The primase of broad-host-range plasmid R1162 is active in conjugal transfer.

The broad-host-range plasmid R1162 is conjugally mobilized at high frequency by the IncP-1 plasmid R751 but is poorly mobilized by pOX38, a derivative of the F factor. In both cases, the origin of transfer (oriT) and the Mob proteins of R1162 are required, indicating that these plasmids are mobilized by similar mechanisms. R1162 encodes a primase, essential for vegetative replication of the plasmid, that is made both as a separate protein and as the carboxy-terminal domain of MobA, one of the R1162 mobilization proteins (P. Scholz, V. Haring, B. Wittman-Liebold, K. Ashman, M. Bagdasarian, and E. Scherzinger, Gene 75:271-288, 1989). When R751 is the mobilizing vector, the primase is not required for mobilization of plasmids containing cloned mob-oriT R1162 DNA. However, detectable mobilization of such plasmids by pOX38 requires both the primase and its cognate initiation site, oriented for synthesis of the complement to the transferred strand. The long form of the primase is required for optimal transfer: R1162 replicons lacking this form also are not transferred detectably by pOX38 and are less well mobilized by R751. The distance between oriT and the primase initiation site affects the frequency of mobilization, and this effect is polar in the direction of transfer. Our results indicate that the R1162 primase is active in mobilization of R1162 and suggest that the MobA-linked form is an adaptation increasing its effectiveness during transfer.     

DNA primase of plasmid ColIb is involved in conjugal DnA synthesis in donor and recipient bacteria.

The sog gene of the IncI alpha group plasmid ColIb is known to encode a DNA primase that can substitute for defective host primase in dnaG mutants of Escherichia coli during discontinuous DNA replication. The biological significance of this enzyme was investigated by using sog mutants, constructed from a derivative of ColIb by in vivo recombination of previously defined mutations in a cloned sog gene. The resultant Sog- plasmids failed to specify detectable primase activity and were unable to suppress a dnaG lesion. These mutants were maintained stably in E. coli, implying that the enzyme is not involved in vegetative replication of ColIb. However, the Sog- plasmids were partially transfer deficient in E. coli and Salmonella typhimurium matings, consistent with the hypothesis that the normal physiological role of this enzyme is in conjugation. This was confirmed by measurements of conjugal DNA synthesis. Studies of recipient cells have indicated that plasmid primase is required to initiate efficient synthesis of DNA complementary to the transferred strand, with the protein being supplied by the donor parent and probably transmitted between the mating cells. Primase specified by the dnaG gene of the recipient can substitute partially for the mutant enzyme, thus providing an explanation for the partial transfer proficiency of the mutant plasmids. Conjugal DNA synthesis in dnaB donor cells was deficient in the absence of plasmid primase, implying that the enzyme also initiates synthesis of DNA to replace the transferred material.     

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.     

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.     

Initiation of DNA synthesis in the transfer origin region of RK2 by the plasmid-encoded primase: detection using defective M13 phage

The broad host range IncP (IncP1) plasmids of gram-negative bacteria encode DNA primases that are involved in conjugal DNA synthesis. The primase of RK2/RP4 is required for efficient DNA transfer to certain gram-negative bacteria, indicating that the enzyme primes complementary strand synthesis in the recipient. In vitro, the primase initiates synthesis of oligoribonucleotides at 3'-dGdT-5' dinucleotides on the template strand. In this report, replication-defective M13 phage are used to assay the ability of the RK2-encoded primase to initiate complementary strand synthesis in vivo on single-strand templates containing the RK2 origin of conjugal transfer (oriT) or the RK2 origin of vegetative replication (oriV). The results show that sequences from either strand of the oriT region serve as efficient substrates for the RK2 primase and can enhance the growth of the defective M13 vectors delta E101 and delta Elac to levels approaching wild-type. The primise-oriT interaction appeared specific, since neither the oriV sequence nor another RK2 region, trfB, significantly enhanced growth of the defective phage, either in the presence or in the absence of the primase. In contrast to ColEl and F, this study also shows that the oriV region of RK2 lacks sites that are recognized by the host-specified DNA priming systems. The results suggest that the oriT region contains sites on both DNA strands that are efficient substrates for the plasmid-encoded primase, facilitating initiation of complementary strand DNA synthesis in both donor and recipient during conjugation.     

Replication of a plasmid lacking the normal site for initiation of one strand.

