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Charakterisierung eines ABC-Transporters für kompatible Solute in dem hyperthermophilen Archaeon Archaeoglobus fulgidus und Untersuchungen zur thermoprotektiven Wirkung kompatibler Solute in Bacillus subtilisHoltmann, Gudrun. January 1900 (has links) (PDF)
Marburg, Universiẗat, Diss., 2003. / Erscheinungsjahr an der Haupttitelstelle: 2002.
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Crystal structures of two nucleic acid-binding proteinsToro, Imre January 2000 (has links)
The Crystal Structure of Sl Nuclease from Aspergillus oryzae S 1 nuclease from Aspergillus oryzae is a glycoprotein of 32 kDa molecular weight. The protein has two enzymatic activities: it is an endo-exonuclease with high specificity for single stranded nucleic acids, and it has an additional 3' -nucleotidase activity. S 1 nuclease is widely used in molecular biology as a single-strand specific nuclease due to its high stability and efficiency. It cleaves single-stranded regions of nucleic acids producing 5' -nucleotides without significant side-reactions. The crystal structure of S 1 nuclease has been determined to 1.7 A resolution by molecular replacement based on the known structure of PI nuclease from Penicillinum citrinum, which has 49 % sequence identity compared to S 1. The overall fold and the active site of S 1 nuclease is basically identical to that of PI nuclease, and also very similar to Phospholipase C from Bacillus cereus and alpha-toxin from Clostridium perfringens. The characteristic feature of this family of enzymes is a trinuclear zinc cluster in their active sites. A BLAST search in the sequence databases revealed several other protein sequences from bacteria, protozoa and plants possessing an approximately 30 % sequence identity compared to S 1 nuclease, but showing an almost complete conservation of structurally and functionally important residues. Soaking and co-crystallisation experiments with substrate analogues have been carried out in order to obtain an enzyme-substrate complex. These efforts have not resulted in the structure determination of any complexes under crystallisation conditions: no binding of substrate has been observed. Nevertheless, an enzyme mechanism has been proposed based on structural data of S 1 nuclease and nucleases with similar active sites. The Crystal Structure of an Sm-Related Protein from Archaeoglobus fulgidus In eukaryotes Sm and Sm-like proteins are the core components of the small nuclear ribonucleoprotein particles (snRNPs), which are involved in a variety of functions including rRNA processing, tRNA maturation and pre-mRNA processing. The Sm proteins are 70 to 120 amino acids long and share a common bi-partite signature sequence. The spliceosome, where the transesterification reaction of splicing occurs, is assembled by several snRNPs named after their constituting snRNA: U1, U2, U4, U5 and U6. An snRNA contains a short single stranded, uridine rich sequence motif, where the Sm proteins bind, but the three-dimensional arrangement of the Sm proteins and the mode of binding is unknown. In humans there are seven different canonical Sm proteins, which according to biochemical and electron microscopic studies seem to form a seven membered ring in vitro. Recently two crystal structures of human Sm protein dimers have been published. Interestingly Sm-related protein sequences have been found in the available genomic database of various Archaebacteria based on sequence homology. In contrast with eukaryotes only one or two Sm-related protein sequences have been identified in one organism. Their function is currently unknown, since analogous pre-mRNA splicing does not occur in Archaebacteria. Two Sm-related proteins of Archaeoglobus fulgidus have been cloned and expressed as fusion proteins. One of them called AF-Sm2 has been o crystallised utilising ammonium sulphate as precipitant and solved to 1.95 A resolution by SIRAS using a single mercury derivative. AF-Sm2 crystallises in a hexagonal space group (P6) and contains one molecule per asymmetric unit. The 77 residue long protein has a very similar fold compared to the solved human Sm protein structures: a short N-terminal a-helix followed by a five stranded, strongly bent, U-shaped ~-sheet resulting in a barrel-like overall fold. Six AF-Sm2 molecules form a ring in the crystal structure mediated by extensive hydrophobic and hydrogen-bonding interactions. Gel filtration experiments have indicated a pH dependence of oligomerisation in accordance with the crystallisation experiences. Currently the target of the Sm-related proteins of Archaeoglobus fulgidus and the stochiometry of oligomerisation in vivo is completely unknown.
