Cointegrates between bacteriophage P1 DNA and plasmid pBR322 derivatives suggest molecular mechanisms for P1-mediated transduction of small plasmids

Bacteriophages vehiculate a high amount of antibiotic resistance determinants of bacterial origin in the Orne River ecosystem

Aquatic environments are important dissemination routes of antibiotic resistance genes (ARGs) from and to pathogenic bacteria. Nevertheless, in these complex matrices, identifying and characterizing the driving microbial actors and ARG dissemination mechanisms they are involved in remain difficult. We here explored the distribution/compartmentalization of a panel of ARGs and mobile genetic elements (MGEs) in bacteria and bacteriophages collected in the water, suspended material and surface sediments from the Orne River ecosystem (France). By using a new bacteriophage DNA extraction method, we showed that, when packaging bacterial DNA, bacteriophages rather encapsidate both ARGs and MGEs than 16S rRNA genes, i.e. chromosomal fragments. We also show that the bacteria and bacteriophage capsid contents in ARGs/MGEs were similarly influenced by seasonality but that the distribution of ARGs/MGEs between the river physical compartments (water vs. suspended mater vs. sediment) is more impacted when these markers were carried by bacteria. These demonstrations will likely modify our understanding of the formation and fate of transducing viral particles in the environment. Consequently, they will also likely modify our estimations of the relative frequencies of the different horizontal gene transfer mechanisms in disseminating antibiotic resistance by reinforcing the roles played by environmental bacteriophages and transduction.

Bacteriophage P1vir-induced cell-to-cell plasmid transformation in Escherichia coli

Bacteria undergo horizontal gene transfer via various mechanisms. We recently reported that cell-to-cell transfer of nonconjugative plasmids occurs between strains of Escherichia coli in co-cultures, and that a specific strain (CAG18439) causes frequent plasmid transfer involving a DNase-sensitive mechanism, which we termed "cell-to-cell transformation". Here we found that CAG18439 is a type of P1 bacteriophage lysogen that continuously releases phages. We tested the ability of P1vir bacteriophage to induce horizontal plasmid transfer and demonstrated that such a horizontal plasmid transfer was caused by adding culture supernatants of P1vir-infected cells harboring plasmids to other plasmid-free cells. This plasmid transfer system also reproduced the major features of plasmid transfer involving CAG18439, suggesting that P1vir-induced plasmid transfer is equivalent or very similar to plasmid transfer involving CAG18439. We further revealed that approximately two-thirds of the P1vir-induced plasmid transfer was DNase-sensitive, but that complete abolition of plasmid transfer was observed when proteins were denatured or removed, despite the presence or absence of DNase. Therefore, we concluded that P1vir-induced plasmid transfer is largely due to the occurrence of cell-to-cell transformation, which involves the assistance of some proteinaceous factor, and partly due to the occurrence of plasmid transduction, which is mediated by phage virions. This is the first demonstration of the P1-phage-induced cell-to-cell transformation.

High-Frequency Plasmid Transduction by Lactobacillus gasseri Bacteriophage phiadh

The temperate bacteriophage phiadh mediates plasmid DNA transduction in Lactobacillus gasseri ADH at frequencies in the range of 10 to 10 transductants per PFU. BglII-generated DNA fragments from phage phiadh were cloned into the BclI site of the transducible plasmid vector pGK12 (4.4 kb). Phage phiadh lysates induced from Lactobacillus lysogens harboring pGK12 or the recombinant plasmids were used to transduce strain ADH to chloramphenicol resistance. The transduction frequencies of recombinant plasmids were 10- to 10-fold higher than that of native pGK12. The increase in frequency generally correlated with the extent of DNA-DNA homology between plasmid and phage DNAs. The highest transduction frequency was obtained with plasmid pTRK170 (6.6 kb), a pGK12 derivative containing the 1.4- and 0.8-kb BglII DNA fragments of phiadh. DNA hybridization analysis of pTRK170-transducing phage particles revealed that pTRK170 had integrated into the phiadh genome, suggesting that recombination between homologous sequences present in phage and plasmid DNAs was responsible for the formation of high-frequency transducing phage particles. Plasmid DNA analysis of 13 transductants containing pTRK170 showed that each had acquired intact plasmids, indicating that in the process of transduction a further recombination step was involved in the resolution of plasmid DNA monomers from the recombinant pTRK170::phiadh molecule. In addition to strain ADH, pTRK170 could be transduced via phiadh to eight different L. gasseri strains, including the neotype strain, F. Gasser 63 AM (ATCC 33323).

