Separate resistances to arsenate and arsenite (antimonate) encoded by the arsenical resistance operon of R factor R773.

The arsenical resistance operon of R factor R773 was analyzed by subcloning and insertional inactivation. The operon was found to have two functional regions, the promoter-proximal region encoding resistance to arsenite and antimonate and the promoter-distal region encoding arsenate resistance. A unique 1.6-kilobase fragment was shown to be sufficient to encode arsenate resistance and produce arsenate extrusion from intact cells.     

Identification of polypeptides encoded by the replication of resistance factor R100

Several polypeptides encoded by the resistance factor R100 were synthesized in a DNA-dependent protein synthesis system using a miniplasmid derived from R100 as a template. Nine polypeptides were detected. The locations of the genes for these polypeptides were investigated by using DNA restriction fragments as templates, and also by examining the effect of restriction endonuclease digestion of these templates on the synthesis of the polypeptides. The genes for seven of the polypeptides were identified or located by comparing the results with the known nucleotide sequence and restriction map of this region. Three of the polypeptides appeared to be encoded by the repA1, repA2 and repA3 genes, which are located in the region required for the replication of R100 and the expression of incompatibility. Four of the polypeptides were encoded by regions that are not required for the autonomous replication of R100 in Escherichia coli. One is the gene product of finO, which regulates the expression of the tra genes on R100.The miniplasmid used for these experiments carried one ISI sequence that has three potential genes. However, no polypeptide was detected that could be clearly demonstrated to be encoded by ISI.     

Chromosomally encoded arsenical resistance of the moderately thermophilic acidophile Acidithiobacillus caldus

Arsenical resistance is important to bioleaching microorganisms because these organisms release arsenic from minerals such as arsenopyrite during bioleaching. The acidophile Acidithiobacillus caldus KU was found to be resistant to the arsenical ions arsenate, arsenite, and antimony via an inducible, chromosomally encoded resistance mechanism. Because no apparent alteration of the toxic ions was observed, Acidithiobacillus (At.) caldus was tested to determine if it was resistant as a result of decreased accumulation of toxic ions. Reduced accumulation of arsenate and arsenite by induced At. caldus cells supported this hypothesis. It was also found that, with the addition of an energy source, induced At. caldus could transport arsenate and arsenite out of the cell against a concentration gradient. The lack of efflux in the absence of an added energy source and in the presence of inhibitors suggested that efflux was energy dependent. Induced At. caldus also expressed arsenate reductase activity, indicating that At. caldus has an arsenical resistance mechanism that is analogous to previously described systems from other Bacteria. Southern hybridization analysis showed that At. caldus and other gram-negative acidophiles carry an Escherichia coli arsB homologue on the chromosome.     

The ars operon of Escherichia coli confers arsenical and antimonial resistance.

The chromosomally encoded arsenical resistance (ars) operon subcloned into a multicopy plasmid was found to confer a moderate level of resistance to arsenite and antimonite in Escherichia coli. When the operon was deleted from the chromosome, the cells exhibited hypersensitivity to arsenite, antimonite, and arsenate. Expression of the ars genes was inducible by arsenite. By Southern hybridization, the operon was found in all strains of E. coli examined but not in Salmonella typhimurium, Pseudomonas aeruginosa, or Bacillus subtilis.     

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.     

The arsD gene encodes a second trans-acting regulatory protein of the plasmid-encoded arsenical resistance operon

The plasmid-encoded arsenical resistance (ars) operon produces resistance to trivalent and pentavalent salts of arsenic and antimony. The first gene in the operon, arsR, was previously shown to encode a repressor protein. A newly identified gene, arsD, is shown here to encode a regulatory protein, the ArsD protein. The gene was identified by construction of an in-frame fusion between the C-terminally truncated arsD gene and the coding region for the mature form of β-lactamase (blaM). The native arsD gene product was overexpressed and radioactively labelled as a 13kDa polypeptide. A frameshift mutation within the arsD gene resulted in elevated levels of expression of downstream ars genes. Co-expression of a wild-type arsD gene in trans with the operon containing the mutated arsD gene reduced expression of the downstream genes to wild-type levels. The presence of the arsD gene had no effect on the basal level of operon expression set by the arsR gene product, and the repression produced by the arsD gene product was not affected by inducers of the operon. The results indicate that the ArsD protein is an inducer-independent trans-acting regulatory protein.     

