Evidence that the hemolysin/bacteriocin phenotype of Enterococcus faecalis subsp. zymogenes can be determined by plasmids in different incompatibility groups as well as by the chromosome.

The hemolysin (Hly/Bac) determinant in strains of Enterococcus faecalis was found to be present on plasmids in different incompatibility groups (conferring different sex pheromone responses) as well as on the chromosome. Of 33 Hly/Bac plasmids identified in clinical isolates, the related pheromone for 30 was cAD1; the related pheromone for another two (pYI1 and pYI3) or one (pYI2) was cOB1 or cY12, respectively. The representative Hly/Bac plasmids pAD1, pYI1, pOB1, and pYI2, which responded to pheromones cAD1, cOB1, cOB1, and cYI2, respectively, were compatible with one another. As additions to the incompatibility group IncHly of pAD1, groups for pOB1, pYI1, and pYI2 were designated IncHlyII, IncHlyIII, and IncHlyIV, respectively. Eleven of the 30 plasmids conferring a response to cAD1 were very similar to pAD1 on the basis of their restriction endonuclease profiles. EcoRI fragment D, F, or H containing parts of the Hly/Bac gene(s) of pAD1 hybridized to similar EcoRI fragments from each of the other three representatives of incompatibility groups (i.e., pOB1, pYI1, and pYI2) and to homologous DNA representing the chromosome of the plasmid-free Hly/Bac strain YI6-1.     

Cloning of replication, incompatibility, and stability functions of R plasmid NR1.

The region of R plasmid NR1 that is capable of mediating autonomous replication was cloned by using EcoRI, SalI, and PstI restriction endonucleases. The only EcoRI fragment capable of mediating autonomous replication in either a pol+ or a polA host was fragment B. SalI fragment E joined in native orientation with the part of SalI fragment C that overlapped with EcoRI fragment B, and also two contiguous PstI fragments of sizes 1.6 and 1.1 kilobases from EcoRI fragment B-mediated autonomous replication. When these individual SalI fragments were cloned onto plasmid pBR313 or the individual PstI fragments were cloned onto plasmid pBR322, none of these single fragments could rescue the replication of the ColE1-like vectors in a polA host, even in the presence of a compatible "helper" plasmid derived from a copy mutant of NR1. In contrast to the results reported for closely related R plasmid R6, EcoRI fragment A of NR1 could not rescue the replication of ColE1 derivative RSF2124 in a polA(Am) mutant or in a polA(Ts) mutant at the restrictive temperature. Although capable of autonomous replication, EcoRI fragment B of NR1 (or smaller replicator fragments cloned from it by using other restriction enzymes) was not stably inherited in the absence of selection for the recombinant plasmid. When EcoRI fragment B was ligated to EcoRI fragment A of NR1, the recombinant plasmid was stable. Thus, EcoRI fragment A contained a stability (stb) function. The stb function did not act in trans since EcoRI fragment B was not stably inherited when a ColE1 derivative (RSF2124) ligated to EcoRI fragment A was present in the same cell. A cointegrate plasmid consisting of EcoRI fragment B of NR1 ligated to RSF2124 was also not stably inherited, whereas only EcoRI fragment B was unstable when both RSF2124 and EcoRI fragment B coexisted as autonomous plasmids in the same cell. The incompatibility gene of NR1 was shown to be located within the region of overlap between SalI fragment E and the PstI 1.1-kilobase fragment. A copy mutant of NR1 (called pRR12) was found to have greatly reduced incompatibility with NR1; this Inc- phenotype is cis dominant.     

Replication Mechanism and Sequence Analysis of the Replicon of pAW63, a Conjugative Plasmid from Bacillus thuringiensis

