Genetic Determination of Resistance to Acriflavine, Phenethyl Alcohol, and Sodium Dodecyl Sulfate in Escherichia coli

Wild-type strains of Escherichia coli K-12 are resistant to acriflavine. Gene acrA(+) which determines resistance to acriflavine is located near the lac region of the chromosome. This gene determines not only resistance to basic dyes but also resistance to phenethyl alcohol. Acriflavine resistance was transmitted, together with phenethyl alcohol resistance, from a resistant Hfr strain to a sensitive recipient by mating. Reversion of the mutant gene acrA1 (phenotypically acriflavine-sensitive) to acriflavine resistance was accompanied by a change from phenethyl alcohol sensitivity to resistance, and conversely the revertants selected for phenethyl alcohol resistance were resistant to acriflavine. A suppressor mutation, sup-100, closely linked to the acr locus, suppresses the acrA1 gene (phenotypically acriflavine-resistant), but does not determine resistance to phenethyl alcohol and basic dyes other than acriflavine. The genetic change in the locus acrA1 to types resistant to basic dyes and phenethyl alcohol was accompanied by an increase in resistance to sodium dodecyl sulfate, a potent solvent of lipopolysaccharide and lipoprotein. It is suggested that gene acrA determines synthesis of a membrane substance. The system seemed to be affected strongly by the presence of inorganic phosphate.     

Effect of alternating current exposure on the resistivity of resting Escherichia coli B cells to crystal violet and other basic dyes

Phosphate buffer suspensions of resting Escherichia coli B cells at pH 70 were anaerobically exposed to alternating current (a.c.) of 50 Hz at a current density of 600 60 mA/cm² and 34 3C. The minimum inhibitory concentrations of eight basic dyes: crystal violet, malachite green, brilliant green, fuchsin, methylene blue, toluidine blue, safranin and acriflavine for exposed cells were decreased to about the half values of those for unexposed ones when both cells were grown in the minimal medium including one of the dyes. The integrated viabilities of exposed cells tended to decline with increasing concentration of the dyes markedly more than those of unexposed ones, whereas the exposed cells took up the dyes less readily than the unexposed cells. These results suggested that a.c. exposure may serve as an agent which renders E. coli cells susceptible to the basic dyes.     

Effect of alternating current exposure on the resistivity of resting Escherichia coli B cells to crystal violet and other basic dyes

Phosphate buffer suspensions of resting Escherichia coli B cells at pH 7.0 were anaerobically exposed to alternating current (a.c.) of 50 Hz at a current density of 600 +/- 60 mA/cm2 and 34 degrees +/- 3 degrees C. The minimum inhibitory concentrations of eight basic dyes: crystal violet, malachite green, brilliant green, fuchsin, methylene blue, toluidine blue, safranin and acriflavine for exposed cells were decreased to about the half values of those for unexposed ones when both cells were grown in the minimal medium including one of the dyes. The integrated viabilities of exposed cells tended to decline with increasing concentration of the dyes markedly more than those of unexposed ones, whereas the exposed cells took up the dyes less readily than the unexposed cells. These results suggested that a.c. exposure may serve as an agent which renders E. coli cells susceptible to the basic dyes.     

Effect of inorganic phosphate on acridine inhibition and plasmid curing in Escherichia coli.

Some mutants and stock strains of Escherichia coli K12 were sensitive to acriflavine in the presence of inorganic phosphate but were resistant to acriflavine in its absence. They mutated spontaneously to resistance to acriflavine plus phosphate. The synergistic effect of phosphate on acriflavine sensitivity was increased at high pH values. Genetic analysis suggested that the mutations occurred in the gene acrA. Electron microscopic observation suggested that the presence of acriflavine plus phosphate affected the structure of the plasma membrane and the cytoplasm under it. This structural alteration was not caused by acriflavine alone. Acridine orange plus phosphate can more effectively eliminate the plasmid F8-gal+ than acridine orange alone.     