Characterization of in vitro constructed IS30-flanked transposons

In order to facilitate functional studies on the mobile genetic element IS30, a resident of the Escherichia coli chromosome, transposon structures with two copies of IS30 flanking the chloramphenicol-resistance gene cat were constructed in vitro. Transposons containing IS30 as direct repeats (Tn2700 and Tn2702) transpose from multicopy plasmids into the genome of phage P1-15, thus giving rise to special transduction for cat with frequencies between 10(-5) and 10(-8)/plaque-forming unit. In contrast, transposon structures with IS30 in inverted repeat (Tn2701 and Tn2703) showed no detectable (less than 10(-9] transposition activity in vivo. By restriction analysis, two insertion sites of Tn2700 and Tn2702 on the phage P1-15 genome were indistinguishable from those observed earlier with a single copy of the IS30 element. These two insertion sites were used several times independently by Tn2700 and Tn2702. This confirms the non-random target selection by the element and it indicates that transposition of Tn2700 and Tn2702 follows the same rules as that of IS30.

Expression and proteolytic processing of the darA antirestriction gene product of bacteriophage P1

The darA gene coding for one of the two bacteriophage P1 antirestriction functions is expressed late after infection or induction. The protein is made as a high-molecular-weight soluble precursor. This is proteolytically cleaved to the mature form, which is a structural component of the phage head. Defective mutants of the phage have been found in which the synthesis of gpdarA is normal but processing does not take place. These mutations all map to the same region of the P1 genome and we propose that they lie in the structural gene for the processing protease.

Selection of bacterial pac sites recognized by Salmonella phage P22

A gene library of chromosomal PstI fragments from Salmonella typhimurium strain DB5575 has been established. By means of phage P22 mediated transduction, ten different clones which contained inserts that promoted plasmid transduction were selected out of a total of about 7,000 clones. Seven of these clones carried inserts that stimulated transduction independently of general and int-promoted recombination and were interpreted as carrying pac analogous signals. The remaining three clones carried inserts that promoted transduction under recombination proficient conditions, whereas transduction occurred at reduced rate in the absence of recombination. These were believed to have short regions of homology with P22 DNA.

Small Staphylococcus aureus plasmids are transduced as linear multimers that are formed and resolved by replicative processes

The molecular processes involved in the transduction of small staphylococcal plasmids by a generalized transducing phage, phi 11, have been analysed. The plasmids are transduced in the form of linear concatemers containing only plasmid DNA; plasmid-initiated replication is required for their generation but additive interplasmid recombination is not. Concatemers are probably generated by the interaction of one or more phage functions with replicating plasmid DNA. Insertion of any restriction fragment of the phage into the plasmid causes an approximately 10(5)-fold increase in transduction frequency, regardless of the size or genetic content of the fragment. The resulting transducing particles (Hft particles) contain mostly pure linear concatemers composed of tandem repeats of the plasmid::phage chimera, and their production requires active plasmid-initiated replication. The high frequency of transduction is a consequence of homologous recombination between the linear chimeric and phage concatemers, which has the effect of introducing an efficient pac site into the former. Following introduction into lysogenic recipient bacteria, the transducing DNA is first converted to the supercoiled form, then processed to monomers by a mechanism that requires the active participation of the plasmid replication system.

