Cloning of a plasmid region specifying the N transfer system of bacterial conjugation in Escherichia coli

HindIII restriction sites were created artificially by the insertion of the transposon Tn.5 into the IncN plasmid pCU1 near a presumptive end of its conjugal transfer region (tra). This allowed cloning of an entire and continuous 19.4-kb region of this plasmid that specifies the N transfer system. The cloning vector was the nonconjugative plasmid pACYC184. The recombinant plasmid was as efficient in transfer as the parental N plasmid. Other clones and deletions extending into the tra region allowed localization of a 11.2-kb segment of this region that determines sensitivity to the N-specific bacteriophages IKe and PRD1. It could also be concluded that the ability of pCU1 to promote the killing of Klebsiella pneumoniae requires a 2-kb region that is not part of, but adjacent to the tra region.     

Isolation and characterization of kikA, a region on IncN group plasmids that determines killing of Klebsiella oxytoca.

Transfer of the IncN group plasmid pCU1 from Escherichia coli to Klebsiella oxytoca by conjugation kills a large proportion (90 to 95%) of the recipients of plasmid DNA, whereas transfer to E. coli or even to the closely related Enterobacter aerogenes does not. Two regions, kikA and kikB, have been identified on pCU1 that contribute to the Kik (killing in klebsiellas) phenotype. We have localized the kikA region to 500 bp by deletion analysis and show by DNA-DNA hybridization that kikA is highly conserved among the plasmids of incompatibility group N. The expression in K. oxytoca of kikA under the control of the strong inducible E. coli tac promoter results in loss of cell viability. The nucleotide sequence showed two overlapping open reading frames (ORFs) within the kikA region. The first ORF codes for a putative polypeptide of 104 amino acids (ORF104). The second ORF codes for a 70-amino-acid polypeptide (ORF70). The properties of the putative protein encoded by ORF104 and gene fusions of kikA to alkaline phosphatase by using TnphoA suggest that killing may involve an association with the bacterial membrane; however, we could not rule out the possibility that ORF70 plays a role in the Kik phenotype.     

Regions on plasmid pCU1 required for the killing of Klebsiella pneumoniae.

Plasmid pCU1 was Kik+ (promotes killing of Klebsiella pneumoniae). All Tn5 insertions within the tra region of pCU1 were Kik-. Two other regions, kikA and kikB, were needed. They may be separated on different plasmids, but both must be mobilized into Klebsiella pneumoniae. Establishment of one kik region in K. pneumoniae followed by receipt of the second did not lead to killing. Kik was therefore intracellular and required concerted and transient action of both regions.     

Conditionally lethal genes in the N pilus region of plasmid pCU1.

Plasmid genes or regions that are conditionally lethal to Escherichia coli have been called kil and those lethal to Klebsiella but not to E. coli have been called kik. Both classes of genes are found in or close to the N pilus region of the plasmid pCU1 and the closely related plasmid pKM101. Here we describe two new and overlapping lethal genes that are located between kikA and traA of the plasmid pCU1 and display host specificity. KilC is lethal in E. coli and Klebsiella while kikC is lethal only in Klebsiella. The previously identified korA gene is sufficient to override the lethality of kilC in trans or in cis but is insufficient to override kikC. kilC expression in E. coli leads to cell death accompanied by an increase in average cell length without affecting septum formation.     

Inverted repeats in the DNA of plasmid pCU1

Renaturable regions in the DNA strands of the N group plasmid pCU1 have been visualized as stem-loop structures by electron microscopy. Four such distinct structures are described, the smallest of which is within the loop of a larger one. The region of pCU1 in which these structures occur has several restriction sites. This and the availability of plasmid deletions and recombinants has permitted the mapping of these structures relative to one another and to the restriction and functional map of the plasmid. The replication and maintenance region of the plasmid is located within one of these stem-loop structures.     

The oriT region of the conjugative transfer system of plasmid pCU1 and specificity between it and the mob region of other N tra plasmids.

