The zinc metalloregulatory protein Synechococcus PCC7942 SmtB binds a single zinc ion per monomer with high affinity in a tetrahedral coordination geometry

Multiple metal binding domains enhance the Zn(II) selectivity of the divalent metal ion transporter AztA

Transition metal-transporting P1B-type CPx ATPases play crucial roles in mediating metal homeostasis and resistance in all cells. The degree to which N-terminal metal binding domains (MBDs) confer metal specificity to the transporter is unclear. We show that the two MBDs of the Zn/Cd/Pb effluxing pump Anabaena AztA are functionally nonequivalent, but only with respect to zinc resistance. Inactivation of the a-MBD largely abrogates resistance to high intracellular Zn(II) levels, whereas inactivation of the b-MBD is not as deleterious. In contrast, inactivation of either the a- or b-MBD has little measurable impact on Cd(II) and Pb(II) resistance. The membrane proximal b-MBD binds Zn(II) with a higher affinity than the distal N-terminal a-MBD. Facile Zn(II)-specific intermolecular transfer from the a-MBD to the higher-affinity b-MBD is readily observed by 1H-15N HSQC spectroscopy. Unlike Zn(II), Cd(II) and Pb(II) form saturated 1:1 S4 or S3(O/N) complexes with AztAaHbH, where a single metal ion bridges the two MBDs. We propose that the tandem MBDs enhance Zn(II)-specific transport, while stabilizing a non-native inter-MBD Cd/Pb cross-linked structure that is a poor substrate and/or regulator for the transporter.

Mycobacterial cells have dual nickel-cobalt sensors: sequence relationships and metal sites of metal-responsive repressors are not congruent

A novel ArsR-SmtB family transcriptional repressor, KmtR, has been characterized from mycobacteria. Mutants of Mycobacterium tuberculosis lacking kmtR show elevated expression of Rv2025c encoding a deduced CDF-family metal exporter. KmtR-dependent repression of the cdf and kmtR operator-promoters was alleviated by nickel and cobalt in minimal medium. Electrophoretic mobility shift assays and fluorescence anisotropy show binding of purified KmtR to nucleotide sequences containing a region of dyad symmetry from the cdf and kmtR operator-promoters. Incubation of KmtR with cobalt inhibits DNA complex assembly and metal-protein binding was confirmed. KmtR is the second, to NmtR, characterized ArsR-SmtB sensor of nickel and cobalt from M. tuberculosis suggesting special significance for these ions in this pathogen. KmtR-dependent expression is elevated in complete medium with no increase in response to metals, whereas NmtR retains a response to nickel and cobalt under these conditions. KmtR has tighter affinities for nickel and cobalt than NmtR consistent with basal levels of these metals being sensed by KmtR but not NmtR in complete medium. More than a thousand genes encoding ArsR-SmtB-related proteins are listed in databases. KmtR has none of the previously defined metal-sensing sites. Substitution of His88, Glu101, His102, His110, or His111 with Gln generated KmtR variants that repress the cdf and kmtR operator-promoters even in elevated nickel and cobalt, revealing a new sensory site. Importantly, ArsR-SmtB sequence groupings do not correspond with the different sensory motifs revealing that only the latter should be used to predict metal sensing.

Understanding the mechanisms of zinc-sensing by metal-response element binding transcription factor-1 (MTF-1)

The regulation of divalent zinc has been observed in a wide range of organisms. Since this metal is an essential nutrient, but also toxic in excess, zinc homeostasis is crucial for normal cellular functioning. The metal-responsive-element-binding transcription factor-1 (MTF-1) is a key regulator of zinc in higher eukaryotes ranging from insects to mammals. MTF-1 controls the expression of metallothioneins (MTs) and a number of other genes directly involved in the intracellular sequestration and transport of zinc. Although the diverse functions of MTF-1 extend well beyond zinc homeostasis to include stress-responses to heavy metal toxicity, oxidative stress, and selected chemical agents, in this review we focus on the recent advances in understanding the mechanisms whereby MTF-1 regulates MT gene expression to protect the cell from fluctuations in environmental zinc. Particular emphasis is devoted to recent studies involving the Cys2His2 zinc finger DNA-binding domain of MTF-1, which is an important contributor to the zinc-sensing and metal-dependent transcriptional activation functions of this protein.

NMR structural analysis of cadmium sensing by winged helix repressor CmtR

CmtR from Mycobacterium tuberculosis is a winged helical DNA-binding repressor of the ArsR-SmtB metal-sensing family that senses cadmium and lead. Cadmium-CmtR is a dimer with the metal bound to Cys-102 from the C-terminal region of one subunit and two Cys associated with helix alphaR from the other subunit, forming a symmetrical pair of cadmium-binding sites. This is a significant novelty in the ArsR-SmtB family. The structure of the dimer could be solved at 312 K. The apoprotein at the same temperature is still a dimer, but it experiences a large conformational exchange at the dimer interface and within each monomer. This is monitored by an overall decrease of the number of nuclear Overhauser effects and by an increase of H(2)O-D(2)O exchange rates, especially at the dimeric interface, in the apo form with respect to the cadmium-bound state. The C-terminal tail region is completely unstructured in both apo and cadmium forms but becomes less mobile in the cadmium-bound protein due to the recruitment of Cys-102 as a metal-ligand. DNA binds to the apo dimer with a ratio 1:3 at millimolar concentration. Addition of cadmium to the apo-CmtR-DNA complex causes DNA detachment, restoring the NMR spectrum of free cadmium-CmtR. Cadmium binding across the dimer interface impairs DNA association by excluding the apo-conformers suited to bind DNA.

Human serum albumin coordinates Cu(II) at its N-terminal binding site with 1 pM affinity

The conditional stability constant at pH 7.4 for Cu(II) binding at the N-terminal site (NTS) of human serum albumin (HSA) was determined directly by competitive UV-vis spectroscopy titrations using nitrilotriacetic acid (NTA) as the competitor in 100 mM NaCl and 100 mM N-(2-hydroxyethyl)piperazine-N'-ethanesulfonic acid (Hepes). The log Kc (NTS) value of 12.0 +/- 0.1 was determined for HSA dissolved in 100 mM NaCl. A false log log Kc (NTS) (c) value of 11.4 +/- 0.1 was obtained in the 100 mM Hepes buffer, owing to the formation of a ternary Cu(NTA)(Hepes) complex. The impact of the picomolar affinity of HSA for Cu(II) on the availability of these ions in neurodegenerative disorders is briefly discussed.