Sequence relations among the IncY plasmid p15B, P1, and P7 prophages

Electron microscopic analysis of heteroduplex molecules between the 94-kb plasmid p15B and the 92-kb phage P1 genome revealed nine regions of nonhomology, eight substitutions, and two neighboring insertions. Overall, the homologous segments correspond to 83% of the P1 genome and 81% of p15B. Heteroduplex molecules between p15B and the 99-kb phage P7 genome showed nonhomology in eight of the same nine regions; in addition, two new nonhomologous segments are present and P7 carries a 5-kb insertion representing Tn902. The DNA homology between those two genomes amounts to 79% of P7 DNA and 83% of p15B. Plasmid p15B contains two stem-loop structures. One of them has no equivalent structure on P1 and P7 DNA. The other substitutes the invertible C segments of P1 and P7 and their flanking sequences including cin, the gene for the site-specific recombinase mediating inversion.

Gene organization and target specificity of the prokaryotic mobile genetic element IS26

The 820-bp mobile genetic element IS26 loses its ability to promote transpositional cointegration (1) by short deletions near the middle of the element causing shifts in both reading frames ORFI (left to right) and ORFII (right to left) and (2) by deletions causing substitutions of the C-terminus of ORFI but not affecting ORFII. The 702-bp ORFI is thus likely to code for the IS26 transposase. An 82-bp long sequence from the left end of IS26 contains a promoter-like structure in front of the start of ORFI at coordinate 64. In appropriately constructed plasmids, this sequence promotes the expression of the galK structural gene. The observation provides additional evidence for the functional relevance of ORFI. Neither the presence nor the absence of an intact IS26 element on the same plasmid affects measurably the degree of the galK gene expression by the IS26 promoter. Sequence comparison of 14 independent integration sites of IS26 and its relatives reveals no striking rules for target selection by the element, and the distrubtion of integration sites of IS26 on small multicopy plasmids is nearly random and independent of the local AT-content.

Reversion of a truncated gene for ampicillin resistance by genetic rearrangements in Escherichia coli K12

The composite transposon Tn2672 is a derivative of the Tn3-related transposon Tn902 whose bla gene providing ampicillin resistance had been inactivated by the insertion of the IS1-flanked multiple drug resistance transposon Tn2671. Most ampicillin resistant revertants of Tn2672 are due to precise excision of Tn2671. However, a rare Bla+ revertant which still retains all the previously acquired drug resistance markers was isolated. On this revertant, the 5' part of the split bla gene on Tn2672 has converted to an intact, active bla gene, and the entire Tn902 is structurally restored. In contrast, the adjacent IS1b element belonging to Tn2671 has its terminal 142 base pairs deleted. Despite of this rearrangement, the split 3' part of bla and its adjacent sequences have remained unchanged. Models are presented to explain the observed DNA rearrangements, and their similarity with gene conversion events is discussed.

In vivo transfer of chromosomal mutations onto multicopy plasmids by transduction with bacteriophage P1

A technique is presented by which chromosomal mutations may be efficiently transferred onto chimeric multicopy plasmids in vivo. The technique employs the transduction of plasmids using bacteriophage P1 as vector. The utility of this method was demonstrated by cloning a chromosomal ompR mutation of Escherichia coli K-12. The high-frequency transduction of the chimeric plasmid appeared to be dependent on its integration into the chromosome by homologous recombination. The results also suggest that the plasmid was transduced as part of the chromosome and resolved from its integrated state in the recipient cell, resulting in a high yield of mutant plasmid segregants.

Functional characterization of the prokaryotic mobile genetic element IS26

IS26L and IS26R are the 820 bp long elements found as direct repeats at both ends of the kanamycin resistance transposon Tn2680. They can mediate cointegration in E. coli K12 which contains no IS26 in its chromosome. Cointegration occurs in rec+ or recA- strains with similar frequency. Upon cointegration mediated by either IS26R or IS26L, the element is duplicated and integrated into one of many different sites. Both IS26L and IS26R carry 14 bp perfect terminal inverted repeats and generate 8 bp direct repeats at their target sequences. Deletion formation mediated by IS26R was also observed. These functional and structural features of IS26 are characteristic of a prokaryotic mobile genetic element.

