Biochemical characterization of HgCl2-inducible polypeptides encoded by the mer operon of plasmid R100.

Minicells carrying the subcloned mer operon from plasmid R100 were pulse-labeled with [35S]methionine, and the labeled polypeptides were analyzed at various subsequent times by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The Hg(II) reductase monomer encoded by plasmid R100 occurred as two proteins of 69 and 66 kilodaltons (kd). The minor 66-kd protein is a modified form of the 69-kd protein. This modification occurs in vivo. Both of these mer proteins are found in the soluble fraction of the cell; however, the 66-kd protein appears to have a slight affinity for the cellular envelope. Both the 69- and 66-kd mer proteins have pI values greater (pI = 5.8) than that reported (pI = 5.3) for the analogous monomer encoded by plasmid R831. The 15.1- and 14-kd mer proteins are localized in the inner membrane and are probably elements of the mer-determined Hg(II) uptake system. These two mer membrane proteins, which are antigenically unrelated to the Hg(II) reductase monomer, are quite basic (pI values greater than 7.8). The 12-kd mer protein is also a basic polypeptide that is present in the soluble fraction of the cell. Unlike the two membrane-bound mer proteins, the 12-kd mer protein is processed from a 13-kd precursor.     

Effect of catabolite repression on the mer operon

The plasmid-determined mer operon, which provides resistance to inorganic mercury compounds, was subject to a 2.5-fold decrease in expression when glucose was administered at the same time as the inducer HgCl2. This glucose-mediated transient repression of the operon was overcome by the addition of cyclic AMP. Permanent catabolite repression of the operon was observed in the 1.6- to 1.9-fold decrease in expression in mutants lacking either adenyl cyclase (cya) or the catabolite activator protein (crp). The effect of the cya mutation on mer expression could be overcome by the addition of cyclic AMP at the time of induction, In addition to these effects on the whole cells of a wild-type strains, we examined the effect of catabolite repression on the expression of the mercuric ion [Hg(II)] reductase enzyme, assayable in cell extracts, and on the Hg(II) uptake system, assayable in a mutant strain which lacked reductase activity. There was a two- to threefold effect of repression on the Hg(II) reductase enzyme assayable in vitro after induction under catabolite repressing conditions (either with glucose or in the crp and cya mutants). We did not find a similar repressing effect on the induction of the Hg(II) uptake system, which is also determined by the mer operon.     

Translation of merD in Tn21.

All four sequenced examples of the mercury resistance (mer) operon of gram-negative bacteria have a promoter-distal reading frame, merD, whose removal has little effect on the resistance phenotype and whose translation has not previously been observed. Using merD-lacZ protein fusions, we show that merD is translated. However, Hg(II)-induced merD expression, as measured by beta-galactosidase activity and immunoblotting, is 10- to 15-fold lower than that of fusions to the gene immediately preceding it, merA.     

Diversity of mercury resistance determinants among Bacillus strains isolated from sediment of Minamata Bay

Thirty mercury-resistant (Hg R) Bacillus strains were isolated from mercury-polluted sediment of Minamata Bay, Japan. Mercury resistance phenotypes were classified into broad-spectrum (resistant to inorganic Hg(2+) and organomercurials) and narrow-spectrum (resistant to inorganic Hg(2+) and sensitive to organomercurials) groups. Polymerase chain reaction (PCR) product sizes and the restriction nuclease site maps of mer operon regions from all broad-spectrum Hg R Bacillus were identical to that of Bacillus megaterium MB1. On the other hand, the PCR products of the targeted merP (extracellular mercury-binding protein gene) and merA (intracellular mercury reductase protein gene) regions from the narrow-spectrum Hg R Bacillus were generally smaller than those of the B. megaterium MB1 mer determinant. Diversity of gene structure configurations was also observed by restriction fragment length polymorphism (RFLP) profiles of the merA PCR products from the narrow-spectrum Hg R Bacillus. The genetic diversity of narrow-spectrum mer operons was greater than that of broad-spectrum ones.     

Nucleotide sequence of a chromosomal mercury resistance determinant from a Bacillus sp. with broad-spectrum mercury resistance.

