Metal-binding characteristics of the amino-terminal domain of ZntA: binding of lead is different compared to cadmium and zinc

ZntA from Escherichia coli, a P1-type ATPase, specifically transports Pb(II), Zn(II), and Cd(II). Most P1-type ATPases have an N-terminal domain that contains one or more copies of the conserved metal-binding motif, GXXCXXC. In ZntA, the N-terminal domain has approximately 120 residues with a single GXXCXXC motif, as well as four additional cysteine residues as part of the CCCDGAC motif. The metal-binding specificity and affinity of this domain in ZntA was investigated. Isolated proteins, N1-ZntA and N2-ZntA, containing residues 1-111 and 47-111 of ZntA, respectively, were characterized. N1-ZntA has both the CCCDGAC and GXXCXXC motifs, while N2-ZntA has only the GXXCXXC motif. ICP-MS measurements showed that N1-ZntA can bind both divalent metal ions such as Cd(II), Pb(II), and Zn(II) and monovalent metal ions such as Ag(I), with a stoichiometry of 1. N2-ZntA can bind Zn(II) and Cd(II) with a stoichiometry of 1 but not Pb(II). The affinity of N1-ZntA for Zn(II), Pb(II), and Cd(II) was measured by competition titration with metallochromic indicators. Association constants of approximately 10(8) M(-)(1) were obtained for Zn(II), Pb(II), and Cd(II) binding to N1-ZntA. To investigate whether the CCCDGAC sequence has an important role in binding specifically Pb(II), a mutant of ZntA, which lacked the first 46 residues, was constructed. This mutant, Delta46-ZntA, had the same activity as wtZntA with respect to Cd(II) and Zn(II). However, its activity with Pb(II) was similar to the mutant DeltaN-ZntA, which lacks the entire N-terminal domain (Mitra, B., and Sharma, R. (2001) Biochemistry 40, 7694-7699). Thus, binding of Pb(II) appears to involve different ligands, and possibly geometry, compared to Cd(II) and Zn(II).     

Functional analysis of chimeric proteins of the Wilson Cu(I)-ATPase (ATP7B) and ZntA, a Pb(II)/Zn(II)/Cd(II)-ATPase from Escherichia coli

ATP7B, the Wilson disease-associated Cu(I)-transporter, and ZntA from Escherichia coli are soft metal P1-type ATPases with mutually exclusive metal ion substrates. P1-type ATPases have a distinctive amino-terminal domain containing the conserved metal-binding motif GXXCXXC. ZntA has one copy of this motif while ATP7B has six copies. The effect of interchanging the amino-terminal domains of ATP7B and ZntA was investigated. Chimeric proteins were constructed in which either the entire amino-terminal domain of ATP7B or only its sixth metal-binding motif replaced the amino-terminal domain of ZntA. Both chimeras conferred resistance to lead, zinc, and cadmium salts but not to copper salts. The purified chimeras displayed activity with lead, cadmium, zinc, and mercury, which are substrates of ZntA. There was no activity with copper or silver, which are substrates of ATP7B. The chimeras were 2-3-fold less active than ZntA. Thus, the amino-terminal domain of P1-type ATPases cannot alter the metal specificity determined by the transmembrane segment. Also, these results suggest that this domain interacts with the rest of the transporter in a metal ion-specific manner; the amino-terminal domain of ATP7B cannot replace that of ZntA in restoring full catalytic activity.     