Metal sensor proteins: nature's metalloregulated allosteric switches

Metalloregulatory proteins control the expression of genes that allow organisms to quickly adapt to chronic toxicity or deprivation of both biologically essential metal ions and heavy metal pollutants found in their microenvironment. Emerging evidence suggests that metal ion homeostasis and resistance defines an important tug-of-war in human host-bacterial pathogen interactions. This adaptive response originates with the formation of "metal receptor" complexes of exquisite selectivity. In this perspective, we summarize consensus structural features of metal sensing coordination complexes and the evolution of distinct metal selectivities within seven characterized metal sensor protein families. In addition, we place recent efforts to understand the structural basis of metal-induced allosteric switching of these metalloregulatory proteins in a thermodynamic framework, and review the degree to which coordination chemistry drives changes in protein structure and dynamics in selected metal sensor systems. New insights into how metal sensor proteins function in the complex intracellular milieu of the cytoplasm of cells will require a more sophisticated understanding of the "metallome" and will benefit greatly from ongoing collaborative efforts in bioinorganic, biophysical and analytical chemistry, structural biology and microbiology.

Metal binding studies and EPR spectroscopy of the manganese transport regulator MntR

Manganese transport regulator (MntR) is a member of the diphtheria toxin repressor (DtxR) family of transcription factors that is responsible for manganese homeostasis in Bacillus subtilis. Prior biophysical studies have focused on the metal-mediated DNA binding of MntR [Lieser, S. A., Davis, T. C., Helmann, J. D., and Cohen, S. M. (2003) Biochemistry 42, 12634-12642], as well as metal stabilization of the MntR structure [Golynskiy, M. V., Davis, T. C., Helmann, J. D., and Cohen, S. M. (2005) Biochemistry 44, 3380-3389], but only limited data on the metal-binding affinities for MntR are available. Herein, the metal-binding affinities of MntR were determined by using electron paramagnetic resonance (EPR) spectroscopy, as well as competition experiments with the fluorimetric dyes Fura-2 and Mag-fura-2. MntR was not capable of competing with Fura-2 for the binding of transition metal ions. Therefore, the metal-binding affinities and stoichiometries of Mag-fura-2 for Mn2+, Co2+, Ni2+, Zn2+, and Cd2+ were determined and utilized in MntR/Mag-fura-2 competition experiments. The measured Kd values for MntR metal binding are comparable to those reported for DtxR metal binding [Kd from 10(-)7 to 10(-4) M; D'Aquino, J. A., et al. (2005) Proc. Natl. Acad. Sci. U.S.A. 102, 18408-18413], AntR [a homologue from Bacillus anthracis; Sen, K. I. et al. (2006) Biochemistry 45, 4295-4303], and generally follow the Irving-Williams series. Direct detection of the dinuclear Mn2+ site in MntR with EPR spectroscopy is presented, and the exchange interaction was determined, J = -0.2 cm-1. This value is lower in magnitude than most known dinuclear Mn2+ sites in proteins and synthetic complexes and is consistent with a dinuclear Mn2+ site with a longer Mn...Mn distance (4.4 A) observed in some of the available crystal structures. MntR is found to have a surprisingly low binding affinity (approximately 160 microM) for its cognate metal ion Mn2+. Moreover, the results of DNA binding studies in the presence of limiting metal ion concentrations were found to be consistent with the measured metal-binding constants. The metal-binding affinities of MntR reported here help to elucidate the regulatory mechanism of this metal-dependent transcription factor.

A novel regulatory metal binding domain is present in the C terminus of Arabidopsis Zn2+-ATPase HMA2

HMA2 is a Zn2+-ATPase from Arabidopsis thaliana. It contributes to the maintenance of metal homeostasis in cells by driving Zn2+ efflux. Distinct from P1B-type ATPases, plant Zn2+-ATPases have long C-terminal sequences rich in Cys and His. Removal of the 244 amino acid C terminus of HMA2 leads to a 43% reduction in enzyme turnover without significant effect on the Zn2+ K(1/2) for enzyme activation. Characterization of the isolated HMA2 C terminus showed that this fragment binds three Zn2+ with high affinity (Kd = 16 +/- 3 nM). Circular dichroism spectral analysis indicated the presence of 8% alpha-helix, 45% beta-sheet, and 48% random coil in the C-terminal peptide with noticeable structural changes upon metal binding (8% alpha-helix, 39% beta-sheet, and 52% random coil). Zn K-edge XAS of Zn-C-MBD in the presence of one equivalent of Zn2+ shows that the average zinc complex formed is composed of three His and one Cys residues. Upon the addition of two extra Zn2+ ions per C-MBD, these appear coordinated primarily by His residues thus, suggesting that the three Zn2+ binding domains might not be identical. Modification of His residues with diethyl pyrocarbonate completely inhibited Zn2+ binding to the C terminus, pointing out the importance of His residues in Zn2+ coordination. In contrast, alkylation of Cys with iodoacetic acid did not prevent Zn2+ binding to the HMA2 C terminus. Zn K-edge XAS of the Cys-alkylated protein was consistent with (N/O)4 coordination of the zinc site, with three of those ligands fitting for His residues. In summary, plant Zn2+-ATPases contain novel metal binding domains in their cytoplasmic C terminus. Structurally distinct from the well characterized N-terminal metal binding domains present in most P1B-type ATPases, they also appear to regulate enzyme turnover rate.

Zinc transporters and the cellular trafficking of zinc

Zinc is an essential nutrient for all organisms because this metal serves as a catalytic or structural cofactor for many different proteins. Zinc-dependent proteins are found in the cytoplasm and within many organelles of the eukaryotic cell including the nucleus, the endoplasmic reticulum, Golgi, secretory vesicles, and mitochondria. Thus, cells require zinc transport mechanisms to allow cells to efficiently accumulate the metal ion and distribute it within the cell. Our current knowledge of these transport systems in eukaryotes is the focus of this review.

