Global ETD Search

1	Influence of Nickel and pH on Helicobacter pylori NikR Li, Yanjie 18 February 2011 (has links) Helicobacter pylori (H. pylori) is a gram-negative pathogenic bacterium that infects half of the world’s population. It resides in the human stomach, where it survives extremely acidic conditions. Efficient colonization by H. pylori requires urease and hydrogenase enzymes, both of which utilize nickel as a cofactor. The intracellular level of nickel in H. pylori is strictly maintained by a nickel-responsive transcription factor, HpNikR, which acts as a master regulator to control both activation of the urease genes and repression of a variety of other genes including its own. In addition to its role in nickel homeostasis, HpNikR has been implicated in the adaptive response of H. pylori to acidic environmental conditions. In this work, two representative genes, ureA and nikR, are confirmed to be regulated by HpNikR directly in response to changes in nickel concentration, with HpNikR binding to the promoter region of each gene. The binding sequences on the two promoters are distinct from each other and no consensus sequence could be identified from them. The binding affinity of HpNikR to the ureA promoter is much tighter than to the nikR promoter. Another signal that can activate the DNA-binding activity of HpNikR is a change in pH. Once HpNikR is activated by proton binding, it binds to the ureA promoter independently of nickel concentration, but still binds to the nikR promoter in a nickel-dependent manner. Several amino acids at the N-terminus of HpNikR, including Asp7, Asp8 and Lys6, are critical for the specific response of HpNikR to pH changes. In addition, the binding of HpNikR to distinct DNA sequences induces different degrees of DNA bending, which provides another possible means of gene regulation by HpNikR. The ability of HpNikR to differentially regulate distinct genes in response to several signals allows a graduated level of control of gene expression by HpNikR. In vivo studies to evaluate the physiological relevance of the above in vitro results have been initiated. Given the relatively low abundance of transcription factors in H. pylori, information about the effects of nickel and pH on HpNikR in vivo is important for understanding the multifaceted roles of HpNikR in fine-tuning the physiology of this organism. Ultimately this study may provide us with a better idea of how to control H. pylori-caused diseases. Helicobacter pylori NikR nickel pH 0487
2	Influence of Nickel and pH on Helicobacter pylori NikR Li, Yanjie 18 February 2011 (has links) Helicobacter pylori (H. pylori) is a gram-negative pathogenic bacterium that infects half of the world’s population. It resides in the human stomach, where it survives extremely acidic conditions. Efficient colonization by H. pylori requires urease and hydrogenase enzymes, both of which utilize nickel as a cofactor. The intracellular level of nickel in H. pylori is strictly maintained by a nickel-responsive transcription factor, HpNikR, which acts as a master regulator to control both activation of the urease genes and repression of a variety of other genes including its own. In addition to its role in nickel homeostasis, HpNikR has been implicated in the adaptive response of H. pylori to acidic environmental conditions. In this work, two representative genes, ureA and nikR, are confirmed to be regulated by HpNikR directly in response to changes in nickel concentration, with HpNikR binding to the promoter region of each gene. The binding sequences on the two promoters are distinct from each other and no consensus sequence could be identified from them. The binding affinity of HpNikR to the ureA promoter is much tighter than to the nikR promoter. Another signal that can activate the DNA-binding activity of HpNikR is a change in pH. Once HpNikR is activated by proton binding, it binds to the ureA promoter independently of nickel concentration, but still binds to the nikR promoter in a nickel-dependent manner. Several amino acids at the N-terminus of HpNikR, including Asp7, Asp8 and Lys6, are critical for the specific response of HpNikR to pH changes. In addition, the binding of HpNikR to distinct DNA sequences induces different degrees of DNA bending, which provides another possible means of gene regulation by HpNikR. The ability of HpNikR to differentially regulate distinct genes in response to several signals allows a graduated level of control of gene expression by HpNikR. In vivo studies to evaluate the physiological relevance of the above in vitro results have been initiated. Given the relatively low abundance of transcription factors in H. pylori, information about the effects of nickel and pH on HpNikR in vivo is important for understanding the multifaceted roles of HpNikR in fine-tuning the physiology of this organism. Ultimately this study may provide us with a better idea of how to control H. pylori-caused diseases. Helicobacter pylori NikR nickel pH 0487