Kinetic analysis of metal binding to the amino-terminal domain of ZntA by monitoring metal-thiolate charge-transfer complexes

ZntA, a P(1B)-ATPase transporter from Escherichia coli, mediates resistance specifically to Pb(2+), Zn(2+), and Cd(2+) by active efflux. ZntA has a hydrophilic N-terminal domain that binds one metal ion. This domain, approximately 120 residues long, contains the GXXCXXC motif that has been shown to be the binding site for metal ions such as Cu(+) and Zn(2+) in P(1B)-type ATPases, and an additional cysteine-rich motif, CCCDGAC. We report here that binding of Pb(2+) and Cd(2+) to this domain produces changes in the absorbance spectrum in the 250-400 nm range indicative of metal-thiolate charge-transfer complexes. The spectral changes indicate that only two cysteines are ligands to Cd(2+), but three or more cysteines are involved in binding Pb(2+); this confirms earlier results that the GXXCXXC sequence is not sufficient to bind Pb(2+), which likely involves residues from the CCCDGAC motif. The absorbance changes were used to measure metal binding kinetics of the N-terminal domain using stopped-flow techniques. Binding was described by simple second-order kinetics with a rate constant, k(on), of approximately 10(6)-10(7) M(-)(1) s(-)(1), at 4 degrees C. The activation energy of binding is similar for both Pb(2+) and Cd(2+); however, the entropy change is greater for Pb(2+). The surprisingly large rate constant for metal binding to the N-terminal domain of ZntA, compared to its low turnover rate, indicates that this step is not rate limiting in the overall transport mechanism. These results, in conjunction with earlier studies, suggest that metal binding to the transmembrane site in ZntA or metal release from the transporter is the slow step in the reaction cycle.     

The ATP hydrolytic activity of purified ZntA, a Pb(II)/Cd(II)/Zn(II)-translocating ATPase from Escherichia coli

ZntA, a soft metal-translocating P1-type ATPase from Escherichia coli, confers resistance to Pb(II), Cd(II), and Zn(II). ZntA was expressed as a histidyl-tagged protein, solubilized from membranes with Triton X-100, and purified to homogeneity. The soft metal-dependent ATP hydrolysis activity of purified ZntA was characterized. The activity was specific for Pb(II), Cd(II), Zn(II), and Hg(II), with the highest activity obtained when the metals were present as thiolate complexes of cysteine or glutathione. The maximal ATPase activity of ZntA was approximately 3 micromol/(mg x min) obtained with the Pb(II)-thiolate complex. In the absence of thiolates, Cd(II) inhibits ZntA above pH 6, whereas the Cd(II)-thiolate complexes stimulate activity, suggesting that a metal-thiolate complex is the true substrate in vivo. These results are consistent with the physiological role of ZntA as mediator of resistance to toxic concentrations of the divalent soft metals, Pb(II), Cd(II), and Zn(II), by ATP-dependent efflux. Our results confirm that ZntA is the first Pb(II)-dependent ATPase discovered to date.     

The metal specificity and selectivity of ZntA from Escherichia coli using the acylphosphate intermediate

ZntA from Escherichia coli is a P-type ATPase that confers resistance to Pb(II), Zn(II), and Cd(II) in vivo. We had previously shown that purified ZntA shows ATP hydrolysis activity with the metal ions Pb(II), Zn(II), and Cd(II). In this study, we utilized the acylphosphate formation activity of ZntA to further investigate the substrate specificity of ZntA. The site of phosphorylation was Asp-436, as expected from sequence alignments. We show that in addition to Pb(II), Zn(II), and Cd(II), ZntA is active with Ni(II), Co(II), and Cu(II), but not with Cu(I) and Ag(I). Thus, ZntA is specific for a broad range of divalent soft metal ions. The activities with Ni(II), Co(II), and Cu(II) are extremely low; the activities with these non-physiological substrates are 10-20-fold lower compared with the values obtained with Pb(II), Zn(II), and Cd(II). Similar results were obtained with DeltaN-ZntA, a ZntA derivative lacking the amino-terminal metal binding domain. By characterizing the acylphosphate formation reaction in ZntA in detail, we show that a step prior to enzyme phosphorylation, most likely the metal ion binding step, is the slow step in the reaction mechanism in ZntA. The low activities with Ni(II), Co(II), and Cu(II) are because of a further decrease in the rate of binding of these metal ions. Thus, metal ion selectivity in ZntA and possibly other P1-type ATPases is based on the charge and the ligand preference of particular metal ions but not on their size.     

