The mexR repressor of the mexAB-oprM multidrug efflux operon in Pseudomonas aeruginosa: characterization of mutations compromising activity

Mutations in mexR yield a multidrug resistance phenotype in nalB mutants of Pseudomonas aeruginosa as a result of derepression of the mexAB-oprM multidrug efflux operon. MexR produced by several nalB strains carried single amino acid changes that compromised MexR stability or its ability to dimerize. Changes at residues L95 and R21, however, produced a stable MexR protein capable of dimerization and, thus, likely compromised DNA binding.     

Growth phase-dependent switch in osmolyte strategy in a moderate halophile: ectoine is a minor osmolyte but major stationary phase solute in Halobacillus halophilus

The moderately halophilic, chloride-dependent bacterium Halobacillus halophilus switches its osmolyte strategy with the salinity in its environment by the production of different compatible solutes. Ectoine is produced predominantly at very high salinities, along with proline. Interestingly, ectoine production is growth phase dependent which led to a more than 1000-fold change in the ectoine : proline ratio from 0.04 in exponential to 27.4 in late stationary phase cultures. The genes encoding the ectoine biosynthesis pathway were identified on the chromosome in the order ectABC . They form an operon that is expressed in a salinity-dependent manner with low-level expression below 1.5 M NaCl but 10-fold and 23-fold increased expression at 2.5 and 3.0 M NaCl respectively. The temporal expression of genes involved in osmoresponse is different with gdh / gln and pro genes being first, followed by ect genes. Chloride had no effect on expression of ect genes, but stimulated cellular EctC synthesis as well as ectoine production. These data demonstrate, for the first time, a growth-phase dependent switch in osmolyte strategy in a moderate halophile and, additionally, represent another piece of the chloride regulon of H. halophilus .     

Organic solvent-tolerant mutants of Pseudomonas aeruginosa display multiple antibiotic resistance.

Organic solvent-tolerant mutants of Pseudomonas aeruginosa selected in the presence of hexane exhibited increased resistance to a variety of structurally unrelated antimicrobial agents, including beta-lactams, fluoroquinolones, chloramphenicol, tetracycline, and novobiocin, a phenotype typical of nalB multidrug-resistant mutants. Western immunoblotting with antibodies specific to components of the three known multidrug efflux systems in P. aeruginosa demonstrated that the solvent-tolerant mutants displayed increased expression of the MexAB-OprM system and decreased expression of the MexEF-OprN system. Sequence analysis of mexR, the repressor gene of mexAB-oprM efflux operon, identified a nonsense mutation and a point mutation in the mexR genes of two solvent-tolerant mutants. These results emphasize the importance of the MexAB-OprM efflux system in organic solvent tolerance and the ability of environmental pollutants to select bacteria with a medically relevant antibiotic-resistant phenotype.     

Interplay between the efflux pump and the outer membrane permeability barrier in fluorescent dye accumulation in Pseudomonas aeruginosa.

Pseudomonas aeruginosa encodes three types of xenobiotic efflux pumps, MexAB-OprM, MexCD-OprJ, and MexEF-OprN, which are regulated by the nalB, nfxB, and nfxC genes, respectively, and their high expression renders the cells resistant to multiple species of antibiotics. We evaluated the role of the outer membrane permeability barrier and the efflux pump in lowering the intracellular concentration of fluorescent probes. The wild-type, nalB, nfxB, and nfxC strains with an intact outer membrane showed equally high capability in draining out intracellular fluorescent dye, 2-(4-dimethylaminostyryl)-1-ethylpyridinium and ethidium bromide. When the outer membrane barrier was dismantled by the EDTA treatment, wild-type, nfxC, nfxB, and nalB strains showed significantly different levels of dye accumulation. The polymyxin B-treated cells showed an even more pronounced difference in dye accumulation among the nfxC, nfxB, and nalB mutants. We concluded from these results that the xenobiotic extrusion pumps interplay with the outer membrane permeability barrier in lowering the intracellular substrate concentration. Among three extrusion pumps in P. aeruginosa, MexAB-OprM was the most efficient, followed by MexCD-OprJ and MexEF-OprN pumps for the fluorescent dye extrusion.     