3	Disrupting the Non-specific Interactions between DNA and the Escherichia coli Transcriptional Repressor NikR Krecisz, Sandra 20 July 2012 (has links) The Escherichia coli transcription factor NikR is responsible for nickel-mediated repression of the nik operon. The crystal structure of NikR in complex with its operator sequence provided insight into the mechanistic details of nickel-activated NikR-DNA complex formation. The crystal structure revealed that the α3 helix and its preceding loop (residues 63-79) in two of the metal-binding domains—which become structurally ordered after high-affinity nickel binding—make non-specific contacts with the DNA phosphodiester backbone. The proposed mechanism of NikR binding to DNA suggests that the non-specific interactions between the DNA phosphodiester backbone and the positively-charged residues Lys64 and Arg65 anchor NikR to the DNA, thereby allowing the protein to initiate a one-dimensional search for its recognition sequence. The DNA-binding studies presented here strongly support an important role for Lys64 and Arg65 in NikR-DNA complex formation which is in agreement with the proposed model of NikR binding to DNA. NikR nickel transcription factor transcriptional repressor 0485 0487
4	Disrupting the Non-specific Interactions between DNA and the Escherichia coli Transcriptional Repressor NikR Krecisz, Sandra 20 July 2012 (has links) The Escherichia coli transcription factor NikR is responsible for nickel-mediated repression of the nik operon. The crystal structure of NikR in complex with its operator sequence provided insight into the mechanistic details of nickel-activated NikR-DNA complex formation. The crystal structure revealed that the α3 helix and its preceding loop (residues 63-79) in two of the metal-binding domains—which become structurally ordered after high-affinity nickel binding—make non-specific contacts with the DNA phosphodiester backbone. The proposed mechanism of NikR binding to DNA suggests that the non-specific interactions between the DNA phosphodiester backbone and the positively-charged residues Lys64 and Arg65 anchor NikR to the DNA, thereby allowing the protein to initiate a one-dimensional search for its recognition sequence. The DNA-binding studies presented here strongly support an important role for Lys64 and Arg65 in NikR-DNA complex formation which is in agreement with the proposed model of NikR binding to DNA. NikR nickel transcription factor transcriptional repressor 0485 0487
5	Adaptive Responses by Transcriptional Regulators to small molecules in Prokaryotes : Structural studies of two bacterial one-component signal transduction systems DntR and HpNikR Dian, Cyril January 2007 (has links) <p>Prokaryotes are continually exposed to variations in their environment. Survival in unstable milieu requires a wide range of transcriptional regulators (TRs) that respond to specific environmental and cellular signals by modulating gene expression and provide an appropriate physiological response to external stimuli. These adaptive responses to environmental signals are mostly mediated by TRs from one of two families: the single or the two component signal transduction systems (1CSTS; 2CSTS). In this thesis the structural analysis of two 1CSTS – DntR and NikR − are presented. One study was carried out to try to develop a bacterial biosensor for synthetic dinitrotulenes compounds, the other to characterise the Ni-sensing mechanism that contributes to the acid adaptation of the human pathogen<i> Helicobacter pylori.</i> DntR belongs to the LysR family and the crystal structures obtained have allowed the proposal a model of the interaction of DntR with salicylate inducer as well as giving insights into the signal propagation mechanism in LysR-type transcription factors (<b>paper I</b>). DntR mutant crystal structures combined with the modelling of DntR-2,4-dnt interactions led to the design of a DntR mutant that has a limited response to 2,4-dnt in a whole cell biosensor system (<b>paper 2</b>). Crystal structures of apo-NikR from <i>H. pylori </i>(HpNikR) and of Ni-bound intermediary states of the protein were obtained. The latter have helped in unravelling the Ni incorporation and selectivity mechanisms of NikRs and have shown a strong cooperativity between conformational changes in the Ni binding domain with movements of the DNA binding domain (<b>paper 3</b>). Biochemical studies and comparisons of the HpNikR crystal structures with those of NikR homologues strongly suggest that HpNikR has evolved different surface properties (<b>paper 4</b>) and a new mode of DNA binding. </p> transcription regulator bacterial biosensor LysR family Inducer-binding nickel-sensing NikR signal transduction system Helicobacter pylori Biochemistry Biokemi
