectable activity. Furthermore, I demonstrate that HerA and NurA physically interact, and this interaction stimulates both helicase and nuclease activities. The products of HerA/NurA long-range resection are oligonucleotide products and HerA/NurA activity demonstrates both sequence specificity and a preference to cut at a specific distance from the DNA end. I demonstrate a novel activity of Mre11/Rad50 to make an endonucleolytic cut on the 5’ strand, which is consistent with a role for the Mre11 nuclease in the removal of 5’ protein conjugates. I also show that Mre11/Rad50 stimulates HerA/NurA-mediated resection through two different mechanisms. The first involves an initial Mre11 nucleolytic processing event of the DNA to generate a 3’ ssDNA overhang, which is then resected by HerA/NurA in the absence of Mre11/Rad50. The second mechanism likely involves local unwinding of the DNA end in a process dependent on Rad50 ATPase activity. I propose that this unwinding step facilitates binding of HerA/NurA to the DNA end and efficient resection of the break. Furthermore, the binding affinity of NurA for 3’ overhang and unwound DNA end substrates partially explains the efficiency of the two resection mechanisms. Lastly, 3’ single-stranded DNA generated by these enzymes can be used by the Archaeal RecA homolog RadA to catalyze strand exchange. This work elucidates how the conserved Mre11/Rad50 complex promotes DNA end resection in Archaea, and may serve as a model for DSB processing in eukaryotes. / text
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