Characterization of the plasmids comprising the “R Factor” R5 and their relationships to other R plasmids

The “R factor” R5 confers resistance to tetracycline (Tc), streptomycin (Sm) and spectinomycin (Sp), chloramphenicol (Cm), sulfonamides (Su), kanamycin (Km), and mercuric ion (Mer). This phenotype is mediated by the presence of two R plasmids: pMH1 and pMH2, having approximate weights of 18.5 and 62 megadaltons (Mdal), respectively. pMH1 encodes Sm, Su, Cm, Mer, and Km resistance, and is nonconjugative. pMH2 confers Sm, Su, Cm, Mer, and Tc resistance, is conjugative, and belongs to the FII incompatibility group. NR79 is a 63-Mdal R plasmid encoding the same resistances as “R5,” and was derived from the same geographical source. It belongs to the FII incompatibility group and is conjugative. Analysis of restriction endonuclease digestion patterns and polynucleotide sequence homologies indicate that pMH1, pMH2, and NR79 are closely related. In addition, pMH2 and NR79 exhibit nearly complete homology to R100. Restriction endonuclease maps and resistance gene locations for pMH1, pMH2, and NR79 have been derived and a model for the evolutionary relationships of these plasmids is presented.     

Characteristics of the pKMR plasmids found in Shigella flexneri

The clinical isolate of Sh. flexneri 1b, resistant to 5 antibiotics and sulfonamides, has been studied by the method of conjugation and found to have a group of transfer-suppressed pKMR-plasmids: pKMR 204-1 (Ap Sm Tc Cm Km Su), pKMR 204-2 (Sm Km Su), pKMR 204-5 (Km Su) and pKMR 204-7 (Sm Tc Cm Km Su), whose molecular weight was 99, 71.2, 73.8 and 59.5 Md respectively. The treatment of the plasmids with restriction endonuclease BamHI has revealed that plasmids pKMR 204-2 and pKMR 204-5 are definitely related to plasmid KMR 204-1, being its deletion mutants. At the same time plasmids pKMR 204-1 and pKMR 204-7 differ in their sensitivity to endonuclease BamHI and stably coexist within the same cell, thus seeming to belong to different compatibility groups.     

Location of an ampicillin resistance transposon, Tn1701, in a group of small, nontransferring plasmids.

By restriction endonuclease cleavage mapping and electron microscopic examination of heteroduplexes, we have identified an ampicillin resistance determinant transposon, designated Tn1701, in a group of small, nontransferring plasmids which confer resistance to ampicillin (Ap), sulfonamide (Su), and streptomycin (Sm). Plasmid NTP1, which mediates Ap resistance, contains Tn1701. Recombinant plasmids NTP3 (Ap Su) and NTP4 (Ap Su Sm) contain Tn1701, indicating that they were derived by transposition of Tn1701 from NTP1 to an unrelated plasmid, NTP2 (Su Sm). The transposon Tn1701 is very similar to the known ampicillin resistance transposons Tn1, Tn2, and Tn3 in its size (3.2 x 10(6) daltons), base sequence homology observed by heteroduplex formation, restriction endonuclease cleavage sites, and possession of a short inverted repeat sequence at both ends. Like the other TnA elements, Tn1701 also specifies a type TEM beta-lactamase.     

Tn2301, a transposon construct carrying the entire transfer region of the F plasmid.

The largest R . BamHI fragment of the plasmid F, which carries the entire F conjugation system, has been cloned into the single R . BamHI site of the ampicillin (Ap) resistance transposon TN1. pDS1106 (ColE1 mob::Tn1) was the vector plasmid, and the resultant conjugative plasmid, pED830, was characterized both genetically and by restriction enzyme analysis. The transposon construct, denoted Tn2301, was transposable at frequencies similar to Tn1 to small nonconjugative plasmids or to the Escherichia coli host chromosome. In the former case, Apr conjugative plasmids were obtained, whereas in the latter case, Hfr strains resulted. Representative Hfr strains were characterized by quantitative and interrupted mating experiments. Extension of this technique for Hfvr formation should aid chromosome mapping both in E. coli and in other bacterial genera.     

Characterization and mobilization of nonconjugative plasmids encoding resistance to streptomycin and sulfanilamide

Most of nonconjugative streptomycin (Sm)- and sulfanilamide (Su)- resistance of clinical isolates belonging to various species of Enterobacteriaceae and Pseudomonas were encoded by an Inc Q plasmid, molecular size of which was 5.5 Md. The SmSu plasmids were efficiently mobilized by Inc P plasmids between E. coli strains. Inc I group and Inc F group plasmids could mobilize the Inc Q plasmids at lower efficiencies. The Inc Q plasmid was also mobilized to various species of Enterobacteriaceae at high frequencies without accompanying the conjugative Inc P plasmid; as a result, most of the SmSu-resistant transconjugants were nontransferable. The above results may explain the wide distribution of nonconjugative SmSu strains among clinical isolates.     