A 5.8-kb fragment of the large conjugative plasmid pAW63 from Bacillus thuringiensis subsp. kurstaki HD73 containing all the information for autonomous replication was cloned and sequenced. By deletion analysis, the pAW63 replicon was reduced to a 4.1-kb fragment harboring four open reading frames (ORFs). Rep63A (513 amino acids [aa]), encoded by the largest ORF, displayed strong similarity (40% identity) to the replication proteins from plasmids pAMbeta1, pIP501, and pSM19035, indicating that the pAW63 replicon belongs to the pAMbeta1 family of gram-positive theta-replicating plasmids. This was confirmed by the facts that no single-stranded DNA replication intermediates could be detected and that replication was found to be dependent on host-gene-encoded DNA polymerase I. An 85-bp region downstream of Rep63A was also shown to have strong similarity to the origins of replication of pAMbeta1 and pIP501, and it is suggested that this region contains the bona fide pAW63 ori. The protein encoded by the second large ORF, Rep63B (308 aa), was shown to display similarity to RepB (34% identity over 281 aa) and PrgP (32% identity over 310 aa), involved in copy control of the Enterococcus faecalis plasmids pAD1 and pCF10, respectively. No significant similarity to known proteins or DNA sequences could be detected for the two smallest ORFs. However, the location, size, hydrophilicity, and orientation of ORF6 (107 codons) were analogous to those features of the putative genes repC and prgO, which encode stability functions on plasmids pAD1 and pCF10, respectively. The cloned replicon of plasmid pAW63 was stably maintained in Bacillus subtilis and B. thuringiensis and displayed incompatibility with the native pAW63. Hybridization experiments using the cloned replicon as a probe showed that pAW63 has similarity to large plasmids from other B. thuringiensis subsp. kurstaki strains and to a strain of B. thuringiensis subsp. alesti.     

Second EcoRI fragment of F capable of self-replication.

The cloning of fragments of F' plasmid deoxyribonucleic acid produced by restriction endonuclease EcoRI has revealed that fragment f7, not previously suspected to have replicative properties, is able to replicate autonomously. The ability of f7 to replicate was observed when it was cloned with fragments coding for resistance to either kanamycin or streptomycin and sulfonamide. Such f7 miniplasmids have been obtained from an F'lac+ and two F'gal+ temperature-sensitive mutant plasmids and from the unmutated F plasmid. Plasmids containing both f5 and f7 fragments were also obtained. Expression of resistance to "female-specific" bacteriophages requires that f5 and f7 be present in the same plasmid since cells containing separate f5 and f7 plasmids are not resistant to bacteriophage phi II. f7 plasmids were less stable than miniplasmids containing f5, particularly at fast growth rates. The bearing of these results on the isolation and behavior of temperature-sensitive F mutants is discussed.     

Generation of miniplasmids from copy number mutants of the R plasmid NR1.

Small, closed circular deoxyribonucleic acid molecules, called miniplasmids, were observed in Escherichia coli harboring copy number mutants of the R plasmid NR1 after growth in medium containing tetracycline. The level of tetracycline resistance conferred by the copy mutant plasmids was lower (3 to 6 microgram/ml) than that conferred by NR1 (100 MICROGRAM/ML). The presence of the miniplasmid enhanced the level of tetracycline resistance conferred by the copy mutant. Miniplasmids of molecular weights 4 X 10(6) to 13 X 10(6) were found. They carried no antibiotic resistance markers and could be eliminated by growth in the presence of chloramphenicol and/or streptomycin-spectinomycin. Studies with the restriction endonucleases EcoRI and Sal I indicated that the miniplasmids are derived from the region of the copy mutant plasmids that contains the origin for replication of the resistance transfer factor. There were approximately 12 copies of the miniplasmid per chromosome, compared with 3 and 6 copies of the copy mutants of NR1. The miniplasmids appeared to be incompatible with the copy mutant plasmids.     

Plasmid replication functions: two distinct segments of plasmid R1, RepA and RepD, express incompatibility and are capable of autonomous replication.

The genetic determinants for replication and incompatibility of plasmid R1 were investigated by gene cloning methods, and three types of R1 miniplasmid derivatives were generated. The first, exemplified by plasmid pKT300, consisted of a single BglII endonuclease-generated deoxyribonucleic acid fragment derived from the R1 region that is located between the determinants for conjugal transfer and antibiotic resistance. Two types of miniplasmids could be formed from PstI endonuclease-generated fragments of pKT300. One of these, which is equivalent to miniplasmids previously generated from plasmids R1-19 and R1-19B2, consisted of two adjacent PstI fragments that encode the RepA replication system of plasmid R1. The other type contained a segment of R1, designated the RepD replication region, that is adjacent to the RepA region and that has not been identified previously as having the capacity for autonomous replication. Plasmid R1, therefore, contained two distinct deoxyribonucleic acid segments capable of autonomous replication. The RepA-RepD miniplasmid pKT300 had a copy number about eightfold higher than that of R1 and hence lacked a determinant for the regulation of plasmid copy number. Like R1, it was maintained stably in dividing bacteria. RepA miniplasmids had copy numbers which were two- to fourfold higher than that of R1 (i.e., which were lower than that of pKT300) and were maintained slightly less stably than those of pKT300 and R1. The RepD miniplasmid was not maintained stably in dividing bacteria. Previous experiments have shown that incompatibility of IncFII group plasmids is specified by a plasmid copy control gene. Despite the fact that RepA miniplasmids of R1 were defective in copy control, they nevertheless expressed incompatibility. This suggests that two genes are responsible for plasmid copy control, one that specifies incompatibility and is located on RepA miniplasmids and another that is located outside of, but adjacent to, the RepA replication region. Hybrid plasmids composed of pBR322 and one PstI fragment from the RepA region, P-8, exhibited incompatibility towards R2 and RepA miniplasmids but not the RepD miniplasmid, whereas hybrids composed of pBR322 and the PstI fragment of the RepD region, P-3, exhibited incompatibility towards R1 and the RepD miniplasmid but not RepA miniplasmids. These results indicate that the two replication systems are functionally distinct and that, although the RepA system is the principal replication system of R1, the RepD system also plays a role in the maintenance of this plasmid.     