A new zinc-protein coordination site in intracellular metal trafficking: solution structure of the Apo and Zn(II) forms of ZntA(46-118)

Zinc, a metal ion that functions in a wide variety of catalytic and structural sites in metalloproteins, is shown here to adopt a novel coordination environment in the Escherichia coli transport protein ZntA. The ZntA protein is a P-type ATPase that pumps zinc out of the cytoplasm and into the periplasm. It is physiologically selective for Zn(II) and functions with metalloregulatory proteins in the cell to keep the zinc quota within strict limits. Yet, the N-terminal cytoplasmic domain contains a region that is highly homologous to the yeast Cu(I) metallochaperone Atx1. To investigate how the structure of this region may influence its function, this fragment, containing residues 46-118, has been cloned out of the gene and overexpressed. We report here the solution structure of this fragment as determined by NMR. Both the apo and Zn(II)-ZntA(46-118) structures have been determined. It contains a previously unknown protein coordination site for zinc that includes two cysteine residues, Cys59 and Cys62, and a carboxylate residue, Asp58. The solvent accessibility of this site is also remarkably high, a feature that increasingly appears to be a characteristic of domains of heavy metal ion transport proteins. The participation of Asp58 in this ZntA metal ion binding site may play an important role in modulating the relative affinities and metal exchange rates for Zn(II)/Pb(II)/Cd(II) as compared with other P-type ATPases, which are selective for Cu(I) or Ag(I).     

Conservative and nonconservative mutations of the transmembrane CPC motif in ZntA: effect on metal selectivity and activity

ZntA from Escherichia coli belongs to the P1B-ATPase transporter family and mediates resistance to toxic levels of selected divalent metal ions. P1B-type ATPases can be divided into subgroups based on substrate cation selectivity. ZntA has the highest selectivity for Pb2+, followed by Zn2+ and Cd2+; it also shows low levels of activity with Cu2+, Ni2+, and Co2+. It has two high-affinity metal-binding sites, one each in the N-terminus and the transmembrane domains. Ligands to the transmembrane metal site in ZntA include the cysteine residues of the conserved 392CPC394 motif in the sixth transmembrane helix. Pro393 is invariant in all P-type ATPases. For ZntA homologues with different metal ion selectivity, the cysteines are replaced by serine, histidine, and threonine. To test the effect on activity and metal ion selectivity, single alanine, histidine, and serine substitutions at Cys392 or Cys394 in ZntA were characterized, as well as double substitutions of both cysteines by histidine or serine. P393A was also characterized. C392A, C394A, and P393A lost the ability to bind a metal ion with high affinity in the transmembrane domain. Histidine and serine substitutions at Cys392 and Cys394 resulted in loss of binding of Pb2+ at the transmembrane site, indicating that both cysteines of the CPC motif are required for binding Pb2+ with high affinity in ZntA homologues. However, C392H, C392S, C394H, C394S, C392S/C394S, and C392H/C394H could bind other divalent metal ions at the transmembrane site and retained low but measurable activity. Interestingly, these mutants lost the predominant selectivity for Zn2+ and Cd2+ shown by wtZntA. Therefore, conserved residues contribute to metal selectivity by supplying ligands that bind metal ions not only with high affinity, as for Pb2+, but also with the most favorable binding geometry that results in efficient catalysis.     

