Physicochemical Characterization of the Bacterial Cu(I) Sensor CsoR

Ma, Zhen

2009 December 1900

M. tuberculosis copper-sensitive operon repressor (Mtb CsoR) is the founding member of a new metalloregulatory protein family in prokaryotes that regulates the transcription of the cso operon in response to copper toxicity. Mtb CsoR tetramer binds 1 monomer mol equiv of Cu(I) with very high affinity (log KCu=18.0) via three conserved residues, Cys36, His61' and Cys65'. Binding of Cu(I) allosterically inhibits the CsoR binding to the DNA operator (CsoO) overlapping the cso promoter (DeltaGc=+3.6 kcal/mol, pH 7.0, 25 oC). These findings are consistent with a role of CsoR as a transcriptional repressor with Cu(I) binding inducing transcriptional derepression. To explore the mechanism of this regulation, His61 was substituted with 1-methylhistidine (MeH) or Beta- (2-thiazolyl)-alanine (Thz) using a native chemical ligation strategy. The CsoO binding affinities of the resultant H61MeH and H61Thz CsoRs are both refractory to inhibition by Cu(I) binding despite the fact that each forms a high affinity 3-coordinate complex with Cu(I). This suggests that while Cu(I) is coordinated by the N?11 atom of His61, the N?22 atom plays an critical role in driving this allosteric switch. Evidence in support of a formation of a hydrogen bonding network involving the N?1 face of His61 and two conserved "second coordination shell" residues, Glu81' and Tyr35, is presented. Remarkably, this mechanism is analogous to that proposed for the Zn(II) sensor CzrA from S. aureus. To test this, we employed the same native chemical ligation approach to substitute the key Zn(II) ligand His97 with 1-methylhistidine; with the preliminary findings fully consistent with an intersubunit allosteric switch involving the N?2 face of this key His97 residue in CzrA. Two predicted homologs of Mtb CsoR were also biochemically characterized to obtain additional support for the hypothesis that CsoR is a key Cu(I) regulatory protein in many bacterial species. B. subtilis CsoR, known to regulate the transcription of the copZA operon, was found to have biochemical properties similar to those of Mtb CsoR as to Cu(I) binding, DNA binding and Cu(I)-dependent allosteric regulation. Interestingly, Bsu CsoR also binds other divalent metal ions (Zn, Ni) with high affinity but with metal coordination geometries distinct from that of Cu(I). Binding of these divalent metal ions only weakly regulates copZA operator binding in vitro, suggesting that coordination number and geometry are most closely related to the allosteric regulation. Finally, a putative CsoR from the pathogenic S. aureus Newman strain was identified and characterized, and was found to exhibit biochemical properties similar to those of Mtb and Bsu CsoRs. Parallels between Cu(I)-sensing CsoRs and functional orthologs in the CsoR/RcnR family are further discussed in the context of the mechanism and evolutionary divergence of this new family of regulatory proteins.

CsoR

Cu(I) sensor

allosteric regulation

native chemical ligation

Structure-function relationships in cellular copper control

Zhang, Limei

09 June 2009

X-ray absorption spectroscopy and computational chemistry have been used to probe the structure of biomolecules involved in cellular copper homeostasis. X-ray absorption spectroscopy shows that copper chaperones involved in cytochrome c oxidase assembly bind Cu(I) with trigonal coordination environments in poly-copper thiolate clusters, but the number of coppers in these clusters remains unclear. X-ray absorption spectroscopy of the metal-sensing transcription factor-1 from Drosophila melanogaster and metallothionein from Saccharomyces cerevisiae with stoichiometries of four or less shows a tetracopper cluster in an all-or-none manner in these molecules. These results suggest that cooperative binding of copper to form tetracopper clusters may be a common mechanism employed by copper control molecules. The active site structure of the novel copper-sensitive repressor CsoR in Mycobacterium tuberculosis binds copper in a trigonal coordination geometry with two sulfur and one nitrogen donors according to X-ray absorption spectroscopy results. Molecular dynamics simulations of both apo- and Cu-bound CsoR reveal local conformational changes in CsoR upon copper binding, which suggests multiple possible mechanisms of Cu-dependent transcriptional regulation by CsoR. Finally, X-ray absorption spectroscopy and X-ray fluorescence imaging have been used to understand the molecular basis of a promisng new treatment for Wilsons disease (a genetic disorder of Cu homeostasis) using tetrathiomolybdate. Overall, the results presented provide an essential structural basis for understanding copper homeostasis in living cells.

density functional theory

X-ray absorption spectroscopy

cellular Cu control

molecular dynamics

metallothionein

Cu chapterone

CsoR

MTF-1

Structure-function relationships in cellular copper control

Zhang, Limei

09 June 2009

X-ray absorption spectroscopy and computational chemistry have been used to probe the structure of biomolecules involved in cellular copper homeostasis. X-ray absorption spectroscopy shows that copper chaperones involved in cytochrome c oxidase assembly bind Cu(I) with trigonal coordination environments in poly-copper thiolate clusters, but the number of coppers in these clusters remains unclear. X-ray absorption spectroscopy of the metal-sensing transcription factor-1 from Drosophila melanogaster and metallothionein from Saccharomyces cerevisiae with stoichiometries of four or less shows a tetracopper cluster in an all-or-none manner in these molecules. These results suggest that cooperative binding of copper to form tetracopper clusters may be a common mechanism employed by copper control molecules. The active site structure of the novel copper-sensitive repressor CsoR in Mycobacterium tuberculosis binds copper in a trigonal coordination geometry with two sulfur and one nitrogen donors according to X-ray absorption spectroscopy results. Molecular dynamics simulations of both apo- and Cu-bound CsoR reveal local conformational changes in CsoR upon copper binding, which suggests multiple possible mechanisms of Cu-dependent transcriptional regulation by CsoR. Finally, X-ray absorption spectroscopy and X-ray fluorescence imaging have been used to understand the molecular basis of a promisng new treatment for Wilsons disease (a genetic disorder of Cu homeostasis) using tetrathiomolybdate. Overall, the results presented provide an essential structural basis for understanding copper homeostasis in living cells.

density functional theory

X-ray absorption spectroscopy

cellular Cu control

molecular dynamics

metallothionein

Cu chapterone

CsoR

MTF-1