Nigel L. Brown

The MerR family of transcriptional regulators

The MerR family is a group of transcriptional activators with similar N-terminal helix-turn-helix DNA binding regions and C-terminal effector binding regions that are specific to the effector recognised. The signature of the family is amino acid similarity in the first 100 amino acids, including a helix-turn-helix motif followed by a coiled-coil region. With increasing recognition of members of this class over the last decade, particularly with the advent of rapid bacterial genome sequencing, MerR-like regulators have been found in a wide range of bacterial genera, but not yet in archaea or eukaryotes. The few MerR-like regulators that have been studied experimentally have been shown to activate suboptimal sigma(70)-dependent promoters, in which the spacing between the -35 and -10 elements recognised by the sigma factor is greater than the optimal 17+/-1 bp. Activation of transcription is through protein-dependent DNA distortion. The majority of regulators in the family respond to environmental stimuli, such as oxidative stress, heavy metals or antibiotics. A subgroup of the family activates transcription in response to metal ions. This subgroup shows sequence similarity in the C-terminal effector binding region as well as in the N-terminal region, but it is not yet clear how metal discrimination occurs. This subgroup of MerR family regulators includes MerR itself and may have evolved to generate a variety of specific metal-responsive regulators by fine-tuning the sites of metal recognition.

Whole cell- and protein-based biosensors for the detection of bioavailable heavy metals in environmental samples:

The principal goal of this work was to establish the feasibility of two biosensor technologies with enhanced specificity and selectivity for the detection of several bioavailable heavy metals in environmental samples. Two parallel strategies have been followed. The first approach was to construct whole cell bacterial biosensors that emit a bioluminescent or fluorescent signal in the presence of a biologically available heavy metal. The molecular basis of σ-54 promoters as sensing elements of environmental pollutants has been determined and a number of metal-induced promoter regions have been identified, sequenced and cloned as promoter cassettes. The specificity of the promoter cassettes has been determined using luxCDABE reporter systems. Whole cell-biosensors containing metal-induced lux reporter systems have been incorporated into different matrices for their later immobilisation on optic fibres and characterised in terms of their sensitivity and storage capacity. The second type of sensors was based on the direct interaction between metal-binding proteins and heavy metal ions. In this case, the capacitance changes of the proteins, such as synechoccocal metallothionein (as a GST-SmtA fusion protein) and the mercury regulatory protein, MerR, were detected in the presence of femtomolar to millimolar metal ion concentrations.

ZntR is a Zn(II)-responsive MerR-like transcriptional regulator of zntA in Escherichia coli

We have identified the promoter/operator region of the zntA gene of Escherichia coli and shown that Zn(II) is the primary inducer of expression of this Zn(II)/Cd(II) export gene. The promoter PzntA shows sequence similarities to the promoters of mercury resistance (mer ) operons, including a long spacer region containing an inverted repeat sequence. The gene encoding the transcriptional regulator of PzntA, designated zntR, has been identified from genome sequence data, by expression of the gene product and by insertional inactivation/complementation. The ZntR product is a member of the MerR family of transcriptional regulators and appears to act as a hypersensitive transcriptional switch. A hybrid MerR/ZntR protein has been constructed and indicates that the C‐terminal region of ZntR recognizes Zn(II).

Molecular genetics and transport analysis of the copper-resistance determinant (pco) from Escherichia coli plasmid pRJ1004

The copper‐resistance determinant (pco) of Escherichia coli plasmid pRJ1004 was cloned and sequenced. Tn1000 transposon mutagenesis identified four complementation groups, mutations in any of which eliminated copper resistance. DNA sequence analysis showed that the four complementation groups contained six open reading frames, designated pcoABCDRS. The protein product sequences derived from the nucleotide sequence show close homology between this copper‐resistance system and the cop system of a plasmid pPT23D of Pseudomonas syringae pv. tomato. The PcoR and PcoS protein sequences show homology to the family of two‐component sensor/responder phosphokinase regulatory systems. A seventh reading frame (pcoE) was identified from DNA sequence data, and lies downstream of a copper‐regulated promoter. Transport assays with 64Cu(II) showed that the resistant cells containing the plasmid had reduced copper accumulation during the log phase of growth, while increased accumulation had previously been observed during stationary phase. Chromosomal mutants defective in cellular copper management were obtained and characterized. In two of these mutants pco resistance was rendered totally inactive, whilst in another two mutants pco complemented the defective genes. These data indicate that plasmid‐borne copper resistance in E. coli is linked with chromosomal systems for copper management.

