Structural and functional characterization of the transcriptional repressor CsoR from Thermus thermophilus HB8

Sakamoto, Keiko; Agari, Yoshihiro; Agari, Kazuko; Kuramitsu, Seiki; Shinkai, Akeo

doi:10.1099/mic.0.037382-0

Cited by 53 publications

(65 citation statements)

References 39 publications

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“…Experimental evidence for copper-responsive gene regulation by CsoR in proteobacteria and cyanobacteria is lacking to date. However, CsoR has been shown to control copper homeostasis in Thermus thermophilus belonging to the phylum Deinococcus-Thermus, which is only distantly related to proteobacteria and Grampositive species (Sakamoto et al, 2010). Apparently, CsoR homologues are the primary one-component copperresponsive regulators in prokaryotes lacking CueR (Liu et al, 2007).…”

Section: Class 8: Csor-like Repressors Are Widespread In Prokaryotesmentioning

confidence: 99%

“…T. thermophilus harbours the copZ-csoR-copA operon, which is repressed by CsoR under copper-limiting conditions (Sakamoto et al, 2010). In vitro, T. thermophilus CsoR is very promiscuous and binds various metal ions, including Cu + , Cu 2+ , Zn 2+ , Cd 2+ , Ag + and Ni 2+ , all of which release CsoR from the copZ promoter.…”

Section: T Thermophilusmentioning

confidence: 99%

“…Gene regulation by copper proteobacteria (Sakamoto et al, 2010). Future studies are required to clarify the roles of predicted CsoR homologues in proteobacteria.…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

“…tuberculosis, Streptomyces lividans and T. thermophilus (Dwarakanath et al, 2012;Liu et al, 2007;Sakamoto et al, 2010). Mt-CsoR forms homodimers, while Sl-CsoR and Tt-CsoR form tetramers.…”

Section: Class 8: Csor-like Repressors Are Widespread In Prokaryotesmentioning

confidence: 99%

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Copper-responsive gene regulation in bacteria

2012

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Section: Class 8: Csor-like Repressors Are Widespread In Prokaryotesmentioning

confidence: 99%

Section: T Thermophilusmentioning

confidence: 99%

“…Gene regulation by copper proteobacteria (Sakamoto et al, 2010). Future studies are required to clarify the roles of predicted CsoR homologues in proteobacteria.…”

Section: Conclusion and Future Perspectivesmentioning

confidence: 99%

“…tuberculosis, Streptomyces lividans and T. thermophilus (Dwarakanath et al, 2012;Liu et al, 2007;Sakamoto et al, 2010). Mt-CsoR forms homodimers, while Sl-CsoR and Tt-CsoR form tetramers.…”

Section: Class 8: Csor-like Repressors Are Widespread In Prokaryotesmentioning

confidence: 99%

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Copper-responsive gene regulation in bacteria

2012

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“…tuberculosis CsoR 6 (copper-sensitive operon repressor) is a founding member of large family of regulators now known collectively to respond to Cu(I), Ni(II), and perhaps other stressors, the structural basis of which is not fully understood (11, 12). All CsoR family proteins lack a known canonical DNA binding domain and are projected to adopt the flat disc-shaped dimer of dimers homotetrameric structure characteristic of Cu(I)-sensing CsoRs, with individual dimers consisting of an antiparallel four-helix bundle flanked by a C-terminal ␣3 helix (13,14). Two cysteine residues on opposite subunits within a dimer make coordination bonds to the Cu(I) ion, with the third ligand a His from the ␣2 helix (Cys 36 Ј, His 61 , Cys 65 ), thus completing a trigonal S 2 N coordination complex (13).…”

mentioning

confidence: 99%

Control of Copper Resistance and Inorganic Sulfur Metabolism by Paralogous Regulators in Staphylococcus aureus

