Salmonella typhimurium LT2 mutation affecting the deletion of resistance determinants on R plasmids.

Plasmid Rms312, specifying resistance to tetracycline (Tc), chloramphenicol (Cm), streptomycin (Sm), sulfonamide (Su), and mercury chloride (Mer), deletes both Tc and Cm Sm Su Mer determinants at a high frequency in Salmonella typhimurium LT2. S. typhimurium mutants that were stable carriers of Rms312 were isolated by alternate culture of R-bearing cells in a medium containing either tetracycline or chloramphenicol. In one of these mutants the deletion frequency of drug resistance determinants was decreased by about 100-fold not only Rms312, but also in R100, R1, and R6-5. This mutation caused a slight reduction of ultraviolet resistance but did not affect generalized genetic recombination, indicating that the mutation is different from recA. The mutation, designated dor (deletion of r-determinants), was mapped to a position near 57 units in the new linkage map of S. typhimurijm LT2 (K. E. Sanderson and P. E. Hartman, Microbiol. Rev. 42:471-519, 1978). The dor mutation had no effect on IS1-mediated illegitimate deletion, indicating that the dor mutation is different from the del mutation described by Nevers and Saedler (P. Nevers and H. Saedler, Mol. Gen. Genet. 160:209-214, 1978).     

Characterization of pili determined by drug resistance plasmids R711b and R778b.

The bacterial drug resistance plasmids R711b and R778b, at present classified in the X incompatibility group, determine pili (designated 711) that resemble F pili morphologically. Like F pili, 711 pili adsorb F-specific filamentous bacteriophages to their tips, though more often in pairs, than singly. However, F-specific RNA-containing bacteriophages are not adsorbed to their sides, and strains carrying the plasmids are resistant to these phages. Pili determined by the only IncFV plasmid Folac are similar to 711 pili in their phage adsorption properties, but they are serologically different, as are F pili. It is concluded that F, Folac and 711 pili have basic differences in spite of a morphological resemblance.     

Antimicrobial resistance and resistance plasmids in Salmonella from Ontario, Canada.

Collections of 589 human and 204 animal strains of Salmonella isolated in Ontario during the summer of1974 were examined for susceptibility to 12 antimicrobial agents. Many isolates were found to be resistant to both chloramphenicol (12.4% of the human and 38.2% of the animal sample) and ampicillin. The chloramphenicol resistance almost always occurred in strains which were also resistant to ampicillin and was usually due to a self-transmissible plasmid with a resistance pattern of CmKmSmTc (chloramphenicol, kanamycin, streptomycin, and tetracycline) or CmTc. Ampicillin resistance in these strains was mediated by a variety of plasmids with patterns ApSu (ampicillin and sulfa drugs) and ApSmSu, many of which were nonself-transmissible. Ampicillin resistance in chloramphenicol-sensitive strains was transferable from 21% of the strains, and it was associated with resistance patterns which were different from the self-transferable ampicillin patterns from the chloramphenicol-resistance strains.     

R plasmids among Gram-negative bacteria with multiple drug resistance isolated in a general hospital.

The incidence of conjugative R plasmids in multiple drug-resistant strains of gram-negative bacteria isolated in 1973 from patients in a 700-bed general hospital in Tokyo and some properties of the R plasmids isolated are described. Conjugative R plasmids were found in 52 of the 96 strains (54%), from which 74 R plasmids were demonstrated. It is remarkable that the isolation frequency of R plasmids mediating quadruple- or five-drug resistance was rather low, and the complete pattern of multiple resistance of the original isolates was only rarely transferred by conjugation. These results revealed the existing state of the distribution of R plasmids among hospital strains with multiple drug-resistance.     

Genetic properties of the Salmonella enteritidis R404 plasmid aggregate. II. Separation of plasmids by transformation.