The oriT region of the conjugative IncN plasmid pCU1 has been localized to a 669-bp sequence extending from pCU1 coordinates 8.48 to 9.15 kb. The nucleotide sequence of this region was determined. The region is AT-rich (69% AT residues), with one 19-bp and one 81-bp sequence containing 79% or more AT residues. Prominent sequence features include one set of thirteen 11-bp direct repeats, a second set of two 14-bp direct repeats, six different inverted repeat sequences ranging from 6 to 10 bp in size, and two sequences showing 12 of 13 nucleotides identical to the consensus integration host factor binding sequence. Specificity between this oriT and mobilization (mob) functions encoded by the N tra system was demonstrated. This specificity is encoded by the region lying clockwise of the BglII site at coordinate 3.3 on the pCU1 map. Two N tra plasmids isolated in the preantibiotic era were unable to mobilize recombinant plasmids carrying the oriT region of pCU1 or to complement transposon Tn5 mutations in the mob region of the closely related plasmid pKM101.     

Localization of the nic site of IncN conjugative plasmid pCU1 through formation of a hybrid oriT.

The N-type oriT of plasmid pMUR274 was cloned on a 474-bp RsaI-SspI fragment, and the nucleotide sequence was determined. A comparison of the pMUR274 oriT sequence and the sequence of the oriTs of IncN plasmid pCU1 and IncW plasmid R388 demonstrated 57 and 28% identity, respectively. Intramolecular, site-specific recombination between the pCU1 oriT and the oriT of pMUR274 resulted in the formation of a hybrid oriT containing one half of each parental sequence. The junction point of the hybrid occurred within a 10-bp sequence, GCTATACACC, present in both parental sequences and represents the nic site of each oriT. Mutation of the first A or second T residue within the 10-bp junction sequence reduced transfer less than 20-fold, while mutation of either the second or third A residue reduced transfer over 1,000-fold. Site-specific recombination between a wild-type pCU1 oriT and these four mutant pCU1 oriTs demonstrated that nic lies between the second T and second A residues of the 10-bp junction sequence. Site-specific recombination between wild-type and mutant pCU1 oriTs also demonstrated that point mutations to the right of nic reduced both initiation and termination of transfer while point mutations to the left of nic reduced termination but had little or no effect on initiation. A 28-bp deletion within the AT-rich region 39 bases to the right of nic reduced both initiation and termination, while deletion of a 6-bp inverted repeat sequence at the right-most boundary of the minimal oriT region reduced initiation but not termination.     

Analysis of pCU1 replication origins: dependence of oriS on the plasmid-encoded replication initiation protein RepA

The broad-host-range replicon of the plasmid pCU1 has three origins of vegetative replication called oriB, oriS, and oriV. In the multi-origin replicon, individual origins can distinguish among replication factors provided by the host. It has been found that during replication in Escherichia coli polA(-) host, oriS was the only active origin of a mutant pCU1 derivative bearing a mutation in the gene encoding replication initiation protein RepA. To further investigate the capacity of oriS to function in an E. coli polA(-) host we constructed a number of clones of the basic replicon of pCU1 containing oriS as the only replication origin. An oriS construct created with pUC18 could transform the polA(-) strain when RepA was supplied in trans. When the oriS region (between nucleotides 290 and 832) was ligated to an antibiotic resistance Omega fragment, the construct could be recovered as a plasmid from polA(+) strain if functional RepA was provided in trans. Our results therefore indicate that the basic replicon of pCU1, containing oriS as the sole origin, does require RepA to initiate plasmid replication in E. coli     

Tyrosine partners coordinate DNA nicking by the Salmonella typhimurium plasmid pCU1 relaxase enzyme

Conjugative plasmid transfer results in the spread of antibiotic resistance genes and virulence factors between bacterial cells. Plasmid transfer is dependent upon the DNA nicking activity of a plasmid-encoded relaxase enzyme. Tyrosine residues within the relaxase cleave the DNA plasmid nic site in a highly sequence-specific manner. The conjugative resistance plasmid pCU1 encodes a relaxase with four tyrosine residues surrounding its active site (Y18,19,26,27). We use activity assays to demonstrate that the pCU1 relaxase preferentially uses Y26 or a combination of Y18 + 19 to nick DNA at wild type levels, and that an adjacent aspartic acid deprotonates these tyrosines to activate them for attack. Our findings illustrate the unique modifications that the pCU1 relaxase has introduced into the traditional relaxase-mediated DNA nicking mechanism.     