A zinc(II)/lead(II)/cadmium(II)-inducible operon from the Cyanobacterium anabaena is regulated by AztR, an alpha3N ArsR/SmtB metalloregulator

A novel Zn(II)/Pb(II)/Cd(II)-responsive operon that consists of genes encoding a Zn(II)/Pb(II) CPx-ATPase efflux pump (aztA) and a Zn(II)/Cd(II)/Pb(II)-specific SmtB/ArsR family repressor (aztR) has been identified and characterized from the cyanobacterium Anabaena PCC 7120. In vivo real time quantitative RT-PCR assays reveal that both aztR and aztA expression are induced by divalent metal ions Zn(II), Cd(II), and Pb(II) but not by other divalent [Co(II), Ni(II)] or monovalent metal ions [Cu(I) and Ag(I)]. The introduction of a plasmid containing the azt operon into a Zn(II)/Cd(II)-hypersensitive Escherichia coli strain GG48 functionally restores Zn(II) and Pb(II) resistance with a limited effect on Cd(II) resistance. Gel mobility shift assays and aztR O/P-lacZ induction experiments confirm that AztR is the metal-regulated repressor of this operon. In vitro biochemical and mutagenesis studies indicate that AztR contains a sole metal-binding site, designated the alpha3N site, that binds Zn(II), Cd(II), and Pb(II) with a high affinity. Optical absorption spectra of Co(II)- and Cd(II)-substituted AztR and (113)Cd NMR spectroscopy of (113)Cd(II)-substituted AztR reveal that the sole alpha3N site in AztR is a CadC-like distorted tetrahedral S(3)(N,O) metal site. The first metal-coordination shell in the AztR alpha3N site differs from other alpha3N family members that sense Cd(II)/Pb(II) and those alpha5 repressors that sense Zn(II)/Co(II). Our results reveal that the alpha3N site in AztR mediates derepression of the azt operon in the presence of Zn(II), as well as Cd(II) and Pb(II); this might have provided Anabaena with an evolutionary advantage to adapt to heavy-metal-rich environments, while maintaining homeostasis of an essential metal ion, Zn(II).     

Metal-binding affinity of the transmembrane site in ZntA: implications for metal selectivity

ZntA, a P1B-type ATPase, confers resistance specifically to Pb2+, Zn2+, and Cd2 in Escherichia coli. Inductively coupled plasma mass spectrometry measurements show that ZntA binds two metal ions with high affinity, one in the N-terminal domain and another in the transmembrane domain. Both sites can bind monovalent and divalent metal ions. Two proteins, deltaN-ZntA, in which the N-terminal domain is deleted, and C59A/C62A-ZntA, in which the N-terminal metal-binding site is disabled by site-specific mutagenesis, can only bind one metal ion. Because C59A/C62A-ZntA can bind a metal ion at the transmembrane site, the N-terminal domain does not block direct access of metal ions to it from the cytosol. A third mutant protein, C392A/C394A-ZntA, in which cysteines from the conserved CPC motif in transmembrane helix 6 are altered, binds metal ions only at the N-terminal site, indicating that both these cysteines form part of the transmembrane site. The metal affinity of the transmembrane site was determined in deltaN-ZntA and C59A/C62A-ZntA by competition titration using a metal ion indicator and by tryptophan fluorescence quenching. The binding affinity for the physiological substrates, Zn2+, Pb2+, and Cd2+, as well as for the extremely poor substrates, Cu2+, Ni2+, and Co2+, range from 10(6)-10(10) M(-1), and does not correlate with the metal selectivity shown by ZntA. Selectivity in ZntA possibly results from differences in metal-binding geometry that produce different structural responses. The affinity of the transmembrane site for metal ions is of similar magnitude to that of the N-terminal site [Liu J. et al. (2005) Biochemistry 44, 5159-5167]; thus, metal transfer between them would be facile.     

