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.     

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.     

Protein transfer into the recipient cell during bacterial conjugation: studies with F and RP4

Transfer of donor cell proteins to the recipient bacterium was examined in F- and RP4-mediated conjugation. Transfer of a 120 kD polypeptide, identified as the larger product of the plasmid DNA primase gene, was readily detected during RP4-promoted conjugation. The protein was transmitted to the cytoplasm of the recipient, presumably complexed to the transferred ssDNA. F DNA was transferred without detectable association with any cytoplasmic tra protein or with the ssDNA-binding protein encoded by the plasmid. However, a 92 kD protein, possibly F TraD product, was transmitted to the membrane fraction of the recipient cell.     

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.     

DNA-independent transport of plasmid primase protein between bacteria by the I1 conjugation system

The ColIb-P9 (IncI1)-encoded conjugation system supports transfer of the plasmid T-strand plus hundreds of molecules of the Sog polypeptides determined by the plasmid primase gene. Here, we report that Sog primase is abundantly donated to the recipient cell from cells carrying a non-transferable ColIb plasmid deleted of the nic site essential for DNA export. Such DNA-independent secretion of Sog primase is typical of authentic conjugation, both in being blocked when the recipient cell specifies the entry exclusion function of ColIb and in requiring the thin I1 pilus encoded by the ColIb pil system under the mating conditions used. It is proposed that Sog polypeptides form a complex with the ColIb T-strand during conjugation and aid DNA transport through processive secretion of the proteins into the recipient cell. Functional and genetic relationships between the ColIb conjugation system and other type IV secretion pathways are discussed.     

Mechanisms of strand replacement synthesis for plasmid DNA transferred by conjugation

A single strand of plasmid DNA is transferred during conjugation. We examined the mechanism of complementary strand synthesis in recipient cells following conjugative mobilization of derivatives of the IncQ plasmid R1162. A system for electroporation of donor cells, followed by immediate mating, was used to eliminate plasmid-specific replicative functions. Under these conditions, Escherichia coli recipients provided a robust mechanism for initiation of complementary strand synthesis on transferred DNA. In contrast, plasmid functions were important for efficient strand replacement in recipient cells of Salmonella enterica serovar Typhimurium. The mobilizing vector for R1162 transfer, the IncP1 plasmid R751, encodes a DNA primase with low specificity for initiation. This protein increased the frequency of transfer of R751 into Salmonella, but despite its low specificity, it was inactive on the R1162 derivatives. The R751 primase was slightly inhibitory for the transfer of both R751 and R1162 into E. coli. The results show that there is a chromosomally encoded mechanism for complementary strand synthesis of incoming transferred DNA in E. coli, while plasmid-specific mechanisms for this synthesis are important in Salmonella.     

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.     

Transfer of tra proteins into the recipient cell during bacterial conjugation mediated by plasmid ColIb-P9.

Selective transfer of the two products of the ColIb primase gene, sog, from donor to recipient cell during conjugation was demonstrated by two independent methods. The transfer of these tra proteins was unidirectional and dependent on DNA transfer. The Sog polypeptides were localized to the cytoplasm of the donor cell, but they appeared to interact with other tra gene products located in the inner membrane. After cell mating, the transferred polypeptides were found to be in the cytoplasm of the recipient cell, and it is estimated that as many as 500 Sog polypeptides were transferred per round of conjugation. It is proposed that these proteins are transferred as a result of an interaction with the single-stranded DNA and that the transferred strand may be coated with Sog polypeptides.     

Analysis of the R16 plasmid primase gene

The cloned genetic determinant of R16 (IncB) plasmid primase encodes two polypeptides (apparent Mr 240,000 and 175,000), probably products of the same coding sequence of DNA, which are also detectable in extracts of cells carrying the parent plasmid. Deletion analysis and transposon mutagenesis indicate that only about 1.7 kilobase pairs (kb) of the cloned fragment, encoding a truncated polypeptide of 76,000 Da, is necessary for activity. The cloned genetic determinant of the R387 (IncK) plasmid primase, which encodes polypeptides of apparent Mr 270,000 and 200,000, appears to be very similar to the R16 gene except for an additional sequence of approximately 0.65 kb.     

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.     

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.     

鸡Ⅹ期胚盘细胞体外培养

为证实经遗传修饰的鸡X期胚盘细胞具有参与受体胚胎发育和形成嵌合体的能力 ,本研究将由鸡X期胚盘制成的细胞悬液与经脂质体包埋的抗鸡传染性支气管炎病毒基因重组质粒PGS1共孵育后 ,直接显微注入同期受体胚盘 (14 0枚 ) ;或对转染后供体细胞进行G418抗性筛选后显微注入同期受体鸡胚盘 (14 0枚 ) ;或将供体细胞体外培养 4 8h ,再与脂质体 PGS1复合物共孵育后显微注入同期受体鸡胚盘 (190枚 ) ,制备转基因嵌合体鸡 ,并应用PCR和RAPD方法 ,对鸡胚和雏鸡不同组织或血液中的DNA进行检测。结果表明 :直接注射组孵化率(5 7% )显著 (P <0 0 1)高于G418筛选处理组 (1 4 % )和培养 4 8h处理组 (2 1% ) ;G418筛选处理组不同胚龄鸡胚组织、器官中外源DNA的PCR检测阳性率均高于其它二个组。实验结果证明 ,体外培养 4 8h并经遗传修饰的胚盘细胞仍然具有形成嵌合体的能力 ,利用早期胚盘细胞途径制备转基因鸡是可行的。     