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.     

Thiolactomycin resistance in Escherichia coli is associated with the multidrug resistance efflux pump encoded by emrAB.

Thiolactomycin (TLM) and cerulenin are antibiotics that block Escherichia coli growth by inhibiting fatty acid biosynthesis at the beta-ketoacyl-acyl carrier protein synthase I step. Both TLM and cerulenin trigger the accumulation of intracellular malonyl-coenzyme A coincident with growth inhibition, and the overexpression of synthase I protein confers resistance to both antibiotics. Strain CDM5 was derived as a TLM-resistant mutant but remained sensitive to cerulenin. TLM neither induced malonyl-coenzyme A accumulation nor blocked fatty acid production in vivo; however, the fatty acid synthase activity in extracts from strain CDM5 was sensitive to TLM inhibition. The TLM resistance gene in strain CDM5 was mapped to 57.5 min of the chromosome and was an allele of the emrB gene. Disruption of the emrB gene converted strain CDM5 to a TLM-sensitive strain, and the overexpression of the emrAB operon conferred TLM resistance to sensitive strains. Thus, activation of the emr efflux pump is the mechanism for TLM resistance in strain CDM5.     

Overexpression of a single membrane component from the Bacillus mer operon enhanced mercury resistance in an Escherichia coli host

Overexpression of a mercuric ion binding protein, MerP, from the mercury resistance operon genes of Gram-positive bacterial strain Bacillus megaterium MB1 and from Gram-negative bacterial strain Pseudomonas aeruginosa K-62 was found to enhance the mercury resistance level of Escherichia coli host cells, even though they share only 27.3% identity. Immunoblot analysis showed that MerP (BMerP) from Bacillus could be expressed on the membrane fraction of E. coli cells. Treated with 10 microM Hg2+, a recombinant strain harboring the BMerP gene significantly improved, showing a 27% increase in mercuric ion adsorption capacity, 16% better than that of a Pseudomonas merP gene (PMerP)-harboring strain. While multiple heavy metals co-existed, the mercuric ion adsorption capacity of the BMerP-harboring E. coli was not affected while that of the PMerP-harboring strain decreased. These results suggest that BMerP can act as a bio-adsorbent compartmentalizing the toxic mercuric ion on the cell membrane and enhancing resistance.     

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.     

Characterization of the proteins encoded by the Bacillus subtilis yoxA-dacC operon

In Bacillus subtilis , the yoxA and dacC genes were proposed to form an operon. The yoxA gene was overexpressed in Escherichia coli and its product fused to a polyhistidine tag was purified. An aldose-1-epimerase or mutarotase activity was measured with the YoxA protein that we propose to rename as GalM by analogy with its counterpart in E. coli . The peptide d -Glu-δ- m -A₂pm- d -Ala- m -A₂pm- d -Ala mimicking the B. subtilis and E. coli interpeptide bridge was synthesized and incubated with the purified dacC product, the PBP4a. A clear dd -endopeptidase activity was obtained with this penicillin-binding protein, or PBP. The possible role of this class of PBP, present in almost all bacteria, is discussed.     

Identification of repressor binding sites controlling expression of tetracycline resistance encoded by Tn10

The regulatory region controlling the expression of tetracycline resistance and repressor genes contains two nearly identical regions of dyad symmetry. Deletions of this control region were isolated by digestion with S1 nuclease. The ability of these deletions to bind the tet repressor was determined by an in vivo repressor titration assay. The results indicate that repressor specifically binds both regions of dyad symmetry.     

Compartmentalization of the proteins encoded by IS50R

IS50R is a transposable genetic element that serves as the right inverted repeat of the transposon Tn5. Earlier work has shown that IS50R encodes at least two proteins (called P1 and P2) involved in transposition. In this paper, we describe the localization properties of the proteins encoded on this repeat. Strains were constructed that overproduced either these two proteins or hybrids between beta-galactosidase and the IS50R proteins. An antiserum was raised against the hybrid proteins, and this was used to study the localization of P1 and P2. Based on studies in maxicells as well as in growing cells, we show that P1 and P2 are localized differently in the cell. P2 is a cytoplasmic protein, while P1 largely fractionates with the membrane.