Genes for tight adherence of Actinobacillus actinomycetemcomitans: from plaque to plague to pond scum.

The Gram-negative periodontal pathogen Actinobacillus actinomycetemcomitans forms an extremely tenacious biofilm on solid surfaces such as glass, plastic and hydroxyapatite. This characteristic is likely to be important for colonization of the oral cavity and initiation of a potentially devastating form of periodontal disease. Genetic analysis has revealed a cluster of tad genes responsible for tight adherence to surfaces. Evidence indicates that the tad genes are part of a locus encoding a novel secretion system for the assembly and release of long, bundled Flp pili. Remarkably similar tad loci appear in the genomes of a wide variety of Gram-negative and Gram-positive bacteria, including many significant pathogens, and in Archaea. We propose that the tad loci are important for microbial colonization in a variety of environmental niches.

A small protein-protein interaction domain common to KlcB and global regulators KorA and TrbA of promiscuous IncP plasmids.

The kor regulon of broad host-range, incompatibility group P (IncP) plasmids uses the KorA, KorB, and KorC repressors to regulate expression of genes for replication, conjugation, segregation, and host range. One operon, kilC, encodes the KorC repressor and two genes of unknown function (klcA and klcB). The predicted sequences of the 51.1 kDa KlcB protein, the 11.3 kDa KorA repressor, and another small (13.5 kDa) regulatory protein, TrbA, show a highly related 35 amino acid residue segment (V-L-P domain). We found that induction of the klcB gene is toxic to Escherichia coli host cells harboring an IncP plasmid. We confirmed a model in which the V-L-P domain of KlcB interacts directly with the V-L-P domain of KorA to derepress KorA-regulated operons, thereby allowing expression of toxic genes. First, a lacZ reporter fused to the kleA promoter, which is regulated by KorA and KorC, revealed that klcB induction specifically releases KorA-repression but has no effect on KorC repression. Second, induced expression of the V-L-P domains from KorA or KlcB is sufficient to release KorA-repression at the kleA promoter. Third, purified GST-KlcB fusion protein interacts specifically with His-tagged KorA. Fourth, fusion of the V-L-P domains of KorA and TrbA and full-length KlcB polypeptide to the DNA-binding domain of bacteriophage lambda repressor leads to the formation of functional, dimeric repressors, and mutations that alter conserved residues of the V-L-P domain adversely affect dimerization. Fifth, crosslinking experiments demonstrated that the V-L-P domain of KorA is able to dimerize in solution and form heterodimers in mixtures with full-length KorA polypeptide. These findings show that the V-L-P domain is a protein-protein interaction module that is likely to be responsible for dimerization of KorA and TrbA, and important for KlcB dimerization. We speculate on the possible significance of KlcB-KorA heterodimers in IncP plasmid maintenance.

Inhibition of bacteriophage lambda development by the klaA gene of broad-host-range plasmid RK2.

The kil-kor regulon of broad-host-range plasmid RK2 is an unusual array of eight co-regulated operons that express at least 21 genes, including the plasmid replication initiator gene. Some of the operons were first identified as kil loci because uncontrolled expression in the absence of certain kor regulatory genes leads to death of the host cells. The functions of kilA, C and E are unknown, although co-regulation with the replication initiator gene suggests that they may have importance in the maintenance or host range of the plasmid. Here we report studies on the function of klaA, the first of three host-lethal genes in the kilA operon. We found that lambda pklaA-1, a lambda phage containing the klaA gene, is unable to form plaques unless the host expresses the KorA and KorB repressors needed to regulate transcription from the klaA promoter. The failure to form plaques depends on the klaA gene product and results from the inability of infected cells to produce viable phage particles. Transcription of early, delayed early and late genes or processing of lambda DNA are not affected by klaA overexpression, while cell lysis, lambda DNA replication and production of functional phage heads are reduced. However, the failure to produce viable phage is best explained by the inability to synthesize lambda tails. The finding that klaA strongly inhibits a specific morphogenetic step in the assembly of lambda phage particles has significance with respect to the function of klaA on plasmid RK2.

Nucleotide sequence of korB, a replication control gene of broad host-range plasmid RK2.