The mechanism and control of DNA transfer by the conjugative relaxase of resistance plasmid pCU1

Bacteria expand their genetic diversity, spread antibiotic resistance genes, and obtain virulence factors through the highly coordinated process of conjugative plasmid transfer (CPT). A plasmid-encoded relaxase enzyme initiates and terminates CPT by nicking and religating the transferred plasmid in a sequence-specific manner. We solved the 2.3 Å crystal structure of the relaxase responsible for the spread of the resistance plasmid pCU1 and determined its DNA binding and nicking capabilities. The overall fold of the pCU1 relaxase is similar to that of the F plasmid and plasmid R388 relaxases. However, in the pCU1 structure, the conserved tyrosine residues (Y18,19,26,27) that are required for DNA nicking and religation were displaced up to 14 Å out of the relaxase active site, revealing a high degree of mobility in this region of the enzyme. In spite of this flexibility, the tyrosines still cleaved the nic site of the plasmid’s origin of transfer, and did so in a sequence-specific, metal-dependent manner. Unexpectedly, the pCU1 relaxase lacked the sequence-specific DNA binding previously reported for the homologous F and R388 relaxase enzymes, despite its high sequence and structural similarity with both proteins. In summary, our work outlines novel structural and functional aspects of the relaxase-mediated conjugative transfer of plasmid pCU1.     

Plasmid conferring increased sensitivity to mercuric chloride and cobalt chloride found in some laboratory strains of Escherichia coli K-12.

Some lines of the widely used strain CR34 of Escherichia coli K-12 carry a plasmid. The plasmid has a mass of 12 +/- 2 X 10(6) megadaltons and is maintained at a low copy number per cell (1 to 2), and this number is not amplified by growth of cells in the presence of chloramphenicol. The plasmid is designated as pCU3. The presence of pCU3 confers on the strain increased sensitivity to mercuric chloride and cobalt chloride. The plasmid has also been observed to fuse or recombine with the plasmid R64-11.     

Host Ranges of the IncN Group Plasmid pCU1 and Its Minireplicon in Gram-Negative Purple Bacteria

The bacterial host ranges of the conjugatively self-transmissible IncN group plasmid pCU1 and its mobilizable miniderivative, pCU785, were examined. Species of the gram-negative purple bacteria were chosen for this study. Conjugative mobilization of pCU785 into a wide variety of bacteria was facilitated by the presence of oriT of the broad-host-range plasmid RK2 in pCU785. Although the host range of the IncN tra system of pCU1 is broad, the host range of its replicon is limited. However, the pCU1 replicon can be maintained in Agrobacterium, Bradyrhizobium, and Rhizobium species under conditions that select for plasmid maintenance. It is lost efficiently from these populations on release of selection.     

Physical and genetic organization of the IncN-group plasmid pCU1

A restriction endonuclease-cleavage map of the IncN group plasmid pCU1 was constructed. Deletion mutants of the plasmid were obtained by in vivo or in vitro methods. Comparison of the restriction maps of these mutants to that of pCU1 enables one to assign the known functions of the plasmid to particular regions on the plasmid DNA. For different enzymes, the number and distribution of restriction sites on pCU1 is compared to that of other IncN and related plasmids.     

A mutant killer plasmid whose replication depends on a chromosomal "superkiller" mutation

Yeast strains carrying a 1.5 x 10(6) molecular weight linear double-stranded RNA in virus-like particles (M dsRNA, the killer plasmid or virus) secrete a toxin that is lethal to strains not carrying this plasmid. Recessive mutations in any of four chromosomal genes (called ski1-ski4) result in increased production of toxin activity. We report here a mutation of the killer plasmid (called [KIL-sd] for ski-dependent) that makes the killer plasmid dependent for its replication on the presence of a chromosomal mutation in any ski gene. Thus, the [KIL-sd] plasmid is lost from SKI(+) strains. When the wild-type killer plasmid, [KIL-k], is introduced into a ski2-2 [KIL-o] strain, the killer plasmid changes to a [KIL-sd] plasmid. This may represent a specific form of mutagenesis or selective replication in the ski2-2 strain of [KIL-sd] variants (mutants) in the normal [KIL-k] population. The ski2-1 and ski2-3 mutations do not convert [KIL-k] to [KIL-sd], but ski2-3 does allow maintenance of the [KIL-sd] plasmid. The [KIL-sd] plasmid thus lacks a plasmid site or product needed for replication in wild-type cells.     

