Selectivity of metal binding and metal-induced stability of Escherichia coli NikR

High-affinity Ni2+ binding selectively promotes binding of Helicobacter pylori NikR to its target urease promoter

NikR is a prokaryotic transcription factor that regulates the expression of Ni2+ enzymes and other proteins involved in Ni2+ trafficking. In the human pathogen Helicobacter pylori, NikR controls transcription of the Ni2+ enzyme urease, which allows survival of the bacterium in the acidic gastric niche. The in vitro affinity of NikR from H. pylori (HpNikR) for different metal ions and the metal-ion-dependent capability of HpNikR to bind PureA, the promoter of the urease operon, were the object of this study. Electrophoretic mobility shift and DNase I footprinting assays indicated that Ni2+ is necessary and sufficient to promote HpNikR binding to PureA, while the effect of other metal ions in identical conditions is significantly lower (Zn2+ and Co2+) or absent (Ca2+ and Mg2+). Isothermal titration calorimetry (ITC) demonstrated the absence of specific Ca2+ and Mg2+ binding to the protein. ITC also established the binding of Zn2+ and Co2+ to two sets of high-affinity sites on HpNikR, differing in stoichiometry (n1=2, n2=4) and dissociation constant (Kd1=6 nM, Kd2=90 nM for Zn2+; Kd1=0.3 microM, Kd2=2.7 microM for Co2+). Additional low-affinity binding sites were observed for Zn2+ (n=8, Kd=1.6 microM). Mobility shift assays and ITC proved that binding of stoichiometric Ni2+ (but not Zn2+ or Co2+) to the high-affinity sites (but not to the low-affinity sites) selectively activates HpNikR to bind its target operator with 1:1 stoichiometry and Kd=56 nM. A protein conformational rearrangement is selectively induced by Ni2+ and not by Zn2+, as indicated by fluorescence spectroscopy and microcalorimetry. Accordingly, competition experiments showed that stoichiometric Ni2+ outperforms Zn2+, as well as Co2+, in functionally activating HpNikR toward high affinity binding to PureA. A general scheme for the nickel-selective HpNikR-DNA interaction is proposed.

Binding of Ni2+ to a histidine- and glutamine-rich protein, Hpn-like

Hpn-like (Hpnl) protein, encoded by the hpnl gene in Helicobacter pylori and featuring a histidine-rich and two glutamine-rich motifs, can render nickel tolerance to H. pylori when the external nickel level reaches toxic limits. We found that the recombinant Hpnl exists as an oligomer in the native state and binds to two molar equivalents of nickel ions per monomer with a dissociation constant of 3.8 microM. Nickel could be released from Hpnl either at acidic pH (pH(1/2) 4.6) or in the presence of chelate ligands, such as EDTA (t(1/2) = 220, 355, and 716 min at pH 6.0, 7.0, and 7.5, respectively). Our combined spectroscopic data show that nickel ion coordinates to a nitrogen of a histidine residue possibly with a coordination number of four (square-planar geometry) or five. The growth of Escherichia coli cells with or without the hpnl gene implied a protective role of Hpnl under higher concentrations of external nickel ions. Hpnl may serve a role in binding/storage or detoxification of excess nickel ions.

Ni(II) and Co(II) sensing by Escherichia coli RcnR

Escherichia coli RcnR and Mycobacterium tuberculosis CsoR are the founding members of a recently identified, large family of bacterial metal-responsive DNA-binding proteins. RcnR controls the expression of the metal efflux protein RcnA only in response to Ni(II) and Co(II) ions. Here, the interaction of Ni(II) and Co(II) with wild-type and mutant RcnR proteins is examined to understand how these metals function as allosteric effectors. Both metals bind to RcnR with nanomolar affinity and stabilize the protein to denaturation. X-ray absorption and electron paramagnetic resonance spectroscopies reveal six-coordinate high-spin sites for each metal that contains a thiolate ligand. Experimental data support a tripartite N-terminal coordination motif (NH2-Xaa-NH-His) that is common for both metals. However, the Ni(II)- and Co(II)-RcnR complexes are shown to differ in the remaining coordination environment. Each metal coordinates a conserved Cys ligand but with distinct M-S distances. Co(II)-thiolate coordination has not been observed previously in Ni(II)-/Co(II)-responsive metalloregulators. The ability of RcnR to recruit ligands from the N-terminal region of the protein distinguishes it from CsoR, which uses a lower coordination geometry to bind Cu(I). These studies facilitate comparisons between Ni(II)-RcnR and NikR, the other Ni(II)-responsive transcriptional regulator in E. coli, to provide a better understanding how different nickel levels are sensed in E. coli. The characterization of the Ni(II)- and Co(II)-binding sites in RcnR, in combination with bioinformatics analysis of all RcnR/CsoR family members, identified a four amino acid fingerprint that likely defines ligand-binding specificity, leading to an emerging picture of the similarities and differences between different classes of RcnR/CsoR proteins.