Acridine Binding by Escherichia coli: pH Dependency and Strain Differences

Acridine dye binding by cells of Escherichia coli has been characterized in terms of a number of parameters. There is a temperature-dependent, readily reversible binding of acriflavine which occurs to a greater extent with acridine-sensitive mutants of E. coli K-12 than with wild-type E. coli B or K-12. There is an essentially irreversible internal binding of acriflavine which occurs when the cellular permeability barriers are destroyed or altered by heat-treatment, elevated pH, treatment with toluene or phenethyl alcohol, or infection with bacteriophage T2 or T4. Both the reversible and the irreversible binding of acridines occurs more effectively with the acridine dye acriflavine than with the related dye proflavine, and still less effectively with 9-aminoacridine and quinacrine. These properties of acridine binding can be correlated with various inhibitory effects of the dyes on the cells.     

Molecular cloning and characterization of the HmrM multidrug efflux pump from Haemophilus influenzae Rd

We cloned a gene responsible for norfloxacin resistance from the chromosomal DNA of Haemophilus influenzae Rd, and designated the gene as hmrM. HmrM showed sequence similarity with NorM of Vibrio parahaemolyticus and YdhE of Escherichia coli and others that belong to the MATE family multidrug efflux pumps. The recombinant plasmid carrying the hmrM gene conferred elevated resistance not only to norfloxacin but also to acriflavine, 4 ', 6-diamidino-2-phenylindole, doxorubicin, ethidium bromide, tetraphenylphosphonium chloride, Hoechst 33342, daunomycin, berberine, and sodium deoxycholate in Escherichia coli KAM32, a drug-hypersensitive strain. We observed an Na+-dependent efflux of ethidium and an ethidium-induced efflux of Na+ in E. coli KAM32 cells harboring the plasmid carrying the hmrM gene. These results indicate that HmrM is an Na+/drug antiporter-type multidrug efflux pump. A difference in substrate preference was observed between HmrM, NorM, and YdhE.     

Effect of acriflavine on the plasma membrane of Escherichia coli K12

Plasma membranes of acriflavine-sensitive mutant (acrA) and acriflavine-resistant (acrA+, wild-type and true revertant) Escherichia coli K12 strains treated with acriflavine were observed under the electron microscope by means of the freeze-fracture technique. The plasma membrane of the acrA mutant exhibited a complex lamellar structure at the end of the cell when treated with 20 micrograms acriflavine ml-1. However, the membrane of the acrA+ cells also gave the lamellar complex when treated with a very high concentration of acriflavine (100 micrograms ml-1). The size of the intramembranous particles was not affected by the acriflavine treatments.     

A two-component multidrug efflux pump, EbrAB, in Bacillus subtilis

Genes (ebrAB) responsible for ethidium resistance were cloned from chromosomal DNA of Bacillus subtilis ATCC 9372. The recombinant plasmid produced elevated resistance against ethidium bromide, acriflavine, pyronine Y, and safranin O not only in Escherichia coli but also in B. subtilis. It also caused an elevated energy-dependent efflux of ethidium in E. coli. EbrA and EbrB showed high sequence similarity with members of the small multidrug resistance (SMR) family of multidrug efflux pumps. Neither ebrA nor ebrB was sufficient for resistance, but introduction of the two genes carried on different plasmids conferred drug resistance. Thus, both EbrA and EbrB appear to be necessary for activity of the multidrug efflux pump. In known members of the SMR family, only one gene produces drug efflux. Thus, EbrAB is a novel SMR family multidrug efflux pump with two components.     

dye (arc) Mutants: insights into an unexplained phenotype and its suppression by the synthesis of poly (3-hydroxybutyrate) in Escherichia coli recombinants

arcA codes for a central regulator in Escherichia coli that responds to redox conditions of growth. Mutations in this gene, originally named dye, confer sensitivity to toluidine blue and other redox dyes. However, the molecular basis for the dye-sensitive phenotype has not been elucidated. In this work, we show that toluidine blue redirects electrons to O2 and causes an increase in the generation of reactive O2 species (ROS). We also demonstrate that synthesis of poly (3-hydroxybutyrate) suppresses the Dye phenotype in E. coli recombinants, as the capacity to synthesize the polymer reduces sensitivity to toluidine blue, O2 consumption and ROS production levels.     