The origin of replication of the plasmid R1162 contains an initiation site for the synthesis of each DNA strand. When one of these sites (oriL) is deleted, synthesis on the corresponding strand is no longer initiated efficiently in vitro by the R1162-encoded replication proteins, and the plasmid is no longer stably maintained in the cell. However, in vivo the two strands of the plasmid duplex molecule are active at a similar level as templates for DNA synthesis, and newly synthesized copies of each strand are incorporated into daughter molecules at a similar rate. No secondary, strong initiation sites on the delta oriL strand were detected in the region of the origin. The delta oriL plasmid induces the SOS response, and this is important for plasmid maintenance even in a recombination-proficient strain. Our results indicate that an SOS-induced host system can maintain an R1162 derivative lacking one of its initiation sites.     

Localized denaturation of oriT DNA within relaxosomes of the broad-host-range plasmid R1162

The broad-host-range, multicopy plasmid R1162 is efficiently mobilized during conjugation by the self-transmissible plasmid R751. The relaxosome, a complex of plasmid DNA and R1162-encoded proteins, forms at the origin of transfer ( oriT ) and is required for mobilization. Transfer is initiated by strand- and site-specific nicking of the DNA within this structure. We show by probing with potassium permanganate that oriT DNA is locally melted within the relaxosome, in the region from the inverted repeat to the site that is nicked. Mutations in this region of oriT , and in genes encoding the protein components of the relaxosome, affect both nicking and melting of the DNA. The nicking protein in the relaxosome is MobA, which also ligates the transferred linear, single strand at the termination of a round of transfer. We propose that there is an underlying similarity in the substrates for these two MobA-dependent, DNA-processing reactions. We also show that MobA has an additional role in transfer, beyond the nicking and resealing of oriT DNA.     

Deletion of sites for initiation of DNA synthesis in the origin of broad host-range plasmid R1162

The origin of replication of the broad host-range plasmid R1162 contains two, oppositely facing initiation sites for DNA synthesis. Either of these sites can be deleted from an R1162 plasmid derivative. However, the resulting plasmids are unstable, maintained at a lower copy-number in the cell, and form dimers and other recombinants that are required for propagation of the plasmid. In vitro, a derivative lacking one initiation site is deficient in synthesis of the strand normally initiated from that site. The properties of the intact origin are restored if it contains two oppositely facing sites; one initiation site may substitute for the other, and each site need not be in its original orientation. Overall, the results suggest that synthesis of each strand of R1162 DNA is initiated at a single site, and that there is no efficient system for initiation of lagging strand synthesis during transit of the replication forks.     

A novel priming system for conjugal synthesis of an IncI alpha plasmid in recipients.

Summary Synthesis of DNA complementary to the transferred strand of an IncI plasmid has been shown previously to require DNA polymerase III. The possible involvement of the two defined priming proteins of Escherichia coli K12, RNA polymerase and primase, in initiating this conjugal DNA synthesis has been examined. Primase was inactivated using temperature-sensitive dnaG3 mutants and RNA polymerase was inhibited using rifampicin. When these two proteins were simultaneously inactivated in both parental strains, the average recipient synthesised at least one single-stranded equivalent of R144drd-3 before the rifampicin-treated donors lost the ability to transmit DNA. It is proposed that the product of a plasmid transfer gene is responsible for initiating this DNA synthesis in recipients. The results imply that this protein is supplied by the donors.     

Bacterial conjugative transfer: visualization of successful mating pairs and plasmid establishment in live Escherichia coli

We used the LacO/GFP-LacI system to label and visualize the IncP beta plasmid R751 fluorescently during conjugative transfer between live donor and recipient bacteria. Comparisons of R751 in conjugative and non-conjugative conditions have allowed us to identify key localizations and movements associated with the initiation of conjugative transfer in the donor and the establishment of R751 in the recipient. A survey of successful mating pairs demonstrates that close physical contact between donor and recipient bacteria is required for DNA transfer and that regions of intimate contact can occur at any location on the donor or recipient cell membrane. The transferred DNA is positioned at the characteristic centre or quarter-cell position after conversion to a double-stranded molecule in the recipient cell. Initial duplication of plasmids often results in an asymmetric distribution of plasmid foci. Symmetric localization (either at centre or at 1/4 and 3/4 cell lengths) occurs only after a significant lag, presumably reflecting the time required to synthesize the plasmid-encoded partitioning proteins.     

