One His, two His…the emerging roles of histidine in cellular nickel trafficking.

Biological environments present a complex array of metal-binding ligands. Metal-binding proteins have been the overwhelming focus of study because of their important and well-defined biological roles. Consequently, the presence of functional low molecular weight (LMW) metal-ligand complexes has been overlooked in terms of their roles in metallobiochemistry, particularly within cells.

Protein metalation in biology.

Inorganic metals supplement the chemical repertoire of organic molecules, especially proteins. This requires the correct metals to associate with proteins at metalation. Protein mismetalation typically occurs when excesses of unbound metals compete for a binding site ex vivo.

Bacterial sensors define intracellular free energies for correct enzyme metalation.

There is a challenge for metalloenzymes to acquire their correct metals because some inorganic elements form more stable complexes with proteins than do others. These preferences can be overcome provided some metals are more available than others. However, while the total amount of cellular metal can be readily measured, the available levels of each metal have been more difficult to define.

Co(II) and Ni(II) binding of the transcriptional repressor RcnR orders its N terminus, alters helix dynamics, and reduces DNA affinity.

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).

Glutamate Ligation in the Ni(II)- and Co(II)-Responsive Escherichia coli Transcriptional Regulator, RcnR.

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 P. The DNA binding affinity is weakened when the cognate ions Ni(II) and Co(II) bind to EcRcnR in a six-coordinate site that features a (N/O)S 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 noncognate 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.

Elucidation of the biosynthesis of the methane catalyst coenzyme F.

Methane biogenesis in methanogens is mediated by methyl-coenzyme M reductase, an enzyme that is also responsible for the utilization of methane through anaerobic methane oxidation. The enzyme uses an ancillary factor called coenzyme F, a nickel-containing modified tetrapyrrole that promotes catalysis through a methyl radical/Ni(ii)-thiolate intermediate. However, it is unclear how coenzyme F is synthesized from the common primogenitor uroporphyrinogen iii, incorporating 11 steric centres into the macrocycle, although the pathway must involve chelation, amidation, macrocyclic ring reduction, lactamization and carbocyclic ring formation.

A tight tunable range for Ni(II) sensing and buffering in cells.

The metal affinities of metal-sensing transcriptional regulators co-vary with cellular metal concentrations over more than 12 orders of magnitude. To understand the cause of this relationship, we determined the structure of the Ni(II) sensor InrS and then created cyanobacteria (Synechocystis PCC 6803) in which transcription of genes encoding a Ni(II) exporter and a Ni(II) importer were controlled by InrS variants with weaker Ni(II) affinities. Variant strains were sensitive to elevated nickel and contained more nickel, but the increase was small compared with the change in Ni(II) affinity.

The mechanism of a formaldehyde-sensing transcriptional regulator.

Most organisms are exposed to the genotoxic chemical formaldehyde, either from endogenous or environmental sources. Therefore, biology has evolved systems to perceive and detoxify formaldehyde. The frmRA(B) operon that is present in many bacteria represents one such system.

Nickel recognition by bacterial importer proteins.

Nickel supports the growth of microbes from a variety of very different growth environments that affect nickel speciation. The mechanisms of nickel uptake and the molecular bases for the selectivity of this process are emerging. The recent surge of Ni-importer protein structures provides an understanding of Ni-recognition in the initial binding step of the import process.

Effects of select histidine to cysteine mutations on transcriptional regulation by Escherichia coli RcnR.

The RcnR metalloregulator represses the transcription of the Co(II) and Ni(II) exporter, RcnAB. Previous studies have shown that Co(II) and Ni(II) bind to RcnR in six-coordinate sites, resulting in derepression. Here, the roles of His60, His64, and His67 in specific metal recognition are examined.

Identification of Ni-(L-His)₂ as a substrate for NikABCDE-dependent nickel uptake in Escherichia coli.

Nickel is an important cofactor for several microbial enzymes. The ATP-dependent NikABCDE transporter is one of several types of uptake pathways known to be important for nickel acquisition in microbes. The Escherichia coli NikA periplasmic binding protein is structurally homologous to the di- and oligopeptide binding proteins, DppA and OppA.

