pED100, a conjugative F plasmid derivative without insertion sequences

Why do mobile genetic elements transfer DNA of their hosts?

The prokaryote world is replete with mobile genetic elements (MGEs) - self-replicating entities that can move within and between their hosts. Many MGEs not only transfer their own DNA to new hosts but also transfer host DNA located elsewhere on the chromosome in the process. This could potentially lead to indirect benefits to the host when the resulting increase in chromosomal variation results in more efficient natural selection. We review the diverse ways in which MGEs promote the transfer of host DNA and explore the benefits and costs to MGEs and hosts. In many cases, MGE-mediated transfer of host DNA might not be selected for because of a sex function, but evidence of MGE domestication suggests that there may be host benefits of MGE-mediated sex.

Escherichia coli CoIV plasmid pRK100: genetic organization, stability and conjugal transfer

Uropathogenic Escherichia coli strains express chromosomal and plasmid-encoded virulence-associated factors such as specific adhesins, toxins and iron-uptake systems. A CoIV plasmid (pRK100) of a uropathogenic strain and its host KS533 were studied. The host strain encodes the K1 capsule, and P and S fimbriae, but neither haemolysin nor the cytotoxic-necrotic factor CNF1, indicating that this strain does not harbour a larger pathogenicity island. A restriction map of pRK100 was constructed on the basis of hybridization experiments and nucleotide sequencing. pRK100 harbours CoIV, the conserved replication region RepFIB, the aerobactin-uptake system, a RepFIC replicon and additionally Colla as well as transposon Tn5431. The location of the RepFIC replicon was similar to that in plasmid F. CoIV plasmids and F thus share a region spanning more than half the length of plasmid F. Even though their replication and transfer regions are homologous, CoIV plasmids are found only in E. coli strains. Among the four other species tested, conjugal transfer of pRK100 was demonstrated, with low frequency, only to Klebsiella pneumoniae, suggesting that a natural barrier effectively bars transfer. In vitro stability of the plasmid with integration into the chromosome to ensure maintenance in the presence of an incompatible plasmid was demonstrated.

Plasmid profiles of Mycobacterium avium complex isolated from swine

Twenty strains of Mycobacterium avium complex (MAC) isolated from swine and five strains from humans were examined for drug susceptibility and plasmid content. Four strains of swine origin and two strains of human origin harbored plasmid DNAs differing in molecular weights. No relationship between plasmid contents and drug resistance was observed. Southern DNA-DNA hybridization showed that small plasmids from swine MAC strains were homologous to those from human origin at the nucleotide level.

Construction of transposons carrying the transfer functions of RP4

The transfer genes and origin of transfer of the wide host range plasmid RP4 have been cloned into the transposons Tn1 and Tn5. The newly constructed transposons can be used to mutagenize bacterial plasmids or the chromosome in species such as Escherichia coli or Rhizobium. It is then possible to mobilize the plasmid or chromosome using the transfer functions provided in cis by the transposon. These constructs may aid chromosome mapping in many gram-negative species by allowing the wider use of the RP4 conjugal transfer system combined with the potential ability to select the site of insertion and thus the site of the origin of transfer.

Nucleotide sequence of insertion sequence IS3411, which flanks the citrate utilization determinant of transposon Tn3411

The nucleotide sequences of insertion sequences IS3411L (left) and IS3411R (right), present as direct terminal repeats in the citrate utilization of citrate utilization transposon Tn3411, and of IS3411 (generated by intramolecular recombination between IS3411L and IS3411R) were determined. The three IS3411 elements (IS3411R, IS3411L, and IS3411) were 1,309 base pairs long and identical in DNA sequence. IS3411 had 27-base-pair terminal inverted repeats with three bases mismatched and one long open reading frame (240 amino acids) that was proposed to be a transposase. Three polypeptides of 29,000, 27,000, and about 10,000 molecular weight, determined by IS3411, were identified in minicells. Since Tn3411 generates a 3-base-pair repeat upon integration, the nucleotide sequences of IS3411 were compared with those of IS3.

An F-derived conjugative cosmid: analysis of tra polypeptides in cosmid-infected cells

The genes involved in the conjugational transfer of F plasmid DNA are organized into three closely linked operons spanning an overall length of approximately 33 kilobase pairs of F. The entire transfer (tra) region comprising all three operons has been cloned into the cosmid vector pHC79 by in vitro recombination and packaging techniques. The transfer-proficient chimeric cosmid pRS2405 was packaged into lambda capsids, and uv-irradiated E. coli cells were infected with these DNA-filled particles. A number of polypeptides programmed by the infecting DNA were identified as tra-specified products; a traJ90 mutation on pRS2405 resulted in the significant reduction of synthesis of all detectable pRS2405-specified tra polypeptides, with the exception of TraTp.

Construction of a conjugative plasmid with potential use in vaccines against heat-labile enterotoxin

A conjugative plasmid with potential usefulness for vaccine strains was constructed. In the first step, a 5.9-kilobase DNA segment containing the two loci for the A and B subunits of heat-labile enterotoxin with a mutation in the gene for the A subunit was joined to the cloning vehicle pGA22, generating the nonconjugative plasmid pPMC4 with genes for resistance to tetracycline and chloramphenicol. In the second step, a segment of pPMC4 containing the genes for the A and B subunits, the gene for chloramphenicol resistance, and the replication genes of pGA22 was ligated to the genes for conjugal transfer of the F plasmid, generating the 54.9-kb plasmid pPMC5. Eleven porcine Escherichia coli isolates were tested as recipients for pPMC4 and pPMC5. For pPMC4, transformation and mobilization with a conjugative R plasmid were used to effect plasmid transfer. Only 1 of the 11 strains acted as a recipient in transformation. Mobilization with the R plasmid occurred with two strains, but the plasmids were altered during transfer. In contrast, pPMC5 was transferred with high frequency and unaltered to 9 of the 11 E. coli strains. Transconjugants from these nine matings produced high titers of the B subunit and no active heat-labile enterotoxin. Plasmid pPMC5 was stable in three porcine E. coli strains tested; plasmid pPMC4 was somewhat less stable in these strains. The method we describe for the construction of conjugative chimeric plasmids offers an opportunity for introducing genes with potential for immunization into bacterial strains that are suitable for colonizing the appropriate host sites.