6	Adaptive Responses by Transcriptional Regulators to small molecules in Prokaryotes : Structural studies of two bacterial one-component signal transduction systems DntR and HpNikR Dian, Cyril January 2007 (has links) Prokaryotes are continually exposed to variations in their environment. Survival in unstable milieu requires a wide range of transcriptional regulators (TRs) that respond to specific environmental and cellular signals by modulating gene expression and provide an appropriate physiological response to external stimuli. These adaptive responses to environmental signals are mostly mediated by TRs from one of two families: the single or the two component signal transduction systems (1CSTS; 2CSTS). In this thesis the structural analysis of two 1CSTS – DntR and NikR − are presented. One study was carried out to try to develop a bacterial biosensor for synthetic dinitrotulenes compounds, the other to characterise the Ni-sensing mechanism that contributes to the acid adaptation of the human pathogen Helicobacter pylori. DntR belongs to the LysR family and the crystal structures obtained have allowed the proposal a model of the interaction of DntR with salicylate inducer as well as giving insights into the signal propagation mechanism in LysR-type transcription factors (<b>paper I</b>). DntR mutant crystal structures combined with the modelling of DntR-2,4-dnt interactions led to the design of a DntR mutant that has a limited response to 2,4-dnt in a whole cell biosensor system (<b>paper 2</b>). Crystal structures of apo-NikR from H. pylori (HpNikR) and of Ni-bound intermediary states of the protein were obtained. The latter have helped in unravelling the Ni incorporation and selectivity mechanisms of NikRs and have shown a strong cooperativity between conformational changes in the Ni binding domain with movements of the DNA binding domain (<b>paper 3</b>). Biochemical studies and comparisons of the HpNikR crystal structures with those of NikR homologues strongly suggest that HpNikR has evolved different surface properties (<b>paper 4</b>) and a new mode of DNA binding. transcription regulator bacterial biosensor LysR family Inducer-binding nickel-sensing NikR signal transduction system Helicobacter pylori Biochemistry Biokemi
7	Propriétés de métallation et de liaison à l'ADN de NikR d'Escherichia coli et de NikR et FUR d'Helicobacter pylori Fauquant, Caroline 23 November 2007 (has links) (PDF) Les facteurs de transcription NikR et FUR sont impliqués dans l'homéostasie des métaux. Les propriétés de métallation et de liaison à l'ADN de NikR d'E.coli (Ec) et d'H.pylori (Hp) ont été comparées. EcNikR, protéine tétramérique, lie 8 nickels par sous unité dont un nickel dans un site dit de haute affinité ayant un Kd submicromolaire. Les autres sites métalliques, de plus basse affinité, sont impliqués dans le processus l'agrégation Ni- et pH-dépendant. HpNikR, partage des propriétés de métallation avec EcNikR, dont la liaison possible de différents métaux dans son site de haute affinité (Cu(II), Ni(II), Co(II)). Les 4 sites de haute affinité de cette protéine semblent égaux 2 à 2. La métallation des premiers sites faciliterait une « fermeture de la protéine » permettant la métallation des deux derniers sites. La métallation de ces 4 sites semble suffire pour qu'HpNikR puisse lier l'ADN.<br />Cependant cette liaison serait améliorée en présence d'un métal stabilisateur dans d'autres sites. Selon les séquences opératrices, le métal et la technique employée, l‘affinité d'HpNikR métallée pour l'ADN varie. En présence d'un excès de Ni(II), HpNikR se lie à pureA et à pnixA avec un Kd de 2,5 et 1,7 nM mais se lie faiblement à pnikR et pexbB. En présence d'un excès de Ni(II) puis de Mn(II), HpNikR se lie à pnikR et à pexbB avec un Kd de 38 et 24 nM. FUR d'H.pylori (HpFUR), un métallorégulateur Fe dépendant, a aussi été caractérisé dans le but d'étudier sa co-régulation avec HpNikR de la région intergénique nikR-exbB. HpFUR est dimérique et contient au moins deux sites métalliques : un site structural et un site de régulation permettant l'activation pour la liaison à l'ADN. Métallorégulateur NikR FUR Escherichia coli Helicobacter pylori nickel fer homéostasie spectroscopie affinité dichroïsme circulaire interaction ADN/Protéine

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