Conjugal Deoxyribonucleic Acid Replication by Escherichia coli K-12: Effect of Nalidixic Acid

During the conjugal transfer of the R64-11 plasmid at 42 C from donor cells thermosensitive for vegetative deoxyribonucleic acid (DNA) synthesis to recipient minicells, the plasmids are conjugally replicated in the donor cells. This conjugal replication is inhibited by nalidixic acid, and the degree of inhibition is comparable to the reduction in the amount of plasmid DNA transferred to the recipient minicells in the presence of the drug. In addition, the size of DNA transferred to the minicells and the fraction of conjugally replicated DNA in the donor cells that can be isolated as closed-circular plasmid DNA under alkaline conditions are both reduced by nalidixic acid. When the drug is added to a mating that is underway, the rate of conjugal replication is immediately reduced. This change is accompanied by a reduction in the amount of conjugally replicated DNA in the donor cells that can be isolated as closed-circular plasmid DNA. Furthermore, conjugally replicated plasmid DNA that is not associated with the donor cell membrane becomes membrane bound after the addition of nalidixic acid.     

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.     

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.     

Integration of plasmid DNA coding for beta-lactamase production in the Haemophilus influenzae chromosome.

Of beta-lactamase-producing strains of Haemophilus influenzae, 65% do not contain extrachromosomal plasmid DNA. These strains, however, conjugally transfer beta-lactamase production to a recipient strain from which a 30-megadalton plasmid can be isolated. Restriction enzyme analysis and Southern transfer of DNA from both donor and recipient strains revealed that chromosomal integration of plasmid sequences occurred in all donor strains examined.     

Mechanism of retrotransfer in conjugation: prior transfer of the conjugative plasmid is required.

Bacterial conjugation normally involves the unidirectional transfer of DNA from donor to recipient. Occasionally, conjugation results in the transfer of DNA from recipient to donor, a phenomenon known as retrotransfer. Two distinct models have been generally considered for the mechanism of retrotransfer. In the two-way conduction model, no transfer of the conjugative plasmid is required. The establishment of a single conjugation bridge between donor and recipient is sufficient for the transfer of DNA in both directions. In the one-way conduction model, transfer of the conjugative plasmid to the recipient is required to allow the synthesis of a new conjugation bridge for the transfer of DNA from recipient to donor. We have tested these models by the construction of a mutant of the self-transmissible, IncP plasmid RK2lac that allows the establishement of the conjugation bridge but is incapable of self-transfer. Four nucleotides of the nic region of the origin of transfer (oriT) were changed directly in the 67-kb plasmid RK2lac by a simple adaptation of the vector-mediated excision (VEX) strategy for precision mutagenesis of large plasmids (E. K.Ayres, V. J. Thomson, G. Merino, D. Balderes, and D. H. Figurski, J. Mol. Biol. 230:174-185, 1993). The resulting RK2lac oriT1 mutant plasmid mobilizes IncQ or IncP oriT+ plasmids efficiently but transfers itself at a frequency which is 10(4)-fold less than that of the wild type. Whereas the wild-type RK2lac oriT+ plasmid promotes the retrotransfer of an IncQ plasmid from Escherichia coli or Pseudomonas aeruginosa recipients, the RK2lac oriT1 mutant is severely defective in retrotransfer. Therefore, retrotransfer requires prior transfer of the conjugative plasmid to the recipient. The results prove that retrotransfer occurs by two sequential DNA transfer events.     

The requirements for conjugal DNA synthesis in the donor strain during flac transfer.

Although neither rifampicin nor spectinomycin had any effect on the frequency of Flac transfer by a sensitive donor, rifampicin but not spectinomycin prevented donor conjugal DNA synthesis as measured in matings between a dnaB donor and a tdk recipient. An untranslated RNA species is therefore probably required for this synthesis, although transfer took place even in its absence. Donor conjugal DNA synthesis was abolished in a dnaE donor, showing that DNA polymerase III is responsible for this process; again, plasmid DNA transfer was not affected.Flac mutants lacking the F pilus gave neither donor conjugal DNA synthesis nor plasmid DNA transfer, probably because they could not receive a “mating signal” to activate the transfer process. The products of traI and traM were also required both for donor conjugal DNA synthesis and for physical transfer of plasmid DNA, probably being involved in the conversion of covalently closed circular plasmid DNA into the open circular form that is the substrate for the independent although normally simultaneous synthesis and transfer steps. In contrast, donor conjugal DNA synthesis took place at a normal rate in both piliated traG and traN mutants, and at a reduced rate in traD mutants, although in no case was there physical transfer of plasmid DNA. These gene products are therefore required for DNA transfer to the recipient, and in addition, the absence of the traD product may hinder DNA synthesis.Based upon these results, a scheme for the processing of DNA during conjugation is presented.