Molecular dynamics simulation of the Escherichia coli NikR protein: equilibrium conformational fluctuations reveal interdomain allosteric communication pathways

Escherichia coli NikR is a homotetrameric Ni(2+)- and DNA-binding protein that functions as a transcriptional repressor of the NikABCDE nickel permease. The protein is composed of two distinct domains. The N-terminal 50 amino acids of each chain forms part of the dimeric ribbon-helix-helix (RHH) domains, a well-studied DNA-binding fold. The 83-residue C-terminal nickel-binding domain forms an ACT (aspartokinase, chorismate mutase, and TyrA) fold and contains the tetrameric interface. In this study, we have utilized an equilibrium molecular dynamics simulation in order to explore the conformational dynamics of the NikR tetramer and determine important residue interactions within and between the RHH and ACT domains to gain insight into the effects of Ni(2+) on DNA-binding activity. The molecular simulation data were analyzed using two different correlation measures based on fluctuations in atomic position and noncovalent contacts together with a clustering algorithm to define groups of residues with similar correlation patterns for both types of correlation measure. Based on these analyses, we have defined a series of residue interrelationships that describe an allosteric communication pathway between the Ni(2+)- and DNA-binding sites, which are separated by 40 A. Several of the residues identified by our analyses have been previously shown experimentally to be important for NikR function. An additional subset of the identified residues structurally connects the experimentally implicated residues and may help coordinate the allosteric communication between the ACT and RHH domains.

Structural basis of the metal specificity for nickel regulatory protein NikR

In the presence of excess nickel, Escherichia coli NikR regulates cellular nickel uptake by suppressing the transcription of the nik operon, which encodes the nickel uptake transporter, NikABCDE. Previously published in vitro studies have shown that NikR is capable of binding a range of divalent transition metal ions in addition to Ni2+, including Co2+, Cu2+, Zn2+, and Cd2+. To understand how the high-affinity nickel binding site of NikR is able to accommodate these other metal ions, and to improve our understanding of NikR's mechanism of binding to DNA, we have determined structures of the metal-binding domain (MBD) of NikR in the apo form and in complex with Cu2+ and Zn2+ ions and compared them with the previously published structures with Ni2+. We observe that Cu2+ ions bind in a manner very similar to that of Ni2+, with a square planar geometry but with longer bond lengths. Crystals grown in the presence of Zn2+ reveal a protein structure similar to that of apo MBD with a disordered alpha3 helix, but with two electron density peaks near the Ni2+ binding site corresponding to two Zn2+ ions. These structural findings along with biochemical data on NikR support a hypothesis that ordering of the alpha3 helix is important for repressor activation.

The N-terminal arm of the Helicobacter pylori Ni2+-dependent transcription factor NikR is required for specific DNA binding

The Ni(2+)-dependent transcription factor NikR is widespread among microbes. The two experimentally characterized NikR orthologs, from Helicobacter pylori and Escherichia coli, display vastly different regulatory capabilities in response to increased intracellular Ni(2+). Here, we demonstrate that the nine-residue N-terminal arm present in H. pylori NikR plays a critical role in the expanded regulatory capabilities of this NikR family member. Specifically, the N-terminal arm is required to inhibit NikR binding to low affinity and nonspecific DNA sequences and is also linked to a cation requirement for NikR binding to the nixA promoter. Site-directed mutagenesis and arm-truncation variants of NikR indicate that two residues, Asp-7 and Asp-8, are linked to the cation requirement for binding. Pro-4 and Lys-6 are required for maximal DNA binding affinity of the full-length protein to both the nixA and ureA promoters. The N-terminal arm is highly variable among NikR family members, and these results suggest that it is an adaptable structural feature that can tune the regulatory capabilities of NikR to the nickel physiology of the microbe in which it is found.

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.

The Ni2+ binding properties of Helicobacter pylori NikR

The binding constants between Ni2+ and Helicobacterpylori NikR have been determined using isothermal titration microcalorimetry in order to rationalize the role of this protein as a nickel-dependent biological sensor.

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.

