On the role of IS1 in the formation of hybrids between the bacteriophage P1 and the R plasmid NR1

Summary The genomes of bacteriophage P1 derivatives carrying drug resistance genes derived from an R plasmid NR1 were analysed by restriction cleavage and be DNA-DNA hybridization. Two representatives of a class of oversized P1CmSmSu phages were identified as P1 carrying the entire r-determinant of NR1 together with its two flanking, directly repeated IS1. In one case the r-determinant insertion is carried at the site of the residential IS1 of P1, in the other case it is transposed into another region of the P1 genome. Models postulate that the first type resulted from reciprocal recombination within IS1 elements and that the formation of the second type of P1-R hybrid depended both on IS1 mediated transposition and reciprocal recombination. Plaque forming P1Cm or P1CmSm phages are explained as IS1 mediated deletion derivatives of P1CmSmSu, although an alternative model postulates that sometimes P1Cm phages might result from two consecutive transposition events of only one IS1 without involving reciprocal recombination. Secondary P1 derivatives carrying only one IS1 at the site of the original r-determinant or of Cm insertions into P1 must have been produced by reciprocal recombination between the two IS1 flanking the insertions. An implication from this study, that any genetic material carried adjacent to an IS1 element may undergo passive transposition, is discussed.     

Dissection of the r-determinant of the plasmid R100.1: the sequence at the extremities of Tn21.

We have sequenced the extremities of the transposon Tn21, isolated from the r-determinant of the multiple antibiotic resistance plasmid R100.1, and show that it is a member of the Tn3 family of elements.     

Suppression of an Escherichia coli dnaA mutation by the integrated R factor R100.1: generation of small plasmids after integration.

We have observed that integration of the R plasmid R100.1 into the chromosome of Escherichia coli is associated with the formation of small, covalently closed circular elements. Contour length measurements, partial denaturation mapping, and analysis of the deoxyribonucleic acid fragments produced by digestion of one of these, pLC1, with the restriction endonuclease EcoRI indicate that it is the r-determinant element of R100.1.     

Mapping of the drug resistance genes carried by the r-determinant of the R100.1 plasmid

Summary We have cloned the EcoRI fragments of pLC1, a circular DNA element found in an Escherichia coli dnaA _ts strain integratively suppressed by R100.1 (Chandler et al., 1977a), using the plasmid vector pCR1. All the resistance genes known to be present on the r-determinant of R100.1 were found to be present on pLC1. The isolation of pCR1 derivatives carrying various EcoRI fragments of either pLC1 or R100.1 has allowed a more precise mapping of the position of the resistance genes on the R100.1 molecule.     

Frequency of replication from alternative origins in the composite R plasmid NR1.

The relative frequency of initiation of DNA replication within the RTF-Tc and r-determinant components of the composite drug resistance plasmid NR1 in Proteus mirabilis was evaluated. Using fractionated radioactively labeled plasmid DNA, analytical procedures that distinguished between the two components of the composite plasmid were carried out. A mixture of uniformly 14C-labeled and 3H-pulse-labeled plasmid DNA (pulse-labeled origin[s] of replication) was used in each of three experiments. First, shear products of the DNA were analyzed using CsCl density gradient centrifugation. Second, fragmented DNA was hybridized to nonradioactive RTF-Tc and r-determinant DNAs immobilized on nitrocellulose filters. Third, the radioactive plasmid DNAs immobilized on nitrocellulose filters. Third, the radioactive plasmid DNA was digested with restriction enzyme (EcoRI), producing a set of RTF-Tc and r-determinant fragments with differing 3H/14C isotpe ratios. The three experiments suggested that under the conditions used to accumulate replicating plasmid DNA molecules (DNA substrate limitation), the r-determinant origin of replication was preferentially utilized in the composite plasmid.     

Occurrence and properties of composite transposon Tn2672: evolution of multiple drug resistance transposons.

We found Tn2671 (the 23-kb long IS1-flanked r-determinant of NR1-Basel) inserted into the ampicillin resistance gene bla of the Tn3-related transposon Tn902. The resulting 28-kilobase-long composite transposon Tn2672 (= Tn902 bla::Tn2671) is stable, and it translocates as a unit into various loci including IS1 of the resistance transfer factor of R100-1. These results are discussed with respect to the evolution of R plasmids providing multiple drug resistance.     

Does the insertion element IS1 transpose preferentially into A+T-rich DNA segments?

Summary IS1-mediated insertion and deletion formation occur preferentially into A+T-rich regions of DNA of bacteriophage P1 and of the r-determinant of the R plasmid NR1. The significance of this correlation is discussed in view of other published data.     

The construction and replication properties of hybrid plasmids composed of the r-determinant of R100.1 and the plasmids pCRI or pSC201

Summary We have cloned the entire r-determinant of the antibiotic resistance plasmid R100.1 on the plasmid vectors pCR1 and pSC201. We find that the hybrid plasmids segregate from cultures in which replication of the vector is blocked. This suggests that the r-det is not capable of autonomous replication.     