The korB gene is a major regulatory element in the replication and maintenance of broad host-range plasmid RK2. It negatively controls the replication gene trfA, the host-lethal determinants kilA and kilB, and the korA-korB operon. Here, we present the nucleotide sequence of an 1167 base-pair region that encodes korB. Using sequence data from korB mutants, we identified the korB structural gene. The predicted polypeptide product is negatively charged and has a molecular weight of 39,015, which is considerably less than that estimated by its electrophoretic mobility in SDS/polyacrylamide gels. Secondary-structure predictions of korB polypeptide revealed three closely spaced helix-turn-helix regions with significant homology to similar structures in known DNA-binding proteins. The korB gene, like all other sequenced RK2 genes, shows a strong preference for codons ending in a G or C residue. This is similar to codon usage by genes of Klebsiella and Pseudomonas, the original hosts for RK2 and some closely related plasmids. We also sequenced the site of transposon Tn76 insertion in the host-range mutant pRP761 and found it to be located immediately upstream from korB in the incC gene. Finally, we report the presence of sequences resembling a replication origin within the korB structural gene: a cluster of four 19 base-pair direct repeats and a nearby potential binding site for Escherichia coli dna A replication protein.

Host-inhibitory functions encoded by promiscuous plasmids. Transient arrest of Escherichia coli segregants that fail to inherit plasmid RK2.

An effective strategy for a plasmid to be maintained in a growing population of bacteria is to prevent the proliferation of newly formed daughter cells that lack the plasmid. In this study, we determined that the promiscuous, incompatibility group P plasmid RK2 encodes such a system. To induce large numbers of RK2-free segregants of an RK2-containing host, we designed a genetic system that made RK2 replication temperature-sensitive. A double amber mutant of the trfA replication initiator gene was constructed to complement a trfA deletion mutant of an otherwise wild-type RK2 in an Escherichia coli supD(Ts) strain. At the permissive temperature (30 degrees C), RK2 was maintained stably in the strain. Shifting the cells to the non-permissive temperature (42 degrees C) resulted in the nearly synchronous appearance of cells lacking RK2. We found that the number of viable cells rose only slowly over a period of six hours, during which time the cells formed long filaments reaching 20 to 40 times the length of a normal E. coli cell. After six hours, the arrested cells regained the ability to divide and multiply exponentially, and the filaments were eventually reduced to normal-sized cells. Neither arrest nor filamentation required the host recA function. Inhibiting the replication of an RK2 mutant deleted for the par stability locus also induced the arrest of segregants lacking the plasmid, but the arrested cells were not filamented. Our results demonstrate that RK2 encodes at least two functions that are activated in a plasmidless segregant: (1) a filamentation-inducing function specified by the par stability locus, and (2) a post-segregational arrest function (psa) that inhibits the proliferation of plasmidless segregants independent of par. We discuss the possible roles of these functions in the stable maintenance of RK2.

Precise deletions in large bacterial genomes by vector-mediated excision (VEX). The trfA gene of promiscuous plasmid RK2 is essential for replication in several gram-negative hosts.

We have developed a simple and efficient method of vector-mediated excision (VEX) for in vivo generation of precisely defined deletions in large bacterial genomes. The system uses homologous recombination with small cloned fragments on specialized pVEX plasmids to insert directly repeated bacteriophage P1 loxP sites at positions flanking the region to be deleted. In the presence of Cre recombinase, the loxP sites are efficiently recombined to produce the deletion. Deletion endpoints can be directed to specific nucleotides because they are defined by the termini of small homology-bearing fragments cloned into the pVEX plasmids. We have used VEX to delete trfA, the only known replication initiator gene of the 56.4 kb broad host-range plasmid RK2. The RK2 delta trfA mutant was found to be conjugation proficient, but unable to replicate in the RK2 hosts Acinetobacter calcoaceticus, Caulobacter crescentus, Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa, Pseudomonas putida, Rhizobium meliloti, or Rhodobacter sphaeroides. These results show that trfA is essential for replication in these hosts and indicate that the broad host-range of RK2 does not involve multiple replicons.

Complete nucleotide sequence of Birmingham IncP alpha plasmids. Compilation and comparative analysis.

