Dissociation of unstable cointegrate plasmids formed during transposition of IS1 element: the role of IS1 encoded recombinase

The properties of IS1/Tn9'-mediated cointegrates between plasmids pDK57 (pBR322:: :: Tn9') and pRP3.1--the deletion derivative of RP1 were investigated. It was found that IS1/Tn9'-mediated integration of pDK57 into the active transcribed regions of pRP3.1 (in particular kan and tet genes) leads to formation of unstable cointegrates capable of resolving in E. coli K-12 rec+ and recA cells. The structure of dissociation products of unstable cointegrates was studied. According to the data received in rec+ cells, the unstable cointegrates mainly produced plasmids pDK57 and pBR322::IS1--Cms-derivative of pDK57 as resolution products. In recA cells the cointegrates dissociate in different ways, and this process leads to the formation of not only pDK57 and pBR322::IS1, but also to the production of the deletion derivatives of these plasmids as well as to the derivatives of pDK57 and pBR322::IS1, containing duplications of IS1 or separate parts of Tn9'. It was concluded that the IS1-specific recombinase is involved in the dissociation (resolution) of unstable IS1/Tn9'-mediated cointegrates. This recombinase recognizes the sites localized in both inverted termini of IS1 as well as in the adjacent DNA segments. Hence, it is possible, that the IS1 recombinase is involved also in the generation of IS1-adjacent delations.     

Structural instability of IncP-1 plasmids in Pseudomonas aeruginosa PAT involves interaction with plasmid pVS1

The structural instability exhibited by IncP-1 plasmids in Pseudomonas aeruginosa strain PAT was shown to be Rec+ dependent and involved interaction with the resident plasmid pVS1. Structural instability resulted from deletion of plasmid deoxyribonucleic acid at a frequency of ca. 10(-2)/cell per generation. Deletants could be stabilized by transduction into P. aeruginosa strain PAO, but in strain PAT deletants had only a transient existence, as continued deletion led eventually to the loss of the entire plasmid. The patterns of markers lost in PAT were used to demonstrate a marker order for R68 similar to that published elsewhere for RP4 (Barth and Grinter, J. Mol. Biol. 113:455-474, 1977), except that only one Tra region was found. R68 also exhibited Rec+-dependent structural instability in PAO(pVS1) derivatives but, unlike the case in PAT, instability was not accompanied by chromosome mobilization. We isolated deletants of pVS1 which were unable to promote structural instability.     

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.     

IS1-mediated tandem duplication of plasmid pBR322. Dependence on recA and on DNA polymerase I

Transposable-element-mediated fusion of the conjugal plasmid pOX38::Tn9 with pBR322 results in the appearance of cointegrates composed of a single copy of each plasmid, and cointegrates which carry a single copy of pOX38 but multiple tandem copies of pBR322. These plasmids are separated by directly repeated copies of the transposable element. We demonstrate here that such multimers can be generated from monomeric cointegrates, probably by unequal crossing over between the flanking Tn9(IS1) elements. Their appearance is thus not necessarily associated with the original transposition (fusion) event. Our study demonstrates that the process of duplication is strongly dependent on the homologous recombination system of Escherichia coli, since it is undetectable by our methods in recA- strains. It is also strongly dependent on the presence of a functional DNA polymerase I in the cell. The major pathway(s) for this duplication thus appears to rely on both the homologous recombination system and the replication of the duplicated segment.     