Drug resistance of the causative agent of Grigo'rev-Shiga dysentery (Shigella dysenteriae 1)isolated in the USSR

Forty strains of S. dysenteriae 1 isolated in the USSR within 1986-1988 were tested for their resistance to 11 antibacterial drugs. It was shown that 92.5-97.5 per cent of the isolates were resistant to chloramphenicol (Cm) and tetracycline (Tc), 22.5 per cent to streptomycin (Sm), 17.5 per cent to nalidixic acid (Nal) and 10 per cent to ampicillin (Ap) and polymyxin (Pm). Resistance to Cm Tc (51.4 per cent) and Cm Tc Nal (13.5 per cent) represented the predominating phenotype. 35 per cent of the strains carried conjugative R plasmids. In the majority of the cases, the determinants of resistance to Cm and Tc were transferred, which must define the high frequency of the strains resistant to Cm and Tc. All the tested strains were sensitive to gentamicin, neomycin, rifampicin, cefamezin and ciprofloxacin. Since the strains of S. dysenteriae 1 proved to be highly sensitive to the tested drugs it appeared possible to consider them as the drugs of choice in etiotropic therapy of patients with dysentery caused by the pathogens of the Grigoryev-Shiga group.     

The R-factors of multiple antibiotic resistant faecal coliforms isolated from a domestic dog

The antibiotic resistant faecal flora of a domestic dog suffering from an acute enteric infection was examined. The flora exhibited overall resistance to a wide variety of antibiotics. However, following restoration of the animal to normal health, overall resistance to ampicillin (Ap), tetracycline (Tc), chloramphenicol (Cm) and streptomycin (Sm) was lost, although low numbers of bacteria resistant to these four antimicrobial agents could still be isolated up to one year later. A total of 11 strains were purified for further study. All 11 were positively identified as Escherichia coli and shown to be resistant to various combinations of the above antibiotics, and additionally to kanamycin (Km). Each strain harboured from one to five plasmids, although only four proved capable of transferring antibiotic resistance to Escherichia coli K-12. One of the strains was found to harbour two conjugal plasmids pNJ101 (60 Md) and pNJ102 (133 Md) which coded for resistance to Cm, Tc, Ap and Cm, Tc, Km respectively. A third plasmid pNJ103 (29 Md) remains cryptic. The possession of the two plasmids pNJ101 and pNJ102 appears to be an unstable situation as variants arose harbouring one or other of the plasmids.     

Physical characterization of plasmids determining synthesis of a microcin which inhibits methionine synthesis in Escherichia coli.

Plasmid deoxyribonucleic acid (DNA) isolated from each of three antibiotic-resistant clinical strains of Escherichia coli producing the same microcin showed multiple bands upon agarose gel electrophoresis. Transformants selected either for microcin resistance or ampicillin resistance yielded plasmid DNA corresponding in size to only one of the multiple bands. Plasmids, isolated from all three hosts, which determined microcin resistance and microcin production measured about 4 megadaltons by sucrose density, restriction enzyme, and contour length analyses; cleavage of the DNAs by each of eight restriction enzymes showed the same response, and DNA-DNA hybridization indicated complete homology. The antibiotic resistance plasmids of the three host strains were uniformly larger, were of different sizes, and showed different restriction enzyme cleavage patterns. One of these R plasmids (pCP106) also determined the synthesis of the same microcin, and DNA-DNA hybridization studies indicated an approximate 2.4-megadalton homology with the 4-megadalton microcin plasmid pCP101. The microcin plasmids were present at approximately 20 copies per genome equivalent and were nonconjugative, whereas the R plasmids had a copy number of about 1, were conjugative, and could mobilize the microcin plasmid. Microcin plasmid pCP101 showed replication properties similar to those of a number of small multicopy plasmids such as ColE1.     

R factors of pathogenic strains of Escherichia coli isolated from infant diarrhoea

Several drug resistance patterns were determined in 170 pathogenic strains of E. coli isolated in 6 Polish towns from infant diarrhoea. The most frequent were strains resistant to 5 different drugs: ampicillin, tetracycline, chloramphenicol, streptomycin and sulfonamide. Conjugative R factors of 30 strains of the same resistance pattern (Ap Tc Cm Sm Su) were characterised by determining their Fi(F) character, incompatibility and molecular weight.     

