Plasmid RP4 specifies a deoxyribonucleic acid primase involved in its conjugal transfer and maintenance.

We surveyed plasmids representative of most incompatibility groups for their conferred deoxyribonucleic acid (DNA) primase activity. RP4 (IncP) was one of the few with such activity although, unlike the derepressed IncIalpha plasmids (which also specify a primase), it did not suppress the dnaG mutation. Using deletion and Tn7 derivatives of RP4, we located the presumed primase structural gene (pri) in the 37- to 42-kilobase region. Tn7 insertions in the adjacent Tra1 region also reduced or caused overproduction of primase. We purified the RP4 primase to a single polypeptide of molecular weight 118,000. It is an anisometric molecule and functions as a monomer, initiating complementary strand synthesis on phi X174 DNA in Escherichia coli dnaG cell extracts in the presence of ribonucleotide triphosphates and rifampin. It is immunologically unrelated to either the E. coli dnaG or the IncIalpha plasmid-specified DNA primases. RP4 pri mutants conjugated with a lower efficiency into some bacterial species, including Salmonella typhimurium. Back-transfer experiments showed that this effect was recipient specific. There was also a comparable reduction in mobilization efficiency of R300B by RP4 pri into such recipients. Loss of RP4 primase led to detectable plasmid instability. The RP4-specified primase therefore seems to serve two functions: the single DNA strand transferred during conjugation is primed by it in the recipient cell, and it appears to be necessary for the efficient priming of discontinuous plasmid DNA replication despite the presence of the chromosomal priming system.     

A common sequence motif, -E-G-Y-A-T-A-, identified within the primase domains of plasmid-encoded I- and P-type DNA primases and the alpha protein of the Escherichia coli satellite phage P4.

DNA primases encoded by the conjugative plasmids ColIb-P9 (IncI1), RP4, and R751 (IncP), and the protein of the Escherichia coli satellite phage P4 alpha were shown to contain a common amino acid sequence motif -E-G-Y-A-T-A-. The P4 alpha gene product, required for initiation of phage DNA replication, exhibits primase activity on single-stranded circular DNA templates. This priming activity resembles the enzymatic activity of DNA primases encoded by conjugative plasmids in terms of template utilization and the ability to synthesize primers that can be elongated by DNA polymerase III holoenzyme. The -E-G-Y-A-T-A- motif is part of an extended sequence region most conserved within the primase domains of the four enzymes. Single amino acid substitutions generated in the -E-G-Y-A-T-A- motif of the RP4 TraC2 and the P4 alpha protein affect priming activity, supporting the hypothesis that the conserved sequence motif is part of the active center for primase function. A mutation that eliminates priming activity causes P4 phage to grow poorly and to depend upon the host dnaG primase. Computer analysis identified two additional sequence motifs within the amino acid sequence of the P4 alpha protein: a potential zinc-finger motif and a "type A" nucleotide binding site, both strikingly similar to sequence motifs described in various DNA primases and helicases.     

Detection of tellurite-resistance determinants in IncP plasmids

Six IncP plasmids were tested for their ability to generate tellurite-resistant variants by plating bacterial strains harbouring them on medium containing potassium tellurite. Four plasmids, three of subgroup IncP alpha and one not allocated, formed variants that could transfer tellurite-resistance at the same frequency as plasmid-determined drug resistance. This property was not shared by two examples of subgroup IncP beta.     

Comparison of 10 IncP plasmids: homology in the regions involved in plasmid replication.

We have examined the DNA homology in the replication regions of 10 IncP plasmids independently isolated from several different countries. Two regions of RK2, the best-studied plasmid of this group, are required for vegetative DNA replication: the origin of replication (oriV) and the trfA region, which codes for a gene product necessary for replication. Six of nine IncP plasmids studied were identical to RK2 in the oriV and trfA regions as shown by Southern hybridization. Three P plasmids, R751, R772, and R906, showed weaker homology with the RK2 trfA, region and hybridized to different-sized HaeII fragments than the other six plasmids. R751, R772, and R906 hybridized to the region of the RK2 replication origin which expresses P incompatibility but differed markedly from RK2 and the other six plasmids in the GC-rich region of the origin required for replication. These data indicate that the P-group plasmids can be divided into two subgroups: IncP alpha, which includes the RK2-like plasmids, and IncP beta which includes the R751-like plasmids.     

Role and specificity of plasmid RP4-encoded DNA primase in bacterial conjugation.