Comparative analysis of Enterococcus faecalis sex pheromone plasmids identifies a single homologous DNA region which codes for aggregation substance.

An analysis of the 11 known sex pheromone plasmids of Enterococcus faecalis was performed by DNA-DNA hybridization. Plasmids pAD1, pJH2, and pBEM10 turned out to be closely related, whereas pAM373 showed only weak homology with pAD1. A comparison of the hemolysin/bacteriocin determinants of pAD1, pJH2, and pOB1 revealed strong similarities at the DNA level. Our main finding was that one DNA region is conserved among all sex pheromone plasmids, with pAM373 again being an exception; for pAD1 this region was shown earlier to code for aggreagation substance. Detailed hybridization studies of the genes for this plasmid-coded adhesin, which is responsible for cell-cell contact during conjugative transfer via the so-called sex pheromone system of E. faecalis, support the idea of their common origin.     

Cloning and characterization of a region of the Enterococcus faecalis conjugative plasmid, pCF10, encoding a sex pheromone-binding function.

In order to investigate the mechanism by which peptide sex pheromones induce expression of the conjugation functions of certain Enterococcus faecalis plasmids, a biological assay was developed to measure the ability of cells carrying the conjugative plasmid pCF10 to bind the sex pheromone cCF10. The data indicated that pCF10 endows its host E. faecalis cell with the ability to specifically remove (apparently by irreversible binding) cCF10 activity from culture medium. The pCF10 DNA encoding this ability was localized to a 3.4-kb segment within a region involved in negative control of expression of conjugal transfer functions. This segment also encoded ability to bind the pheromone inhibitor peptide iCF10. DNA sequencing revealed three open reading frames, which have been denoted prgW (pheromone responsive gene W), prgZ, and prgY. The deduced product of prgW resembled regulatory proteins from other bacteria and eucaryotes, with a very high degree of identity within a putative DNA-binding domain. The prgY gene actually extended into an adjacent region of pCF10 and could encode a protein with significant similarity to a protein called TraB, believed to be involved in shutdown of pheromone cAD1 production by cells carrying the pheromone-inducible hemolysin plasmid pAD1, according to F.Y. An and D.B. Clewell (Abstr. Gen. Meet. Am. Soc. Microbiol. 1992, H70, 1992). The prgZ gene product showed significant relatedness to binding proteins encoded by oligopeptide permease (opp) operons in gram-positive and gram-negative bacteria and is highly similar to a pAD1-encoded protein, TraC, which is believed to mediate sex pheromone cAD1 binding (K. Tanimoto, F. Y. An, and D. B. Clewell, submitted for publication). A Tn5 insertion into prgZ abolished cCF10 binding ability.     

Control of Enterococcus faecalis sex pheromone cAD1 elaboration: effects of culture aeration and pAD1 plasmid-encoded determinants

Aeration of plasmid-free Enterococcus faecalis strains resulted in an 8- to 16-fold decrease in sex pheromone cAD1 activity in culture filtrates. Levels of two unrelated pheromones, cPD1 and cAM373, were unaffected by culture aeration. Aeration also resulted in a decrease in the expression of conjugative transfer functions observed in cells containing pAD1 traB mutations, verifying a link between traB function and pheromone "shutdown." Tests with a series of pAD1 mini-plasmids indicated that the product of the traB gene was involved in, but not sufficient for, pheromone shutdown; the cooperation of one or more other gene products encoded within the pheromone response control region was required.     

Characterization and mapping of regions encoding clindamycin resistance, tetracycline resistance, and a replication function on the Bacteroides R plasmid pCP1.