The IncP alpha promiscuous plasmid (R18, R68, RK2, RP1 and RP4) comprises 60,099 bp of nucleotide sequence, encoding at least 74 genes. About 40 kb of the genome, designated the IncP core and including all essential replication and transfer functions, can be aligned with equivalent sequences in the IncP beta plasmid R751. The compiled IncP alpha sequence revealed several previously unidentified reading frames that are potential genes. IncP alpha plasmids carry genetic information very efficiently: the coding sequences of the genes are closely packed but rarely overlap, and occupy almost 86% of the genome's nucleotide sequence. All of the 74 genes should be expressed, although there is as yet experimental evidence for expression of only 60 of them. Six examples of tandem-in-frame initiation sites specifying two gene products each are known. Two overlapping gene arrangements occupy different reading frames of the same region. Intergenic regions include most of the 25 promoters; transcripts are usually polycistronic. Translation of most of the open reading frames seems to be initiated independently, each from its own ribosomal binding and initiation site, although, a few cases of coupled translation have been reported. The most frequently used initiation codon is AUG but translation for a few open reading frames begins at GUG or UUG. The most common stop-codon is UGA followed by UAA and then UAG. Regulatory circuits are complex and largely dependent on two components of the central control operon. KorA and KorB are transcriptional repressors controlling at least seven operons. KorA and KorB act synergistically in several cases by recognizing and binding to conserved nucleotide sequences. Twelve KorB binding sites were found around the IncP alpha sequence and these are conserved in R751 (IncP beta) with respect to both sequence and location. Replication of IncP alpha plasmids requires oriV and the plasmid-encoded initiator protein TrfA in combination with the host-encoded replication machinery. Conjugative plasmid transfer depends on two separate regions occupying about half of the genome. The primary segregational stability system designated Par/Mrs consists of a putative site-specific recombinase, a possible partitioning apparatus and a post-segregational lethality mechanism, all encoded in two divergent operons. Proteins related to the products of F sop and P1 par partitioning genes are separately encoded in the central control operon.

Prevalence and distribution of bacteriophage phi Aa DNA in strains of Actinobacillus actinomycetemcomitans.

phi Aa is a bacteriophage that was originally isolated by induction of a lysogenic strain of the oral bacterium Actinobacillus actinomycetemcomitans. Since the discovery of phage phi Aa, additional phages infecting several other strains of A. actinomycetemcomitans have been identified. To determine the prevalence of phi Aa or phi Aa-related temperate phages in this species, a phi Aa-specific DNA probe was prepared to screen for homologous sequences among 42 strains of A. actinomycetemcomitans. Fourteen (33%) of the 42 strains examined contained DNA sequences that hybridized with the phage phi Aa probe. A bacteriophage designated phi Aa33384 was isolated by induction from one of the strains (ATCC 33384) that contained a sequence that hybridized with the phi Aa probe. The phi Aa probe hybridized with the DNA extracted from bacteriophage phi Aa33384. The distribution of the phage phi Aa sequence among A. actinomycetemcomitans serotypes was 5/13 (38%) of the serotype a strains, 0/16 (0%) of the serotype b strains, and 9/13 (69%) of the serotype c strains. The results of this investigation suggest that the target sequence prepared from the phage phi Aa genome is fairly common in the A. actinomycetemcomitans chromosome, and that the sequence is distributed among the A. actinomycetemcomitans serotypes in a seemingly nonrandom manner.

Tenacious adhesion of Actinobacillus actinomycetemcomitans strain CU1000 to salivary-coated hydroxyapatite.

Adherence of Actinobacillus actinomycetemcomitans to hard-tissue surfaces was evaluated by comparing a phenotypically stable, well-maintained clinical isolate (strain CU1000) to Streptococcus gordonii G9B, an extensively studied oral-colonizing bacterium. Standard innocula of radiolabelled bacteria were added to saliva-coated hydroxyapatite (SHA) and the ratio of bound to unbound cells counted. Several other clinical isolates as well as laboratory strain Y4 were studied. In other experiments, cell detachment from SHA was compared in static and shaking vessels to calculate controlled desorption of cells over time. A sonic-displacement assay was used to measure avidity of binding to HA and SHA. To better define the attachment properties of CU1000, bacteria were treated with a variety of agents including detergents, salts and enzymes before or after incubation with SHA. Results indicated that CU1000 bound better than G9B (a minimum of 10-fold greater; p < or = 0.05) and did not desorb from SHA, while G9B desorbed to equilibrium in 4 h. Furthermore, Langmuir isotherm calculations indicated that, unlike G9B, CU1000 did not follow second-order adsorption kinetics and thus did not achieve saturation. In addition, of the agents tested only periodate reduced attachment and resulted in detachment of CU1000 from surfaces. These experiments suggest that clinical isolates of A. actinomycetemcomitans possess unique binding properties that promote adsorption to and impede desorption from SHA. The characteristics described for the actinobacillus in this study have been previously underestimated, appear to be mediated by glycoconjugates, and may resemble attachment described for several biofilm-forming, non-oral pathogens.