Partitioning of plasmid R1. Structural and functional analysis of the parA locus

The stability locus, parA+, of plasmid R1 is shown to be localized within a 1500 base-pair region of DNA on the largest EcoRI restriction fragment of plasmid R1. The nucleotide sequence of the region revealed the presence of two open reading frames, one of 320 codons, and another of 60 codons. The larger open reading frame encodes a polypeptide of 36,000 Mr. Deletions covering the promoter distal end of the 36,000 Mr reading frame give rise to synthesis of large amounts of truncated protein. Construction of promoter fusions between the parA+ promoter and the lacZ gene showed that the parA+ region encodes a factor that negatively regulates the expression of the 36,000 Mr protein. The locus exerting parA+-associated incompatibility, denoted incA+, was mapped to a 60 base-pair region covering the parA+ promoter. Most likely, this region is involved both in the negative regulation of the parA+ operon and in the parA+-associated incompatibility. Two explanations are suggested to explain this possible dual function of the parA+ promoter region. The parA+ region was cloned into an unstably inherited (par-) derivative of a mini-F derivative. The low copy number plasmid mini-F devoid of its own partition genes was stabilized more than 100-fold by carrying the parA+ genes. This observation is in accordance with the proposal that the parA+ locus specifies the true partition function of plasmid R1.     

Transfer and expression of pseudomonas plasmid RP1 in Caulobacter.

This study demonstrates that the host range of Pseudomonas plasmid RP1 includes the genus Caulobacter. Caulobacter was shown to acquire three antibiotic resistance markers located in RP1. A fourth plasmid marker, susceptibility to an RNA bacteriophage, was not expressed, but could be transferred from Caulobacter to Escherichia coli. The lack of phenotypic expression of the phage marker was manifested by the inability of the phage to adsorb or to produce plaques on Caulobacter transcipients. Matings of Pseudomonas aeruginosa and Caulobacter vibrioides CV6 were carried out in the presence of bacteriophage phi6, a DNA phage that infects and kills only swarmer cells of Caulobacter. No decrease in plasmid transfer in the presence of phage phi6 was detected, suggesting that stalked cells, and not swarmer cells, serve as recipients. Our evidence suggests that transfer of chromosomal segments from Caulobacter may be mediated by plasmid RP1; such segments are not stably maintained.     

Isolation of a nontransmissible antibiotic resistance plasmid by transductional shortening of R factor RP1.

A plasmid segregant carrying tetracycline and carbenicillin resistance markers has been isolated from R factor RP1 by transductional shortening with phage P22. The new plasmid RP1-S2, which has a molecular weight of 23 times 10-6, has lost the transfer, phage sensitivity, and neomycin resistance functions of RP1. It combines readily with a W group plasmid, R388, to form a transmissible carbenicillin and trimethoprim resistance plasmid, RWP1.     

Study of the role of the insA open reading frame in the IS1 insertion element structure during transposition and resolution of the IS1 mediated cointegrates

In order to elucidate the function of the IS1 insA gene derivatives of plasmid pUC19::Tn9' with insertions of synthetic oligonucleotides were obtained. The latter are equal or multiple of 9 b.p. in length and are located in the Pst1 site within each of the two IS1 copies of the Tn9' transposon. The insertions of the nine base oligonucleotides code for the neutral amino acids and do not shift the reading frame. One of the mutant transposon obtained - Tn9'/X was studied on the ability to form simple insertions and plasmid cointegrates. For this purpose the pUC19 derivatives carrying the wild type and mutant transposon were mobilized by conjugative plasmid pRP3.1. It was found that the damage of the insA gene does not influence the ability of transposon to form simple insertions and plasmid cointegrates in both recA - and rec+ cells of E. coli. However, the frequency of the cointegrate formation in the subsequent transposition of the mutant transposon from pRP3.1::Tn9'/X to pBR322 was by 10-20 times lower in comparison to the wild type transposon. Instable (dissociating) Tn9'/X-mediated plasmid cointegrates formed by interaction pUC19::Tn9'/X and pRP3.1 were obtained. It was shown that in the E. coli recA-cells such cointegrates dissociate, as a rule, "correctly", i.e. they segregate mainly plasmids of types pUC19::Tn9'/X and pUC19::IS1/X. The data obtained correspond with the notion that the gene insA product is not essential for transposition, but is, possibly, involved in the formation of the IS1-generated deletions.     

Transfer region of IncI1 plasmid R64 and role of shufflon in R64 transfer.