Spontaneous deletion of citrate-utilizing ability promoted by insertion sequences

The citrate utilization (Cit+) transposon Tn3411 was shown to be flanked by directly repeated sequences (IS3411L and IS3411R) by restriction enzyme analysis and electron microscope observation. Cit- deletion mutants were frequently found to be generated in pBR322::Tn3411 by intramolecular recombination between the two copies of IS3411. The flanking IS3411 elements of Tn3411 were shown to be functional insertion sequences by Tn3411-mediated direct and inverse transposition. Tn3411-mediated inverse transposition from pBR322::Tn3411 to the F-plasmid derivative pED100 occurred more efficiently than that of direct transposition of the Cit+ determinant. This was thought to be due to the differential transposability of IS3411L and IS3411R in the transposition process. The frequency of transposition of IS3411 marked with a chloramphenicol resistance determinant was much higher than IS3411-mediated cointegrate formation, suggesting that replicon fusions are not essential intermediates in the transposition process of Tn3411 or IS3411. Spontaneous deletions occurred with high frequency in recA hosts. The spontaneous deletion promoted by homologous recombination between two IS3411 elements in Tn3411 was examined with deletion mutants.

Plasmids containing one inverted repeat of Tn21 can fuse with other plasmids in the presence of Tn21 transposase

In the presence of the Tn21 transposase, plasmids that contain a single Tn21 inverted repeat sequence fuse efficiently with other plasmids. This reaction occurs in recA strains, is independent of the transposon-encoded resolution system, and results in insertions into different sites in the recipient plasmid. All fusion products studied contained at least one complete copy of the donor plasmid; most also contained some duplication of it as well. The data are consistent with processive models of transposition.

Role of the F factor oriV1 region in recA-independent illegitimate recombination. Stable replicon fusions of the F derivative pOX38 and pBR322-related plasmids

We have used a mating protocol to isolate recA-independent recombinants of pOX38 , an F factor derivative, and the non-conjugative plasmid pMBO311 . Plasmid pMBO311 is a derivative of pBR322 carrying a DNA insertion that contains IS121 and shows no extensive sequence homology to pOX38 . Twenty-seven cointegrate molecules formed during independent mobilizations of pMBO311 by pOX38 were examined by restriction and Southern hybridization analysis. In general, there were two classes of recombinants. A minority class appears to have been mediated by IS121 , resulting in the formation of cointegrate molecules containing IS121 at the junctions between the two plasmids. The majority class (23/27) apparently involved reciprocal recombination between sites on pOX38 and pMBO311 . IS121 does not seem to be responsible for the formation of this type of cointegrate molecule, since similar structures were generated at approximately the same frequency during mobilization of control plasmids that do not contain IS121 . We have localized the regions involved in this second class of recombination events and find that most (17/23) occur at or near oriV1 , the primary replication initiation site of pOX38 . Twelve of the cointegrate molecules showed identical restriction and Southern hybridization patterns demonstrating a preferred region on pMBO311 as well. This site was localized just distal to the tet genes, within a 640-base AvaI-PvuII segment in the pBR322 portion of the molecule.

Physical and functional map of the hemolytic plasmid pSU316

A restriction endonuclease analysis of the hemolytic plasmid pSU316 has allowed location of the cleavage sites for the endonucleases BamHI, XbaI, KpnI, Bg/II, Sa/GI, EcoRI, and HindIII. Hybridization experiments between pSU316 and pED100 have shown that the tra region of pSU316 lies in a segment comprising part of Sa/GI fragments S-1 and S-3 and the entire fragment S-4. The positions of other plasmids coded functions, namely the replication functions and alpha-hemolysin production, have been determined in the physical map.

Cloning and polypeptide analysis of the leading region in F plasmid DNA transfer

A segment of the F plasmid DNA, located between the origin of transfer and the primary F replication region, is the first to enter the recipient cell during conjugation. PstI, SalI, and SmaI restriction endonuclease sites have been mapped within this leading region in conjugational DNA transfer and chimeric plasmids carrying overlapping fragments of the region have been constructed. Analyses of polypeptides of Mr 27,800, 23,100, 14,400, and 11,000 to be encoded by sequences within the leading region.

R483 and F plasmid genes promoting RNA degradation: comparative restriction mapping

The gene promoting nucleic-acid degradation (pnd) on IncIa plasmid R483 was cloned into pBR322. It is located on a 0.85 kilobase (kb) EcoRI-SalI fragment and is close to Tn7. The pnd gene has similar properties to the srnB gene on the F plasmid. A cleavage map of the 0.85 kb pnd fragment was constructed and compared with that of the 1.18 kb EcoRI-BamHI fragment containing the srnB gene. These two regions showed marked heterogeneity as evidenced by their distinctly different restriction maps. This result suggests separate paths of evolution of the two genes for stable RNA degradation.