Physical structure and genetic expression of the sulfonamide-resistance plasmid pLS80 and its derivatives in Streptococcus pneumoniae and Bacillus subtilis

The 10-kb chromosomal fragment of Streptococcus pneumoniae cloned in pLS80 contains the sul-d allele of the pneumococcal gene for dihydropteroate synthase. As a single copy in the chromosome this allele confers resistance to sulfanilamide at 0.2 mg/ml; in the multicopy plasmid it confers resistance to 2.0 mg/ml. The sul-d mutation was mapped by restriction analysis to a 0.4-kb region. By the mechanism of chromosomal facilitation, in which the chromosome restores information to an entering plasmid fragment, a BamHI fragment missing the sul-d region of pLS80 established the full-sized plasmid, but with the sul-s allele of the recipient chromosome. A spontaneous deletion beginning approximately 1.5 kb to the right of the sul-d mutation prevented gene function, possibly by removing a promoter. This region could be restored by chromosomal facilitation and be demonstrated in the plasmid by selection for sulfonamide resistance. Under selection for a vector marker, tetracycline resistance, only the deleted plasmid was detectable, apparently as a result of plasmid segregation and the advantageous growth rates of cells with smaller plasmids. When such cells were selected for sulfonamide resistance, the deleted region returned to the plasmid, presumably by equilibration between the chromosome and the plasmid pool, to give a low frequency (approximately 10(-3) of cells resistant to sulfanilamide at 2.0 mg/ml. Models for the mechanisms of chromosomal facilitation and equilibration are proposed. Several derivatives of pLS80 could be transferred to Bacillus subtilis, where they conferred resistance to sulfanilamide at 2 mg/ml, thereby demonstrating cross-species expression of the pneumococcal gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cloning and characterization of the yeast methionyl-tRNA synthetase mutation mes1

The chromosomal mes 1 mutation appears to elevate the Km of methionine for yeast methionyl-tRNA synthetase. The mutation was cloned on a multicopy plasmid by gap repair of a plasmid bearing the wild type MES1 gene for a fragment corresponding to the mes 1 mutation. DNA sequencing established that the mutation consists of a single conversion of guanine into adenine which results in the replacement of a glycine by an aspartic acid at position 502. This causes the enzyme to be labile and inactive in vitro and to show a requirement for high concentrations of methionine in vivo. The mutation is in the COOH-terminal domain of the mononucleotide binding fold of the yeast enzyme and suggests participation of this region in the binding of the amino acid residue.     

Exploitation of gene(s) involved in 2,4-diacetylphloroglucinol biosynthesis to confer a new biocontrol capability to a Pseudomonas strain.

Tn5 mutagenesis and complementation analysis were used to clone a 6-kb genomic fragment required for biosynthesis of 2,4-diacetylphloroglucinol (Phl) from fluorescent Pseudomonas sp. strain F113. A recombinant plasmid, pCU203, containing this region partially complemented a Phl production-negative mutant (F113G22) derived from strain F113. When sugar beet seeds were sown into an unsterilized soil, in which sugar beet was subject to damping-off by Pythium ultimum, the emergence of sugar beet seeds inoculated with strain F113 was significantly greater than that of seeds inoculated with F113G22. Transfer of pCU203 into eight other Pseudomonas strains conferred the ability to synthesize Phl in only one of these strains, Pseudomonas sp. strain M114. Strain M114(pCU203) showed enhanced antagonism towards P. ultimum in vitro and significantly increased the emergence of sugar beet seeds in the same soil compared with emergence induced by the parent strain M114.     

Exploitation of gene(s) involved in 2,4-diacetylphloroglucinol biosynthesis to confer a new biocontrol capability to a Pseudomonas strain.

Tn5 mutagenesis and complementation analysis were used to clone a 6-kb genomic fragment required for biosynthesis of 2,4-diacetylphloroglucinol (Phl) from fluorescent Pseudomonas sp. strain F113. A recombinant plasmid, pCU203, containing this region partially complemented a Phl production-negative mutant (F113G22) derived from strain F113. When sugar beet seeds were sown into an unsterilized soil, in which sugar beet was subject to damping-off by Pythium ultimum, the emergence of sugar beet seeds inoculated with strain F113 was significantly greater than that of seeds inoculated with F113G22. Transfer of pCU203 into eight other Pseudomonas strains conferred the ability to synthesize Phl in only one of these strains, Pseudomonas sp. strain M114. Strain M114(pCU203) showed enhanced antagonism towards P. ultimum in vitro and significantly increased the emergence of sugar beet seeds in the same soil compared with emergence induced by the parent strain M114.