Solution Structure of a Zap1 Zinc-responsive Domain Provides Insights into Metalloregulatory Transcriptional Repression in Saccharomyces cerevisiae

The Zap1 transcription factor controls expression of genes that regulate zinc homeostasis in Saccharomyces cerevisiae. The solution structure of two zinc fingers (zf1-2(CA3)) derived from a zinc-responsive domain of Zap1 (zf1-2) has been determined. Under zinc-limiting conditions, zinc finger 2 (zf2) from this domain has been shown to be a constitutive transcriptional activator. Moreover, repression of zf2 function in zinc-replete cells required zinc coordination to both canonical finger 1 (zf1) and zf2 metal sites, suggesting zf1-zf2 cooperativity underlies Zap1 metalloregulation. A structural basis for this cooperativity is identified here. Favorable inter-helical contacts in zf1-2(CA3) extend the individual finger hydrophobic cores through the zf1-zf2 interface. Tryptophan residues at position 5 in each finger provide numerous non-helical inter-finger contacts reminiscent of those observed in GLI1 zinc fingers 1 and 2. The molecular mechanism for zf1-dependent repression of zf2 transcriptional activation is explored further using NMR and CD titration studies. While zf1 independently forms a betabetaalpha solution structure, the majority of zf2 ensemble solution states do not adopt the canonical betabetaalpha zinc finger fold without zf1-zf2 interactions. Cooperative effects on Zn(II) affinities stemming from these finger-finger interactions are observed also in calorimetric studies, in which the 160(+/-20)nM (zf1) and 250(+/-40)nM (zf2) K(d) values for each individual finger increased substantially in the context of the zf1-2 protein (apparent K(dzf1-2WT)=4.6(+/-1.2)nM). On the basis of the above observations, we propose a mechanism for Zap1 transcriptional regulation in which zf1-zf2 interactions stabilize the betabetaalpha folded "repressed state" of the zf2 activation domain in the presence of cellular Zn(II) excess. Moreover, in contrast to earlier reports of <<1 labile zinc ion/Escherichia coli cell, the zf1-zf2 zinc affinities determined calorimetrically are consistent with Zn(II) levels >>1 labile zinc ion/eukaryotic cell.

Kinetics of metal binding by the toxic metal-sensing transcriptional repressor Staphylococcus aureus pI258 CadC

The mechanisms by which metal ions are sensed in bacterial cells by metal-responsive transcriptional regulators (metal sensor proteins) may be strongly influenced by the kinetics of association and dissociation of specific metal ions with specific metalloregulatory targets. Staphylococcus aureus pI258-encoded CadC senses toxic metal pollutants such as Cd(II), Pb(II) and Bi(III) with very high thermodynamic affinities ( approximately 10(12)M(-1)) in forming either distorted tetrahedral (Cd/Bi) or trigonal (Pb) coordination complexes with cysteine thiolate ligands derived from the N-terminal domain (Cys7/11) and a pair of Cys in the alpha4 helix (Cys58/60). We show here that metal ion binding to this site (denoted the alpha3N or type 1 metal site) is characterized by two distinct kinetic phases, a fast bimolecular encounter phase and a slower intramolecular conformational transition. Metal association rates are fast ( approximately 10(5)-10(7)M(-1)s(-1)) and strongly dependent on the metal ion type in a manner that correlates with metal specificity in vivo. In contrast, the observed rate of the slower isomerization step is independent of the metal ion type (2.8+/-0.4s(-1)) but is reduced 6-fold upon substitution of Cys7, a key metal ligand that drives allosteric negative regulation of DNA binding. Chelator (EDTA)-mediated metal dissociation rates from the alpha3N site are extremely slow (10(-4)s(-1)). Where observable dissociation can be observed, a ternary CadC-metal ion-chelator complex is invoked, suggesting that metal-ligand exchange may be an important factor in metal sensing and resistance in the cell.

Predicting metals sensed by ArsR-SmtB repressors: allosteric interference by a non-effector metal

Many bacterial genomes encode multiple metal-sensing ArsR-SmtB transcriptional repressors. There is interest in understanding and predicting their metal specificities. Here we analyse two arsR-smtB genes, ydeT and yozA (now aseR and czrA) from Bacillus subtilis. Purified AseR and CzrA formed complexes in gel-retardation and fluorescence-anisotropy assays with fragments of promoters that were derepressed in DeltaaseR and DeltaczrA cells. Candidate (i) partly thiolate, alpha3-helix (for AseR) and (ii) tetrahedral, non-thiolate, alpha5-helix (for CzrA) metal binding sites were predicted then tested in vitro and/or in vivo. The precedents are for such sites to sense arsenite/antimonite (alpha3) and zinc (alpha5). This correlated with the respective metal inducers of AseR and CzrA repressed promoters in B. subtilis and matched the metals that impaired formation of protein-DNA complexes in vitro. The putative sensory sites of 1024 ArsR-SmtB homologues are reported. Although AseR did not sense zinc in vivo, it bound zinc in vitro exploiting alpha3 thiols, but AseR DNA binding was not impaired by zinc. If selectivity relies on discriminatory triggering of allostery not just selective metal binding, then tight non-effector metal complexes could theoretically inhibit metal sensing. AseR remained arsenite-sensitive in equimolar zinc, while CzrA remained zinc-sensitive in equimolar arsenite in vitro. However, cupric ions did not impair CzrA-DNA complex formation but did inhibit zinc-mediated allostery in vitro and prevent zinc binding. Access to copper must be controlled in vivo to avoid formation of cupric CzrA.

Structural Insights into Homo- and Heterotropic Allosteric Coupling in the Zinc Sensor S. aureus CzrA from Covalently Fused Dimers

The Zn(II)/Co(II)-sensing transcriptional repressor, Staphylococcus aureus CzrA, is a homodimer containing a symmetry-related pair of subunit-bridging tetrahedral N(3)O metal sensor coordination sites. A metal-induced quaternary structural change within the homodimer is thought to govern the biological activity of this and other metal sensor proteins. Here, we exploit covalent (Gly(4)Ser)(n)() linkers of variable length in "fused" CzrAs, where n = 1 (designated 5L-fCzrA), 2 (10L-fCzrA), or 3 (15L-fCzrA), as molecular rulers designed to restrict any quaternary structural changes that are associated with metal binding and metal-mediated allosteric regulation of DNA binding to varying degrees. While 15L-fCzrA exhibits properties most like homodimeric CzrA, shortening the linker in 10L-fCzrA abolishes negative homotropic cooperativity of Zn(II) binding and reduces DNA binding affinity of the apoprotein significantly. Decreasing the linker length further in 5L-fCzrA effectively destroys one metal site altogether and further reduces DNA binding affinity. However, Zn(II) negatively regulates DNA binding of all fCzrAs, with allosteric coupling free energies (DeltaG(1)(c)) of 4.6, 3.1, and 2.7 kcal mol(-1) for 15L-, 10L-, and 5L-fCzrAs, respectively. Introduction of a single nonliganding H97N substitution into either the N-terminal or C-terminal protomer domain in 10L-fCzrA results in DeltaG(1)(c) = 2.6 kcal mol(-1) or approximately 83% that of 10L-fCzrA; in contrast, homodimeric H97N CzrA gives DeltaG(1)(c) = 0. (1)H-(15)N HSQC spectra acquired for wt-, 10L-fCzrA and H97N 10L-fCzrA in various Zn(II) ligation states reveal that the allosteric change of the protomer domains within the fused dimer is independent and not concerted. Thus, occupancy of a single metal site by Zn(II) introduces asymmetry into the CzrA homodimer that leads to significant allosteric regulation of DNA binding.

