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.

Escherichia coli can tolerate insertions of up to 16 amino acids in the RNA polymerase alpha subunit inter-domain linker.

The C-terminal domain of the Escherichia coli RNA polymerase alpha subunit (alphaCTD) plays a key role in transcription initiation at many activator-dependent promoters and at UP element-dependent promoters. This domain is connected to the alpha N-terminal domain (alphaNTD) by an unstructured linker. To investigate the requirements of the alpha inter-domain linker to support growth of E. coli, we utilised a recently described technique for the substitution of the chromosomal rpoA gene, encoding alpha, by mutant rpoA alleles. We found that it was possible to replace wild-type rpoA by mutant alleles encoding alpha subunits containing inter-domain linkers that were longer by as many as 16 amino acids. However, using this method, it was not possible to transfer to the chromosome rpoA alleles encoding alpha subunits that contained an insertion of 32 amino acids or short deletions within the inter-domain linker. The effect of lengthening the alpha linker on activator-dependent and UP element-dependent transcription in the "haploid" rpoA system was shown to be qualitatively the same as observed previously in the diploid system. The ability of E. coli to tolerate insertions within the alpha inter-domain linker suggests that lengthening the alpha linker does not severely impair transcription of essential genes.

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 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.

FNR-dependent repression of ndh gene expression requires two upstream FNR-binding sites.

The ndh gene of Escherichia coli encodes a non-proton-translocating NADH dehydrogenase (NdhII) that is anaerobically repressed by the global transcription regulator, FNR. FNR binds at two sites (centred at -50.5 and -94.5) in the ndh promoter but the mechanism of FNR-mediated repression appears not to be due to promoter occlusion. This mechanism has been investigated using an aerobically active derivative of FNR, FNR* (FNR-D154A), with ndh promoters containing altered FNR-binding sites. FNR* repressed ndh gene expression both aerobically and anaerobically in vivo. Gel retardation analysis and DNase I footprinting with purified FNR* protein confirmed that FNR interacts at two sites in the ndh promoter, and that FNR and RNA polymerase (RNAP) can bind simultaneously. Studies with three altered ndh promoters, each containing an impaired or improved FNR-site, indicated that both FNR-sites are needed for efficient repression in vivo. The alpha-subunit of RNAP interacted with two regions (centred at -105 and -46), each overlapping one of the FNR-sites in the ndh promoter. Footprints of the FNR*-RNAP-ndh ternary complex indicated that FNR*-binding at -50.5 prevents the alpha-subunit of RNAP from docking with the DNA just upstream of the -35 element. Binding of a second FNR* molecule at the -105 site likewise prevents binding of the alpha-subunit at its alternative site, thus providing a plausible mechanism for FNR-mediated repression based on displacement of the alpha-subunit of RNAP.