Functional expression of a bacterial heavy metal transporter in Arabidopsis enhances resistance to and decreases uptake of heavy metals

Large parts of agricultural soil are contaminated with lead (Pb) and cadmium (Cd). Although most environments are not heavily contaminated, the low levels observed nonetheless pose a high risk of heavy metal accumulation in the food chain. Therefore, approaches to develop plants with reduced heavy metal uptake are important. Recently, many transgenic plants with increased heavy metal resistance and uptake of heavy metals were developed for the purpose of phytoremediation. However, to reduce heavy metal in the food chain, plants that transfer less heavy metals to the shoot are required. We tested whether an Escherichia coli gene, ZntA, which encodes a Pb(II)/Cd(II)/Zn(II) pump, could be useful for developing plants with reduced heavy metal content. Yeast cells transformed with this gene had improved resistance to Pb(II) and Cd(II). In Arabidopsis plants transformed with ZntA, ZntA was localized at the plasma membrane and improved the resistance of the plants to Pb(II) and Cd(II). The shoots of the transgenic plants had decreased Pb and Cd content. Moreover, the transgenic protoplasts showed lower accumulation of Cd and faster release of preloaded Cd than wild-type protoplasts. These results show that a bacterial transporter gene, ZntA, can be functionally expressed in plant cells, and that that it may be useful for the development of crop plants that are safe from heavy metal contamination.     

The metal-binding sites of the zinc-transporting P-type ATPase of Escherichia coli. Lys693 and Asp714 in the seventh and eighth transmembrane segments of ZntA contribute to the coupling of metal binding and ATPase activity

ZntA is a P-type ATPase which transports Zn(2+), Pb(2+) and Cd(2+) out of the cell. Two cysteine-containing motifs, CAAC near the N-terminus and CPC in transmembrane helix 6, are involved in binding of the translocated metal. We have studied these motifs by mutating the cysteines to serines. The roles of two other possible metal-binding residues, K(693) and D(714), in transmembrane helices 7 and 8, were also addressed. The mutation CAAC-->SAAS reduces the ATPase activity by 50%. The SAAS mutant is phosphorylated with ATP almost as efficiently as the wild type. However, its phosphorylation with P(i) is poorer than that of the wild type and its dephosphorylation rate is faster than that of the wild type ATPase. The CPC-->SPS mutant is inactive but residual phosphorylation with ATP could still be observed. The most important findings of this work deal with the prospective metal-binding residues K(693) and D(714): the substitution K693N eliminates the Zn(2+)-stimulated ATPase activity completely, although significant Zn(2+)-dependent phosphorylation by ATP remains. The K693N ATPase is hyperphosphorylated by P(i). ZntA carrying the change D714M has strong metal-independent ATPase activity and is very weakly phosphorylated both by ATP and P(i). In conclusion, K(693) and D(714) are functionally essential and appear to contribute to the metal specificity of ZntA, most probably by being parts of the metal-binding site made up by the CPC motif.     

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.     

Preference of Cd(II) and Zn(II) for the two metal sites in Bacillus cereus beta-lactamase II: A perturbed angular correlation of gamma-rays spectroscopic study

Cd-substituted forms of the Bacillus cereus metallo-beta-lactamases (BCII) were studied by perturbed angular correlation of gamma-rays (PAC) spectroscopy. At very low [Cd]:[apo-beta-lactamase] ratios, two nuclear quadrupole interactions (NQI) were detected. For [Cd]:[apo-beta-lactamase] ratios between 0.8 and 3.0, two new NQIs appear, and the spectra show that up to 2 cadmium ions can be bound per molecule of apoenzyme. These results show the existence of two interacting Cd-binding sites in BCII. The relative populations of the two NQIs found at low [Cd]:[apo-beta-lactamase] ratios yielded a 1:3 ratio for the microscopic dissociation constants of the two different metal sites (when only one cadmium ion is bound). X-ray diffraction data at pH 7.5 demonstrate that also for Zn(II) two binding sites exist, which may be bridged by a solvent molecule. The measured NQIs could be assigned to the site with three histidines as metal ligands (three-His site) and to the site with histidine, cysteine, and aspartic acid as metal ligands (Cys site), respectively, by PAC measurements on the Cys168Ala mutant enzyme. This assignment shows that cadmium ions preferentially bind to the Cys site. This is in contrast to the preference of Zn(II) in the hybrid Zn(II)Cd(II) enzyme, where an analysis of the corresponding PAC spectrum showed that Cd(II) occupied the Cys site, whereby Zn(II) occupied the site with three histidines. The difference between Zn(II) and Cd(II) in affinity for the two sites is combined with the kinetics of hydrolysis of nitrocefin for different metal ion substitutions (Zn(2)E, ZnE, Cd(2)E, CdE, and ZnCdE) to study the function of the two metal ion binding sites.     

