The kil-kor regulon of broad-host-range plasmid RK2: nucleotide sequence, polypeptide product, and expression of regulatory gene korC.

Broad-host-range plasmid RK2 encodes several kil operons (kilA, kilB, kilC, kilE) whose expression is potentially lethal to Escherichia coli host cells. The kil operons and the RK2 replication initiator gene (trfA) are coregulated by various combinations of kor genes (korA, korB, korC, korE). This regulatory network is called the kil-kor regulon. Presented here are studies on the structure, product, and expression of korC. Genetic mapping revealed the precise location of korC in a region near transposon Tn1. We determined the nucleotide sequence of this region and identified the korC structural gene by analysis of korC mutants. Sequence analysis predicts the korC product to be a polypeptide of 85 amino acids with a molecular mass of 9,150 daltons. The KorC polypeptide was identified in vivo by expressing wild-type and mutant korC alleles from a bacteriophage T7 RNA polymerase-dependent promoter. The predicted structure of KorC polypeptide has a net positive charge and a helix-turn-helix region similar to those of known DNA-binding proteins. These properties are consistent with the repressorlike function of KorC protein, and we discuss the evidence that KorA and KorC proteins act as corepressors in the control of the kilC and kilE operons. Finally, we show that korC is expressed from the bla promoters within the upstream transposon Tn1, suggesting that insertion of Tn1 interrupted a plasmid operon that may have originally included korC and kilC.     

Replication control in promiscuous plasmid RK2: kil and kor functions affect expression of the essential replication gene trfA.

We previously reported that broad-host-range plasmid RK2 encodes multiple host-lethal kil determinants (kilA, kilB1, kilB2, and kilC) which are controlled by RK2-specified kor functions (korA, korB, and korC). Here we show that kil and kor determinants have significant effects on RK2 replication control. First, korA and korB inhibit the replication of certain RK2 derivatives, unless plasmid replication is made independent of the essential RK2 gene trfA. Second, kilB1 exerts a strong effect on this interaction. If the target plasmid is defective in kilB1, sensitivity to korA and korB is enhanced at least 100-fold. Thus, korA and korB act negatively on RK2 replication, whereas kilB1 acts in a positive manner to counteract this effect. A mutant RK2 derivative, resistant to korA and korB, was found to have fused a new promoter to trfA, indicating that the targets for korA and korB are at the 5' end of the trfA gene. We constructed a trfA-lacZ fusion and found that synthesis of beta-galactosidase is inhibited by korA and korB. Thus korA, korB, and kilB1 influence RK2 replication by regulating trfA expression. We conclude that the network of kil and kor determinants is part of a replication control system for RK2.     

Control of the kilA gene of the broad-host-range plasmid RK2: involvement of korA, korB, and a new gene, korE.

Broad-host-range plasmid RK2 encodes several different kil genes which are potentially lethal to an Escherichia coli host. The kil genes and the essential RK2 replication gene trfA are regulated by the products of kor genes. We have shown previously that kilA can be controlled by a constitutively expressed korA gene. In this study, we have found that the wild-type, autoregulated korA gene is insufficient for control of kilA cloned on high-copy-number plasmids. One of two other genes must also be present with korA. One gene is korB, originally discovered by its ability to control the determinants in the kilB region and later found to affect expression of both trfA and korA. The other is a new gene, korE, which has been cloned from the 2.2' to 4.1' region located between korC and kilA. Studies with a kilA-cat fusion suggest that korA, korB, and korE all participate in the control of kilA gene expression.     

The kilE locus of promiscuous IncP alpha plasmid RK2 is required for stable maintenance in Pseudomonas aeruginosa.

Eight coordinately regulated operons constitute the kor regulon of the IncP alpha plasmid RK2. Three operons specify functions required for replication initiation, conjugative transfer, and control of gene expression. The functions of the other operons, including those of the four coregulated operons that compose the kilA, kilC, and kilE loci, have not been determined. Here, we present the first evidence that a kil determinant is involved in IncP plasmid maintenance. Elevation of KorC levels specifically to reduce the expression of the KorC-regulated kilC and kilE operons severely affected the maintenance of both the IncP alpha plasmid RK2lac and the IncP beta plasmid R751 in Pseudomonas aeruginosa but had little effect on plasmid maintenance in Escherichia coli. Precise deletion of the two kilE operons from RK2lac was achieved with the VEX mutagenesis system for large genomes. The resulting plasmid showed significant loss of stability in P. aeruginosa only. The defect could be complemented by reintroduction of kilE at a different position on the plasmid. The instability of the RK2lac delta kilE mutant did not result from a reduction in average plasmid copy number, reduced expression of kilC, decreased conjugative transfer, or loss of the korE regulator. We found that both the par and kilE loci are required for full stability of RK2lac in P. aeruginosa and that the par and kilE functions act independently. These results demonstrate a critical role for the kilE locus in the stable inheritance of RK2 in P. aeruginosa.     

The kilA operon of promiscuous plasmid RK2: the use of a transducing phage (λpklaA-1) to determine the effects of the lethal klaA gene on Escherichia coli cells

The kil-kor regulon of promiscuous plasmid RK2 includes the replication initiator gene trfA and several potentially host-lethal kil loci (kilA, kilB, kilC, kilE), whose functions may be involved in plasmid maintenance or broad host range. The kilA locus consists of a single operon of three genes (klaA, klaB, klaC), each of which is lethal when expressed from the klaA promoter in the absence of repressors encoded by korA and korB. In this study, we examined the effects of the unregulated klaA gene on the host cell. Bacteriophage lambda was used to construct a transducing phage (lambda pklaA-1) that allows efficient introduction of the klaA gene into Escherichia coli. Cells lacking korA and korB (to allow uncontrolled expression of klaA) and expressing lambda repressor (to prevent phage lytic growth) are killed by lambda pklaA-1. Cell death is dependent on the klaA structural gene, independent of the SOS system of the host, and is prevented by the presence of korA and korB. lambda pklaA-1 was used to synchronously infect cells lacking korA and korB to determine the effects of klaA on the cells over time. The earliest effects, visible at two hours post-infection, are inhibition of growth of the culture, formation of elongated cells, and striking changes in the appearance of the outer membrane. After four to five hours, the viability of the culture declined sharply and macromolecular synthesis ceased. The distinct class of early events is consistent with the hypothesis that the KlaA polypeptide interacts with a specific target in the host cell.     

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.