Role of the N-terminus in determining metal-specific responses in the E. coli Ni- and Co-responsive metalloregulator, RcnR.

RcnR (resistance to cobalt and nickel regulator) is a 40-kDa homotetrameric protein and metalloregulator that controls the transcription of the Co(II) and Ni(II) exporter, RcnAB, by binding to DNA as an apoprotein and releasing DNA in response to specifically binding Co(II) and Ni(II) ions. Using X-ray absorption spectroscopy (XAS) to examine the structure of metals bound and lacZ reporter assays of the transcription of RcnA in response to metal binding, in WT and mutant proteins, the roles of coordination number, ligand selection, and residues in the N-terminus of the protein were examined as determinants in metal ion recognition. The studies show that the cognate metal ions, Co(II) and Ni(II), which bind in (N/O)(5)S six-coordinate sites, are distinguished from non-cognate metal ions (Cu(I) and Zn(II)), which bind only three protein ligands and one anion from the buffer, by coordination number and ligand selection.

Point mutations in Helicobacter pylori's fur regulatory gene that alter resistance to metronidazole, a prodrug activated by chemical reduction.

Background: Helicobacter pylori's Fur regulatory protein controls transcription of dozens of genes in response to iron availability, acidity and oxidative stress, and affects the vigor of infection and severity of disease. It is unusual among Fur family proteins in being active both when iron-loaded and iron-free. METHOLODOLGY/PRINCIPAL FINDINGS: We tested if H.

Helicobacter pylori NikR protein exhibits distinct conformations when bound to different promoters.

Helicobacter pylori NikR (HpNikR) is a ribbon-helix-helix (RHH) DNA-binding protein that binds to several different promoter regions. The binding site sequences are not absolutely conserved. The ability of HpNikR to discriminate specific DNA sites resides partly in its nine-amino acid N-terminal arm.

Communication between the zinc and nickel sites in dimeric HypA: metal recognition and pH sensing.

Helicobacter pylori , a pathogen that colonizes the human stomach, requires the nickel-containing metalloenzymes urease and NiFe-hydrogenase to survive this low pH environment. The maturation of both enzymes depends on the metallochaperone, HypA. HypA contains two metal sites, an intrinsic zinc site and a low-affinity nickel binding site.

Geobacter uraniireducens NikR displays a DNA binding mode distinct from other members of the NikR family.

NikR is a nickel-responsive ribbon-helix-helix transcription factor present in many bacteria and archaea. The DNA binding properties of Escherichia coli and Helicobacter pylori NikR (factors EcNikR and HpNikR, respectively) have revealed variable features of DNA recognition. EcNikR represses a single operon by binding to a perfect inverted repeat sequence, whereas HpNikR binds to promoters from multiple genes that contain poorly conserved inverted repeats.

Coordinating intracellular nickel-metal-site structure-function relationships and the NikR and RcnR repressors.

Metalloregulator function requires both sensitivity and selectivity to ensure metal-specific activity without interfering with intracellular metal trafficking pathways. Here, we examine the role of metal coordination geometry in the function of NikR and RcnR, two widely conserved nickel-responsive regulators that are both present in E. coli.

DNA recognition and wrapping by Escherichia coli RcnR.

Escherichia coli RcnR is a founding member of a recently discovered large and widespread structural family of bacterial transcription factors that are predicted to respond to a variety of environmental stresses. RcnR directly regulates transcription of the gene encoding the RcnA nickel and cobalt efflux protein by coordination of DNA-binding and metal-binding activities. A crystal structure of a Cu(I)-sensing homolog from Mycobacterium tuberculosis did not reveal how the novel all-alpha-helical fold of this protein family interacts with DNA because it lacks a well-characterized DNA-binding motif.

An intact urease assembly pathway is required to compete with NikR for nickel ions in Helicobacter pylori.

We examined the effects of urease and hydrogenase assembly gene deletions on NikR activation in H. pylori strains 26695 and G27. The loss of any component of urease assembly increased NikR activity under Ni2+-limiting conditions, as measured by reduced transcript levels and 63Ni accumulation.

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.

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.