Expression and mutagenesis of ZntA, a zinc-transporting P-type ATPase from Escherichia coli.

Cation-transporting P-type ATPases comprise a major membrane protein family, the members of which are found in eukaryotes, eubacteria, and archaea. A phylogenetically old branch of the P-type ATPase family is involved in the transport of heavy-metal ions such as copper, silver, cadmium, and zinc. In humans, two homologous P-type ATPases transport copper. Mutations in the human proteins cause disorders of copper metabolism known as Wilson and Menkes diseases. E. coli possesses two genes for heavy-metal translocating P-type ATPases. We have constructed an expression system for one of them, ZntA, which encodes a 732 amino acid residue protein capable of transporting Zn(2+). A vanadate-sensitive, Zn(2+)-dependent ATPase activity is present in the membrane fraction of our expression strain. In addition to Zn(2+), the heavy-metal ions Cd(2+), Pb(2+), and Ag(+) activate the ATPase. Incubation of membranes from the expression strain with [gamma-(33)P]ATP in the presence of Zn(2+), Cd(2+), or Pb(2+) brings about phosphorylation of two membrane proteins with molecular masses of approximately 90 and 190 kDa, most likely representing the ZntA monomer and dimer, respectively. Although Cu(2+) can stimulate phosphorylation by [gamma-(33)P]ATP, it does not activate the ATPase. Cu(2+) also prevents the Zn(2+) activation of the ATPase when present in 2-fold excess over Zn(2+). Ag(+) and Cu(+) appear not to promote phosphorylation of the enzyme. To study the effects of Wilson disease mutations, we have constructed two site-directed mutants of ZntA, His475Gln and Glu470Ala, the human counterparts of which cause Wilson disease. Both mutants show a reduced metal ion stimulated ATPase activity (about 30-40% of the wild-type activity) and are phosphorylated much less efficiently by [gamma-(33)P]ATP than the wild type. In comparison to the wild type, the Glu470Ala mutant is phosphorylated more strongly by [(33)P]P(i), whereas the His475Gln mutant is phosphorylated more weakly. These results suggest that the mutation His475Gln affects the reaction with ATP and P(i) and stabilizes the enzyme in a dephosphorylated state. The Glu470Ala mutant seems to favor the E2 state. We conclude that His475 and Glu470 play important roles in the transport cycles of both the Wilson disease ATPase and ZntA.     

Expression of ZntA, a zinc-transporting P1-type ATPase, is specifically regulated by zinc and cadmium

All cells have developed various mechanisms to regulate precisely the availability of important micronutrients such as zinc and copper; in many cells, this regulation is mediated by P1-type ATPases. Most of the P1-ATPases have been described very recently, and little is known about their molecular mechanism and regulation. Here, we demonstrate that the expression of ZntA, a Zn,Cd-transporting P-type ATPase of Escherichia coli, is specifically regulated by the transported cations, cadmium and zinc. Nickel, cobalt, and copper did not induce the expression of ZntA, even when present at concentrations as high as 0.6-1 mM. The effect of zinc and cadmium on the ZntA expression is concentration dependent, the apparent Km for Cd (19 microM) being markedly lower than that for Zn (100 microM). This metal selectivity is opposite to the known metal selectivity of transport by ZntA. Thus, we speculate that, to maintain zinc concentrations in the cell in the presence of cadmium, ZntA probably interacts with other proteins that modulate the ZntA selectivity towards transported cations.