The Bacteroides drug resistance plasmid pCP1 encodes clindamycin resistance (Clr) and a cryptic tetracycline resistance (Tcr) determinant that is expressed in Escherichia coli cells grown aerobically, but not anaerobically, and is not expressed phenotypically in Bacteroides spp. Localization of genetic functions on pCP1 was facilitated by the construction of hybrid shuttle plasmids containing portions of pCP1 ligated to pDG5, a pBR322 derivative carrying the RK2 transfer origin. pDP1 delta 4 is a BglII deletion derivative of pCP1 linked to pDG5 and can be maintained in both E. coli and Bacteroides fragilis. By using Tn5 mutagenesis and subcloning, we localized the Clr and Tcr regions on the EcoRI B fragment between the 1.2-kilobase direct repeats of pCP1. The Clr and Tcr determinants are distinct and appear to be transcribed separately. Control of the Tcr phenotype is unusual in that expression is constitutive and is enhanced by a region encompassing the adjacent direct repeat. In addition, a region of pCP1 required for replication in Bacteroides spp. has been identified in the neighboring EcoRI A fragment.     

Regeneration of insertionally inactivated streptococcal DNA fragments after excision of transposon Tn916 in Escherichia coli: strategy for targeting and cloning of genes from gram-positive bacteria

The conjugative transposon Tn916 (15 kilobases), originally identified in Streptococcus faecalis DS16, has been cloned as an intact element on the pBR322-derived vector pGL101 in Escherichia coli. The EcoRI F' (EcoRI F::Tn916) fragment of pAM211 (pAD1::Tn916) was cloned into the single EcoRI site of pGL101 to form the chimera, pAM120, by selecting for the expression of Tn916-encoded tetracycline resistance (Tcr). Interestingly, in the absence of continued selection for Tcr, Tn916 excised from pAM120 at high frequency. This excision event resulted in a plasmid species consisting of the pGL101 vector and a 2.7-kilobase restriction fragment comigrating with the EcoRI F fragment of pAD1 during agarose gel electrophoresis. Filter blot hybridization experiments showed the 2.7-kilobase fragment generated as a result of Tn916 excision to be homologous with the EcoRI F fragment of pAD1. Analogous results were obtained with another chimera, pAM170, generated by ligating the EcoRI D' (EcoRI D::Tn916) fragment of pAM210 (pAD1::Tn916) to EcoRI-digested pGL101. Comparison of the AluI and RsaI cleavage patterns of the EcoRI F fragment isolated after Tn916 excision with those from an EcoRI F fragment derived from pAD1 failed to detect any difference in the two fragments: data in support of a precise Tn916 excision event in E. coli. Subcloning experiments showed that an intact transposon was required for Tn916 excision and located the Tcr determinant near the single HindIII site on Tn916. Although excision occurred with high frequency in E. coli, Tn916 insertion into the E. coli chromosome was a much rarer event. Tcr transformants were not obtained when pAM120 DNA was used to transform a polA1 strain, E. coli C2368.     

Characterization of an active partition system for the Enterococcus faecalis pheromone-responding plasmid pAD1

Enterococcus faecalis plasmid pAD1 is a 60-kb conjugative, low-copy-number plasmid that encodes a mating response to the peptide sex pheromone cAD1 and a cytolytic exotoxin that contributes to virulence. Although aspects of conjugation have been studied extensively, relatively little is known about the control of pAD1 maintenance. Previous work on pAD1 identified a 5-kb region of DNA sufficient to support replication, copy control, and stable inheritance (K. E. Weaver, D. B. Clewell, and F. An, J. Bacteriol. 175:1900-1909, 1993), and recently, the pAD1 replication initiator (RepA) and the origin of vegetative replication (oriV) were characterized (M. V. Francia, S. Fujimoto, P. Tille, K. E. Weaver, and D. B. Clewell, J. Bacteriol. 186:5003-5016, 2004). The present study focuses on the adjacent determinants repB and repC, as well as a group of 25 8-bp direct repeats (iterons with the consensus sequence TAGTARRR) located between the divergently transcribed repA and repB. Through mutagenesis and trans-complementation experiments, RepB (a 33-kDa protein, a member of the ParA superfamily of ATPases) and RepC (a protein of 14.4 kDa) were shown to be required for maximal stabilization. Both were active in trans. The iteron region was shown to act as the pAD1 centromere-like site. Purified RepC was shown by DNA mobility shift and DNase I footprinting analyses to interact in a sequence-specific manner with the iteron repeats upstream of the repBC locus. The binding of RepC to the iteron region was shown to be modified by RepB in the presence of ATP via a possible interaction with the RepC-iteron complex. RepB did not bind to the iteron region in the absence of RepC.     