Molecular epidemiology of plasmid patterns in Shigella dysenteriae type I obtained from an outbreak in West Bengal (India)

Abstract Multiple antibiotic-resistant Shigella dysenteriae type 1 isolates from a recent epidemic in West Bengal (India) showed identical plasmid patterns. All isolates were resistant to ampicillin (Am), chloramphenicol (Cm), tetracycline (Tc), streptomycin (Sm) and trimethoprim (Tp) and contained 6 plasmids, ranging from 2.5–120 kb. The Am resistance determinant was located on the 120 kb plasmid. This plasmid was unstable when the S. dysenteriae strains were grown above 37°C. The Bangladesh strains of S. dysenteriae type 1 showed identical plasmid patterns, except that many isolates were Am-sensitive and lacked the 120 kb plasmid. In strains from both Bangladesh and West Bengal, predominantly group-B plasmids conferred resistance to Cm and Tc. Comparisons of Eco R1 fragments generated from the total plasmid DNA content of each strain support the view that the plasmids present in the S. dysenteriae type 1 strains isolated from all recent epidemics in India and Bangladesh were identical.     

Genetic and molecular characterization of an epidemic plasmid coding for multidrug resistance in Salmonella typhimurium of human origin

All 201 multidrug resistant Salmonella typhimurium strains isolated from epidemics in India contained nonconjugative (157 strains) or conjugative (44 strains) Inc F1me multiresistance plasmids. Two small R-plasmids of 7 MDa which coded for resistance to either ampicillin or streptomycin and sulfamethoxazole were also detected along with other plasmids. The small plasmids were members of group 1 and group 2 incompatibility groups. Restriction endonuclease analysis of conjugative (96 MDa) and nonconjugative (88 MDa) Inc F1me plasmids showed considerable similarity except for the presence of unique fragments among both the groups and the loss of fragments corresponding to the smaller size of the nonconjugative plasmid. A single Inc F1me plasmid appears responsible for various outbreaks of multiresistant S. typhimurium in different parts of India.     

Survey of modifying enzymes and plasmids in amikacin-resistant Serratia marcescens

Forty amikacin-resistant strains of Serratia marcescens isolated from four different hospitals (A, B, C, and D) were examined for modifying enzymes and plasmids. Twenty-one of the isolates produced acetyltransferase that modified amikacin. Eighteen of the 21 acetyltransferase-bearing isolates were from different inpatients in hospital A and the other three were from hospital C. Amikacin resistance was mediated by conjugative plasmid of 24 megadaltons in 15 of the 18 acetyltransferase-bearing isolates of hospital A and by nonconjugative plasmids, derivatives of the 24-megadalton plasmids, in the remaining three isolates of the same hospital. The 24-megadalton plasmid determined aminoglycoside acetyltransferase (6') IV. This plasmid-borne enzyme conferred amikacin resistance on S. marcescens but not on Escherichia coli K12. The frequency of transfer of the 24-megadalton plasmid from the S. marcescens isolate to E. coli K12 by conjugation was approximately 10(-7) (transconjugants/donors) and was 0.1% of that between E. coli strains. In acetyltransferase-bearing isolates from hospital C, the enzyme was mediated by a nonconjugative plasmid in one case and could not be associated with a plasmid in the remaining two cases. Neither enzymes nor plasmids could be associated with amikacin resistance of the isolates of the other two hospitals.     

Drug resistance and R plasmids in Pasteurella multocida isolates from swine

A total of 163 strains of Pasteurella multocida isolated from swine were examined for drug resistance and R plasmids. Strains resistant to sulfadimethoxine (Sar), ampicillin (Apr), streptomycin (Smr), kanamycin (Kmr), and chloramphenicol (Cpr) were found in 93.9, 1.8, 16.6, 1.2, and 10.4%, respectively. There were two patterns of drug resistance (Sar and SarCpr) in isolates from nasal cavities, and five patterns (Sar, SarSmr, SarSmrCpr, SarSmrApr, and SarSmrKmrCpr) in isolates from pneumonic lung specimens. Two isolates studied were proved to carry a nonconjugative R plasmid pJY2 or pJY8 with other unidentified plasmids, respectively. pJY2 (3.6 megadaltons) encoding resistance to SarSmr had one cleavage site for EcoRI or HindIII endonuclease and two sites for PstI endonuclease. pJY8 (5.5 megadaltons) encoding resistance to Sar SmrKmrCpr had one EcoRI site and two PstI sites.     