NikR-operator complex structure and the mechanism of repressor activation by metal ions

Metal ion homeostasis is critical to the survival of all cells. Regulation of nickel concentrations in Escherichia coli is mediated by the NikR repressor via nickel-induced transcriptional repression of the nickel ABC-type transporter, NikABCDE. Here, we report two crystal structures of nickel-activated E. coli NikR, the isolated repressor at 2.1 A resolution and in a complex with its operator DNA sequence from the nik promoter at 3.1 A resolution. Along with the previously published structure of apo-NikR, these structures allow us to evaluate functional proposals for how metal ions activate NikR, delineate the drastic conformational changes required for operator recognition, and describe the formation of a second metal-binding site in the presence of DNA. They also provide a rare set of structural views of a ligand-responsive transcription factor in the unbound, ligand-induced, and DNA-bound states, establishing a model system for the study of ligand-mediated effects on transcription factor function.

Cloning of a heavy-metal-binding protein derived from activated-sludge microorganisms

A gene of the heavy-metal-binding protein (HMBP) was newly isolated from a genetic DNA library of activated-sludge microorganisms. HMBP was produced by transformed Escherichia coli, and the copper-binding ability of HMBP was confirmed. HMBP derived from activated sludge could be available as heavy metal adsorbents in water and wastewater treatments.

pH dependent Ni(II) binding and aggregation of Escherichia coli and Helicobacter pylori NikR

NikR proteins are bacterial metallo-regulatory transcription factors that control the expression of the nickel uptake system and/or nickel containing enzymes such as urease, and are involved in the acid stress response. Here, a comparative study is reported on NikR from Helicobacter pylori (HpNikR) and Escherichia coli (EcNikR), as well as the Q2E mutant of EcNikR. Most attention was focused on the Ni(II) binding properties of these proteins, as a function of pH. The influence of the pH on the Ni(II) binding and aggregation properties was studied using gel filtration analysis and UV-visible absorption spectroscopy in the presence of an increasing concentration of nickel. Q2E and wt EcNikR are identical in Ni(II) binding but the Q2E mutant is impaired to some extent in DNA-binding. For EcNikR it is shown that between pH 6 and 8, addition of Ni(II) above 1 equiv. induces mass aggregation and precipitation, concomitant with binding of Ni(II) up to a maximum of 5-8 Ni(II) ions per monomer. The Ni(II) site with highest affinity is the well-described square planar site with three histidines and one cysteine ligands. Aggregation is complete in the presence of less than 1 extra equiv. of Ni(II) and aggregation is fully reversible and precipitates are rapidly solubilized by addition of EDTA. The sensitivity of EcNikR to aggregation decreases with decreasing pH, concurrent with histidines being the main ligands of the site responsible for aggregation. HpNikR does not display aggregation except at alkaline pH, where 3 Ni(II) equiv. are needed. The participation of a cluster consisting of surface-exposed histidines present in EcNikR but not in HpNikR, is proposed to be involved in aggregation. Our results on HpNikR are compatible with the crystallographic data and with the ability of this protein to bind more than one nickel.

Microbial nickel metalloregulation: NikRs for nickel ions

Nickel is a required co-factor for several microbial enzymes; however, because of its potential toxicity, nickel import and homeostasis must be tightly controlled. Recent biophysical and biochemical studies have revealed that NikR proteins are a new type of metalloregulatory protein that utilize allostery and coordination geometry to sense nickel ions and regulate transcription of genes involved in nickel import and processing. Nickel import into bacteria occurs through either ABC-type transporters (NikABCDE) or HoxN type permeases (NixA). Recent structural evidence suggests that nickel is transported through NikABCDE as a metallophore (akin to a siderophore). Nickel storage is accomplished via the HPN protein, a histidine-rich protein similar to metallothionein.

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).

The metal- and DNA-binding activities of Helicobacter pylori NikR

The pathogenic bacteria Helicobacter pylori require nickel as a cofactor of the enzymes urease and hydrogenase. One of the proteins that controls nickel homeostasis in this organism is Helicobacter pylori NikR (HpNikR), a homologue of nickel-dependent transcription factors from other organisms, which regulates the expression of multiple proteins such as the urease structural subunits and itself. To examine the properties of this protein, metal analysis was used to demonstrate that HpNikR can bind stoichiometric nickel or copper, and electronic absorption spectroscopy revealed that HpNikR binds nickel with picomolar affinity in what is likely a conserved square-planar site. In vitro DNA-binding assays revealed that HpNikR can bind directly to the promoter region of the ureA operon in response to nickel, and the location of the binding site was defined. Nickel also induces DNA binding to the nikR promoter sequence but the complex is much weaker. These experiments suggest that HpNikR directly controls the expression of multiple genes by binding to separate DNA sequences, and the possible mechanisms for differential regulation are discussed.