The role of the DNA primase of IncP plasmids was examined with a derivative of RP4 containing Tn7 in the primase gene (pri). The mutant was defective in mediating bacterial conjugation, with the deficiency varying according to the bacterial strains used as donors and recipients. Complementation tests involving recombinant plasmids carrying cloned fragments of RP4 indicated that the primase acts to promote some event in the recipient cell after DNA transfer and that this requirement can be satisfied by plasmid primase made in the donor cell. It is proposed that the enzyme or its products or both are transmitted to the recipient cell during conjugation, and the role of the enzyme in the conjugative processing of RP4 is discussed. Specificity of plasmid primases was assessed with derivatives of RP4 and the IncI1 plasmid ColIb-P9, which is known to encode a DNA primase active in conjugation. When supplied in the donor cell, neither of the primases encoded by these plasmids substituted effectively in the nonhomologous conjugation system. Since ColIb primase provided in the recipient cell acted weakly on transferred RP4 DNA, it is suggested that the specificity of these enzymes reflects their inability to be transmitted via the conjugation apparatus of the nonhomologous plasmid.     

The completely sequenced plasmid pEST4011 contains a novel IncP1 backbone and a catabolic transposon harboring tfd genes for 2,4-dichlorophenoxyacetic acid degradation

The herbicide 2,4-dichlorophenoxyacetic acid (2,4-D)-degrading bacterium Achromobacter xylosoxidans subsp. denitrificans strain EST4002 contains plasmid pEST4011. This plasmid ensures its host a stable 2,4-D(+) phenotype. We determined the complete 76,958-bp nucleotide sequence of pEST4011. This plasmid is a deletion and duplication derivative of pD2M4, the 95-kb highly unstable laboratory ancestor of pEST4011, and was self-generated during different laboratory manipulations performed to increase the stability of the 2,4-D(+) phenotype of the original strain, strain D2M4(pD2M4). The 47,935-bp catabolic region of pEST4011 forms a transposon-like structure with identical copies of the hybrid insertion element IS1071::IS1471 at the two ends. The catabolic regions of pEST4011 and pJP4, the best-studied 2,4-D-degradative plasmid, both contain homologous, tfd-like genes for complete 2,4-D degradation, but they have little sequence similarity other than that. The backbone genes of pEST4011 are most similar to the corresponding genes of broad-host-range self-transmissible IncP1 plasmids. The backbones of the other three IncP1 catabolic plasmids that have been sequenced (the 2,4-D-degradative plasmid pJP4, the haloacetate-catabolic plasmid pUO1, and the atrazine-catabolic plasmid pADP-1) are nearly identical to the backbone of R751, the archetype plasmid of the IncP1 beta subgroup. We show that despite the overall similarity in plasmid organization, the pEST4011 backbone is sufficiently different (51 to 86% amino acid sequence identity between individual backbone genes) from the backbones of members of the three IncP1 subgroups (the alpha, beta, and gamma subgroups) that it belongs to a new IncP1subgroup, the delta subgroup. This conclusion was also supported by a phylogenetic analysis of the trfA2, korA, and traG gene products of different IncP1 plasmids.     

Gene organization and nucleotide sequence of the primase region of IncP plasmids RP4 and R751.

The primase genes of RP4 are part of the primase operon located within the Tra1 region of this conjugative plasmid. The operon contains a total of seven transfer genes four of which (traA, B, C, D) are described here. Determination of the nucleotide sequence of the primase region confirmed the existence of an overlapping gene arrangement at the DNA primase locus (traC) with in-phase translational initiation signals. The traC gene encodes two acidic and hydrophilic polypeptide chains of 1061 (TraC1) and 746 (TraC2) amino acids corresponding to molecular masses of 116,721 and 81,647 Da. In contrast to RP4 the IncP beta plasmid R751 specifies four large primase gene products (192, 152, 135 and 83 kDa) crossreacting with anti-RP4 DNA primase serum. As shown by deletion analysis at least the 135 and 83 kDa polypeptides are two separate translational products that by analogy with the RP4 primases, arise from in-phase translational initiation sites. Even the smallest primase gene products TraC2 (RP4) and TraC4 (R751) exhibit primase activity. Nucleotide sequencing of the R751 primase region revealed the existence of three in-phase traC translational initiation signals leading to the expression of gene products with molecular masses of 158,950 Da, 134,476 Da, and 80,759 Da. The 192 kDa primase polypeptide is suggested to be a fusion protein resulting from an in frame translational readthrough of the traD UGA stopcodon. Distinct sequence similarities can be detected between the TraC proteins of RP4 and R751 gene products TraC3 and TraC4 and in addition between the TraD proteins of both plasmids. The R751 traC3 gene contains a stretch of 507 bp which is unrelated to RP4 traC or any other RP4 Tra1 gene.     