To locate the transfer region of the 122-kiloase plasmid R64drd-11 belonging to incompatibility group I1, a series of deletion derivatives was constructed by in vitro recombinant DNA techniques followed by double homologous recombination in vivo. A plasmid designated pKK609 and bearing a 56.7-kilobase R64 sequence was the smallest transferable plasmid. A plasmid designated pKK610 and no longer possessing the 44-base-pair sequence of the R64 transfer system is located at one end. The other end of the R64 transfer region comprises a DNA segment of about 19 kilobases responsible for pilus formation. Shufflon, DNA with a novel rearrangement in R64, was found to be involved in pilus formation.     

Isolation and characteristics of a temperature-sensitive plasmid pRP19.6--an RP1 derivative containing the duplicated IS21 sequence

When analysing the antibiotic resistant, temperature-independent derivatives of Proteus mirabilis cells, carrying the plasmid RP1ts12, a derivative of the latter (pRP19.6) with an elevated frequency of integration into E. coli K12 chromosome, has been isolated. The structure and properties of pRP19.6 was studied. As revealed from the data of structural and genetic analyses pRP19.6 is identical to the factor R68.45 described earlier by Haas and Holloway. Similarly to R68.45, the plasmid under study contains two copies of IS21 sequence and mobilises nonconjugative plasmid pBR325 with high efficiency. Using the temperature sensitive replication of pRP19.6, frequency of it's integration into the chromosomes of E. coli rec+ and recA- stains is determined. It is demonstrated that the clones carrying the plasmid in integrated state are Hfr-strains. The possibilities to use the temperature sensitive R68.45 like plasmid for isolation of Hfr-strains in the broad range of gram-negative bacteria and for insertional inactivation of chromosomal genes are discussed.     

Structural instability of a bifunctional plasmid pZG1 and single-stranded DNA formation in Streptomyces

Structural instability of a hybrid plasmid pZG1, consisting of Escherichia coli pBR322 and Streptomyces pIJ350 plasmids, has been studied in Streptomyces. After transformation of S. lividans 1326 and S. rimsus R6 protoplasts with pZG1, transformants harbored the intact pZG1 and various deleted plasmid forms. The pattern of deleted plasmids varied with the transformant colony age and changed upon subcultivation. The presence of intact pZG1 in at least a part of the Streptomyces colonies indicated that the plasmid was capable of replicating in the transformants and that deletion events occurred after at least one round of replication. Less instability of pZG1 in S. rimosus R6 was observed when this strain was transformed with the DNA isolated from the same strain. pZG1 and its various derivatives were found in S. lividans 1326 and S. rimosus R6 as double- and single-stranded DNA molecules. Structural instability of pZG1 could therefore be due at least in part to the presence of single-stranded DNA.     

Involvement of IS1 in the dissociation of the r-determinant and RTF components of the plasmid R100.1

Summary Detailed mapping localized the PHO 1 mutation between the OLI 2 and OLI 4 loci on mitochondrial DNA of Saccharomyces cerevisiae.In its mitochondrially integrated form, the PHO 1-ATPase³ was difficult to identify either immunologically or by specific inhibitors like oligomycin and DCCD. Solubilization by Triton X-100 allowed unambiguuous identification of this enzyme as an authentic mitochondrial ATPase. However, Triton extraction produced a 2 to 3 fold enhancement of the PHO 1-ATPase activity which also became drastically cold-sensitive. The wild type ATPase was neither activated nor made cold-labile by solubilization, and retained full sensitivity to oligomycin and DCCD.Sucrose gradient analysis of the Triton-extracted ATPase from wild type, PHO 1 mutant and rho ^- strains showed a density difference between the solubilized PHO 1-and wild type ATPase, and similarity between solubilized PHO 1-and rho ^- ATPase (F₁).Whole cells of the PHO 1 mutant present considerably increased respiration rates.Comparison of oligomycin-sensitivity in whole cells, coupled isolated mitochondria and membrane-bound ATPase indicates a contrast between oligomycin-resistance of the ATPase and oligomycin-sensitivity of in vivo or in vitro coupling systems, which might characterize the products of this region of mitochondrial DNA.     

