Fertility inhibition of RP1 by IncN plasmid pKM101.

IncN plasmids, including pKM101, strongly inhibit the conjugal transfer of cohabiting IncP plasmids. We localized the pKM101 DNA sufficient for this phenomenon to a 1.1-kilobase region (denoted fip). Two fip-deficient Tn5 insertion derivatives of pKM101 were isolated; neither affected other pKM101-mediated functions. fip did not inhibit either the synthesis of the IncP plasmid's sex pilus or its ability to mediate entry exclusion against other IncP plasmids.     

Conjugal transfer system of the IncN plasmid pKM101.

The conjugal transfer system of the broad-host range IncN plasmid pKM101 was analyzed genetically. Its organization differed significantly from that of the F plasmid. The tra genes are located in three regions, each between 3 and 4 kilobases in length. All of the genes in the first two regions are required for sensitivity to "donor-specific" phage which bind to the plasmid-mediated sex pilus, and these genes therefore are involved in the synthesis, and possibly retraction, of the sex pilus. The plasmid's origin of transfer was localized to a 1.2-kilobase region at an extreme end of the transfer region. Using two different methods, we have identified 11 complementation groups required for transfer. One of these, traC, is of special interest in that mutations at this locus can be partially suppressed if, prior to mating, cells carrying a traC mutant plasmid are incubated with cells which elaborate sex pili but are unable to transfer their plasmids. One possible explanation for this is that pilus-elaborating cells can donate traC gene product to a traC mutant in a form that can be reused.     

Direction of conjugative transfer of IncI1 plasmid ColIb-P9.

The origin-of-transfer region of ColIb-P9 was inserted into a lambda prophage to give a bacterial chromosome mobilizable by the parental conjugative plasmid. The polarity of mobilization of chromosomal genes indicated that ColIb-P9 transfer is unidirectional, such that the transfer genes adjacent to oriT enter the recipient cell last.     

Genetic analysis of the mobilization and leading regions of the IncN plasmids pKM101 and pCU1

The conjugative IncN plasmids pKM101 and pCU1 have previously been shown to contain identical oriT sequences as well as conserved restriction endonuclease cleavage patterns within their tra regions. Complementation analysis and sequence data presented here indicate that these two plasmids encode essentially identical conjugal DNA-processing proteins. This region contains three genes, traI, traJ, and traK, transcribed in the same orientation from a promoter that probably lies within or near the conjugal transfer origin (oriT). Three corresponding proteins were visualized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and complementation analysis confirmed that this region contains three tra complementation groups. All three proteins resemble proteins of the IncW plasmid R388 and other plasmids thought to have roles in processing of plasmid DNA during conjugation. The hydropathy profile of TraJ suggests a transmembrane topology similar to that of several homologous proteins. Both traK and traI were required for efficient interplasmid site-specific recombination at oriT, while traJ was not required. The leading region of pKM101 contains three genes (stbA, stbB, and stbC), null mutations in which cause elevated levels of plasmid instability. Plasmid instability was observed only in hosts that are proficient in interplasmid recombination, suggesting that this recombination can potentially lead to plasmid loss and that Stb proteins somehow overcome this, possibly via site-specific multimer resolution.     

Entry exclusion determinant(s) of IncN plasmid pKM101.

pKM101 renders its host a poor recipient in conjugal matings with genetically distinguishable derivatives of itself. The gene(s) primarily responsible for this, denoted eex, is located in between genes required for both conjugal transfer and sensitivity to donor-specific bacteriophage, although it itself is not necessary for transfer. A gene linked to, or coincident with, the region needed for vegetative plasmid replication also inhibited establishment of related plasmids under certain conditions. Construction of an operon fusion between eex and the Escherichia coli lac promoter has shown that this gene is transcribed in a clockwise fashion on the circular map of pKM101. To date, we have not been able to visualize a protein product(s) of the eex gene(s).     

Genetic and biochemical analysis of an endonuclease encoded by the IncN plasmid pKM101.

The IncN plasmid pKM101 nuc gene encodes a periplasmically localized endonuclease. DNA sequence analysis indicates that this gene encodes a hydrophilic protein of about 19.5 kDa containing a hydrophobic signal sequence. nuc is homologous to a partially sequenced open reading frame adjacent to the sog gene of the plasmid CollB-P9, a plasmid known to encode an endonuclease similar to that of pKM101. A partially sequenced tra gene directly upstream of nuc is homologous to the virB11 gene of Agrobacterium tumefaciens. We have partially purified the pKM101 nuclease by osmotic shock and cation exchange chromatography, and used this enzyme preparation to sequence the protein's amino terminus. The first 13 amino acids of the mature protein match amino acids 23 to 35 of the predicted sequence, indicating that the protein is proteolytically processed to a molecular mass of approximately 17 kDa, probably during export to the periplasmic space. The enzyme was able to attack many sites along an end labelled duplex DNA substrate, but showed clearly preferred cleavage sites, and may cleave preferentially at purine-rich regions.     