IS30, a new insertion sequence of Escherichia coli K12

Three independent spontaneous mutations of prophage P1 affecting the ability of the phage to reproduce vegetatively are due to the insertion of a mobile genetic element, called IS30. The same sequence is also carried in the R plasmid NR 1-Basel, but not in the parental plasmid NR 1. Southern hybridisation study indicates that the Escherichia coli K 12 chromosome carries several copies of IS30 as a normal resident. IS30 is 1.2 kb long and contains unique restriction cleavage sites for BglII, ClaI, HindIII, NciI and HincII, and it is cleaved twice by the enzymes HpaII and TaqI. The ends of IS30 are formed by 26 bp long inverted repeats with 3 bases mismatched. Upon transposition IS30 generates a duplication of only 2 bp of the target. The following observations suggest a pronounced specificity in target selection by IS30. In transposition to the phage P1 genome a single integration site was used three times independently, and in both orientations. A short region of sequence homology has been identified between the P1 and NR 1-Basel insertion sites. IS30 has mediated cointegration as well as deletion. The entire IS30 sequences were duplicated in the cointegrates between a pBR322 derivative containing IS30 and the genome of phage P1-15, and several loci on the P1-15 genome served as fusion sites, some of which were used more than once.

Coliphage P1-mediated transduction of cloned DNA from Escherichia coli to Myxococcus xanthus: use for complementation and recombinational analyses

We have found that coliphage P1 can be used to transduce cloned DNA from Escherichia coli to Myxococcus xanthus. Transduction occurred at a high efficiency, and no evidence for DNA restriction was observed. The analysis of the transductants showed that they fall into three general categories: (i) haploid cells which contain portions of the cloned DNA substituted for homologous chromosomal DNA; (ii) heterozygous merodiploids which contain the recombinant plasmid integrated into the chromosome at a region of homology; and (iii) homozygous merodiploids which contain two copies of a portion of the cloned DNA with the loss of the chromosomal copy of the genes. The merodiploids, once formed, are relatively stable. They were used to analyze two genes necessary for aggregation and thus fruiting body formation. P1 transduction also permits the reintroduction and substitution of mutated regions of cloned DNA into M. xanthus for the analysis of the role of the DNA in cellular physiology and development.

Physical analysis of the genomes of hybrid phages between phage P1 and plasmid p15B

The genomes of three plaque-forming recombinant phages between phage P1 and plasmid p15B were characterized by restriction cleavage analysis and electron microscopic heteroduplex studies. The structure of all three P1-15 hybrid genomes differs from that of P1 DNA in the res mod region coding for restriction and modification systems EcoP15 and EcoP1, respectively. P1-15 hybrid 2 shows an additional major difference to P1 around the site of the residential IS1 element of P1 and it does not carry an IS1 in its genome.

DNA restriction--modification genes of phage P1 and plasmid p15B. Structure and in vitro transcription

The EcoP1 and EcoP15 DNA restriction-modification systems are coded by the related P1 prophage and p15B plasmid. We have examined the organization of the genes for these systems using P1 itself, "P1-P15" hybrid phages expressing the EcoP15 restriction specificity of p15B and cloned restriction fragments derived from these phage DNAs. The results of transposon mutagenesis, restriction cleavage analysis. DNA heteroduplex analysis and in vitro transcription mapping allow the following conclusions to be drawn concerning the structural genes. (1) All of the genetic information necessary to specify either system is contained within a contiguous DNA segment of 5 x 10(3) bases which encodes two genes. One of them, necessary for both restriction and modification, we call mod and the other, required only for restriction (together with mod), we call res. (2) The res gene is about 2.8 x 10(3) bases long and at the heteroduplex level is largely identical for P1 and P15: it shows a small region of partial nonhomology and some restriction cleavage site differences. The mod gene is about 2.2 x 10(3) bases long and contains a 1.2 x 10(3) base long region of non-homology between P1 and P15 toward the N-terminus of the gene. The rest of the gene at this level of analysis is identical for the two systems. (3) Each of the genes is transcribed in vitro from its own promoter. It is possible that the res gene is also transcribed by readthrough from the mod promoter.