The properties of hybrids formed between the P-group plasmid RP1 and various plasmids from Pseudomonas aeruginosa

Summary Ribosomal DNA content has been determined in several adult and larval tissues of Drosophila melanogaster. Underreplication of rRNA genes was observed in polytenic salivary glands of larvae. On the contrary, polytenic/polyploid ovaries showed no decrease in rDNA. It is concluded that polyteny is not necessarily associated with underreplication of rDNA. No other tissue examined displayed any change in rDNa redundancy. Third-instar-larvae showed a decrease in rDNA amount which might be partly accounted for by underreplication of rDNA in salivary glands. No such decrease was seen in pupae. Bobbed genotypes were essentially similar to wild type in all tissues except salivary glands. In this case, it was found that the extent of underreplication is less in bobbed as compared to wild genotypes.Ribosomal DNA activity was examined in various tissues of Drosophila melanogaster. The rates of rRNA synthesis vary greatly between various tissues. It is concluded that a control at the level of gene activity operates as differences in the amount of precursor rRNA synthesized can be observed both in flies of varying rDNA contents as well as in various tissues of the same genotype.     

Structural and functional analysis of the kid toxin protein from E. coli plasmid R1

We have determined the structure of Kid toxin protein from E. coli plasmid R1 involved in stable plasmid inheritance by postsegregational killing of plasmid-less daughter cells. Kid forms a two-component system with its antagonist, Kis antitoxin. Our 1.4 A crystal structure of Kid reveals a 2-fold symmetric dimer that closely resembles the DNA gyrase-inhibitory toxin protein CcdB from E. coli F plasmid despite the lack of any notable sequence similarity. Analysis of nontoxic mutants of Kid suggests a target interaction interface associated with toxicity that is in marked contrast to that proposed for CcdB. A possible region for interaction of Kid with the antitoxin is proposed that overlaps with the target binding site and may explain the mode of antitoxin action.     

Structural and functional comparison between the stability systems ParD of plasmid R1 and Ccd of plasmid F

Summary The stability determined by the systems ParD of plasmid R1 and Ccd of plasmid F is due to the concerted action of two proteins, a cytotoxin and an antagonist of this function. In this paper we report that CcdA and Kis proteins, the antagonists of the Ccd and ParD systems respectively, share significant sequence homologies at both ends. In Kis, these regions seem to correspond to two different domains. Despite the structural similarities, Kis and CcdA are not interchangeable. In addition we have shown that the cytotoxins of these systems, the Kid and CcdB proteins, do not share structural homologies. In contrast to CcdB, the Kid protein of the ParD system induces RecA-dependent cleavage of the cl repressor of bacteriophage very inefficiently or not at all. The functional implications of these results are discussed.     

Characteristic features of the structure of co-integrating plasmids and simple insertions formed during transposition of the IS1 element in transposon Tn9'

Earlier we have studied unstable dissociating IS1/Tn9'-mediated cointegrates between the plasmids pDK57 (pBR322::Tn9') and pRP3.1, a deletion derivative of RP1, and two types of such cointegrates containing three and four copies of IS1 were revealed. In the present paper we studied the structure of stable IS1/Tn9'-mediates cointegrates and simple insertions formed by interaction between the plasmids pDK57 and pRP3.1 in the E. coli recA- cells. It was shown, that the stable cointegrates were formed by insertion of pDK57 in different loci of pRP3.1 and these cointegrates contain three copies of IS1, i.e. one copy of IS1 and a copy of Tn9' at the junction of the two replicons. The cointegrates are formed predominantly due to the activity of the left copy of Tn9', which occupies a proximal position in regard to the promoter of the cat gene. It was found that the integration of pDK57 into the kan gene region of pRP3.1 leading to the formation of the KmS cointegrates occurs only in one of the two possible orientations. Meanwhile the insertions of the transposon Tn9' into the kan region of pRP3.1 leading to simple insertions occurs in the orientation opposite to the orientation of the transposon in the KmS cointegrates. It is proposed that simple insertions are not the products of direct transposition of Tn9', but they are formed from unstable cointegrates under the action of IS1-specific resolvase.