Conjugal Deoxyribonucleic Acid Replication by Escherichia coli K-12: Stimulation in dnaB(ts) Donors by Minicells

R64-11(+) donor cells that are thermosensitive for vegetative DNA replication will synthesize DNA at the restrictive temperature when recipient minicells are present. This is conjugal DNA replication because it is R64-11 DNA that is being synthesized and there is no DNA synthesis if minicells that cannot be recipients of R64-11 DNA are used. The plasmid DNA present in the donor cells before mating is transferred to recipient minicells within the first 20 min of mating, but additional copies of plasmid DNA synthesized during the mating continue to be transferred for at least 90 min. However, the transfer of R64-11 DNA to minicells is not continuous because the plasmid DNA in minicells is the size of one R64-11 molecule or smaller, and there are delays between the rounds of plasmid transfer. DNA is synthesized in minicells during conjugation, but this DNA has a molecular weight much smaller than that of R64-11. Thus, recipient minicells are defective and are not able to complete the synthesis of a DNA strand complementary to the single-stranded R64-11 DNA received from the donor cell.     

Facilitated transfer of IncP beta R751 derivatives from the chromosome of Bacteroides uniformis to Escherichia coli recipients by a conjugative Bacteroides tetracycline resistance element.

The broad-host-range IncP beta plasmid R751 can mobilize itself from Escherichia coli to Bacteroides spp, but it is not maintained in Bacteroides spp. If R751 carries the Bacteroides transposon Tn4351, it can be integrated into the Bacteroides chromosome. Previously we showed that R751, integrated in the chromosome of Bacteroides uniformis, cannot mobilize itself out of B. uniformis into E. coli or isogenic B. uniformis strains. In this report, we showed that if the Bacteroides conjugative tetracycline resistance element Tcr ERL was coresident with the R751 insertion in B. uniformis, derivatives of R751 were transferred to E. coli, where they were recovered as plasmids. The most common derivatives were R751::Tn4351 and R751::IS4351, but some strains transferred R751 derivatives, containing additional DNA segments ranging in size from 10 to 23 kilobases. These DNA inserts cross-hybridized with chromosomal DNA from B. uniformis which did not carry the Tcr ERL element. Therefore, the inserts appeared to be segments of the wild-type B. uniformis chromosome and were not associated with the Tcr ERL element. The transfer of integrated R751 from B. uniformis was independent of the RecA phenotype of the E. coli recipients and did not appear to be due to transfer of B. uniformis chromosomal DNA, followed by RecA-dependent recombination between homologous IS4351 sequences to form the resultant R751 plasmid derivatives. Consistent with this, no transfer of Tn4351 (associated with the cointegrated R751) from B. uniformis donors to isogenic B. uniformis recipients was detected (< 10(-8)). Our data support the hypothesis that R751 excises from the B. uniformis chromosome by recombination involving flanking Tn4351 or IS4351 sequences and forms nonreplicating circles. The mobilization of these circular forms out of B. uniformis to E.coli is then facilitated by the Tcr ERL element.     

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.     

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.     

Initiation signals for complementary strand DNA synthesis on single-stranded plasmid DNA.

The bacteriophage 0X174 origin for (+) strand DNA synthesis, when inserted in a plasmid, is in vivo a substrate for the initiator A protein, that is produced by infecting phages. The result of this interaction is the packaging of single-stranded plasmid DNA into preformed phage coats. These plasmid particles can transduce 0X-sensitive cells; however, the transduction efficiency depends strongly on the presence in the packaged DNA strand of an initiation signal for complementary strand DNA synthesis. A plasmid with the complementary (-) strand origin of 0X inserted in the same strand as the viral (+) origin transduces 50-100 times more efficient than the same plasmid without the (-) origin of 0X. The transduction efficiency of such a particle is comparable to the infection efficiency of the phage particle. It is shown that in this system the 0X (-) origin can be replaced by the complementary strand origins of the bacteriophages G4 and M13. We have used this system to isolate sequences, from E. coli plasmids (pACYC177, CloDF13, miniF and OriC) and from the E. coli chromosome that can function as initiation signals for the conversion of single-stranded plasmid DNA to double-stranded DNA. All isolated origins were found to be dependent for their activity on the dnaB, dnaC and dnaG proteins. We conclude that these signals were all primosome-dependent origins and that primosome priming is the major mechanism for initiation of the lagging strand DNA synthesis in E. coli. The assembly of the primosome depends on the sequence-specific interaction of the n' protein with single-stranded DNA. We have used the isolated sequences to deduce a consensus recognition sequence for the n' protein. The role of a possible secondary structure in this sequence is discussed.     