Analysis of antibiotic resistance gene expression in Pseudomonas aeruginosa by quantitative real-time-PCR

In Pseudomonas aeruginosa many of the clinically relevant resistance mechanisms result from changes in gene expression as exemplified by the Mex drug efflux pumps, the AmpC beta-lactamase and the carbapenem-specific porin OprD. We used quantitative real-time-PCR to analyze the expression of these genes in susceptible and antibiotic-resistant laboratory and clinical strains. In nalB mutants, which overexpress OprM, we observed a four- to eightfold increase in the expression of mexA, mexB, and oprM genes. MexX and mexY genes were induced eight to 12 times in the presence of 2 mg L(-1) tetracycline. The mexC/oprJ and mexE/oprN gene expression levels were increased 30- to 250-fold and 100- to 760-fold in nfxB and nfxC mutants, respectively. We further found that in defined laboratory strains expression levels of ampC and oprD genes paralleled beta-lactamase activity and OprD protein levels, respectively. Our data support the use of quantitative real-time-PCR chain reaction for the analysis of the antimicrobial resistance gene expression in P. aeruginosa.     

Effects of nonpolar mutations in each of the seven Bacillus subtilis mrp genes suggest complex interactions among the gene products in support of Na(+) and alkali but not cholate resistance

The Bacillus subtilis mrp (multiple resistance and pH) operon supports Na(+) and alkali resistance via an Na(+)/H(+) antiport, as well as cholate efflux and resistance. Among the individual mutants with nonpolar mutations in each of the seven mrp genes, only the mrpF mutant exhibited cholate sensitivity and a cholate efflux defect that were complemented by expression of the deleted gene in trans. Expression of mrpF in the mrp null (VKN1) strain also restored cholate transport and increased Na(+) efflux, indicating that MrpF does not require even low levels of other mrp gene expression for its own function. In contrast to MrpF, MrpA function had earlier seemed to depend upon at least modest expression of other mrp genes, i.e., mrpA restored Na(+) resistance and efflux to strain VK6 (a polar mrpA mutant which expresses low levels of mrpB to -G) but not to the null strain VKN1. In a wild-type background, each nonpolar mutation in individual mrp genes caused profound Na(+) sensitivity at both pH 7.0 and 8.3. The mrpA and mrpD mutants were particularly sensitive to alkaline pH even without added Na(+). While transport assays in membrane vesicles from selected strains indicated that MrpA-dependent antiport can occur by a secondary, proton motive force-dependent mechanism, the requirement for multiple mrp gene products suggests that there are features of energization, function, or stabilization that differ from typical secondary membrane transporters. Northern analyses indicated regulatory relationships among mrp genes as well. All the mrp mutants, especially the mrpA, -B, -D, -E, and -G mutants, had elevated levels of mrp RNA relative to the wild type. Expression of an upstream gene, maeN, that encodes an Na(+)/malate symporter, was coordinately regulated with mrp, although it is not part of the operon.     

Growth-phase-dependent induction of 6-phosphogluconate dehydrogenase and glucose 6-phosphate dehydrogenase in the cyanobacterium Synechococcus sp. PCC7942.

In most cyanobacteria, the only known pathway for oxidation of stored carbohydrate in the dark or under energy-limiting conditions is the hexose monophosphate shunt. To determine whether the increased use of the shunt under these conditions derives from an increase in the activity level of the respective enzymes, we measured the effect of growth phase during the growth of batch cultures of Synechococcus sp. strain PCC7942 on the specific activity of 6-phosphogluconate dehydrogenase (6PGD) and glucose 6-phosphate dehydrogenase. The specific activities were constant during the exponential growth phase of the culture, but they increased about fivefold during the transition into stationary phase. As an approach to determining the level of expression at which the growth-phase-dependent regulation of 6PGD level is exerted, we constructed operon and gene fusions between the gnd gene, which encodes 6PGD, and the Escherichia coli lacZ gene, which encodes beta-galactosidase (beta Gal). Strains harboring the fusions integrated into the cyanobacterial chromosome were prepared, and the growth-phase dependence of beta Gal level was determined. The specific activity of beta Gal in cultures of both types of fusion strains increased during the transition into stationary phase, indicating that the growth-phase-dependent regulation is on the gnd mRNA level. Characterization of the growth-phase-dependent induction of 6PGD in strains carrying differing amounts of DNA upstream from the gnd structural gene led to the localization of the promoter and the regulatory site on the restriction map of the gene, whose sequence has previously been determined.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arsenate reduction mediated by the plasmid-encoded ArsC protein is coupled to glutathione