Individual metal ligands play distinct functional roles in the zinc sensor Staphylococcus aureus CzrA

Recent studies on metalloregulatory proteins suggest that coordination number/geometry and metal ion availability in a host cytosol are key determinants for biological specificity. Here, we investigate the contribution that individual metal ligands of the alpha5 sensing site of Staphylococcus aureus CzrA (Asp84, His86, His97', and His100') make to in vitro metal ion binding affinity, coordination geometry, and allosteric negative regulation of DNA operator/promoter region binding. All ligand substitution mutants exhibit significantly reduced metal ion binding affinity (K(Me)) by > or =10(3) M(-1). Substitutions of Asp84 and His97 give rise to non-native coordination geometries upon metal binding and are non-functional in allosteric coupling of metal and DNA binding (DeltaG(coupling) approximately 0 kcal mol(-1)). In contrast, His86 and His100 could be readily substituted with potentially liganding (Asp, Glu) and poorly liganding (Asn, Gln) residues with significant native-like tetrahedral metal coordination geometry retained in these mutants, leading to strong functional coupling (DeltaG(coupling) > or = +3.0 kcal mol(-1)). 1H-(15)N heteronuclear single quantum coherence (HSQC) spectra of wild-type and mutant CzrAs reveal that all H86 and H100 substitution mutants undergo 4 degrees structural switching on binding Zn(II), while D84N, H97N and H97D CzrAs do not. Thus, only those variant CzrAs that retain some tetrahedral coordination geometry characteristic of wild-type CzrA upon metal binding are capable of driving 4 degrees structural conformational changes linked to allosteric regulation of DNA binding in vitro, irrespective of the magnitude of K(Me).

Understanding how cells allocate metals using metal sensors and metallochaperones

Each metalloprotein must somehow acquire the correct metal. We review the insights into metal specificity in cells provided by studies of ArsR-SmtB DNA binding, metal-responsive transcriptional repressors, and a bacterial copper chaperone. Cyanobacteria are the one bacterial group that have known enzymatic demand for cytoplasmic copper import. The copper chaperone and ATPases that supply cyanobacterial plastocyanin and cytochrome oxidase are reviewed, along with related ATPases for cobalt and zinc. These studies highlight the contributions of protein-protein interactions to metal speciation. Metal sensors and metallochaperones, along with metal transporters and metal-storage proteins, act in concert not only to supply the correct metals but also to withhold the wrong ones.

Structural Determinants of Metal Selectivity in Prokaryotic Metal-responsive Transcriptional Regulators

Metal ion homeostasis in prokaryotes is maintained by metal-responsive transcriptional regulatory proteins that regulate the transcription of genes encoding proteins responsible for metal detoxification, sequestration, efflux and uptake. These metalloregulatory, or metal sensor proteins, bind a wide range of specific metal ions directly; this in turn, allosterically regulates (enhances or decreases) operator/promoter binding affinity or promoter structure. Recent structural studies reveal five distinct families of metal sensor proteins. The MerR and ArsR/SmtB families regulate the expression of genes required for metal ion detoxification, efflux and sequestration; here, metal binding leads to activation (MerR) or derepression (ArsR/SmtB) of the resistance operon. In contrast, the DtxR, Fur, and NikR families regulate genes encoding proteins involved in metal ion uptake; in these cases, the metal ion functions as a co-repressor in turning off uptake genes under metal-replete conditions. Inspection of the structures of representative members from each metal sensor family reveals several common characteristics: (1) they function as homo-oligomers (either dimers or tetramers); (2) metal-binding ligands are found at subunit interfaces, with ligands derived from more than one protomer; this likely helps drive quaternary structural changes that mediate allosteric coupling between the metal and DNA binding sites; and (3) the primary determinant of metal ion selectivity within each protein family is dictated by the coordination geometry of the metal chelate, with trends consistent with expectations from fundamental inorganic chemistry. This review highlights recent efforts to elucidate the structure of metal sensing chelates and the molecular mechanisms of allosteric coupling in metal sensor proteins.

How to hide zinc in a small protein

Small cysteine-rich proteins (metallothioneins) and related domains of some large proteins (e.g., lysine methyltransferases) bind tri- and tetranuclear zinc clusters with topologies resembling fragments of Zn(II) sulfide minerals. These clusters are ubiquitous in animals, plants, and bacteria. Bacterial metallothioneins can also contain histidines as cluster ligands and embed Zn(II) with a "treble-clef"-like finger fold. This unusual embedded Zn(II) is "hidden" and surprisingly inert toward Zn or Cd exchange. Clearly, proteins can exert fine control over both the thermodynamics and kinetics of zinc binding in thiolate clusters. Genome sequences suggest that related zinc-finger sites are common in a variety of bacteria.

Chimeras of P-type ATPases and their transcriptional regulators: contributions of a cytosolic amino-terminal domain to metal specificity

Zn(2+)-responsive repressor ZiaR and Co(2+)-responsive activator CoaR modulate production of P(1)-type Zn(2+)- (ZiaA) and Co(2+)- (CoaT) ATPases respectively. What dictates metal selectivity? We show that Delta ziaDeltacoa double mutants had similar Zn(2+) resistance to Deltazia single mutants and similar Co(2+) resistance to Deltacoa single mutants. Controlling either ziaA or coaT with opposing regulators restored no resistance to metals sensed by the regulators, but coincident replacement of the deduced cytosolic amino-terminal domain CoaT(N) with ZiaA(N) (in ziaR-(p) ziaA-ziaA(N)coaT) conferred Zn(2+) resistance to DeltaziaDeltacoa, Zn(2+) content was lowered and residual Co(2+) resistance lost. Metal-dependent molar absorptivity under anaerobic conditions revealed that purified ZiaA(N) binds Co(2+) in a pseudotetrahedral two-thiol site, and Co(2+) was displaced by Zn(2+). Thus, the amino-terminal domain of ZiaA inverts the metals exported by zinc-regulated CoaT from Co(2+) to Zn(2+), and this correlates simplistically with metal-binding preferences; K(ZiaAN) Zn(2+) tighter than Co(2+). However, Zn(2+) did not bleach Cu(+)-ZiaA(N), and only Cu(+) co-migrated with ZiaA(N) after competitive binding versus Zn(2+). Bacterial two-hybrid assays that detected interaction between the Cu(+)-metallochaperone Atx1 and the amino-terminal domain of Cu(+)-transporter PacS(N) detected no interaction with the analogous, deduced, ferredoxin-fold subdomain of ZiaA(N). Provided that there is no freely exchangeable cytosolic Cu(+), restricted contact with the Cu(+)-metallochaperone can impose a barrier impairing the formation of otherwise favoured Cu(+)-ZiaA(N) complexes.