Inhibition and enhancement of phleomycin-induced DNA breakdown by aromatic tricyclic compounds.

Cationic aromatic tricyclic compounds including triphenylmethane dyes, phenazines, phenoxazines, acridines, phenothiazines, phenanthridinium compounds, anthracenes and xanthene dyes, which amplify cell killing in phleomycin-treated Escherichia coli B cells also modified phleomycin-induced breakdown of DNA to acid-soluble fragments. A plot of DNA breakdown as a function of concentration was bell-shaped for each of the active compounds, i.e. as the concentration increased, DNA breakdown was enhanced initially, but above a certain concentration, the proportion of DNA degraded declined, often to zero. One of the compounds, acriflavine, when tested also inhibited DNA breakdown following ultraviolet irradiation. A study, by sedimentation methods, of DNA single-strand breakage in phleomycin-treated E. coli cells, using 3 representative compounds, Crystal Violet, 3,6-diaminoacridine and Methylene Blue, revealed a consistent increase in DNA strand breaks as concentration of compound increased. In similar experiments with ethidium bromide the breakage yield/concentration curve exhibited a maximum. In general, however, it seems that the inhibition of DNA-breakdown observed at higher concentrations of these amplifying compounds is not explicable by an effect on the primary breakage event, but is due to suppression of exonucleolytic activity in the cells.     

VmrA, a Member of a Novel Class of Na+-Coupled Multidrug Efflux Pumps from Vibrio parahaemolyticus

Gene vmrA, cloned from Vibrio parahaemolyticus, made Escherichia coli resistant to 4',6-diamino-2-phenylindol, tetraphenylphosphonium chloride, acriflavine, and ethidium bromide. VmrA belongs to the DinF branch of MATE family efflux transporters. VmrA catalyzed acriflavine efflux and showed Na(+)/drug transporter activity because the addition of tetraphenylphosphonium to Na(+)-loaded cells caused Na(+) efflux.     

Use of polymyxin B, levallorphan, and tetracaine to isolate novel envelope mutants of Escherichia coli.

Mutants of Escherichia coli were isolated by their resistance to the bacteriocidal effects of the membrane-active drugs polymyxin B, levallorphan, and tetracaine. The mutants were examined for additional changes in cellular physiology evoked by the lesions; many polymyxin-resistant strains had a concomitant increased sensitivity to anionic detergents, and several strains of each type had concomitant alterations in generation time and morphology. Mutants of each class (polymyxin resistant, tetracaine resistant, and levallorphan resistant) were transduced into recipient strains. The levallorphan resistance site (lev) was located at approximately 9 min on the E. coli chromosome. Polymyxin (pmx) and tetracaine (tec) resistance loci were also transduced. The lev and tec strains had a slight prolongation of generation time, in contrast with their isogenic wild-type strains. The tec transductant produced long filaments in the absence of tetracaine and had an altered colonial morphology, it reverted at high frequency, with the morphological abnormalities reverting along with the tetracaine resistance. The pmx transductant had an increased sensitivity to levallorphan and to anionic detergents. In contrast, both lev and tec mutants were more resistant to acriflavine than was the wild type or the pmx transductant. The pmx, lev, and tec loci differed in sensitivity to mitomycin C; the lev strain was more resistant, the tec strain was more sensitive, and the pmx strain was much more sensitive than the wild type. There was no difference in sensitivity to several other dyes and detergents, colicins, or T bacteriophage between the transductant and isogenic wild-type strains. Thus, lev, tec, and pmx loci confer more subtle alterations in the permeability barrier than do lipopolysaccharide-deficient mutants previously studied.     

Characterization of the antiseptic-resistance gene qacEΔ1 isolated from clinical and environmental isolates of Vibrio parahaemolyticus and Vibrio cholerae non-O1

The nucleotide sequence and mechanism of action were examined on the antiseptic-resistance gene qacE delta 1 that had been isolated from Pseudomonas aeruginosa, Vibrio parahaemolyticus and Vibrio cholerae non-O1. The nucleotide sequences of qacE delta 1 genes isolated from environmental isolates of V. cholerae non-O1 and V. parahaemolyticus differed by one base from that of the gene from P. aeruginosa. Escherichia coli C600 that harbored qacE delta 1 genes from several strains of Vibrio spp. exhibited low-level resistance to intercalating dyes. The resistance of E. coli cells with these genes to intercalating dyes, such as ethidium bromide, was mediated by an efflux system. Moreover, the activity of QacE delta 1 was inhibited in the presence of calcium channel blockers but not of calmodulin inhibitors. These results indicate that the qacE delta 1 gene can be function in E. coli and that the gene mediates resistance in a similar manner to the antiseptic-resistance gene smr.     