Translocation of sequences encoding antibiotic resistance from the chromosome to a receptor plasmid in Salmonella ordonez

Summary Salmonella ordonez strain BM2000 carries kanamycin (Km), ampicillin (Ap), spectinomycin (Sp), chloramphenicol (Cm), tetracyline (Tc), and sulfonamide (Su) resistance and production of colicin Ib (Cib). The Km and Cib characters were carried by a 97kb IncI1 plasmid (pIP565). In addition to the Km and Cib traits, all or part of the other antibiotic resistance (R) determinants could be transferred by conjugation from S. ordonez to Escherichia coli where all the acquired characters are borne by an IncI1 plasmid, designated complete or partial composite plasmid respectively. DNA from pIP565 and composite plasmids and total DNA from strain BM2000 were studied by agarose and polyacrylamide gel electrophoresis following digestion with restriction endonucleases, and by Southern hybridization. These comparative analyses enabled us a) to show that acquisition by pIP565 of resistance to all or some of the antibiotics was due to the insertion of a single DNA fragment into the receptor plasmid; b) to detect two types of composite plasmids with regard to the specificity of insertion into pIP565 and the mapping of the inserts; c) to demonstrate that the ApCmSpSuTc resistance determinants were integrated into S. ordonez BM2000 chromosomal DNA; d) to map the restriction fragments of the translocatable sequence integrated into strain BM2000 chromosome or into pIP565.The results obtained suggest that two distinct mechanisms for the translocation of the R determinants coexist in S. ordonez BM2000. Recombination between two of the four directly repeated copies of the IS-like sequence (IS1522) present in S. ordonez chromosome leads to the circularisation of all or part of the AmCmSpSuTc R determinants and is followed by either 1) a second recombination with the copy of IS1522 in pIP565 (Type I composite plasmids), or 2) transposition of precise groups of characters in various sites of pIP565 (Type II composite plasmids).     

Translocation of an ampicillin resistance determinant within an R-factor aggregate inSalmonella panama

The molecular properties of the plasmids of a natural isolate ofSalmonella panama have been studied. This strain, Sp477, harbours 5 different plasmids: the conjugative plasmid pRI477TF (molecular weight 20 megadaltons), the two non-conjugative plasmids, pRI477A and pRI477S, coding for ampicillin and streptomycin plus sulfonamide resistance respectively (molecular weights of both 5.6 megadaltons) and two cryptic plasmids with molecular weights of 1.0 and 2.7, megadaltons respectively. After conjugal transfer toEscherichia coli the ampicillin resistance determinant was frequently found to be integrated into pRI477TF or pRI477S. The translocatable sequence on pRI477A, designated as Tn901, resembles the TnA subclass transposon TnA(1).     

Comparative study of non-conjugative R-plasmids from enterobacteria and Pseudomonas aeruginosa

Nonconjugative R-plasmids pBS76 and pBS94 (Sm Su), pBS95 and pBS96 (Sm Su Ap) isolated from clinical strains of Pseudomonas aeruginosa and plasmids pKMR281-pKMN284 (Sm Su), pKMR285-pKMR286 (Sm Su Tc) isolated from clinical strains of enterobacteria have been studied. Restriction maps of these plasmids are presented in the paper with some of plasmid genes for antibiotic resistance localized on them. The resistance determinants of plasmids pBS95 and pBS96 are shown to be included in transposon Tn3612 analogous to Tn3. Plasmids pBS76, pBS94-96 are of the wide host range and belong to incompatibility group P4 (IncQ). Plasmids pKMR281-pKMR286 are mutually incompatible and share the conspicuous DNA homology. They are inherited only by enterobacteria and are compatible with IncQ plasmids but in contrast to them are mobilized by RP4 plasmid with lower frequency.     

Serotypes,virulence factors,antibiotic sensitivity,beta-lactamase activity and plasmid analysis of Salmonella from children with diarrhea in Tripoli (Libya)