Metal-binding stoichiometry and selectivity of the copper chaperone CopZ from Enterococcus hirae

We studied the interaction of several metal ions with the copper chaperone from Enterococcus hirae (EhCopZ). We show that the stoichiometry of the protein-metal complex varies with the experimental conditions used. At high concentration of the protein in a noncoordinating buffer, a dimer, (EhCopZ)2-metal, was formed. The presence of a potentially coordinating molecule L in the solution leads to the formation of a monomeric ternary complex, EhCopZ-Cu-L, where L can be a buffer or a coordinating molecule (glutathione, tris(2-carboxyethyl)phosphine). This was demonstrated in the presence of glutathione by electrospray ionization MS. The presence of a tyrosine close to the metal-binding site allowed us to follow the binding of cadmium to EhCopZ by fluorescence spectroscopy and to determine the corresponding dissociation constant (Kd = 30 nm). Competition experiments were performed with mercury, copper and cobalt, and the corresponding dissociation constants were calculated. A high preference for copper was found, with an upper limit for the dissociation constant of 10-12 m. These results confirm the capacity of EhCopZ to bind copper at very low concentrations in living cells and may provide new clues in the determination of the mechanism of the uptake and transport of copper by the chaperone EhCopZ.

Zinc fingers can act as Zn2+ sensors to regulate transcriptional activation domain function

The yeast Zap1 transcription factor controls the expression of genes involved in zinc accumulation and storage. Zap1 is active in zinc-limited cells and repressed in replete cells. Zap1 has two activation domains, AD1 and AD2, which are both regulated by zinc. AD2 function was mapped to a region containing two Cys2His2 zinc fingers, ZF1 and ZF2, that are not involved in DNA binding. More detailed mapping placed AD2 almost precisely within the endpoints of ZF2, suggesting a role for these fingers in regulating activation domain function. Consistent with this hypothesis, ZF1 and ZF2 bound zinc in vitro but less stably than did zinc fingers involved in DNA binding. Furthermore, mutations predicted to disrupt zinc binding to ZF1 and/or ZF2 rendered AD2 constitutively active. Our results also indicate that the repressed form of AD2 requires an intramolecular interaction between ZF1 and ZF2. These studies suggest that these zinc fingers play an unprecedented role as zinc sensors to control activation domain function.

A cadmium-lead-sensing ArsR-SmtB repressor with novel sensory sites. Complementary metal discrimination by NmtR AND CmtR in a common cytosol

We report a cadmium- and lead-detecting transcriptional repressor from Mycobacterium tuberculosis designated CmtR. Two genes were co-transcribed with cmtR, one encoding a deduced P1 type ATPase. Purified CmtR bound to the cmt operator-promoter, and repression of transcription was lost after introduction of a stop codon into cmtR. Assays of metal-dependent expression from cmt and nmt operator-promoters established that the metal specificity of CmtR in vivo was perfectly inverted relative to the nickel-cobalt sensor NmtR from the same organism, with CmtR totally insensitive to Co(II) or Ni(II) and NmtR totally insensitive to Cd(II) or Pb(II). Absorption spectroscopy of Cd(II)-, Co(II)-, and Ni(II)-substituted CmtR revealed S- to metal-charge-transfer which was absent in NmtR, providing diagnostic metal-difference spectra that discriminated between metal-binding to these two proteins. Ni(II)-binding isothermal titrations of CmtR are complex, with Kapp = 1.8 x 10(4) m(-1) for site1, three orders of magnitude weaker than KNi for NmtR. Mixing equimolar apo-NmtR and apo-CmtR with 0.9 equivalents of Cd(II) gave Cd(II)-dependent difference spectra almost identical to Cd(II)0.9-CmtR. Thus, Cd(II) bound to CmtR in preference to NmtR, whereas the converse was true for Ni(II); this correlates faithfully with and provides a simplistic basis for metal-sensing preferences. In contrast, CmtR and NmtR had similar affinities for Co(II), and alternative explanations for Co(II) sensitivities are invoked. ArsR-SmtB repressors detect metals through derivatives of one or both of two possible allosteric sites at either carboxyl-terminal alpha5 helices or helix alpha3 proximal to the DNA-binding site. Unexpectedly, neither site was required for inducer recognition by CmtR. The mutants in potential metal ligands in, or near, these regions, Cys4, Cys35, Asp79, His81, Asp97, Asp99, Glu105, Glu111, and Glu114, retained both repression and inducer recognition. Crucially, substitution of Cys57, Cys61, and Cys102 with Ser revealed that each of these three residues is obligatory for Cd(II) detection, and this defines completely new sensory sites.

A Metal–Ligand-mediated Intersubunit Allosteric Switch in Related SmtB/ArsR Zinc Sensor Proteins

The origin of metal ion selectivity by members of the SmtB/ArsR family of bacterial metal-sensing transcriptional repressors and the mechanism of negative allosteric regulation of DNA binding is poorly understood. Here, we report that two homologous zinc sensors, Staphylococcus aureus CzrA and cyanobacterial SmtB, are "winged" helix homodimeric DNA-binding proteins that bind Zn(II) to a pair of tetrahedral, interhelical binding sites, with two ligands derived from the alpha5 helix of one subunit, Asp84 O(delta1) (Asp104 in SmtB), His86 N(delta1) (His106), and two derived from the alpha5 helix of the other, His97' N(delta1) (His117') and His100' N(epsilon2) (Glu120'). Formation of the metal chelate drives a quaternary structural switch mediated by an intersubunit hydrogen-binding network that originates with the non-liganding N(epsilon2) face of His97 in CzrA (His117 in SmtB) that stabilizes a low-affinity, DNA-binding conformation. The structure of the Zn(1) SmtB homodimer shows that both metal-binding sites of the dimer must be occupied for the quaternary structural switch to occur. Thus, a critical zinc-ligating histidine residue obligatorily couples formation of the metal-sensing coordination chelate to changes in the conformation and dynamics of the putative DNA-binding helices.