Linkage and Segregation of Unselected Markers in Matings of Nocardia erythropolis with Nocardia canicruria

The segregation of unselected genes expressing resistance or susceptibility to acriflavine, erythromycin, streptomycin, and tetracycline was analyzed in selected prototrophic recombinants resulting from matings of Nocardia erythropolis and N. canicruria. The organisms were shown to be functionally haploid and appeared to contain not more than one genome. It was postulated that all observed genes were present in a linear linkage group. The ordering of the genes in N. erythropolis was: tetB10 eryB9 his-3 purA1 acr-2 strA1 (respectively, resistance to tetracycline and erythromycin, deficiency for histidine and for purine, and resistance to acriflavine and streptomycin). The ordering of the genes in N. canicruria was: purB2 tetA9 eryA7 acr-11 strB2 (respectively, deficiency for purine, and resistance to tetracycline, erythromycin, acriflavine, and streptomycin). Excluding the genes for acriflavine resistance, acr-2 and acr-11, resistance loci in N. erythropolis were not allelic to and showed lateral displacement from genes controlling phenotypically similar resistance in N. canicruria. Evidence for some lack of homology between N. erythropolis and N. canicruria genomes was found. Recombination phenomena between the nocardial species was postulated to occur as a result of formation of a heterogenomic zygote in which new combinations were produced. Production of selectable, haploid recombinants was ascribed to subsequent haploidization of the zygote.     

Gene cloning and characterization of VcrM,a Na+-coupled multidrug efflux pump,from Vibrio cholerae non-O1

We cloned a DNA fragment responsible for drug resistance from chromosome of Vibrio cholerae non-O1. Nucleotide sequence analysis of this fragment revealed the presence of a single open reading frame encoding a protein consisting of 445 amino acid residues. We designated the gene as vcrM. Hydropathy analysis of the deduced amino acid sequence of VcrM suggests the presence of 12 trans-membrane segments. A dendrogram showed that VcrM is a member of the DinF-subfamily within the MATE family of multidrug efflux pumps. Expression of the cloned vcrM gene in drug-hypersensitive Escherichia coli KAM32 cells made them resistant to acriflavine, 4', 6-diamidino-2-phenylindole, Hoechst 33342, rhodamine 6G, tetraphenylphosphonium chloride (TPPCl) and ethidium bromide. Efflux of acriflavine due to VcrM was dependent on Na+ or Li+. Moreover, Na+ efflux was observed with VcrM when TPPCl was added to Na+-loaded cells. Therefore, we conclude that VcrM is a Na+/drug antiporter-type multidrug efflux pump.     

Membrane Mutation Associated with Sensitivity to Acriflavine in Escherichia coli

The role of plasma membrane on the acriflavine sensitivity of Escherichia coli was studied. (14)C-uracil incorporation into ribonucleic acid fraction by spheroplasts was more sensitive to acriflavine in the acriflavine-sensitive strain (genotype acrA) than in the acriflavine-resistant (genotype acrA(+)) strain. There was no difference between two types of cells in the response to osmotic shock, phage sensitivity, and other treatments used to investigate the structure and stability of cell wall. Differences in the electron-microscopic figures between acrA and acrA(+) cells was found in the plasma membrane, surface area just below the membrane, and ribosomal aggregation, when cells were treated with acriflavine. It is concluded that a primary site of acriflavine action is on the plasma membrane, and the acrA mutation is mediated by it. On the basis of the present results, it is evident that differences in the acriflavine binding and the sensitivity to phenethyl alcohol and sodium dodecyl sulfate between the acrA and acrA(+) strains, previously reported, are attributable to a structural difference in the plasma membrane between the two strains.     