The pilL and pilN genes of IncI1 plasmids R64 and ColIb-P9 encode outer membrane lipoproteins responsible for thin pilus biogenesis

The predicted amino acid sequences of the pilL and pilN genes, required for the thin pilus formation of IncI1 plasmids R64 and ColIb-P9, contain N-terminal lipoprotein signal peptide motifs. The pilL and pilN products were labeled with [(3)H]palmitic acid as 38- and 57-kDa proteins, respectively, indicating that they are lipoproteins. Both PilL and PilN were localized to the outer membrane.     

Comparative analysis of antirestriction activity of the ArdA and ArdB proteins encoded by genes of the R64 transmissible plasmid (IncI1)

Antirestriction proteins ArdA and ArdB are specific inhibitors of type I restriction-modification enzymes. The ardA and yfeB (ardB) genes were cloned from the transmissible plasmid R64 in the pUC18 and pZE21 vectors. The R64 ArdA and ArdB proteins were shown to inhibit only restriction activity of the type I restriction-modification enzyme (EcoKI) in Escherichia coli K12 cells. In contrast to ArdA, ArdB inhibited EcoKI restriction activity only at a high intracellular concentration. Antirestriction activity of ArdB did not depend on the ClpXP protease. The yfeB (ardB) gene of the R64 plasmid is transcribed from a weak promoter located upstream of yfeA.     

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.     

TraC of IncN Plasmid pKM101 Associates with Membranes and Extracellular High-Molecular-Weight Structures in Escherichia coli

Conjugative transfer of IncN plasmid pKM101 is mediated by the TraI-TraII region-encoded transfer machinery components. Similar to the case for the related Agrobacterium tumefaciens T-complex transfer apparatus, this machinery is needed for assembly of pili to initiate cell-to-cell contact preceding DNA transfer. Biochemical and cell biological experiments presented here show extracellular localization of TraC, as suggested by extracellular complementation of TraC-deficient bacteria by helper cells expressing a functional plasmid transfer machinery (S. C. Winans, and G. C. Walker, J. Bacteriol. 161:402-410, 1985). Overexpression of TraC and its export in large amounts into the periplasm of Escherichia coli allowed purification by periplasmic extraction, ammonium sulfate precipitation, and column chromatography. Whereas TraC was soluble in overexpressing strains, it partly associated with the membranes in pKM101-carrying cells, possibly due to protein-protein interactions with other components of the TraI-TraII region-encoded transfer machinery. Membrane association of TraC was reduced in strains carrying pKM101 derivatives with transposon insertions in genes coding for other essential components of the transfer machinery, traM, traB, traD, and traE but not eex, coding for an entry exclusion protein not required for DNA transfer. Cross-linking identified protein-protein interactions of TraC in E. coli carrying pKM101 but not derivatives with transposon insertions in essential tra genes. Interactions with membrane-bound Tra proteins may incorporate TraC into a surface structure, suggested by its removal from the cell by shearing as part of a high-molecular-weight complex. Heterologous expression of TraC in A. tumefaciens partly compensated for the pilus assembly defect in strains deficient for its homolog VirB5, which further supported its role in assembly of conjugative pili. In addition to its association with high-molecular-weight structures, TraC was secreted into the extracellular milieu. Conjugation experiments showed that secreted TraC does not compensate transfer deficiency of TraC-deficient cells, suggesting that extracellular complementation may rely on cell-to-cell transfer of TraC only as part of a bona fide transfer apparatus.     

Spontaneous mutational specificity of drug resistance plasmid pKM101 in Escherichia coli.

Plasmid pKM101 enhances the frequency of spontaneous and ultraviolet light-induced mutations in Escherichia coli and protects the cells against the lethal effects of ultraviolet irradiation. By analyzing reversion patterns of defined trpA alleles, we showed that pKM101 caused all types of spontaneous base-pair substitution mutations with the possible exception of guanine . cytosine leads to adenine. thymine transitions. Neither insertion nor deletion frameshift mutations were enhanced. Transversions were more strongly enhanced than transitions, and adenine . thymine base pairs appeared more susceptible to pKM101 mutator activity than guanine . cytosine base pairs. In addition, there were effects from neighboring base pairs and genetic background that influenced the mutator activity of pKM101.     

Isolation and characterization of mutants of the plasmid pKM101 deficient in their ability to enhance mutagenesis and repair.

A screening procedure was developed for identifying mutants of the plasmid pKM101 no longer capable of enhancing mutagenesis. The test was based on the large pKM101-mediated increase in the number of Gal+ papillae observed on colonies of Salmonella typhimurium gal mutants plated on tetrazolium-galactose plates in the presence of a mutagen. The pKM101 mutant plasmids transferred normally, were stably maintained in cells, caused normal levels of ampicillin resistance, and still imparted sensitivity to phage Ike to their hosts. However, the pKM101 mutants had lost the ability to (i) enhance the reversion of both point and frameshift mutations, (ii) protect the cells against killing by UV irradiation, (iii) increase the spontaneous reversion rates of point mutations, (iv) enhance plasmid-mediated reactivation of UV-irradiated phage P22, (v) enhance Weigle reactivation. One pKM101 mutant with different properties from the others was identified by its increased spontaneous mutator effect. It is suggested that pKM101 amplifies the activity of the inducible error-prone repair systems in bacteria and that this is the function of pKM101 in the Ames Salmonella tester strains used for detection of carcinogens as mutagens.     