The SmtB/ArsR family of metalloregulatory transcriptional repressors: Structural insights into prokaryotic metal resistance

The SmtB/ArsR family of prokaryotic metalloregulatory transcriptional repressors represses the expression of operons linked to stress-inducing concentrations of di- and multivalent heavy metal ions. Derepression results from direct binding of metal ions by these homodimeric "metal sensor" proteins. An evolutionary analysis, coupled with comparative structural and spectroscopic studies of six SmtB/ArsR family members, suggests a unifying "theme and variations" model, in which individual members have evolved distinct metal selectivity profiles by alteration of one or both of two structurally distinct metal coordination sites. These two metal sites are designated alpha3N (or alpha3) and alpha5 (or alpha5C), named for the location of the metal binding ligands within the known or predicted secondary structure of individual family members. The alpha3N/alpha3 sensors, represented by Staphylococcus aureus pI258 CadC, Listeria monocytogenes CadC and Escherichia coli ArsR, form cysteine thiolate-rich coordination complexes (S(3) or S(4)) with thiophilic heavy metal pollutants including Cd(II), Pb(II), Bi(III) and As(III) via inter-subunit coordination by ligands derived from the alpha3 helix and the N-terminal "arm" (CadCs) or from the alpha3 helix only (ArsRs). The alpha5/alpha5C sensors Synechococcus SmtB, Synechocystis ZiaR, S. aureus CzrA, and Mycobacterium tuberculosis NmtR form metal complexes with biologically required metal ions Zn(II), Co(II) and Ni(II) characterized by four or more coordination bonds to a mixture of histidine and carboxylate ligands derived from the C-terminal alpha5 helices on opposite subunits. Direct binding of metal ions to either the alpha3N or alpha5 sites leads to strong, negative allosteric regulation of repressor operator/promoter binding affinity, consistent with a simple model for derepression. We hypothesize that distinct allosteric pathways for metal sensing have co-evolved with metal specificities of distinct alpha3N and alpha5 coordination complexes.

A novel zinc snap motif conveys structural stability to 3-methyladenine DNA glycosylase I

The Escherichia coli 3-methyladenine DNA glycosylase I (TAG) is a DNA repair enzyme that excises 3-methyladenine in DNA and is the smallest member of the helix-hairpin-helix (HhH) superfamily of DNA glycosylases. Despite many studies over the last 25 years, there has been no suggestion that TAG was a metalloprotein. However, here we establish by heteronuclear NMR and other spectroscopic methods that TAG binds 1 eq of Zn2+ extremely tightly. A family of refined NMR structures shows that 4 conserved residues contributed from the amino- and carboxyl-terminal regions of TAG (Cys4, His17, His175, and Cys179) form a Zn2+ binding site. The Zn2+ ion serves to tether the otherwise unstructured amino- and carboxyl-terminal regions of TAG. We propose that this unexpected "zinc snap" motif in the TAG family (CX(12-17)HX(approximately 150)HX(3)C) serves to stabilize the HhH domain thereby mimicking the functional role of protein-protein interactions in larger HhH superfamily members.

Transition metal speciation in the cell: insights from the chemistry of metal ion receptors

The essential transition metal ions are avidly accumulated by cells, yet they have two faces: They are put to use as required cofactors, but they also can catalyze cytotoxic reactions. Several families of proteins are emerging that control the activity of intracellular metal ions and help confine them to vital roles. These include integral transmembrane transporters, metalloregulatory sensors, and diffusible cytoplasmic metallochaperone proteins that protect and guide metal ions to targets. It is becoming clear that many of these proteins use atypical coordination chemistry to accomplish their unique goals. The different coordination numbers, types of coordinating residues, and solvent accessibilities of these sites are providing insight into the inorganic chemistry of the cytoplasm.

Structural elements of metal selectivity in metal sensor proteins

Staphylococcus aureus CzrA and Mycobacterium tuberculosis NmtR are homologous zinccobalt-responsive and nickelcobalt-responsive transcriptional repressors in vivo, respectively, and members of the ArsRSmtB superfamily of prokaryotic metal sensor proteins. We show here that Zn(II) is the most potent negative allosteric regulator of czr operatorpromoter binding in vitro with the trend Zn(II)>Co(II)Ni(II), whereas the opposite holds for the binding of NmtR to the nmt operatorpromoter, Ni(II)>Co(II)>Zn(II). Characterization of the metal coordination complexes of CzrA and NmtR by UVvisible and x-ray absorption spectroscopies reveals that metals that form four-coordinate tetrahedral complexes with CzrA [Zn(II) and Co(II)] are potent regulators of DNA binding, whereas metals that form five- or six-coordinate complexes with NmtR [Ni(II) and Co(II)] are the strongest allosteric regulators in this system. Strikingly, the Zn(II) coordination complexes of CzrA and NmtR cannot be distinguished from one another by x-ray absorption spectroscopy, with the best fit a His-3-carboxylate complex in both cases. Inspection of the primary structures of CzrA and NmtR, coupled with previous functional data, suggests that three conserved His and one Asp from the C-terminal alpha5 helix donate ligands to create a four-coordinate complex in both CzrA and NmtR, with NmtR uniquely capable of expanding its coordination number in the Ni(II) and Co(II) complexes by recruiting additional His ligands from a C-terminal extension of the alpha5 helix.

The soft metal ion binding sites in the Staphylococcus aureus pI258 CadC Cd(II)/Pb(II)/Zn(II)-responsive repressor are formed between subunits of the homodimer

The Staphylococcus aureus plasmid pI258 CadC is a homodimeric repressor that binds Cd(II), Pb(II), and Zn(II) and regulates expression of the cadAC operon. CadC binds two Cd(II) ions per dimer, with a tetrathiolate binding site composed of residues Cys(7), Cys(11), Cys(58), and Cys(60). It is not known whether each site consists of residues from a single monomer or from residues contributed by both subunits. To examine whether Cys(7) and Cys(11) are spatially proximate to Cys(58) and Cys(60) of the same subunit or of the other subunit, homodimers with the same cysteine mutation in each subunit and heterodimers containing different cysteine mutations in the two subunits were reacted with 4,6-bis(bromomethyl)-3,7-dimethyl-1,5-diazabicyclo[3.3.0]octa-3,6-diene-2,8-dione, which cross-links thiol groups that are within 3-6 A of each other. Cys(7) or Cys(11) cross-linked only with Cys(58) or Cys(60) on the other subunit. The data demonstrate that Cys(7) and Cys(11) from one monomer are within 3-6 A of either Cys(58) or Cys(60) in the other monomer. The results of this study strongly indicate that each of the two Cd(II) binding sites in the CadC homodimer is composed of Cys(7) and Cys(11) from one monomer and Cys(58) and Cys(60) from the other monomer.