Resistance to arsenate conferred on Escherichia coli by the ars operon of plasmid R773 requires both the product of the arsC gene and reduction of arsenate to arsenate. A genetic analysis was performed to identify the source of reducing potential in vivo. in addition to the ars genes, arsenate resistance required the products of the gor gene for glutathione reductase and the gshA and gshB genes for glutathione synthesis. Mutations in the trx and grx genes for thioredoxin and glutaredoxin, respectively, had no effect on arsenate resistance. Although resistance required the arsC gene, the rate of reduction of arsenate to arsenate was nearly the same in cells lacking the ars operon. In strains deficient in glutathione biosynthesis this endogenous reduction was greatly diminished, and cells exhibited increased sensitivity to arsenate. When glutathione was supplied exogenously to such mutants, resistance was restored only to cells expressing the ars operon, and only such cells had detectable arsenate reduction after addition of glutathione. Since ArsC-catalysed reduction of arsenate provides high level resistance, physical coupling of the ArsC reaction to efflux of the resulting arsenite is hypothesised.     

The Burkholderia pseudomallei BpeAB-OprB efflux pump: expression and impact on quorum sensing and virulence

BpeAB-OprB is a multidrug efflux pump of the bacterial pathogen Burkholderia pseudomallei and is responsible for conferring antimicrobial resistance to aminoglycosides and macrolides. Expression of bpeAB-oprB is inducible by its substrate erythromycin and upon entry into stationary phase. BpeR, a member of the TetR family, functions as a repressor of the bpeAB-oprB operon. bpeR expression was similarly induced at stationary phase but lagged behind the induction of bpeAB-oprB expression. The induction of bpeAB-oprB expression could be advanced to the early exponential phase by exogenous addition of the B. pseudomallei autoinducers N-octanoyl-homoserine lactone (C8HSL) and N-decanoyl-homoserine lactone (C10HSL), suggesting that the bpeAB-oprB operon may be quorum regulated. On the other hand, acyl-homoserine lactone (acyl-HSL) production was undetectable in the bpeAB-null mutant and strains which overexpress bpeR. The failure of these strains to produce acyl-HSLs seemed to be at the level of synthesis of acyl-HSLs, as growth-phase-dependent expression of the autoinducer synthase BpsI was abolished in the bpeAB-null mutant. bpsI expression remained growth phase dependent in the bpeR mutant which had functional BpeAB-OprB. BpeAB-OprB function is likewise necessary for optimal production of quorum-sensing-controlled virulence factors such as siderophore and phospholipase C and for biofilm formation. Cell invasion and cytotoxicity towards human lung epithelial (A549) and human macrophage (THP-1) cells were also significantly attenuated in both the bpeAB mutant and bpeR-overexpressing strains, thus suggesting the possibility of attenuating B. pseudomallei virulence using inhibitors of the BpeAB-OprB efflux pump.     

Error-prone DNA polymerase IV is regulated by the heat shock chaperone GroE in Escherichia coli

An insertion in the promoter of the operon that encodes the molecular chaperone GroE was isolated as an antimutator for stationary-phase or adaptive mutation. The groE operon consists of two genes, groES and groEL; point mutations in either gene conferred the same phenotype, reducing Lac+ adaptive mutation 10- to 20-fold. groE mutant strains had 1/10 the amount of error-prone DNA polymerase IV (Pol IV). In recG+ strains, the reduction in Pol IV was sufficient to account for their low rate of adaptive mutation, but in recG mutant strains, a deficiency of GroE had some additional effect on adaptive mutation. Pol IV is induced as part of the SOS response, but the effect of GroE on Pol IV was independent of LexA. We were unable to show that GroE interacts directly with Pol IV, suggesting that GroE may act indirectly. Together with previous results, these findings indicate that Pol IV is a component of several cellular stress responses.     