Retrotransfer of IncP piasmid R751 from Escherichia coli maxicells: evidence for the genetic sufficiency of self-transferable plasmids for bacterial conjugation

Gene transfer between organisms is a prime contributor to evolution. Bacterial conjugation is probably the most important mechanism by which genes are spread among prokaryotes and perhaps also contributes to eukaryotic evolution. Conjugation is mediated by plasmids. The mechanism of conjugation remains ill-understood despite progress in the identification, mapping and sequencing of genes required for plasmid transmission. All conjugation-specific genes (those required only for DNA transfer and establishment) identified to date map to plasmids. We found that IncP plasmids could enter and subsequently convert maxicells, which are trapped in a metabolic state that prevents de novo expression of chromosomal genes, into conjugative donors. This suggests that IncP plasmids encode not only necessary functions but indeed all functions specific to DNA transmission. Thus, like viruses, plasmids can convert non-viable cells into gene vectors.     

Structural-functional organization of the incompatibility group P plasmid pBS221

Plasmid pBS221 was physically mapped for restriction endonucleases EcoRI, BamHI, BglII, HindIII. The regions essential for the plasmid existence and participating in replication (oriV trfA*) and mobilization (mob) were cloned. The tet determinant and oriV trfA* regions were localized on the physical map of the plasmid. A DNA sequence homologous to genes of Tn501 mer operon was detected in this plasmid. The studies on homology of plasmids RP4 (IncP alpha), R751 (IncP beta) and pBS221 plasmid suggest that the latter belongs to the IncP beta subgroup.     

Retrotransfer of IncP1-like plasmids from aquatic bacteria

The first observation of plasmid retrotransfer by plasmids isolated from environmental sources is reported. A high incidence of retrotransferring ability amongst plasmids isolated from epilithic bacteria was found; some of these plasmids retrotransferred an IncQ plasmid at very high frequencies. Despite the broad host-range of the majority of the plasmids, only five out of 12 could be assigned to an incompatibility group by DNA hybridization. All five were designated IncP1; this revealed a limitation of probes derived from clinical sources for use with environmental isolates. Incompatibility testing by plate mating suggested that four additional plasmids displayed varying, albeit lower, degrees of incompatibility to the IncP1 plasmid RP1.     

pHH502, a plasmid with IncP and IncI alpha characters, loses the latter by a specific recA-independent deletion event

Plasmid pHH502, of molecular weight 70 X 10(6), determined resistance to tetracycline, chloramphenicol, trimethoprim, sulphonamides and mercuric chloride and was incompatible with members of IncP and IncI alpha. It resembled other plasmids of IncI alpha in the following properties: it determined pili that were morphologically and serologically I alpha pili, whose production was repressed in established plasmid-carrying (R+) cultures; its transfer was equally efficient in liquid or on solid medium; it exerted surface exclusion against other IncI alpha plasmids; it was non-transferable to Proteus. In a reproducible, recA-independent event, pHH502 gave rise to pHH502-1, a plasmid of molecular weight 40 X 10(6), lacking determinants for resistance to tetracycline and chloramphenicol and all detectable IncI alpha characteristics. pHH502-1 was incompatible only with IncP plasmids and resembled other IncP plasmids in determining constitutive production of rigid pili, in its surface exclusion, in transferring at greater frequency on solid than in liquid medium and in being transmissible to Proteus mirabilis. It differed from other IncP plasmids in the morphology and serological type of its pili and in failing to transfer to Pseudomonas aeruginosa or Acinetobacter calcoaceticus. Small numbers of pHH502-1 rigid pili were present on bacteria carrying pHH502. Possible mechanisms for the generation of pHH502 and pHH502-1 are discussed.     

Conserved regions at the DNA primase locus of IncPα and IncPβ plasmids

Genes specifying DNA primases (pri) are common in all IncP plasmids examined so far. These plasmids suppress the thermosensitive character of the Escherichia coli dnaG3 mutation. The mechanism of suppression appears to be identical to that known for RP4 and IncIα plasmids. The DNA primases of both these plasmid types can substitute for the dnaG protein in chromosomal DNA replication. The pri genes of the α and β subgroup of IncP plasmids are related to each other as judged from Southern hybridization and immunological data. Extensive DNA and protein sequence homology has been detected although the gene products of the α and β subgroups exhibit substantial differences in size. The arrangement of overlapping genes at the pri locus of IncPα plasmids also appears to be present in the IncPβ group.     

The conjugal transfer system of Agrobacterium tumefaciens octopine-type Ti plasmids is closely related to the transfer system of an IncP plasmid and distantly related to Ti plasmid vir genes.