Genetic analysis of the requirement for flp-2, tadV, and rcpB in Actinobacillus actinomycetemcomitans biofilm formation.

The tad locus of Actinobacillus actinomycetemcomitans encodes a molecular transport system required for tenacious, nonspecific adherence to surfaces and formation of extremely strong biofilms. This locus is dedicated to the biogenesis of Flp pili, which are required for colonization and virulence. We have previously shown that 11 of the 14 tad locus genes are required for adherence and Flp pilus production. Here, we present genetic and phylogenetic analyses of flp-2, tadV, and rcpB genes in biofilm formation. We show that tadV, predicted to encode prepilin peptidase, is required for adherence. In contrast, targeted insertional inactivation of flp-2, a gene closely related to the prepillin gene flp-1, did not abrogate biofilm formation. Expression studies did not detect Flp2-T7 protein under standard laboratory conditions. We present phylogenetic data showing that there is no significant evidence for natural selection in the available flp-2 sequences from A. actinomycetemcomitans, suggesting that flp-2 does not play a significant role in the biology of this organism. Mutants with insertions at the 3' end of rcpB formed biofilms equivalent to wild-type A. actinomycetemcomitans. Surprisingly, 5' end chromosomal insertion mutants in rcpB were obtained only when a wild-type copy of the rcpB gene was provided in trans or when the Tad secretion system was inactivated. Together, our results strongly suggest that A. actinomycetemcomitans rcpB is essential in the context of a functional tad locus. These data show three different phenotypes for the three genes.

Essential genes of plasmid RK2 in Escherichia coli: trfB region controls a kil gene near trfA.

Plasmid RK2 encodes several kil determinants whose lethal action on Escherichia coli host cells is prevented by RK2 kor genes. Here we show that the mini-RK2 plasmid, pRK248, specifies a kilB component (kilB1) in the region of the replication gene trfA. kilB1 is different from trfA and is completely encoded within the pRK248 HaeII A fragment. Transformation of E. coli cells with hybrid plasmids containing the cloned kilB1 determinant is very inefficient and results in the selection of variant kil- plasmids, many of which show genetic and physical evidence of deletions. If another pRK248 gene (korB1) is present in the cells, kilB1+ plasmids can be established at high efficiency and without any detectable changes. KorB1 is encoded by the trfB region of pRK248 because recombinant plasmids with this region are able to control kilB1 in trans. These results substantiate our earlier explanation for the structure of pRK248 and for the perplexing requirement of the trfB region in this plasmid.

Conditional lethal mutants of the kilB determinant of broad host range plasmid RK2.

We have examined the relationship of kilB to the other known determinants which map in the 14'-22' region of RK2. These are trfA, which encodes a diffusible replication function, and tra3, which specifies a function required for plasmid transmissibility. We found that, in addition to kilB, both tra3 and trfA functions are expressed by the cloned 14'-22' region of RK2. Four temperature-sensitive mutants of kilB were isolated by in vitro mutagenesis of the cloned segment. At 42 degrees C these mutant plasmids can be maintained in Escherichia coli cells which lack a korB+ helper plasmid. At 30 degrees C the helper plasmid is required. Our analysis of these mutants revealed that kilB function is distinct from those of trfA and tra3. One mutant plasmid was temperature-sensitive for maintenance of an RK2 ori plasmid, but this phenotype was shown to be independent of the KilB(ts) phenotype. Thus, kilB appears to be a separate new locus in this portion of the RK2 genome. In addition, these mutants allowed us to test for the existence of an essential replication determinant (trfB) in the 50.4'-56.4' region of RK2. Our results demonstrate that this region is non-essential for replication from the RK2 ori in E. coli. We propose an alternative hypothesis to explain the role of the RK2 trfB region for plasmid maintenance in E. coli.

Map location and nucleotide sequence of korA, a key regulatory gene of promiscuous plasmid RK2.

