David Giedroc

Publications (2)6.84 Total impact

• Article: Molecular insights into the metal selectivity of the copper(I)-sensing repressor CsoR from Bacillus subtilis.

  Zhen Ma, Darin M Cowart, Robert A Scott, David P Giedroc
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  ABSTRACT: Bacillus subtilis CsoR (Bsu CsoR) is a copper-sensing transcriptional repressor that regulates the expression of the copZA operon encoding a copper chaperone and a Cu efflux P-type ATPase, respectively. Bsu CsoR is a homologue of Mycobacterium tuberculosis CsoR (Mtb CsoR), representative of a large Cu(I)-sensing regulatory protein family. We show here that Bsu CsoR binds approximately 1 mol equiv of Cu(I) per monomer in vitro with an affinity >or=10(21) M(-1). X-ray absorption spectroscopy shows Cu(I) adopts a trigonal S(2)N coordination like Mtb CsoR. Both apo and Cu(I)-bound Bsu CsoR are stable tetramers in the low micromolar monomer concentration range by sedimentation velocity and equilibrium ultracentrifugation. Apo-Bsu CsoR binds to a pseudopalindromic 30 bp copZA operator-promoter DNA with a stoichiometry of two tetramers per DNA and stepwise affinities of K(1)(apo) = 3.1(+/-0.8) x 10(7) M(-1) and K(2)(apo) = 8.3 (+/-2.2) x 10(7) M(-1) (0.4 M NaCl, 25 degrees C, pH 6.5). Cu(I) Bsu CsoR binds to the same DNA with greatly reduced affinities, K(1)(Cu) = 2.9(+/-0.4) x 10(6) M(-1) and K(2)(Cu) <or= 1.0 x 10(5) M(-1) consistent with a copper-dependent derepression model. This Cu-dependent regulation is abrogated by a "second shell" Glu90-to-Ala substitution. Bsu CsoR binds Ni(II) with very high affinity but forms a non-native coordination geometry, as does Co(II) and likely Zn(II); none of these metals strongly regulates copZA operator DNA binding in vitro. The implications of these findings on the specificity of metal-sensing sites in CsoR/RcnR proteins are discussed.
  Biochemistry 02/2009; 48(15):3325-34. · 3.42 Impact Factor
• Article: A Cu(I)-sensing ArsR family metal sensor protein with a relaxed metal selectivity profile.

  Tong Liu, Xiaohua Chen, Zhen Ma, Jacob Shokes, Lars Hemmingsen, Robert A Scott, David P Giedroc
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  ABSTRACT: ArsR (or ArsR/SmtB) family metalloregulatory homodimeric repressors collectively respond to a wide range of metal ion inducers in regulating homeostasis and resistance of essential and nonessential metal ions in bacteria. BxmR from the cyanobacterium Osciliatoria brevis is the first characterized ArsR protein that senses both Cu (I)/Ag (I) and divalent metals Zn (II)/Cd (II) in cells by regulating the expression of a P-type ATPase efflux pump (Bxa1) and an intracellular metallothionein (BmtA). We show here that both pairs of predicted alpha3N and alpha5 sites bind metal ions, but with distinct physicochemical and functional metal specificities. Inactivation of the thiophilic alpha3N site via mutation (C77S) abolishes regulation by both Cd (II) and Cu (I), while Zn (II) remains a potent allosteric negative effector of operator/promoter binding (Delta G c >or= +3.2 kcal mol (-1)). In contrast, alpha5 site mutant retains regulation by all four metal ions, albeit with a smaller coupling free energy (Delta G c approximately +1.7 (+/-0.1) kcal mol (-1)). Unlike the other metals ions, the BxmR dimer binds 4 mol equiv of Cu (I) to form an alpha3N binuclear Cu (I) 2S 4 cluster by X-ray absorption spectroscopy. BxmR is thus distinguishable from other closely related ArsR family sensors, in having evolved a metalloregulatory alpha3N site that can adopt an expanded range of coordination chemistries while maintaining redundancy in the response to Zn (II). The evolutionary implications of these findings for the ArsR metal sensor family are discussed.
  Biochemistry 10/2008; 47(40):10564-75. · 3.42 Impact Factor