A 13.5-kilobase HindIII fragment, bearing an intact mercury resistance (mer) operon, was isolated from chromosomal DNA of broad-spectrum mercury-resistant Bacillus sp. strain RC607 by using as a probe a clone containing the mercury reductase (merA) gene. The new clone, pYW33, expressed broad-spectrum mercury resistance both in Escherichia coli and in Bacillus subtilis, but only in B. subtilis was the mercuric reductase activity inducible. Sequencing of a 1.8-kilobase mercury hypersensitivity-producing fragment revealed four open reading frames (ORFs). ORF1 may code for a regulatory protein (MerR). ORF2 and ORF4 were associated with cellular transport function and the hypersensitivity phenotype. DNA fragments encompassing the merA and the merB genes were sequenced. The predicted Bacillus sp. strain RC607 MerA (mercuric reductase) and MerB (organomercurial lyase) were similar to those predicted from Staphylococcus aureus plasmid pI258 (67 and 73% amino acid identities, respectively); however, only 40% of the amino acid residues of RC607 MerA were identical to those of the mercuric reductase from gram-negative bacteria. A 69-kilodalton polypeptide was isolated and identified as the merA gene product by examination of its amino-terminal sequence.     

Tn1 generated mutants in the mercuric ion reductase of the Inc P plasmid, R702

Summary Physiological, biochemical and genetic aspects of resistance to inorganic mercury compounds were examined in a group of mercury sensitive derivatives generated in the Inc P plasmid, R702, by Tn1 insertion. Strains carrying each of these insertion mutations had no detectable mercuric ion reductase, were more sensitive to mercuric ion than a plasmidless strain, and exhibited inducible uptake of Hg²⁺. These characteristics indicate that the mutants are altered in the Hg(II) reductase. This hypothesis was supported by complementation and recombination analysis with known point and deletion mutations in the mer operon of the Inc FII plasmid, R100. Such experiments showed that the eight insertions studied had occurred in four distinct regions of the Hg(II) reductase structural gene (merA). Complementation data also demonstrated that the regulatory protein determined by the R702 plasmid has no effect on the expression of the micro-constitutive Hg(II) reductase activity expressed by merR mutants of R100.     

Polypeptides encoded by the mer operon.

HgCl2-induced polypeptides synthesized by Escherichia coli minicells containing recombinant or natural HgR plasmids were labeled with [35S]methionine and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. All plasmids examined encoded two heavily labeled, HgCl2-inducible polypeptides of 69,000 and 12,000 daltons. Most plasmids also encoded two additional HgCl2-inducible proteins in the 14,000- to 17,000-dalton range. Antiserum prepared against a purified mercuric ion reductase reacts with the 69,000-dalton polypeptide and a minor 66,000-dalton protein seen in several different HgR minicells. Recombinant plasmids constructed from portions of mer DNA from the IncFII plasmid NR1 were also analyzed in the minicell system. Five HgCl2-inducible polypeptides (69,000, 66,000, 15,100, 14,000, and 12,000 daltons) were synthesized in minicells carrying pRR130, a recombinant derivative containing the EcoRI-H and EcoRI-I restriction fragments of NR1. The EcoRI-H fragment of NR1 encodes the three small mer proteins of 15,100, 14,000, and 12,000 daltons and the amino-terminal 40,000 daltons of the mercuric ion reductase monomer.     

Deletions in the r-determinant mer region of plasmid R100-1 selected for loss of mercury hypersensitivy.

A mutant of plasmid R100-1, which conferred cellular hypersensitivity to Hg2+ because of the insertion of Tn801 (TnA) into the gene determining synthesis of mercuric reductase enzyme, allowed further mutational events to be selected which resulted in either reversion to Hg2+ resistance (characteristic plasmid R100-1) or sensitivity at a level characteristic of plasmidless strains. Restriction endonuclease EcoRI and BamHI analysis showed that reversion to resistance resulted from loss of TnA from the R100-mer:Tn801 plasmid, whereas the change from hypersensitivity to sensitivity to Hg2+ usually resulted from deletion of part or all of Tn801 plus plasmid deoxyribonucleic acid sequences corresponding to the operator-proximal end of the mer operon.     

Polypeptides specified by the mercuric resistance (mer) operon of plasmid R100

Overlapping deletion mutations were constructed in chimaeric plasmids carrying the mer operon of plasmid R100. Polypeptides specified by the mutant plasmids in Escherichia coli minicells correlated with the mer genes as follows: merT, 17- and 16-kDa polypeptides; merP, 9.8- and 9.5-kDa polypeptides; merC, a 14-kDa polypeptide; merA, 65- and 62-kDa polypeptides. The products of the merR and merD genes were not identified. The revised nomenclature of the mer genes is explained.