Transition of the R Factor R12 in Proteus mirabilis

When Proteus mirabilis harboring the R factor R12 (a round of replication mutant of the R factor NR1) is cultured in medium containing streptomycin there can be an amplification in the number of copies of r-determinants per cell and the formation of enlarged polygenic R factors containing repeated sequences of r-determinants as well as polygenic molecules consisting of repeated sequences of r-determinants. This phenomenon has been referred to as the "transition." When transitioned cells are then cultured in drug-free medium, within a few generations two distinct density species of R factor deoxyribonucleic acid (DNA) are observed in a CsCl density gradient: a 1.712 g/ml band of covalently closed circular R factor DNA consisting of one transfer factor (RTF-TC) plus one r-determinant and a 1.718 g/ml band consisting of repeated sequences of r-determinants. The RTF-TC component of the R factor appears to control the replication of all the R factor DNA which is attached to it. In the autonomous state, however, polygenic sequences of r-determinants do not appear to replicate under the same control mechanism as when they are attached to an RTF-TC.     

Level and nature of the drug resistance of Shigella flexneri]

Characteristics of antibiotic resistance of 300 strains of Shigella flexner 2a isolated from patients within 1976--1977 in the regions where these bacteria were very rare for a long period of time were studied. It was shown that most of the isolates were resistant to chloramphenicol (88.1 per cent), tetracycline (94.8 per cent), streptomycin (89.1 per cent), polymyxin M (82.4 per cent) and others. 46.5--61.6 per cent of the isolates were resistant to neomycin antibiotics. A high level of the resistance was also noted: the bactericidal effect was registered in 52.0-74.0 per cent of the cultures at a dose of 500--1000 microgram/ml. 91.4 per cent of the strains possessed multiple dug resistance, 78.8 per cent of them being simultaneously resistant to 4--7 drugs. Transmissive R-plasmids were found in 68.8 per cent of the isolates. After exposure to acridine dyes the plasmid nature of the resistance was confirmed in 72.3 per cent of the cultures. Variability of the r-determinant sets in r-plasmids was noted. Strains (64.9 per cent) carrying r-determinants Tc, Cm, Sm and Tc, Cm were more frequent. Strains with one transmissive r-determinant were usually solitary.     

DNA inversion mediated by the r-determinant of plasmid NR1: evidence for the intramolecular replicative transposition of a 23 kb IS1-flanked transposon?

Summary The r-determinant (r-det) of the R plasmid NR1-Basel is a 23 kb, IS1-flanked transposon, called Tn2671, which has been shown to transpose to the genome of bacteriophage P7. Among the derivatives of phage P7::r-det we found one which carried two copies of the r-det as inverted repeats and which also contained the P7 genome segment between them in inverted orientation. Its generation is best explained by assuming that the entire 23 kb Tn2671 transposon has undergone intramolecular replicative transposition.     

Production of extrachromosomal r-determinant circles from integrated R100.1: Involvement of the E. coli recombination system

Summary The drug resistance plasmid R100.1 can integrate into the E. coli chromosome at several sites on the plasmid. Many of the resulting Hfr strains continuously produce extrachromosomal circular forms of the r-determinant. These r-det plasmids seem incapable of stable autonomous replication. We show that their presence in the cell requires the continuous activity of functional recA and recC genes but does not require the lexA function.The production of r-det circular forms is correlated with an increased copy number of r-det sequences, relative to RTF sequences. This copy number increase is, however, also found in a recA ^- backgound where no circular forms of r-det are found. These results show that a specific replication of r-det sequences, not present in the wild-type R100.1 plasmid, occurs in these R-Hfr strains. They suggest that a rec promoted recombination, posterior to the specific replication event, is needed for the production of circular r-det forms.     

Localization of Kpnl restriction sites in the r-determinant of plasmid NR1

Restriction KpnI sites on a molecule of the plasmid NR1 were localized. The position of KpnA (58,0 MD) and KpnB (1,0 MD) fragments on a physical map of the NR1 molecule was shown using endonucleases EcoRI and SaII. Both restriction sites are situated on a r-determinant of the EcoJ fragment of the plasmid NR1.     

Some properties of the chloramphenicol resistance transposon Tn9

Summary We have isolated variants of the plasmid RTF which have received the transposon Tn9 from bacteriophage P1Cm. We have shown by the formation of heteroduplex molecules between one RTF: Tn9 derivative and R100.1 that Tn9 is homologous to the r-determinant region of R100.1 which carries the determinants for chloramphenicol resistance. This suggests that Tn9 was derived from an r-det like structure by deletion, possibly mediated by one of the flanking IS1 elements. In spite of the similarity in structure between Tn9 and r-det however, we have demonstrated two distinct differences in the behavior of these two elements: 1) Tn9 but nor r-det, is able to amplify, by a recA dependent mechanism, when cells harboring RTF::Tn9 are grown in the presence of chloramphenicol, and 2) Tn9, unlike r-det, does not form extrachromosomal circular molecules when RTF::Tn9 is tegrated into the bacterial chromosome.     