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Examination of Mutants that Alter Oxygen Sensitivity and CO<sub>2</sub>/O<sub>2</sub> Substrate Specificity of the Ribulose 1,5-Bisphosphate Carboxylase/Oxygenase (Rubisco) from <i>Archaeoglobus fulgidus</i>Kreel, Nathaniel Edward 18 March 2008 (has links)
No description available.
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Structural and functional study of hydrogenase maturation factor HypB from Archaeoglobus fulgidus. / CUHK electronic theses & dissertations collectionJanuary 2009 (has links)
Based on what we have found, we proposed a model for Ni presenting by HypB involved in hydrogenase maturation. HypB binds two Ni ions in the apo- and GDP-bound form. Ni binding also induces dimerization of HypB. Upon GTP binding, HypB can bind an extra Ni ion at the dimeric interface. GTP hydrolysis will release the extra Ni ion, which may be subsequently inserted into hydrogenases during the maturation process. / Furthermore, two Ni binding sites were determined in a monomeric HypB. One is the cluster including C92, H93 and C122, the other is composed of H97 and H101. Upon GTP-dependent dimerization, HypB can bind an extra Ni ion. Our results have shown that the C92/H93/C122 is involved in binding the extra Ni ion, and such binding requires both cysteine residues in the reduced form. Since the GTP-induced dimerization of HypB is coupled to bind an extra Ni, so HypB could act as a GTP-mediated switch that regulate one Ni release from the GTP-bound form to the GDP-bound form. / In the future, we will attempt to crystallize AfHypB in complex with GDP, GTP analogue and AfHypA. Availability of good quality crystals will pave way for the structure determination of AfHypA and AfHypA/HypB complex. And the results obtained will provide a better understanding of the mechanism of functional interaction between HypA and HypB and how HypA and HypB play a role in Ni ion delivery for hydrogenase maturation. / The assembly of the [NiFe]-hydrogenases requires incorporation of Ni ions into the enzyme's metallocenter, which process requires the GTPase activity of HypB and HypA. Due to the essential role in assembly of the active site of hydrogenases, the two proteins were defined as hydrogenase maturation factors. To better understand the mechanism of GTP hydrolysis-dependent Ni delivery accomplished by HypB and HypA, our work focuses on the structure-function study of AfHypB from Archaeoglobus fulgidus and the functional interaction between AfHypA and AfHypB. / The intrinsic GTPase activity of AfHypB is very low, suggesting that AfHypB requires a G-protein activating protein (GAP) to activate its GTPase activity. Although AfHypB can interact with AfHypA to form 1:1 heterodimer, our data suggests that AfHypA is not a GAP for AfHypB. In addition, the FRET results showed that AfHypA could serve as a GEF (G-protein exchange factor) to activate the AfHypB from GDP-bound form to GTP-bound form and facilitate the dissociation of AfHypB dimer in the presence of GMPPNP. / Up to now, we have solved the structure of apo-AfHypB by X-ray crystallography. Crystals of AfHypB were grown using the hanging-drop-vapor-diffusion method and diffracted to ∼2.3 A. It belonged to space group P2(1)2(1)2, with unit cell dimensions a=72.49, b=82.33, c=68.66 A, alpha=beta=gamma=90°. Two molecules of AfHypB were found in an asymmetric unit. Structural comparison between the apo-AfHypB and GTP-bound HypB from M jannachii showed that the GTP binding broke the salt-bridge between K43 and D66, and induced conformational changes in the switch I loop and helix-3, which caused the HypB to form dimer and bind an extra Ni ion. The GTP-bound form of HypB was ready for Ni presenting. And GTP hydrolysis could induce the conformational changes of HypB in the switch I loop and helix-3, which dissociate the HypB dimer into the monomeric GDP-bound form. / Li, Ting. / Adviser: K. B. Wong. / Source: Dissertation Abstracts International, Volume: 70-09, Section: B, page: . / Thesis (Ph.D.)--Chinese University of Hong Kong, 2009. / Includes bibliographical references (leaves 98-104). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Electronic reproduction. [Ann Arbor, MI] : ProQuest Information and Learning, [200-] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstracts in English and Chinese. / School code: 1307.