We have determined the DNA sequences of two unlinked regions of octopine-type Ti plasmids that contain genes required for conjugal transfer. Both regions previously were shown to contain sequences that hybridize with tra genes of the nopaline-type Ti plasmid pTiC58. One gene cluster (designated tra) contains a functional oriT site and is probably required for conjugal DNA processing, while the other gene cluster (designated trb) probably directs the synthesis of a conjugal pilus and mating pore. Most predicted Tra and Trb proteins show relatively strong sequence similarity (30 to 50% identity) to the Tra and Trb proteins of the broad-host-range IncP plasmid RP4 and show significantly weaker sequence similarity to Vir proteins found elsewhere on the Ti plasmid. An exception is found in the Ti plasmid TraA protein, which is predicted to be a bifunctional nickase-helicase that has no counterpart in IncP plasmids or among Vir proteins but has homologs in at least six other self-transmissible and mobilizable plasmids. We conclude that this Ti plasmid tra system evolved by acquiring genes from two or three different sources. A similar analysis of the Ti plasmid vir region indicates that it also evolved by appropriating genes from at least two conjugal transfer systems. The widely studied plasmid pTiA6NC previously was found to be nonconjugal and to have a 12.65-kb deletion of DNA relative to other octopine-type Ti plasmids. We show that this deletion removes the promoter-distal gene of the trb region and probably accounts for the inability of this plasmid to conjugate.     

Assembly of a functional phage PRD1 receptor depends on 11 genes of the IncP plasmid mating pair formation complex.

PRD1, a lipid-containing double-stranded DNA bacteriophage, uses the mating pair formation (Mpf) complex encoded by conjugative IncP plasmids as a receptor. Functions responsible for conjugative transfer of IncP plasmids are encoded by two distinct regions, Tra1 and Tra2. Ten Tra2 region gene products (TrbB to TrbL) and one from the Tra1 region (TraF) form the Mpf complex. We carried out a mutational analysis of the PRD1 receptor complex proteins by isolating spontaneous PRD1-resistant mutants. The mutations were distributed among the trb genes in the Tra2 region and accumulated predominantly in three genes, trbC, trbE, and trbL. Three of 307 phage-resistant mutants were weakly transfer proficient. Mutations causing a phage adsorption-deficient, transfer-positive phenotype were analyzed by sequencing.     

Self-transmissible IncP R995 plasmids with alternative markers and utility for Flp/FRT cloning strategies

The IncP plasmid R995 has been a useful self-transmissible, broad-host-range vector for a number of applications including the recombinase/conjugation-based cloning of large genomic DNA segments. However, R995 derivatives (or related plasmids) expressing a wide range of different resistance markers and Flp recombinase target sites do not exist in the literature. In addition, documented strategies for applying such plasmids in cloning applications that take advantage of conjugation for the convenient isolation and recovery of constructs are extremely limited. Here, we report a new series of R995 plasmids with alternative markers to increase options for applications in backgrounds already expressing resistance to a particular antibiotic(s). These R995 plasmids have been engineered to contain FRT sites that can be used for recombinase-based cloning. We demonstrate the utility of this approach by cloning 20 kb regions from the Salmonella Typhimurium and Escherichia coli genomes and by cloning DNA from an exogenous plasmid source. To our knowledge, this represents the first systematic engineering of an intact, self-transmissible IncP plasmid with a series of alternative antibiotic markers and FRT sites.     

Detection of IncP replicon-specific regions in DNA from Antarctic microbiota

Plasmids capable of horizontal transfer contribute to the adaptability of bacteria, as they may provide genes that enable their hosts to cope with different selective pressures. Only limited information is available on plasmids from Antarctic habitats, and up until now surveys have only used traditional methods of endogenous plasmid isolation. The method based on primer systems, designed on the basis of published sequences for plasmids from different incompatibility (Inc) groups, is appropriate to detect the replicon-specific regions of corresponding plasmids in cultured bacteria, or in total community DNA, which share sufficient DNA similarity with reference plasmids at the amplified regions. In this study, we applied broad-host-range plasmid-specific primers to DNA from microbial samples collected at six different locations in Northern Victoria Land (Antarctica). DNA preparations were used as targets for PCR (polymerase chain reaction) amplification with primers for the IncP (trfA2) and IncQ (oriV ) groups. PCR products were Southern blotted and hybridized with PCR-derived probes for trfA2 and oriV regions. This approach detected the occurrence of IncP-specific sequences in eight out of fifteen DNA samples, suggesting a gene-mobilizing capacity within the original habitats.     

General organization of the conjugal transfer genes of the IncW plasmid R388 and interactions between R388 and IncN and IncP plasmids.

The complete conjugal transfer gene region of the IncW plasmid R388 has been cloned in multicopy vector plasmids and mapped to a contiguous 14.9-kilobase segment by insertion mutagenesis. The fertility of the cloned region could still be inhibited by a coresident IncP plasmid. The transfer region has been dissected into two regions, one involved in pilus synthesis and assembly (PILW), and the other involved in conjugal DNA metabolism (MOBW). They have been separately cloned. PILW also contains the genes involved in entry exclusion. MOBW contains oriT and the gene products required for efficient mobilization by PILW. MOBW plasmids could also be mobilized efficiently by PILN, the specific pilus of the IncN plasmid pCU1, but not by PILP, the specific pilus of the IncP plasmid RP1.