A nickel-cobalt-sensing ArsR-SmtB family repressor. Contributions of cytosol and effector binding sites to metal selectivity

NmtR from Mycobacterium tuberculosis is a new member of the ArsR-SmtB family of metal sensor transcriptional repressors. NmtR binds to the operator-promoter of a gene encoding a P(1) type ATPase (NmtA), repressing transcription in vivo except in medium supplemented with nickel or, to some extent, cobalt. In a cyanobacterial host, Synechococcus PCC 7942 strain R2-PIM8(smt), NmtR-mediated repression is alleviated by cobalt but not nickel or zinc addition, while the related sensor SmtB responds exclusively to zinc. Quantification of the number of atoms of nickel per cell shows that NmtR nickel sensitivity correlates with cytosolic nickel contents. Differential metal discrimination in a common cytosol by SmtB (zinc) and NmtR (cobalt) is not simply explained by affinities at equilibrium; although NmtR does bind nickel substantially more tightly than SmtB, it has a higher affinity for zinc than for cobalt and binds cobalt more weakly than SmtB. SmtB is known to bind and sense zinc at interhelical four-coordinate, tetrahedral sites across the C-terminal alpha 5 helices, while absorption spectroscopy of Co(II)- and Ni(II)-substituted NmtR reveals five- and six-coordinate metal complexes. Site-directed mutagenesis identifies six potential cobalt/nickel ligands that are obligatory for inducer recognition but not repression by NmtR, four of which (Asp(91), His(93), His(104), His(107)) align with alpha 5 ligands of SmtB with two additional His provided by a carboxyl-terminal "extension" (designated alpha 5C). Gel retardation assays reveal that zinc does not allosterically regulate NmtR-DNA binding at concentrations where lower affinity cobalt does. These data suggest that two additional ligands form hexacoordinate metal complexes and are crucial for driving allosteric regulation of DNA binding by NmtR, thereby allowing NmtR to preferentially sense metals that favor higher coordination numbers relative to SmtB.

Sensing nickel. NikRs with two pockets

NikR represses expression of a nickel transporter in response to elevated levels of Ni(II). Recent results suggest that repression is elicited by binding of nickel to a high-affinity site, but a low-affinity binding pocket may also play a role.

Zinc ions inhibit the protein-DNA complex formation between cyanobacterial transcription factor SmtB and its recognition DNA sequences

SmtB is a trans-acting dimeric repressor of the metal-regulated smtA gene, and the release of SmtB from the smtA operator/promoter region is essential for the tolerance to Zn(2+) stress by SmtA expression. Gel retardation assaying demonstrated that different sizes of SmtB-DNA complexes were formed depending on the DNA sequences, and the amounts of these complexes decreased in the presence of Zn(2+). Here, we present the first direct evidence that Zn(2+ )(>4 micro M) inhibits the SmtB-DNA complex formation in vitro, which ensures the physiological functions of SmtB as a Zn(2+) sensor and a transcription factor.

Conversion of antennapedia homeodomain to zinc finger-like domain: Zn(II)-induced change in protein conformation and DNA binding

From the standpoint of protein dynamics and metalloprotein design, it is interesting to create an artificial protein which induces structural change and regulates its function by metal-ion binding. We engineered a novel protein, "Antennafinger (Ant-F)", whose structure and function can be controlled with Zn(II), by introducing the consensus sequence of a Cys(2)His(2)-type zinc finger protein into a non-metalloprotein scaffold, an Antennapedia homeodomain mutant (Ant-wt), selected using a motif-searching system. The circular dichroism studies demonstrate that Ant-F has secondary structures similar to Ant-wt and also changes its conformation due to Zn(II)-binding. The optical absorption spectra of the Co(II) complexes of Ant-F and its derivative proteins suggest that the geometry of the metal center of holo-Ant-F is tetrahedral and that the mutated Cys(2)His(2) residues are involved in the complex formation. In addition, the gel mobility shift assay reveals that the DNA binding activity of Ant-F can be regulated through Zn(II)-induced structural alteration. These results provide valuable information about the dynamic properties of proteins and a novel concept for metalloprotein design.

Both metal binding sites in the homodimer are required for metalloregulation by the CadC repressor

The cadCA operon of plasmid pI258, which confers resistance to the soft metals Cd(II), Pb(II) and Zn(II), is regulated by CadC, a metal-responsive transcriptional repressor. CadC is a 27.6 kDa homodimer composed of two 122-residue monomers. Three cysteine residues, Cys-7, Cys-58 and Cys-60, have been shown to be required for sensing soft metals. Thus, the repressor has two potential inducer binding sites, one on each monomer. However, it is not known whether both binding sites are required for derepression or whether binding of metal to a single site would result in transcript. In this study, heterodimers were purified in which one binding site was wild type and the other had substitutions of the cysteine residues. The wild type-mutant heterodimers retained the ability to bind to cad operator/promoter DNA but did not dissociate from the DNA upon addition of soft metal ions. The results indicate that both subunits in the dimer must have functional metal binding sites for metal sensing to lead to derepression