A total of 21 Salmonella strains isolated in Libya (16 from children with diarrhea and 5 from healthy controls) were serotyped and studied for their cell invasive ability, production of cytotoxin, antibiotic susceptibility, beta-lactamase activity and plasmid profiles. Eight different serotypes of Salmonella were identified: 6 S. saintpaul, 4 S. wien (1 from control), 2 S. newport, 2 S. muenchen (1 from control), 2 S. typhimurium (1 from control), 2 S. hadar (1 from control), 2 S. reading (1 from control), 1 S. kottbus. Twenty (95%) were positive in the invasiveness assay using HeLa cells, and all (100%) were negative for cytotoxin production in HT29 cells. More than 40% were resistant to ampicillin, cefalexin, cefamandole, cefoperazone, chloramphenicol, gentamicin, mezlocillin and trimethoprimsulphamethoxazole and 100% were susceptible to the new quinolones. Most (67%) of the strains harbored plasmids and 43% produced beta-lactamase. A strong association was observed between the presence of more than one plasmid, beta-lactamase activity, and multiple-resistance to antimicrobial agents and serotypes S. saintpaul and S. wien. Curing experiments with acridine orange showed that 2 plasmids (33 and 1.4 megadaltons) might be responsible for the resistance to chloramphenicol and gentamicin. The present study demonstrated that multiple-resistant salmonellae are widespread in Libya and the resistance is mainly plasmid mediated.     

Transposition of a plasmid deoxyribonucleic acid sequence that mediates ampicillin resistance: identity of laboratory-constructed plasmids and clinical isolates.

The structural gene for ampicillin resistance resides upon a 3.2 X 10(6)-dalton sequence of deoxyribonucleic acid, TnA that can be transposed from replicon to replicon in laboratory experiments. TnA was transposed from a large conjugative plasmid to a small nonconjugative plasmid, RSF1010. Several RSF1010::TnA plasmids isolated in these laboratory experiments have been shown to be identical to plasmids found in clinical isolates. These data provide direct support to the theory that transposition of drug resistance genes play a key role in the evolution of R plasmids.     

Molecular analyses of conjugative, gentamicin-resistance plasmids from staphylococcal clinical isolates

Gentamicin-resistant Staphylococcus aureus and Staphylococcus epidermidis strains which were isolated from infants with staphylococcal bacteremia were analyzed for the presence of self-transmissible gentamicin-resistance (Gmr) plasmids. Conjugative GMr plasmids of approximately 43.8-63 kilobases (kb) were found in all S. aureus strains. Inter- and intra-species transfer of Gmr plasmids by conjugation was observed from S. aureus to S. aureus and to S. epidermidis recipient strains. However, neither inter- nor intra-species transfer of gentamicin resistance by conjugation was observed with nine out of nine S. epidermidis donor strains which were mated with either S. epidermidis or S. aureus recipient strains. These conjugative Gmr plasmids were unable to comobilize a smaller (15-kb) plasmid present in all but two S. aureus clinical isolates. Many of the conjugative Gmr plasmids also carried genetic determinants for kanamycin, tobramycin, neomycin, and ethidium bromide resistance, and for beta-lactamase synthesis. EcoRI restriction endonuclease digests of the S. aureus Gmr conjugative plasmids revealed three different digestion patterns. Four EcoRI restriction endonuclease digestion fragments of 15, 11.4, 6.3, and 4.6 kb in size were common to all plasmids. These plasmids and conjugative Gmr staphylococcal plasmids from other geographical regions shared restriction digestion fragments of similar molecular weights. DNA hybridization with biotinylated S. aureus plasmid pIZ7814 DNA revealed a high degree of homology among these plasmids. A 50.9-kb plasmid from one of the nonconjugative S. epidermidis clinical isolates showed homology with the probe DNA but lacked a portion of a 6.3-kb fragment which was present in all conjugative plasmids and believed to carry much genetic information for conjugation.     

R plasmids in environmental Vibrio cholerae non-O1 strains

The occurrence of drug resistance and its plasmid-mediated transferability was investigated in 140 environmental strains of Vibrio cholerae non-O1 and 6 strains of Vibrio cholerae, both O1 and non-O1, of clinical origin. Of the 146 strains tested, 93% were resistant to at least one drug and 74% were resistant to two or more antibiotics. The O1 strains were susceptible to all antibiotics used. A total of 26 of 28 selected resistant wild strains carried R plasmids that were transferable by intraspecific and intergeneric matings. The most common transmissible R factor determined resistance to ampicillin, amoxicillin, and sulfanilamide (30%), followed by resistance to ampicillin and amoxicillin (13%) and resistance to ampicillin, amoxicillin, phosphomycin, and sulfanilamide (9%). Comparison of the three methods of plasmid analysis showed that the method of Birnboim and Doly (Nucleic Acids Res. 7:1513-1523, 1979) without EDTA and lysozyme was optimal for isolation of both large and small plasmids in environmental V. cholerae strains. Most strains harbored more than one plasmid, and the molecular sizes ranged from 1.1 to 74.8 megadaltons. The plasmids of high molecular size (around 74 megadaltons) were responsible for the resistance pattern transferred and were maintained with high stability in the hosts.