The MobA-linked primase is the only replication protein of R1162 required for conjugal mobilization

Cells newly transformed with plasmid R1162 DNA were used as donors in conjugal matings to determine if the plasmid replication genes are necessary for transfer. An intact system for vegetative replication is not required for transfer at normal frequency, but the plasmid primase, in the form linked to the nickase, must be present in donor cells.     

Role of sog polypeptides specified by plasmid ColIb-P9 and their transfer between conjugating bacteria.

The sog gene of the conjugative plasmid ColIb-P9 specifies two sequence-related polypeptides with the N-terminal third of the larger product having DNA primase activity. To resolve the function of the C-terminal portion of the polypeptides, we constructed a ColIb mutant containing a Tn5 insertion in the 3' region of sog. The mutation truncated sog gene products without inactivating DNA primase and rendered the plasmid defective in conjugation. Tests for the presence of conjugative pili, for complementation by a sog+ recombinant, and for mobilization of small origin of transfer (oriT) recombinant plasmids indicated that the mutant ColIb allows conjugative aggregation of cells but it is defective in DNA transfer at some stage subsequent to its initiation at oriT. Physical evidence is given that normal sog polypeptides are among a group of proteins transferred selectively from the donor to the recipient cell by a conjugation-specific process. No transfer of the mutant sog proteins was detected. It is proposed that the C-terminal region of sog polypeptides facilitates transfer of single-stranded ColIb DNA between conjugating cells following initiation of transfer at the oriT site, and that in this role the proteins are transmitted to the recipient cell.     

Physical Properties and Mechanism of Transfer of R Factors in Escherichia coli

The physical properties of F-like and I-like R factors have been compared with those of the wild-type F factor in Escherichia coli K-12 unmated cells and after transfer to recipient cells by conjugation. The F-like R factor R538-1drd was found to have a molecular weight of 49 x 10(6), whereas the molecular weight of the I-like R factor R64drd11 was 76 x 10(6). The wild-type F factor, F1, had a molecular weight of 62 x 10(6). When conjugation experiments are performed by using donor strains carrying these derepressed F-like or I-like R factors, the transferred deoxyribonucleic acid can be isolated as a covalently closed circle from the recipient cells. This circular deoxyribonucleic acid was characterized by making use of the observation that the complementary strands of these R factors can be separated in a CsCl-poly (U, G) equilibrium gradient. The results of the strand-separation experiments show that only one of the complementary strands of the R factor is transferred from the donor to the recipient. With both the F-like and I-like R factors, this strand is the heavier strand in CsCl-poly (U, G). These results indicate that even though F-like and I-like R factors differ greatly in many properties (phage specificity, size, compatability, etc.), they are transferred by a similar mechanism.     

Affinity and sequence specificity of DNA binding and site selection for primer synthesis by Escherichia coli primase

Primase is an essential DNA replication enzyme in Escherichia coli and responsible for primer synthesis during lagging strand DNA replication. Although the interaction of primase with single-stranded DNA plays an important role in primer RNA and Okazaki fragment synthesis, the mechanism of DNA binding and site selection for primer synthesis remains unknown. We have analyzed the energetics of DNA binding and the mechanism of site selection for the initiation of primer RNA synthesis on the lagging strand of the replication fork. Quantitative analysis of DNA binding by primase was carried out using a number of oligonucleotide sequences: oligo(dT)(25) and a 30 bp oligonucleotide derived from bacteriophage G4 origin (G4ori-wt). Primase bound both sequences with moderate affinity (K(d) = 1.2-1.4 x 10(-)(7) M); however, binding was stronger for G4ori-wt. G4ori-wt contained a CTG trinucleotide, which is a preferred site for initiation of primer synthesis. Analysis of DNA binding isotherms derived from primase binding to the oligonucleotide sequences by fluorescence anisotropy indicated that primase bound to DNA as a dimer, and this finding was further substantiated by electrophoretic mobility shift assays (EMSAs) and UV cross-linking of the primase-DNA complex. Dissection of the energetics involved in the primase-DNA interaction revealed a higher affinity of primase for DNA sequences containing the CTG triplet. This sequence preference of primase may likely be responsible for the initiation of primer synthesis in the CTG triplet sites in the E. coli lagging strand as well as in the origin of replication of bacteriophage G4.