The nickel-responsive regulator NikR controls activation and repression of gene transcription in Helicobacter pylori

The NikR protein is a nickel-dependent regulatory protein which is a member of the ribbon-helix-helix family of transcriptional regulators. The gastric pathogen Helicobacter pylori expresses a NikR ortholog, which was previously shown to mediate regulation of metal metabolism and urease expression, but the mechanism governing the diverse regulatory effects had not been described until now. In this study it is demonstrated that NikR can regulate H. pylori nickel metabolism by directly controlling transcriptional repression of NixA-mediated nickel uptake and transcriptional induction of urease expression. Mutation of the nickel uptake gene nixA in an H. pylori 26695 nikR mutant restored the ability to grow in Brucella media supplemented with 200 microM NiCl2 but did not restore nickel-dependent induction of urease expression. Nickel-dependent binding of NikR to the promoter of the nixA gene resulted in nickel-repressed transcription, whereas nickel-dependent binding of NikR to the promoter of the ureA gene resulted in nickel-induced transcription. Subsequent analysis of NikR binding to the nixA and ureA promoters showed that the regulatory effect was dependent on the location of the NikR-recognized binding sequence. NikR recognized the region from -13 to +21 of the nixA promoter, encompassing the +1 and -10 region, and this binding resulted in repression of nixA transcription. In contrast, NikR bound to the region from -56 to -91 upstream of the ureA promoter, resulting in induction of urease transcription. In conclusion, the NikR protein is able to function both as a repressor and as an activator of gene transcription, depending on the position of the binding site.

Complex transcriptional control links NikABCDE-dependent nickel transport with hydrogenase expression in Escherichia coli

Escherichia coli requires nickel under anaerobic growth conditions for the synthesis of catalytically active NiFe hydrogenases. Transcription of the NikABCDE nickel transporter, which is required for NiFe hydrogenase synthesis, was previously shown to be upregulated by FNR (fumarate-nit rate regulator) in the absence of oxygen and repressed by the NikR repressor in the presence of high extracellular nickel levels. We present here a detailed analysis of nikABCDE transcriptional regulation and show that it closely correlates with hydrogenase expression levels. We identify a nitrate-dependent mechanism for nikABCDE repression that is linked to the NarLX two-component system. NikR is functional under all nickel conditions tested, but its activity is modulated by the total nickel concentration present as well as by one or more components of the hydrogenase assembly pathway. Unexpectedly, NikR function is independent of NikABCDE function, suggesting that NikABCDE is a hydrogenase-specific nickel transporter, consistent with its original identification as a hydrogenase (hyd) mutant. Further, the results suggest that the hydrogenase assembly pathway is sequestered within the cell. A second nickel import pathway in E. coli is implicated in NikR function.

Protease digestion analysis of Escherichia coli NikR: evidence for conformational stabilization with Ni(II)

The Escherichia coli NikR is a 15-kDa protein that negatively regulates transcription of the nikABCDE operon that encodes for an ATP-dependent Ni(II) permease. Thermal and chemical denaturation studies with NikR previously demonstrated that Ni(II)-NikR is more stable than the protein bound to other metals such as Cu(II), Co(II) and Zn(II). To determine if Ni(II) induces a unique conformational change in NikR, digestion experiments with selected proteases were performed in the presence of the above metals. Both denaturing-polyacrylamide gel electrophoresis and reversed-phase HPLC revealed fragmentation patterns in the presence of stoichiometric nickel that were distinct from the cleavage of apo-NikR. Digestion of Cu(II)-NikR produced fragmentation that was similar, although less dramatic, to that produced with Ni(II)-NikR, whereas the Zn(II)- and Co(II)-bound proteins were digested in a similar manner as apo-NikR. Digestion fragments were collected, identified by MALDI-MS, and then mapped onto the available crystal structure of NikR. Although the specificity of the proteases utilized differed, the data suggest that Ni(II) has a selective allosteric effect and that upon metal binding the NikR metal-binding pocket is oriented or protected in such a way as to present itself for digestion in a unique conformation. This data sheds light on the Ni(II)-selective conformational changes that allow NikR to bind DNA optimally and repress transcription of the nik operon.

Purification and properties of the Klebsiella aerogenes UreE metal-binding domain, a functional metallochaperone of urease

Klebsiella aerogenes UreE, a metallochaperone that delivers nickel ions during urease activation, consists of distinct "peptide-binding" and "metal-binding" domains and a His-rich C terminus. Deletion analyses revealed that the metal-binding domain alone is sufficient to facilitate urease activation. This domain was purified and shown to exhibit metal-binding properties similar to those of UreE lacking only the His-rich tail.