Grossoehme

Kehl-Fie

et al. 2011

Journal of Biological Chemistry

214

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All strains of Staphylococcus aureus encode a putative copper-sensitive operon repressor (CsoR) and one other CsoR-like protein of unknown function. We show here that NWMN_1991 encodes a bona fide Cu(I)-inducible CsoR of a genetically unlinked copA-copZ copper resistance operon in S. aureus strain Newman. In contrast, an unannotated open reading frame found between NWMN_0027 and NWMN_0026 (denoted NWMN_0026.5) encodes a CsoR-like regulator that represses expression of adjacent genes by binding specifically to a pair of canonical operator sites positioned in the NWMN_0027-0026.5 intergenic region. Inspection of these regulated genes suggests a role in assimilation of inorganic sulfur from thiosulfate and vectorial sulfur transfer, and we designate NWMN_ 0026.5 as CstR (CsoR-like sulfur transferase repressor). Expression analysis demonstrates that CsoR and CstR control their respective regulons in response to distinct stimuli with no overlap in vivo. Unlike CsoR, CstR does not form a stable complex with Cu(I); operator binding is instead inhibited by oxidation of the intersubunit cysteine pair to a mixture of disulfide and trisulfide linkages by a likely metabolite of thiosulfate assimilation, sulfite. CsoR is unreactive toward sulfite under the same conditions. We conclude that CsoR and CstR are paralogs in S. aureus that function in the same cytoplasm to control distinct physiological processes.The Gram-positive opportunistic human pathogen Staphylococcus aureus is the causative agent of a wide range of hospital and community-acquired infections that are associated with significant morbidity (1). With the incidence of methicillinresistant strains increasing in previously low prevalence areas (2), new antibiotic therapies that target novel metabolic pathways are urgently needed. One approach is to target those processes that allow a pathogen to respond to environmental stresses that might change depending on the microenvironmental host niche in which the organism finds itself. Resistance to host-mediated copper killing of Escherichia coli (3), Salmonella enterica (4), and Mycobacterium tuberculosis (5, 6) and sulfur assimilation and cysteine biosynthesis in M. tuberculosis (7,8) are two such processes. S. aureus is particularly sensitive to rapid killing when exposed to copper or copper alloy surfaces, justifying this therapeutic direction (9, 10).M. tuberculosis CsoR 6 (copper-sensitive operon repressor) is a founding member of large family of regulators now known collectively to respond to Cu(I), Ni(II), and perhaps other stressors, the structural basis of which is not fully understood (11, 12). All CsoR family proteins lack a known canonical DNA binding domain and are projected to adopt the flat disc-shaped dimer of dimers homotetrameric structure characteristic of Cu(I)-sensing CsoRs, with individual dimers consisting of an antiparallel four-helix bundle flanked by a C-terminal ␣3 helix (13,14). Two cysteine residues on opposite subunits within a dimer make coordination bonds to the Cu(I) ion, with the third ...

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Metal Specificity of Metallosensors

Higgins

Giedroc

2004

Encyclopedia of Inorganic and Bioinorganic Chemistry

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Transition metal ions are biologically required yet toxic when in excess. As such, prokaryotes have developed metal homeostasis systems that allow for the acquisition of essential metal ions, the delivery of these metal ions to target proteins, and the export of metal ions from the cell. Specialized metal‐binding proteins termed metallosensors bind to a cognate metal ion(s) in the cell and either transcriptionally repress the expression of importers or de‐repress the expression of exporters or sequestration systems and therefore govern cellular metal homeostasis. Metallosensors must be selective and appropriately sensitive toward the binding of their cognate metals. Prokaryotic metallosensors have been identified in ten different protein structural families. Each family exploits either one general metal‐binding‐site region, individual members of which have evolved different coordination sites, or alternatively, employs multiple metal‐binding sites to effect coordination of different metal ions. There is now broad support for the hypothesis that metal responsiveness in metallosensors is most closely linked to the coordination number and geometry adopted by cognate metal ion(s), and this is the subject of this article. Since a range of metal ions can be collectively sensed by a single repressor family, a particular protein fold cannot be specific for one particular metal ion. In fact, the converse is true: nature has used convergent evolution to evolve metal‐specific sensors on a variety of structural scaffolds that exploit common principles of coordination chemistry (ligand type, coordination number, and geometry) to effect the same biological outcome.

show abstract

Structural and functional characterization of the transcriptional repressor CsoR from Thermus thermophilus HB8

Cited by 53 publications

References 39 publications

Copper-responsive gene regulation in bacteria

Copper-responsive gene regulation in bacteria

Control of Copper Resistance and Inorganic Sulfur Metabolism by Paralogous Regulators in Staphylococcus aureus

Metal Specificity of Metallosensors

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