CueR (YbbI) of Escherichia coli is a MerR family regulator controlling expression of the copper exporter CopA

We have shown that the open reading frame ybbI in the genomic sequence of Escherichia coli K‐12 encodes the regulator of expression of the copper‐exporting ATPase, CopA. In vivo studies showed that ybbI (designated cueR for copper export regulator gene) was required for copper tolerance during growth, that disruption of cueR caused loss of copA expression and that copA gene expression was regulated by cueR and by copper or silver ions. Expression of a lacZ reporter gene under the control of the copA promoter was approximately proportional to the concentration of cupric ions in the medium, but increased more rapidly in response to silver ion concentrations. The start of the copA transcript was located by primer extension mapping, and DNase I protection assays showed that the CueR protein binds in vitro to a dyad symmetrical sequence within a 19 bp spacer sequence in the copA promoter. CueR binding occurs in vitro in both the presence and the absence of RNA polymerase with or without copper ions present but, in the presence of CueR, RNA polymerase and copper ions, permanganate‐sensitive transcription complexes were formed. CueR is predicted to have an N‐terminal helix–turn–helix sequence and shows similarity to MerR family regulators.

Cloning and Functional Analysis of the pbr Lead Resistance Determinant of Ralstonia metallidurans CH34

The lead resistance operon, pbr, of Ralstonia metallidurans (formerly Alcaligenes eutrophus) strain CH34 is unique, as it combines functions involved in uptake, efflux, and accumulation of Pb(II). The pbr lead resistance locus contains the following structural resistance genes: (i) pbrT, which encodes a Pb(II) uptake protein; (ii) pbrA, which encodes a P-type Pb(II) efflux ATPase; (iii) pbrB, which encodes a predicted integral membrane protein of unknown function; and (iv) pbrC, which encodes a predicted prolipoprotein signal peptidase. Downstream of pbrC, the pbrD gene, encoding a Pb(II)-binding protein, was identified in a region of DNA, which was essential for functional lead sequestration. Pb(II)-dependent inducible transcription of pbrABCD from the PpbrA promoter is regulated by PbrR, which belongs to the MerR family of metal ion-sensing regulatory proteins. This is the first report of a mechanism for specific lead resistance in any bacterial genus.

The nucleotide sequence of the mercuric resistance operons of plasmid R100 and transposon Tn501: further evidence for mer genes which enhance the activity of the mercuric ion detoxification system.

SummaryThe DNA sequences of the mercuric resistance determinants of plasmid R100 and transposon Tn501 distal to the gene (merA) coding for mercuric reductase have been determined. These 1.4 kilobase (kb) regions show 79% identity in their nucleotide sequence and in both sequences two common potential coding sequences have been identified. In R100, the end of the homologous sequence is disrupted by an 11.2 kb segment of DNA which encodes the sulfonamide and streptomycin resistance determinants of Tn21. This insert contains terminal inverted repeat sequences and is flanked by a 5 base pair (bp) direct repeat. The first of the common potential coding sequences is likely to be that of the merD gene. Induction experiments and mercury volatilization studies demonstrate an enhancing but non-essential role for these merA-distal coding sequences in mercury resistance and volatilization. The potential coding sequences have predicted codon usages similar to those found in other Tn501 and R100 mer genes.

The Pco proteins are involved in periplasmic copper handling in Escherichia coli.

The interactions between the plasmid-borne copper resistance determinant, pco, and the main copper export system in Escherichia coli have been investigated and no direct interaction has been found. The PcoE and PcoC proteins are periplasmic and PcoC binds one Cu ion per protein molecule. PcoA is also periplasmic and can substitute for the chromosomally encoded CueO protein. The pco determinant is proposed to exert its effect through periplasmic handling of excess copper ions and to increase the level of resistance to copper ions above that conferred by copA alone.

Copper resistance determinants in bacteria.

Copper is an essential trace element that is utilized in a number of oxygenases and electron transport proteins, but it is also a highly toxic heavy metal, against which all organisms must protect themselves. Known bacterial determinants of copper resistance are plasmid-encoded. The mechanisms which confer resistance must be integrated with the normal metabolism of copper. Different bacteria have adopted diverse strategies for copper resistance, and this review outlines what is known about bacterial copper resistance mechanisms and their genetic regulation.

Transcriptional regulation of the mercury-resistance genes of transposon Tn501.

Expression of the mercury-resistance (mer) genes of the transposon Tn501 is positively and negatively controlled by the product of the merR gene. DNA sequence analysis has identified three open reading frames as potential candidates for this gene, one of which is oriented divergently with respect to the mercury-resistance genes. We have demonstrated that although RNA polymerase will bind to fragments containing the potential control regions for all three reading frames, only the control region for this divergent reading frame shows detectable promoter activity in vivo. Transcription of this reading frame is required for repression and induction of mer transcription. We have also shown that the Tn501 merR gene product negatively regulates its own synthesis, and have identified the start point of the transcript for this reading frame and for the mercury-inducible transcript of the mercury-resistance genes.