Phenotypic reversion of an IS1-mediated deletion mutation: a combined role for point mutations and deletions in transposon evolution

We have physically characterised a deletion mutant of the R plasmid R100 which has lost all of the antibiotic resistances, including chloramphenicol resistance (Cmr), coded by its IS1-flanked r-determinant. The deletion was mediated by one of the flanking IS1 elements and terminates within the carboxyl terminus of the Cmr gene. DNA sequence analysis showed that the mutated gene would produce a protein 20 amino acids longer than the wild-type due to fusion with an open reading frame in the IS element. Surprisingly for a deletion mutation, rare, spontaneous Cmr revertants could be recovered. Two of the four revertants studied had frame shifts due to the insertion of a single AT base pair at the same position; the revertants would code for a protein five amino acids shorter than the wild-type. The other two revertants had acquired duplications of the 34-bp inverted terminal repeat sequences of the IS1 element and would direct the synthesis of a protein six amino acids longer than the wild-type. The reverted Cmr markers were still capable of transposition. These observations suggest a role for point mutations and small DNA rearrangements in the formation of new gene organisations produced by mobile genetic elements.     

Is the IS1-flanked r-determinant of the R plasmid NR1 a transposon?

The 23 kilobase multiple drug resistance r-determinant (r-det) of the R plasmid NR1 is an IS1-mediated transposon, Tn2671. Drug-resistant Escherichia coli transductants isolated after infection with bacteriophage P1::Tn2671 derivatives carry the intact r-det in their chromosomes. Independently isolated transductants carry the r-det at different locations on the chromosome. From the E. coli chromosome, Tn2671 can transpose to various locations on the phage P7 genome. Throughout these processes, r-det is maintained as a stable unit. Various possible molecular mechanisms, which all might contribute with characteristic frequencies to the transposition of Tn2671, are discussed. The results presented are relevant to the understanding of mechanisms for a wide spreading of drug resistance genes.     

Operation of an efficient site-specific recombination system of Zygosaccharomyces rouxii in tobacco cells.

Recombinase encoded by the R gene of pSR1 of Zygosaccharomyces rouxii mediates reciprocal recombination between two specific recombination sites (RSs) to induce excision or inversion of the DNA segment that is flanked by the RSs. We report here that site-specific recombination mediated by this system takes place effeciently in tobacco cells. To monitor the recombination events in tobacco cells, we have constructed two types of cryptic beta-glucuronidase reporter gene in such a way that recombination such as inversion of the construct or excision of the intervening sequence results in their expression. When these cryptic reporter constructs were transiently introduced together with the R gene by electroporation into protoplasts of tobacco cells, beta-glucuronidase activity was detected. The cryptic reporter genes, when stably resident in the chromosome of tobacco cells, were also activated by the R gene. Structural analyses of the genomic DNA isolated from these tobacco cells showed that the R protein did in fact catalyze precise recombination between two copies of RSs in tobacco cells, with resultant activation of the cryptic reporter genes. This observation provides the basis for development of a DNA technology whereby large regions of DNA can be manipulated in plant chromosomes. Potential uses of this recombination system are discussed.     

Site-specific recombination at oriT of plasmid R1162 in the absence of conjugative transfer.

R1162 is efficiently comobilized during conjugative transfer of the self-transmissible plasmid R751. Bacteriophage M13 derivatives that contain two directly repeated copies of oriT, the site on R1162 DNA required in cis for mobilization, were constructed. Phage DNA molecules underwent recombination during infection of Escherichia coli, with the product retaining a single functional copy of oriT. Recombination was strand specific and depended on R1162 gene products involved in mobilization, but did not require the self-transmissible plasmid vector. Two genes were identified, one essential for recombination and the other affecting the frequency of recombination. Recombination of bacteriophage DNA could form the basis of a simple model for some of the events occurring during conjugation without the complexity of a true mating system.     

Role of arginine-43 and arginine-69 of the Hin recombinase catalytic domain in the binding of Hin to the hix DNA recombination sites

The Hin recombinase mediates the site-specific inversion of a segment of the Salmonella chromosome between two flanking 26 bp hix DNA recombination sites. Mutations in two amino acid residues, R43 and R69 of the catalytic domain of the Hin recombinase, were identified that can compensate for loss of binding resulting from elimination of certain major and minor groove contacts within the hix recombination sites. With one exception, the R43 and R69 mutants were also able to bind a hix sequence with an additional 4 bp added to the centre of the site, unlike wild-type Hin. Purified Hin mutants R43H and R69C had both partial cleavage and inversion activities in vitro while mutants R43L, R43C, R69S, and R69P had no detectable cleavage and inversion activities. These data support a model in which the catalytic domain plays a role in DNA-binding specificity, and suggest that the arginine residues at positions 43 and 69 function to position the Hin recombinase on the DNA for a step in the recombination reaction which occurs either at and/or prior to DNA cleavage.