EmmdR, a new member of the MATE family of multidrug transporters, extrudes quinolones from Enterobacter cloacae

We cloned a gene, ECL_03329, from the chromosome of Enterobacter cloacae ATCC13047, using a drug-hypersensitive Escherichia coli KAM32 cell as the host. We show here that this gene, designated as emmdR, is responsible for multidrug resistance in E. cloacae. E. coli KAM32 host cells containing the cloned emmdR gene (KAM32/pEMMDR28) showed decreased susceptibilities to benzalkonium chloride, norfloxacin, ciprofloxacin, levofloxacin, ethidium bromide, acriflavine, rhodamine6G, and trimethoprim. emmdR-deficient E. cloacae cells (EcΔemmdR) showed increased susceptibilities to several of the antimicrobial agents tested. EmmdR has twelve predicted transmembrane segments and some shared identity with members of the multidrug and toxic compound extrusion (MATE) family of transporters. Study of the antimicrobial agent efflux activities revealed that EmmdR is an H+-drug antiporter but not a Na+ driven efflux pump. These results indicate that EmmdR is responsible for multidrug resistance and pumps out quinolones from E. cloacae.     

Acceptance and transfer of plasmid Rts1 by bacteria of the genus Erwinia]

The ability of 13 Erwinia strains to accept, to inherit and to transmit the Rts1 factor by conjugation was studied. 11 strains accepted the Rts1 factor from Escherichia coli K-12 CSH-2 with the frequency of about 10(-7)--10(-3). The Rts1 factor was genetically stable in the Erwinia cells and was not eliminated by acriflavine and under the temperature of 37 and 42 degrees C. All the R+ exconjugants were characterized with more high degree of the resistance of kanamycin than E. coli cells harbouring the same R factor. Erwinia strains harbouring the Rts1 plasmid transferred it by conjugation into homologic (Erwinia) and heterologic (E. coli) bacteria. The study of kinetics of the transfer of the Rts1 factor in different mating systems showed that the transfer of this plasmid from R+ Erwinia into R- Erwinia and R- E. coli--in the liquid medium. It is concluded that Erwinia can be the host and the donor of the Rts1 factor.     

An H(+)-coupled multidrug efflux pump, PmpM, a member of the MATE family of transporters, from Pseudomonas aeruginosa

We cloned the gene PA1361 (we designated the gene pmpM), which seemed to encode a multidrug efflux pump belonging to the MATE family, of Pseudomonas aeruginosa by the PCR method using the drug-hypersensitive Escherichia coli KAM32 strain as a host. Cells of E. coli possessing the pmpM gene showed elevated resistance to several antimicrobial agents. We observed energy-dependent efflux of ethidium from cells possessing the pmpM gene. We found that PmpM is an H(+)-drug antiporter, and this finding is the first reported case of an H(+)-coupled efflux pump in the MATE family. Disruption and reintroduction of the pmpM gene in P. aeruginosa revealed that PmpM is functional and that benzalkonium chloride, fluoroquinolones, ethidium bromide, acriflavine, and tetraphenylphosphonium chloride are substrates for PmpM in this microorganism.     

Identification and cloning of a plasmid-encoded erythromycin resistance determinant from Lactobacillus reuteri

Plasmid analysis, plasmid curing, cloning, and hybridization experiments were used to study four Lactobacillus reuteri strains showing high resistance to erythromycin. Plasmid curing with acriflavine resulted in a loss of erythromycin resistance in a frequency of 1-10%. For three of the strains this was accompanied by a loss of a 6.9-MDa plasmid, which was shown to be identical for the different strains and designated pLUL631. The erythromycin (erm) gene was located on a 5.5-MDa plasmid in the fourth strain. A restriction map of pLUL631 was constructed and the location of the erm gene on the plasmid was identified by cloning in Escherichia coli. By using a Streptococcus lactis-E. coli shuttle vector, the erm gene was also transformed to S. lactis and expressed. The erm gene from L. reuteri was shown to be related to the erm gene from pIP501 (Streptococcus agalactiae) by DNA-DNA hybridization.