From our earlier work, we know that the korA gene of broad host range plasmid RK2 is located within the 50.4'-56.4' region. By additional subcloning of this region, we have mapped korA to the segment between the HaeII site at 55.0' and the HincII site at 55.6'. The direction of korA transcription (55.6' to 55.1') was determined by two methods: (1) inactivation of korA expression signals and fusion of the structural gene to other promoters; and (2) hybridization analysis of korA-specific RNA's synthesized in vivo. We have determined the nucleotide sequence of the korA region. A potentially strong promoter overlaps the HincII site at 55.6', and there is a coding region which specifies the putative korA polypeptide. That this is the korA gene was supported by sequence analysis of Ba131-generated deletion mutants of korA. The sequence shows the korA product to be a small, basic polypeptide of 101 amino acids.

Replication of an origin-containing derivative of plasmid RK2 dependent on a plasmid function provided in trans.

pRK212.2, a derivative of the broad host range plasmid RK2, contains two EcoRI cleavage fragments, A and B, neither of which can replicate by itself in Escherichia coli. Fragment A (41.7 kilobases), but not fragment B (14.4 kilobases), can be cloned by insertion into the unrelated plasmids mini-F and ColE1. Fragment B contains the origin of replication and the ampicillin-resistance determinant of RK2. Transformation of E. coli cells containing the mini-F-fragment A hybrid plasmid with fragment B DNA results in the recircularization and replication of fragment B as a nonmobilizable plasmid (pRK2067) with the copy number and incompatibility properties of RK2. Fragment B cannot be cloned in the absence of fragment A because the latter fragment suppresses a function, specified by fragment B, that results in loss of host cell viability. A small segment (2.4 kilobases) of fragment B that contains the RK2 origin of replication but no longer affects host cell growth in the absence of fragment A had been cloned previously by insertion into a ColE1 plasmid. This hybrid plasmid, designated pRK256, will replicate in E. coli polA mutants only when a fragment A-bearing helper plasmid is present. These results demonstrate that the potentially lethal function specified by fragment B of RK2 is not necessary for replication and that at least one trans-acting function is directly involved in RK2 replication.

Structure, expression, and regulation of the kilC operon of promiscuous IncP alpha plasmids.

The kil-kor regulon was first identified on the broad-host-range IncP alpha plasmid RK2 by the presence of multiple kil loci (kilA, kilB, kilC, and recently kilE) that are lethal to Escherichia coli host cells in the absence of regulation by kor functions in various combinations. Whereas the kilB operon is required for mating-pair formation during conjugation, the functions encoded by the other kil loci are not known. They are not essential for replication or conjugal transfer, but their coregulation with replication and transfer genes indicates that they are likely to be important for RK2. In this report, we describe molecular and genetic studies on kilC. We determined the nucleotide sequence of the kilC region, which is located between the origin of vegetative replication (oriV) and transposon Tn1 on RK2. Primer extension analysis identified the transcriptional start site and showed that a sequence corresponding to a strong sigma 70 promoter is functional. The abundance of RNA initiated from the kilC promoter is reduced in the presence of korA and korC, as predicted from genetic analysis of kilC regulation. The first gene of the kilC operon (klcA) is sufficient to express the host-lethal phenotype of the kilC determinant in the absence of korA and korC. By comparing RK2 to the related IncP alpha plasmids pUZ8 and R995, we determined that the Tn1 transposon in RK2 interrupts a gene (klcB) immediately downstream of klcA. Thus, the kilC determinant is normally part of an autoregulated operon of three genes: klcA, klcB, and korC. klcA is predicted to encode a 15,856-Da polypeptide that is related to the ArdB antirestriction protein of the IncN plasmid pKM101, suggesting a role for klcA in the broad host ranges of IncP alpha plasmids. The predicted product of the uninterrupted klcB gene is a polypeptide of 51,133 Da that contains a segment with significant similarity to the RK2 regulatory proteins KorA and TrbA. Located 145 bp upstream of the kilC promoter is a 10th copy of the 17-bp oriV iteron sequence in inverted orientation relative to that of the other nine iterons of oriV. Iteron 10 is identical to the "orphan" iteron 1, and both have identical 6-bp flanking sequences that make them likely to be strong binding sites for the TrfA replication initiator protein. The locations and relative orientation of orphan iterons 10 and 1 raise the possibility that these iterons promote the formation of a DNA loop via protein-protein interactions by bound TrfA and lead us to propose that they demarcate the functional origin of replication. This analysis of the kilC region and our previous studies on the other kil loci of RK2 have revealed that the region between oriV and the korABF operon in wild-type IncP alpha plasmids is saturated by the kilC, kilE, and kilA loci arranged in four kor-regulated operons encoding a total of 12 genes.