Transformational separation of plasmids from R404 plasmid aggregate found in Salmonella enteritidis strain was performed. Three classes of transformants differing in their resistance patterns were isolated. Genetic properties of the transformants suggest that their resistance is determined by single plasmids. Plasmid pCK3 (Tra-ApCbCrSuSm) and pCK4 (Tra-ApCbCrCm) are nonconjugative while plasmid pCG1 (TraApCbCrSuSmTcKmNm) is conjugative. Separation of all plasmids of R404 plasmid aggregate allowed to determine their genetic properties and the manner of conjugational transfer of R404 plasmid aggregate R-determinants.     

Characterization of large plasmids encoding resistance to toxic heavy metals in Salmonella abortus equi

Salmonella abortus equi vaccine strains were found to be resistant to high levels of toxic heavy metals--arsenic, chromium, cadmium, and mercury. The two strains 157 and 158 were resistant to ampicillin also. Curing of these strains resulted in loss of one or more resistance marker indicating plasmid borne resistance. Plasmid profile of strain 157 showed presence of three plasmids of 85, 54, and 0.1 Kb, whereas 158 strain showed presence of 85 Kb and 2 Kb plasmids. Plasmids were isolated from strain 157 and introduced into E. coli DH5alpha with a transformation efficiency of 2 x 10(3) transformants/microg DNA. Interestingly the transformants were resistant to antibiotics, heavy metals (As, Cr, Cd, Hg) and was also able to utilize citrate, a trait specific to Salmonella species. We report and establish for the first time the transferable large plasmids encoding resistance to various heavy metals, antibiotics and biochemical nature of S. abortus equi.     

The role of R plasmids in the resistance of bacteria in air

The study of Escherichia coli J 53, used as a model, has revealed that some R plasmids isolated from Serratia marcescens and Klebsiella pneumoniae, found to be the cause of the outbreak of hospital infection, ensure, besides multiple drug resistance, also their viability in the air.     

R plasmids with thermosensitive transferability in Salmonella strains isolated from humans.

Temperature dependence of transfer was examined with ten R plasmids originating from clinical isolates of Salmonella. Six of the plasmids were thermosensitive upon transfer, five of which were originally harbored in S. typhimurium and the remaining one in S. derby. One of these plasmids, pNR502, which conferred resistance to kanamycin, streptomycin (Sm) and tetracycline (Tc) on its host was stably maintained both in Salmonella and Escherichia coli at either 30, 37, or 43 C. Another plasmid, pNR516, which was resistant to chloramphenicol, sulfathiazole, Sm and Tc, was slightly unstable only at 43 C. The remaining four plasmids, pNR503, pNR510, pNR512 and pNR514, conferred resistance to Sm and Tc. Of these plasmids, the former two were stably maintained at both 30 and 37 C, but were unstable at 43 C. The latter two were slightly unstable at the lower temperatures and considerably unstable at 43 C. Kinetics of the transfer of the plasmid pNR503 revealed that the efficiency of transfer of the plasmid between E. coli strains was affected not only by the temperature of the conjugation but also by the preincubation temperature of the donor culture before the conjugation.     

R1767, an example of the evolution of resistance plasmids

The Salmonella R-factor system R1767 undergoes frequent rearrangement of its plasmid components. The flux of genetic material within this plasmid system depends on a combination of illegitimate and homologous recombination. The presence of several copies of IS160 and two multiresistance transposons, Tn2410 and Tn2411, are substantial reasons for the observed variations.     

Molecular and genetic studies of an R factor system consisting of independent transfer and drug resistance plasmids