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Physiologie des procaryotes sulfato-réducteurs : dégradation d'hydrocarbures et oxydo-réduction d'éléments métalliques / Sulfate-reducing prokaryotes physiology : hydrocarbon degradation and oxydation-reduction of metal elementsAmin Ali, Oulfat 19 December 2013 (has links)
Les procaryotes sulfato-réducteurs (PSRs)jouent un rôle majeur dans les cycles biogéochimiques de la matière et interviennentnotamment dans la dégradation de la matière organique récalcitrante (e.g. hydrocarbures) mais également dans les processus d’oxydo-réduction de métaux et/ou métalloïdes.L’objet de ce travail a consisté à approfondir certain de ces aspects de la physiologie des PSRs. La dégradation d’hydrocarbures a été étudiée en mésophilie, avec la caractérisation d’une souche bactérienne issue d’un site pollué. Cette souche décrite comme une nouvelle espèce,Desulfatiferulaberrensis BE2801, est capable de dégrader les n-alcènes. La dégradation d’hydrocarbures a également été étudiée à très haute température chez une archée,Archaeoglobus fulgidus. Cette souche oxyde les n-alcanes, l’oxydation étant vraisemblablement catalysée par la protéine PflD.L’ensemble des travaux réalisés montre que PflDserait une alkylsuccinate synthase qui permettrait l’activation de l’hydrocarbure par addition au fumarate. Outre ses capacités hydrocarbonoclastes à haute température, A. fulgidusest également capable de corroder le fer, de manière indirecte par la production de sulfures, et directement, en oxydant le fer de manière originale avec la formation de « micro-cheminées ». Outre l’oxydation de matière organique et de métaux, les PSRs sont également capables de réduire un grand nombre d’éléments, notamment les métaux et métalloïdes. C’est le cas de Desulfotomaculum hydrothermale, connue pour réduire à haute température l’arsenic, métalloïde hautement toxique. L’analyse de la séquence du génome de cette souche a confirmé ses capacités de détoxication. / Sulfate-reducing prokaryotes (SRPs) play a significant role in the biogeochemical cycles of matter, in particular in the degradation of recalcitrant organic compounds (e.g. hydrocarbons) but also in oxido-reduction of metals and/or metalloids. The aim of this work was to deepen some of these aspects of SRPs physiology. Hydrocarbon degradation was studied with a mesophilic bacterial strain isolated from a polluted site.This strain, described as a new species, Desulfatiferula berrensis BE2801, is able to degrade n-alkenes. Degradation of hydrocarbons has also been studied at high temperatures with an archaeon, Archaeoglobus fulgidus. This archaeon oxidize n-alkanes with most likely involvement of the PflD protein. All our experiments showed that PflD would be an alkylsuccinate synthase allowing hydrocarbon activation by addition to fumarate. Moreover, A. fulgidus was shown to corrode iron at high temperature, through the production of sulfide and also by directly oxidizing iron with formation of unusual "micro-chimneys". In addition to organic matter oxidation, SRPs are known to reduce a large number of elements, including metals and metalloids. This is the case for Desulfotomaculum hydrothermale reported to reduce arsenic at high temperature. Analyses of the genome sequence of this bacterium confirmed its ability to detoxify this mineral.
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