A potential new gene (tccA) on IncP plasmid RK2 and transposon Tn1721: relationship of its product to the TrwC relaxase/helicase of IncW plasmid R388.

Computational analysis of the fully sequenced 60-kb genome of broad-host-range IncP alpha plasmid RK2 revealed a previously unreported potential protein-coding sequence, an 80-codon open reading frame (tccA), located in the region between the vegetative origin of replication (oriV) and the tetR gene of the tetracycline resistance determinant. The coding region is also present in the transposon Tn1721 tet region, which is nearly identical to the tet region of RK2. Remarkably, the predicted polypeptide product of the coding region displays 56% identity and 72% similarity with the C-terminal domain of the TrwC relaxase/helicase protein of IncW plasmid R388.

The kilA operon of promiscuous plasmid RK2: the use of a transducing phage (lambda pklaA-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.

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.

kil-kor regulon of promiscuous plasmid RK2: structure, products, and regulation of two operons that constitute the kilE locus.

The kil-kor regulon of IncP plasmid RK2 is a complex regulatory network that includes genes for replication and conjugal transfer, as well as for several potentially host-lethal proteins encoded by the kilA, kilB, and kilC loci. While kilB is known to be involved in conjugal transfer, the functions of kilA and kilC are unknown. The coregulation of kilA and kilC with replication and transfer genes indicates a possible role in the maintenance or broad host range of RK2. In this work, we found that a fourth kil locus, designated kilE, is located in the kb 2.4 to 4.5 region of RK2 and is regulated as part of the kil-kor regulon. The cloned kilE locus cannot be maintained in Escherichia coli host cells, unless korA or korC is also present in trans to control its expression. The nucleotide sequence of the kilE region revealed two potential multicistronic operons. The kleA operon consists of two genes, kleA and kleB, predicted to encode polypeptide products with molecular masses of 8.7 and 7.6 kDa, respectively. The kleC operon contains four genes, kleC, kleD, kleE, and kleF, with predicted products of 9.2, 8.0, 12.2, and 11.3 kDa, respectively. To identify the polypeptide products, each gene was cloned downstream of the phage T7 phi 10 promoter and expressed in vivo in the presence of T7 RNA polymerase. A polypeptide product of the expected size was observed for all six kle genes. In addition, kleF expressed a second polypeptide of 6 kDa that most likely results from the use of a predicted internal translational start site. The kleA and kleC genes are each preceded by sequences resembling strong sigma 70 promoters. Primer extension analysis revealed that the putative kleA and kleC promoters are functional in E. coli and that transcription is initiated at the expected nucleotides. The abundance of transcripts initiated in vivo from both the kleA and kleC promoters was reduced in cells containing korA or korC. When korA and korC were present together, they appeared to act synergistically in reducing the level of transcripts from both promoters. The kleA and kleC promoter regions are highly homologous and contain two palindromic sequences (A and C) that are the predicted targets for KorA and KorC proteins. DNA binding studies showed that protein extracts from korA-containing E. coli cells specifically retarded the electrophoretic mobility of DNA fragments containing palindrome A. Extracts from korC-containing cells altered the mobility of DNA fragments containing palindrome C. These results show that KorA and KorC both act as repressors of the kleAand kleC promoters. In the absence of korA and korC, expression of the cloned kleA operon was lethal to E.coli cells, whereas the cloned kleC operon gave rise to slowly growing, unhealthy colonies. Both phenotypes depended on at least one structural gene in each operon, suggesting that the operons encode genes whose products interact with critical host functions required for normal growth and viability. Thus, the kilA, kilC, and kilE loci of RK2 constitute a cluster of at least 10 genes that are coregulated with the plasmid replication initiator and the conjugal transfer system. Their potential toxicity to the host cell indicates that RK2 is able to establish a variety of intimate plasmid-host interactions that may be important to its survival in nature.