MexAB-OprM hyperexpression in NalC-type multidrug-resistant Pseudomonas aeruginosa: identification and characterization of the nalC gene encoding a repressor of PA3720-PA3719

MexAB-OprM is a multidrug efflux system that contributes to intrinsic and acquired multidrug resistance in Pseudomonas aeruginosa, the latter as a result of mutational hyperexpression of the mexAB-oprM operon. While efflux gene hyperexpression typically results from mutations in the linked mexR repressor gene, it also occurs independently of mexR mutations in so-called nalC mutants that demonstrate more modest mexAB-oprM expression and, thus, more modest multidrug resistance than do mexR strains. Using a transposon insertion mutagenesis approach, nalC mutant strains were selected and the disrupted gene, PA3721, identified. Amplification and sequencing of this gene from previously isolated spontaneous nalC mutants revealed the presence of mutations in all instances and as such, PA3721 has been renamed nalC. PA3721 (nalC) encodes a probable repressor of the TetR/AcrR family and occurs upstream of an apparent two-gene operon, PA3720-PA3719, whose expression was negatively regulated by PA3721. Thus, PA3720-PA3719 was hyperexpressed in transposon insertion and spontaneous nalC mutants. The loss of PA3719 but not of PA3720 expression in a spontaneous nalC mutant reduced MexAB-OprM expression to wild-type levels and compromised multidrug resistance, an indication that hyperexpression of PA3719 only was necessary for the nalC phenotype. Introduction of PA3719 into wild-type P. aeruginosa on a multicopy plasmid was, in fact, sufficient to promote elevated MexAB-OprM expression and multidrug resistance characteristic of a nalC strain. Thus, the nalC (PA3721) mutation serves only to enhance PA3720-PA3719 expression, with expression of PA3719 (encodes a 53 amino acid protein of predicted pI 10.4) directly or indirectly impacting MexAB-OprM expression. Intriguingly, nalC strains produce markedly elevated levels of stable MexR protein suggesting that PA3720-PA3719 hyperexpression somehow modulates MexR repressor activity. The deduced products of PA3720-PA3719 show no homology to sequences presently in the GenBank databases, however, and as such provide no clues as to how this might occur.     

Expression of the arginine deiminase pathway genes in Lactobacillus sakei is strain dependent and is affected by the environmental pH

The adaptation of Lactobacillus sakei to a meat environment is reflected in its metabolic potential. For instance, the ability to utilize arginine through the arginine deiminase (ADI) pathway, resulting in additional ATP, represents a competitive benefit. In L. sakei CTC 494, the arc operon (arcABCTDR) shows the same gene order and organization as that in L. sakei 23K, the genome sequence of which is known. However, differences in relative gene expression were found, and these seemed to be optimal in different growth phases, namely, the highest relative gene expression level was in the end exponential growth phase in the case of L. sakei CTC 494 and in the mid-exponential growth phase of L. sakei 23K. Also, the environmental pH influenced the relative expression level of the arc operon, as shown for L. sakei CTC 494, with the highest relative expression level occurring at the optimal pH for growth (pH 6.0). Deviations from this optimal pH (pH 5.0 and pH 7.0) resulted in an overall decline of the relative expression level of all genes of the arc operon. Furthermore, a differential relative expression of the individual genes of the arc operon was found, with the highest relative gene expression occurring for the first two genes of the arc operon (arcA and arcB). Finally, it was shown that some L. sakei strains were able to convert agmatine into putrescine, suggesting an operational agmatine deiminase pathway in these strains, a metabolic trait that is undesirable in meat fermentations. This study shows that this metabolic trait is most probably encoded by a previously erroneously annotated second putative arc operon.