Escherichia coli RcnR (resistance to cobalt and nickel regulator, EcRcnR), is a metal-responsive repressor of the genes encoding the Ni(II) and Co(II) exporter proteins RcnAB by binding to PrcnAB. DNA-binding affinity is weakened when the cognate ions Ni(II) or Co(II) bind to EcRcnR in a six-coordinate site that features a (N/O)5S ligand donor-atom set in distinct sites: while both metal ions are bound by the N-terminus, Cys35, and His64, Co(II) is additionally bound by His3. On the other hand, the non-cognate Zn(II) and Cu(I) ions feature a lower coordination number, have a solvent-accessible binding site, and coordinate protein ligands that do not include the N-terminal amine. A molecular model of apo-EcRcnR suggested potential roles for Glu34 and Glu63 in binding Ni(II) and Co(II) to EcRcnR. The roles of Glu34 and Glu63 in metal binding, metal selectivity and function were therefore investigated using a structure/function approach. X-ray absorption spectroscopy (XAS) was used to assess the structural changes in the Ni(II), Co(II), and Zn(II) binding sites of Glu → Ala and Glu → Cys variants at both positions. The effect of these structural alterations on the regulation of PrcnA by EcRcnR in response to metal binding was explored using LacZ reporter assays. These combined studies indicate that while Glu63 is a ligand for both metal ions, Glu34 is a ligand for Co(II) but possibly not for Ni(II). The Glu34 variants affect the structure of the cognate metal sites, but they have no effect on the transcriptional response. In contrast, the Glu63 variants affect both the structure and transcriptional response, although they do not completely abolish the function of EcRcnR. The structure of the Zn(II) site is not significantly perturbed by any of the Glu variations. The spectroscopic and functional data obtained on the mutants were used to calculate models of the metal site structures of EcRcnR bound to Ni(II), Co(II) and Zn(II). The results are interpreted in terms of a switch mechanism, in which a subset of the metal binding ligands is responsible for the allosteric response required for DNA release.
α-Ketoglutarate (αKG) dependent oxygenases comprise a large superfamily of enzymes that activate O2 for varied reactions. While most of these enzymes contain a nonheme Fe bound by a His2(Asp/Glu) facial triad, a small number of αKG-dependent halogenases require only the two His ligands to bind Fe and activate O2. The enzyme “factor inhibiting HIF” (FIH) contains a His2Asp facial triad and selectively hydroxylates polypeptides; however, removal of the Asp ligand in the Asp201→Gly variant leads to a highly active enzyme, seemingly without a complete facial triad. Herein, we report on the formation of an Fe−Cl cofactor structure for the Asp201→Gly FIH variant using X-ray absorption spectroscopy (XAS), which provides insight into the structure of the His2Cl facial triad found in halogenases. The Asp201→Gly variant supports anion dependent peptide hydroxylation, demonstrating the requirement for a complete His2X facial triad to support O2 reactivity. Our results indicated that exogenous ligand binding to form a complete His2X facial triad was essential for O2 activation and provides a structural model for the His2Cl-bound nonheme Fe found in halogenases.
Helicobacter pylori is a human pathogen that colonizes the stomach, is the major cause of ulcers, and has been associated with stomach cancers. To survive in the acidic environment of the stomach, H. pylori uses urease, a nickel-dependent enzyme, to produce ammonia for maintenance of cellular pH. The bacteria produce apo-urease in large quantities and activate it by incorporating nickel under acid shock conditions. Urease nickel incorporation requires the urease-specific metallochaperone UreE and the (UreFGH) maturation complex. In addition, the H. pylori nickel urease maturation pathway recruits accessory proteins from the [NiFe] hydrogenase maturation pathway, namely, HypA and HypB. HypA and UreE dimers (UreE) are known to form a protein complex, the role of which in urease maturation is largely unknown. Herein, we examine the nickel-binding properties and protein-protein interactions of HypA and UreE using isothermal titration calorimetry and fluorometric methods under neutral and acidic pH conditions to gain insight into the roles played by HypA in urease maturation. The results reveal that HypA and UreE form a stable complex with micromolar affinity that protects UreE from hydrolytic degradation. The HypA·UreE complex contains a unique high-affinity (nanomolar) Ni-binding site that is maintained under conditions designed to mimic acid shock (pH 6.3). The data are interpreted in terms of a proposed mechanism wherein HypA and UreE act as co-metallochaperones that target the delivery of Ni to apo-urease with high fidelity.
RcnR, a transcriptional regulator in , derepresses the expression of the export proteins RcnAB upon binding Ni(II) or Co(II). Lack of structural information has precluded elucidation of the allosteric basis for the decreased DNA affinity in RcnR's metal-bound states. Here, using hydrogen-deuterium exchange coupled with MS (HDX-MS), we probed the RcnR structure in the presence of DNA, the cognate metal ions Ni(II) and Co(II), or the noncognate metal ion Zn(II). We found that cognate metal binding altered flexibility from the N terminus through helix 1 and modulated the RcnR-DNA interaction. Apo-RcnR and RcnR-DNA complexes and the Zn(II)-RcnR complex exhibited similarH uptake kinetics, with fast-exchanging segments located in the N terminus, in helix 1 (residues 14-24), and at the C terminus. The largest difference in H incorporation between apo- and Ni(II)- and Co(II)-bound RcnR was observed in helix 1, which contains the N terminus and His-3, and has been associated with cognate metal binding.H uptake in helix 1 was suppressed in the Ni(II)- and Co(II)-bound RcnR complexes, in particular in the peptide corresponding to residues 14-24, containing Arg-14 and Lys-17. Substitution of these two residues drastically affected DNA-binding affinity, resulting in expression in the absence of metal. Our results suggest that cognate metal binding to RcnR orders its N terminus, decreases helix 1 flexibility, and induces conformational changes that restrict DNA interactions with the positively charged residues Arg-14 and Lys-17. These metal-induced alterations decrease RcnR-DNA binding affinity, leading to expression.
E. coli RcnR (resistance to cobalt and nickel regulator) is a homotetrameric DNA binding protein that regulates the expression of a Ni(II) and Co(II) exporter (RcnAB) by derepressing expression of rcnA and rcnB in response to binding Co(II) or Ni(II). Prior studies have shown that the cognate metal ions, Ni(II) and Co(II), bind in six-coordinate sites at subunit interfaces and are distinguished from noncognate metals (Cu(I), Cu(II), and Zn(II)) by coordination number and ligand selection. In analogy with FrmR, a formaldehyde-responsive transcriptional regulator in the RcnR/CsoR family, the interfacial site allows the metal ions to "cross-link" the N-terminal domain of one subunit with the invariant Cys35 residue in another, which has been deemed to be key to mediating the allosteric response of the tetrameric protein to metal binding. Through the use of mutagenesis to disconnect one subunit from the metal-mediated cross-link, X-ray absorption spectroscopy (XAS) as a structural probe, LacZ reporter assays, and metal binding studies using isothermal titration calorimetry (ITC), the work presented here shows that neither the interfacial binding site nor the coordination number of Ni(II) is important to the allosteric response to binding of this cognate metal ion. The opposite is found for the other cognate metal ion, Co(II), with respect to the interfacial binding site, suggesting that the molecular mechanisms for transcriptional regulation by the two ions are distinct. The metal binding studies reveal that tight metal binding is maintained in the variant. XAS is further used to demonstrate that His33 is not a ligand for Co(II), Ni(II), or Zn(II) in WT-RcnR. The results are discussed in the context of the overall understanding of the molecular mechanisms of metallosensors.
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