Effect of plasmid pKM101 in ultraviolet irradiated uvr+ and uvr- Escherichia coli.

The effect of plasmid pKM101 on UV irradiated excision proficient and excision deficient cells was investigated. The plasmid increased the survival of excision proficient cells while partially inhibiting thymine dimer excision. The frequency of mutations was almost unchanged. In excision deficient cells the effect of the plasmid on survival was less pronounced while cell mutability was increased. Our data indicate that the mucAB genes (carried by the plasmid) influence the two types of cells in a different way.     

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.     

Effect of pKM101 plasmid on lethal and mutagenic damage in UV-irradiated E. coli strains

Introduction of the R-factor plasmid pKM101 increased resistance to UV-killing in uvr lexA(Ind-) recA+ strains of E. coli K12 as well as B, while their UV mutability was not affected. Similar effects were also observed in those strains when the 18-B plasmid (a pBR322 derivative carrying the region (about 5 kb) of the 35.4 kb pKM101 plasmid) was introduced. The muc genes which are considered to be involved in error-prone repair are contained in 18-B. These results suggest the possibility that the pKM101 effect requires the host recA gene and a common genetic region, including the muc genes, in both plasmids and is associated with some unmutable repair systems.     

Antirestriction and antimodification activities of the ArdA protein encoded by the IncI1 transmissive plasmids R-64 and ColIb-P9

Proteins of the Ard family are specific inhibitors of type I restriction-modification enzymes. The ArdA of R64 is highly homologous to ColIb-P9 ArdA, differing only by four amino acid residues of the overall 166. However, unlike ColIb-P9 ArdA, which inhibits both the endonuclease and the methylase activities of EcoKI, the R64 ArdA protein inhibits only the endonuclease activity of this enzyme. The mutant forms of R64 ArdA--A29T, S43A, and Y75W, capable of partially reversing the protein to ColIb-P9 ArdA form--were produced by directed mutagenesis. It was demonstrated that only Y75W mutation of these three variants essentially influenced the functional activity of ArdA: the antimodification activity was restored to approximately 90-99%. It is assumed that R64 ArdA inhibits formation of the complex between unmodified DNA and the R subunit of the type I restriction-modification enzyme EcoKI (R2M2S), which translocates and cleaves DNA. ColIb-P9 ArdA protein is capable of forming the DNA complex not only with the R subunit, but also with the S subunit, which contacts sK site (containing modified adenine residues) in DNA. ArdA bound to the specific sK site inhibits concurrently the endonuclease and methylase activities of EcoKI (R2M2S), while ArdA bound to the nonspecific site in the R subunit blocks only its endonuclease activity.     

Antirestriction and antimodification activities of the ArdA protein encoded by the IncI1 transmissive plasmids R-64 and ColIb-P9

Proteins of the Ard family are specific inhibitors of type I restriction-modification enzymes. The ArdA of R64 is highly homologous to ColIb-P9 ArdA, differing only by four amino acid residues of the overall 166. However, unlike ColIb-P9 ArdA, which inhibits both the endonuclease and the methylase activities of EcoKI, the R64 ArdA protein inhibits only the endonuclease activity of this enzyme. The mutant forms of R64 ArdA—A29T, S43A, and Y75W, capable of partially reversing the protein to ColIb-P9 ArdA form—were produced by directed mutagenesis. It was demonstrated that only Y75W mutation of these three variants essentially influenced the functional activity of ArdA: the antimodification activity was restored to approximately 90%. It is assumed that R64 ArdA inhibits formation of the complex between unmodified DNA and the R subunit of the type I restriction-modification enzyme EcoKI (R₂M₂S), which translocates and cleaves DNA. ColIb-P9 ArdA protein is capable of forming the DNA complex not only with the R subunit, but also with the S subunit, which contacts sK site (containing modified adenine residues) in DNA. ArdA bound to the specific sK site inhibits concurrently the endonuclease and methylase activities of EcoKI (R₂M₂S), while ArdA bound to the nonspecific site in the R subunit blocks only its endonuclease activity.     

A plasmid carrying mucA and mucB genes from pKM101 in Haemophilus influenzae and Escherichia coli.

The plasmid pMucAMucB, constructed from the Haemophilus influenzae vector pDM2, and a similar plasmid, constructed from pBR322, increased the survival after UV irradiation of Escherichia coli AB1157 with the umu-36 mutation and also caused UV-induced mutation in the E. coli strain. In H. influenzae, pMucAMucB caused a small but reproducible increase in survival after UV irradiation in wild-type cells and in a rec-1 mutant, but there was no increase in spontaneous mutation in the wild type or in the rec-1 mutant and no UV-induced mutation.