Certain genetic, structural, and biochemical properties of a class 2 R-factor system consisting of the conjugally proficient transfer plasmid I and the naturally occurring non-conjugative tetracycline (Tc) resistance plasmid 219 are reported. I and 219 exist as separate plasmid deoxyribonucleic acid (DNA) species in both Escherichia coli and Salmonella panama, having molecular weights of 42 x 10(6) and 5.8 x 10(6), respectively. The buoyant densities of I and 219 are 1.702 and 1.710 g/cm(3), respectively, in neutral cesium chloride. Although the Tc resistance plasmid is not transmissible in a normal conjugal mating, it is mobilized in a three-component mating by plasmid I and by certain other conjugative plasmids of the fi(+) or fi(-) phenotype. Mobilization does not appear to involve intermolecular recombination between plasmids, and no covalent linkage of resistance markers and fertility functions is observed. Transformation of CaCl(2)-treated E. coli by plasmid DNA is shown to be a useful procedure for studying the biological properties of different plasmid molecular species that have been fractionated in vitro, and for selectively inserting non-self-transmissible plasmids into specific bacterial strains. The effects of tetracycline on the rate of protein synthesis carried out by plasmid 219 were studied by using isolated E. coli minicells into which this plasmid had segregated. Consistent with the results of earlier investigations showing the inducibility of plasmid-mediated Tc resistance in E. coli, the antibiotic was observed to stimulate protein synthesis in minicells carrying the plasmid 219 and totally inhibit (3)H-leucine incorporation by minicells lacking the Tc resistance marker. Five discrete polypeptide species were synthesized by minicells carrying plasmid 219; exposure of minicells or parent bacteria to Tc resulted in specific and reproducible changes in polypeptide synthesis patterns.     

Plasmid-linked drug resistance in Salmonella typhimurium in Kuwait

A total of 143 strains of S. typhimurium isolated from clinical cases in Kuwait were investigated for drug resistance. Multidrug resistance (3 or more drugs) was seen in 76.9% of the strains. The common resistance patterns were ASuT (16), AKSuT (20), ASSuT (14), CKSSuT (14), ACKSSuT (10), ACGKSSuT (15) and ACKGSSuTTm (8). MIC of resistant strains was usually high. Sixteen isolates were examined for the transferability of the resistance. All had R-plasmids, both autotransferable and non-autotransferable which could be mobilised by factor X.     

Effect of plasmids for multiple antibiotic resistance on the change in Salmonella typhimurium phagovar

The data on the influence of acquired plasmid resistance to antibiotics on S. typhimurium phagovar. Plasmid R was transferred from S. typhimurium strain, isolated from the focus of hospital salmonellosis and resistant to the lytic action of phages, to Escherichia coli K12 and then to antibiotic-sensitive S. typhimurium strains of different phagovars, isolated from patients with alimentary toxicoinfections. The influence of plasmid R on the phagovar of recipient strains, most pronounced in strains of phagovar I, was revealed. The transconjugates of this phagovar considerably changed sensitivity to phages and in some cases acquired resistance to the lytic action of typing phages, thus becoming identical in this feature to the donor of the plasmid.     

Genetic instability of the feature of streptomycin resistance in Streptomyces erythraeus

The feature of streptomycin resistance in S. erythraeus, a culture producing erythromycin, is genetically unstable. Mutants sensitive to 0.03 mg/ml of streptomycin are formed in the initial streptomycin resistant strains at a rate of 0.04 per cent. It was shown possible to perform step-by-step selection for increasing streptomycin resistance (from 0.2 to 15 mg/ml) in the mutants producing and not producing erythromycin. The increase in the streptomycin resistance did not lead to a higher resistance to other aminoglycosides. Restriction analysis of the total DNA with the use of various endonucleases demonstrated that the increase in the resistance was not associated with amplification of DNA nucleotide sequences.     

Naturally occurring drug resistance plasmids in hospital strains of Staphylococcus aureus

A genetic analysis of multiply inorganic salts and antibiotic--resistant strains of Staphylococcus aureus was performed. Experiments designed to show reversion of organisms to antibiotic and inorganic salt susceptibility, as well as studies on the influence of ultraviolet irradiation of phage on the transduction frequencies of the resistance markers, indicated that determinants of chloramphenicol, tetracycline, aminoglycoside antibiotics, inorganic salts, and penicillin resistance in hospital strain are present on separate plasmids. Transduced by us plasmids pN742 and pN794 determined resistance to neomycin, kanamycin, paromomycin, lividomycin and streptomycin.