Regulation of the pAD1 sex pheromone response in Enterococcus faecalis: effects of host strain and traA, traB, and C region mutants on expression of an E region pheromone-inducible lacZ fusion.

Pheromone-induced conjugal transfer of the hemolysin-bacteriocin plasmid pAD1 of Enterococcus faecalis is regulated by a cluster of determinants designated traA, traB, and regions C and E. The E region is believed to include a positive regulator that controls many structural genes related to conjugation. The pheromone-inducible Tn917-lac fusion NR5, located in the E region, is regulated by the products of traA, traB, and the C region. To more closely examine the effects of these genes on the induction of E region products, inserts in each of these genes were combined with the NR5 fusion in a novel approach involving triparental matings with a pAD1 miniplasmid and recombinational mutagenesis. Results indicate that (i) the traA gene product is a key repressor of the pheromone response; (ii) the traB gene product, in cooperation with a gene within or regulated by the E region, controls pheromone shutdown; (iii) a primary function of the C region gene product is in pheromone sensing, with secondary functions in pheromone shutdown and negative regulation; and (iv) the host in which the plasmid resides has a dramatic effect on the regulation of the NR5 fusion in traB and C region mutants. Numerous parallels were observed between the regulation of the NR5 fusion and the regulation of the aggregation and transfer response. These parallels aided in further defining the functions of particular regulatory determinants as well as further establishing the link between the regulation of the E region and the regulation of the aggregation and transfer response.     

Two replication determinants of an antibiotic-resistance plasmid, pTB19, from a thermophilic bacillus

Two different replication determinants were found on an antibiotic resistance plasmid, pTB19, from a thermophilic bacillus. One replication determinant (designated RepA) was functional only in Bacillus subtilis, whereas the other (designated RepB) functioned in both B. subtilis and Bacillus stearothermophilus. A deletion plasmid, pTB90, carrying the RepB derived from pTB19 coincidentally contained the specific 1.0 MDal EcoRI fragment of a cryptic plasmid pBSO2 from B. stearothermophilus. The presence of this 1.0 MDal EcoRI fragment in various deletion plasmids from pTB90 increased transformation frequencies for B. stearothermophilus 10(3) to 10(4) times and lowered plasmid copy numbers in the host strain to about one-tenth of those found for plasmids lacking this fragment.     

Delta dnaK52 mutants of Escherichia coli have defects in chromosome segregation and plasmid maintenance at normal growth temperatures.

Major heat shock proteins, such as the Escherichia coli DnaK protein, not only are required for cell growth after heat shock but seem to possess important functions in cellular metabolism at normal growth temperatures as well. E. coli delta dnaK52 mutants have severe cellular defects at 30 degrees C, one of which is in cell division (B. Bukau and G. C. Walker, J. Bacteriol, 171:2337-2346, 1989). Here we show that at 30 degrees C, delta dnaK52 mutants have defects in chromosome segregation and in maintenance of low-copy-number plasmids. Fluorescence microscopic analysis revealed that chromosomes were frequently lacking at peripheries of cell filaments of delta dnaK52 mutants and clustered at other locations. In other parts of the cell filaments, chromosomes were apparently normally distributed and they were also present in most of the small cells found in populations of delta dnaK52 cells. These defects might be at the level of DNA replication, since delta dnaK52 mutants have a threshold lower rate of DNA synthesis than wild-type cells. Chromosome segregation defects of delta dnaK52 mutants were also observed in an rnh dnaA mutant background, in which initiation of DNA replication is DnaA-oriC independent. We also found that low-copy-number P1 miniplasmids could not be stably maintained in delta dnaK52 mutants at 30 degrees C. delta par P1 miniplasmids that carry the P1-encoded rep functions required for their replication but lack the P1-encoded par functions required for faithful partitioning of the plasmids during cell division were also unstable in delta dnaK52 mutants. Taken together, our results indicate important, although not absolutely essential, functions for DnaK at 30 degrees C in one or more processes necessary for correct replication and/or partitioning of chromosomes and P1 miniplasmids. Furthermore, we found that P1 miniplasmids were also highly unstable in dnaJ259 mutants, indicating a role for the DnaJ heat shock protein in maintenance of these plasmids.