Genome fusion mediated by the site specific DNA inversion system of bacteriophage P1

The genome of bacteriophage P1 contains a segment which is invertible by site specific recombination between sequences near the outside ends of the inverted repeats which flank it. Immediately adjacent to this C segment is the coding sequence for cin, the enzyme catalyzing inversion. We show that multicopy plasmids carrying cin and the sequences at which it acts (cix) can form dimers in the absence of the host recA function. Further, such plasmids can be cotransduced with P1 markers at high frequency from recA lysogens, indicating cointegration with the P1 genome. It is thus demonstrated that a system whose primary role is the inversion of a specific DNA segment can also mediate intermolecular recombination.

Expression of a neomycin phosphotransferase gene from Streptomyces fradiae in Escherichia coli after interplasmidic recombination

Plasmid pIJ2 carrying the neomycin phosphotransferase gene of Streptomyces fradiae was fused to E. coli plasmid pBR325 and the hybrid molecules were introduced into E. coli K12 by transformation. The neomycin phosphotransferase gene of the hybrid plasmid was not expressed in E. coli, except after interplasmidic recombination. Physical analysis of such an in vivo recombinant plasmid revealed that the recombination brought one neomycin phosphotransferase gene to a position downstream from the tet-promoter of pBR325. Subcloning experiments indicated that this is the gene copy expressed, and that transcription is initiated at the tet-promoter of pBR325.

Sequence of the site-specific recombinase gene cin and of its substrates serving in the inversion of the C segment of bacteriophage P1

Inversion of the 4.2-kb C segment flanked by 0.6-kb inverted repeats on the bacteriophage P1 genome is mediated by the P1-encoded site-specific cin recombinase. The cin gene lies adjacent to the C segment and the C inversion cross-over sites cixL and cixR are at the external ends of the inverted repeats. We have sequenced the DNA containing the cin gene and these cix sites. The cin structural gene consists of 561 nucleotides and terminates at the inverted repeat end where the cixL site is located. Only two nucleotides in the cixL region differ from those in the cixR and they are within the cin TAA stop codon. The cin promoter was localized by transposon mutagenesis within a 0.1-kb segment, which contains probable promoter sequences overlapping with a 'pseudo-cix' sequence cixPp. In a particular mutant, integration of an IS1-flanked transposon into the cin control region promoted weak expression of the cin gene. The cin and cix sequences show homology with corresponding, functionally related sequences for H inversion in Salmonella and with cross-over sites for G inversion in phage Mu. Based on a comparison of the DNA sequences and of the gene organizations, a possible evolutionary relationship between these three inversion systems and the possible significance of the cixPp sequence in the cin promoter are discussed.

A site-specific, conservative recombination system carried by bacteriophage P1. Mapping the recombinase gene cin and the cross-over sites cix for the inversion of the C segment

The bacteriophage P1 genome carries an invertible C segment consisting of 3-kb unique sequences flanked by 0.6-kb inverted repeats. With insertion and deletion mutants of P1 derivatives the site-specific recombinase gene cin for C inversion) has been mapped adjacent to the C segment and the cix sites (for C inversion cross-over) have been located at the outside ends of the inverted repeats. Inversion of the C segment functions as a biological switch and controls expression of the gene(s) responsible for phage infectivity carried on the C segment. The cin gene product can promote recombination between a 'quasi- cix ' site on plasmid pBR322 and a cix site on P1 DNA. The junctions formed on the resulting co-integrate can also serve as cix sites. This observation implies a potential evolutionary process to bring genes under the control of a biological switch acting by DNA inversion.