Structural chemistry of a green fluorescent protein Zn biosensor

We designed a green fluorescent protein mutant (BFPms1) that preferentially binds Zn(II) (enhancing fluorescence intensity) and Cu(II) (quenching fluorescence) directly to a chromophore ligand that resembles a dipyrrole unit of a porphyrin. Crystallographic structure determination of apo, Zn(II)-bound, and Cu(II)-bound BFPms1 to better than 1.5 A resolution allowed us to refine metal centers without geometric restraints, to calculate experimental standard uncertainty errors for bond lengths and angles, and to model thermal displacement parameters anisotropically. The BFPms1 Zn(II) site (KD = 50 muM) displays distorted trigonal bipyrimidal geometry, with Zn(II) binding to Glu222, to a water molecule, and tridentate to the chromophore ligand. In contrast, the BFPms1 Cu(II) site (KD = 24 muM) exhibits square planar geometry similar to metalated porphyrins, with Cu(II) binding to the chromophore chelate and Glu222. The apo structure reveals a large electropositive region near the designed metal insertion channel, suggesting a basis for the measured metal cation binding kinetics. The preorganized tridentate ligand is accommodated in both coordination geometries by a 0.4 A difference between the Zn and Cu positions and by distinct rearrangements of Glu222. The highly accurate metal ligand bond lengths reveal different protonation states for the same oxygen bound to Zn vs Cu, with implications for the observed metal ion specificity. Crystallographic anisotropic thermal factor analysis validates metal ion rigidification of the chromophore in enhancement of fluorescence intensity upon Zn(II) binding. Thus, our high-resolution structures reveal how structure-based design has effectively linked selective metal binding to changes in fluorescent properties. Furthermore, this protein Zn(II) biosensor provides a prototype suitable for further optimization by directed evolution to generate metalloprotein variants with desirable physical or biochemical properties.

Interrelationships among biological activity, disulfide bonds, secondary structure, and metal ion binding for a chemically synthesized 34-amino-acid peptide derived from alpha-fetoprotein

A 34-amino-acid peptide has been chemically synthesized based on a sequence from human alpha-fetoprotein. The purified peptide is active in anti-growth assays when freshly prepared in pH 7.4 buffer at 0.20 g/l, but this peptide slowly becomes inactive. This functional change is proven by mass spectrometry to be triggered by the formation of an intrapeptide disulfide bond between the two cysteine residues on the peptide. Interpeptide cross-linking does not occur. The active and inactive forms of the peptide have almost identical secondary structures as shown by circular dichroism (CD). Zinc ions bind to the active peptide and completely prevents formation of the inactive form. Cobalt(II) ions also bind to the peptide, and the UV-Vis absorption spectrum of the cobalt-peptide complex shows that: (1) a near-UV sulfur-to-metal-ion charge-transfer band had a molar extinction coefficient consistent with two thiolate bonds to Co(II); (2) the lowest-energy visible d-d transition maximum at 659 nm, also, demonstrated that the two cysteine residues are ligands for the metal ion; (3) the d-d molar extinction coefficient showed that the metal ion-ligand complex was in a distorted tetrahedral symmetry. The peptide has two cysteines, and it is speculated that the other two metal ion ligands might be the two histidines. The Zn(II)- and Co(II)-peptide complexes had similar peptide conformations as indicated by their ultraviolet CD spectra, which differed very slightly from that of the free peptide. Surprisingly, the cobalt ions acted in the reverse of the zinc ions in that, instead of stabilizing anti-growth form of the peptide, they catalyzed its loss. Metal ion control of peptide function is a saliently interesting concept. Calcium ions, in the conditions studied, apparently do not bind to the peptide. Trifluoroethanol and temperature (60 degrees C) affected the secondary structure of the peptide, and the peptide was found capable of assuming various conformations in solution. This conformational flexibility may possibly be related to the biological activity of the peptide.

Metal response element (MRE)-binding transcription factor-1 (MTF-1): structure, function, and regulation

Metal-responsive control of the expression of genes involved in metal metabolism and metal homeostasis allows an organism to tightly regulate the free or bioavailable concentration of beneficial metal ions, such as zinc, copper, and iron, within an acceptable range, while efficiently removing nonbeneficial or toxic metals. Emerging evidence also suggests that metal homeostasis is intimately coupled to the oxidative stress response in many cell types. The expression of genes that encode metallothioneins in all vertebrate cells is strongly induced by potentially toxic concentrations of zinc and cadmium, as well as in response to strong oxidizing agents, including hydrogen peroxide. This induction requires a cis-acting DNA element, termed a metal response element (MRE), and MRE-binding transcription factor-1 (MTF-1), a Cys2-His2 zinc finger protein. This review summarizes recent progress that has been made toward understanding the structure, function, and metalloregulation of mammalian MTF-1.

Femtomolar sensitivity of metalloregulatory proteins controlling zinc homeostasis

Intracellular zinc is thought to be available in a cytosolic pool of free or loosely bound Zn(II) ions in the micromolar to picomolar range. To test this, we determined the mechanism of zinc sensors that control metal uptake or export in Escherichia coli and calibrated their response against the thermodynamically defined free zinc concentration. Whereas the cellular zinc quota is millimolar, free Zn(II) concentrations that trigger transcription of zinc uptake or efflux machinery are femtomolar, or six orders of magnitude less than one atom per cell. This is not consistent with a cytosolic pool of free Zn(II) and suggests an extraordinary intracellular zinc-binding capacity. Thus, cells exert tight control over cytosolic metal concentrations, even for relatively low-toxicity metals such as zinc.

Role of cysteinyl residues in sensing Pb(II), Cd(II), and Zn(II) by the plasmid pI258 CadC repressor

The cadCA operon of Staphylococcus aureus plasmid pI258 confers resistance to salts of the soft metals lead, cadmium, and zinc. The operon is regulated by CadC, a member of the ArsR family of metal-responsive transcriptional repressors. In this study the role of the five cysteine residues of CadC in soft metal ion sensing was investigated. Cys-7, Cys-11, Cys-52, Cys-58, and Cys-60 were changed individually to glycine or serine residues. The effect of the cadC mutations was examined in Escherichia coli using a green fluorescent protein reporter system. None of the mutations affected the ability of CadC to repress gfp expression. Neither Cys-11 nor Cys-52 was required for in vivo response to Pb(II), Zn(II), or Cd(II). Cys-7, Cys-58, or Cys-60 mutations each reduced or eliminated soft metal sensing. Wild-type and mutant CadC proteins were purified, and the effect of the substitutions on DNA binding was determined using a restriction enzyme protection assay. Binding of wild-type CadC protected cad operator DNA from digestion at the single SspI site, and the addition of Pb(II), Zn(II), or Cd(II) resulted in deprotection. Chemical modification of the cysteine residues in CadC had no effect on protection but eliminated deprotection. C11G and C52G proteins exhibited wild-type properties in vitro. C7G, C58S, and C60G proteins were able to be protected from SspI digestion but had reduced responses to soft metal ions. The results indicate that Cys-7, Cys-58, and Cys-60 are involved in sensing those soft metals and suggest that they are ligands to Pb(II), Zn(II), and Cd(II).