Conjugal acquisition and stable maintenance of Ent plasmids in nontoxigenic wild-type strains of Escherichia coli

In spite of the ability of the genetic determinants for enterotoxin production to be conjugally transferred, mobilized or transposed, enterotoxigenic Escherichia coli (ETEC) isolated from diarrheal patients is restricted to certain serotypes. Four conjugative enterotoxigenic plasmids (Ent plasmids) encoding either a heat-labile enterotoxin or a heat-stable enterotoxin or both and belonging to one of three incompatibility groups IncFI, IncHl, or IncX, were examined for their transferability to and stability in 157 nonenterotoxigenic Escherichia coli strains belonging to various serotypes and 89 clinical isolates nonenterotoxigenic but belonging to those serotypes in which ETEC from diarrheal patients are usually found. The serotypes of the strains to which Ent plasmids were efficiently transferred and in which they were maintained stably were not always the serotypes in which ETEC had usually been found and vice versa. The frequencies of transfer of four Ent and two R plasmids to each of the 157 recipients were correlated with each other, indicating that the frequency of transfer of the plasmid is not determined by a resident plasmid, if there is one, but by a recipient factor which commonly affects transferability to all donors. These results have led to the conclusion that the reason why only certain serotypes are found among ETEC isolated from diarrheal patients is not the ability of these strains specifically and preferentially to acquire and maintain the Ent plasmids.     

Distribution of sequences homologous to the impCAB operon of TP110 among bacterial plasmids of different incompatibility groups

Summary Mutagenic DNA repair is a function of many naturally occurring plasmids belonging to several different incompatibility groups. A DNA probe corresponding to the impCAB operon of the IncIl plasmid TP110, which encodes such functions, was used to investigate the distribution of homologous sequences in both related and unrelated plasmids. Southern blotting was used to demonstrate considerable sequence conservation amongst a number of plasmid types, with imp-related sequences being found on plasmids belonging to the I1, I1/B, B and FIV incompatibility groups. However, no homology was detected amongst plasmids of the N and L/M incompatibility groups, many of which carry functionally similar gene clusters. It appears that sequences determining mutagenic repair functions have been largely conserved within any one incompatibility group, but that significant divergent evolution has occurred between groups.     

Distribution of plasmid maintenance regions among IncFIV plasmids

The distribution of the IncFI basic replicons among IncFIV plasmids was assessed by DNA hybridization. In addition these and 20 other plasmids from 16 incompatibility groups were screened for the presence of IncIV, an incompatibility determinant recently found on the IncFIV plasmid R124. The IncIV determinant was found commonly but not universally among the IncFIV plasmids. It was also detected on the IncFI reference plasmid R386 and plasmids from IncB, IncI alpha and IncI gamma. The frequency and distribution of IncFI replicons among the IncFIV plasmids is similar to that observed in other F groups. The similarity of the IncFIV plasmids to plasmids of the other IncF groups and the failure to find replicons unique to IncFIV plasmids indicates that their division into a separate incompatibility group is not justified.     

Distribution of basic replicons having homology with RepFIA, RepFIB, and RepFIC among IncF group plasmids

Plasmids encoding F-like pili have been divided into groups on the basis of their incompatibility behavior. Three basic replicons have been recognized previously in the IncFI plasmid group and we have now examined their distribution in representative plasmids from 22 of the currently recognized incompatibility groups. The occurrence of these basic replicons was found to be rare outside of the IncF group, and significant hybridization was shown only for RepFIA to IncH1 and I group plasmids. Homology to the RepFIC basic replicon was found in all but one of the IncF group plasmids examined but RepFIA and RepFIB have a more restricted distribution. It appears likely that some plasmids carry vestiges of replicons which still express incompatibility but are incapable of replication. We suggest that evolutionary divergence among the plasmids of the IncF group has resulted from various genetic rearrangements among these basic replicons.     

Plasmids for naphthalene biodegradation incompatible with IncP-2 and IncP-7 group plasmids

Fourteen conjugative naphthalene degradative plasmids have been classified by incompatibility. It is shown that the plasmids of IncP-9 group are characterized by the minor entry exclusion, with respect to the R plasmids belonging to IncP-2 or IncP-7 groups. On the other hand, the naphthalene degradative plasmids of incompatibility group P-7 exhibit a markedly pronounced entry exclusion, with respect to the R plasmids of the same incompatibility groups. Two naphthalene degradative plasmids reveal incompatibility with the reference plasmids of two Inc groups (P-2 and P-7). These plasmids control also resistance of bacterial cells to potassium tellurite, which is characteristic of the IncP-2 plasmids. Two other naphthalene degradative plasmids are capable of stable coexistence with the IncP-2, P-7 or P-9 reference plasmids.     

Detection and characterization of broad-host-range plasmids in environmental bacteria by PCR.

Primer systems for PCR amplification of different replicon-specific DNA regions were designed on the basis of published sequences for plasmids belonging to the incompatibility (Inc) groups IncP, IncN, IncW, and IncQ. The specificities of these primer systems for the respective Inc groups were tested with a collection of reference plasmids belonging to 21 different Inc groups. Almost all primer systems were found to be highly specific for the reference plasmid for which they were designed. In addition, the primers were tested with plasmids which had previously been grouped by traditional incompatibility testing to the IncN, IncW, IncP, or IncQ group. All IncQ plasmids gave PCR products with the IncQ primer systems tested. However, PCR products were obtained for only some of the IncN, IncP, and IncW group plasmids. Dot blot and Southern blot analyses of the plasmids revealed that PCR-negative plasmids also failed to hybridize with probes derived from the reference plasmids. The results indicated that plasmids assigned to the same Inc group by traditional methods might be partially or completely different from their respective reference plasmids at the DNA level. With a few exceptions, all plasmids related to the reference plasmid at the DNA level also reacted with the primer systems tested. PCR amplification of total DNA extracted directly from different soil and manure slurry samples revealed the prevalence of IncQ- and IncP-specific sequences in several of these samples. In contrast, IncN- and IncW-specific sequences were detected mainly in DNA obtained from manure slurries.     

Characterization of pRAS1-like plasmids from atypical North American psychrophilic Aeromonas salmonicida

Atypical psychrophilic Aeromonas salmonicida isolates were obtained from farmed and wild fish in Northeastern North America. These bacteria were isolated between 1992 and 2001 and carried tetracycline resistance (Tc(r)) plasmids of approximately 58 kb. The nine isolates had plasmids which could be divided into four groups based on the specific tetracycline resistance (tet) gene carried [tet(A) or tet(B)], incompatibility of the plasmid [IncU or other], whether the plasmid carried the IS6100 sequences, the sul1 gene, coding for sulfonamide resistance, the dfrA16 gene, coding for trimethoprim resistance, and/or carried a complete Tn1721, and their ability to transfer their Tc(r) plasmids to an Escherichia coli recipient at 15 degrees C. Five of the isolates, with genetically related Tc(r) plasmids, were able to transfer their plasmids to an E. coli recipient at frequencies ranging from 5.7x10(-4) to 2.8x10(-6) per recipient. The 1992 isolate carried a genetically distinct plasmid, which transferred at a slightly higher rate. The three remaining isolates carried one of two genetically different plasmids, which were unable to transfer to an E. coli recipient. Conjugal transfer at 15 degrees C is the lowest temperature that has been documented in bacteria.     

Second replicon in ColV2-K94 mediates the stable coexistence of two incompatible plasmids.

The colicin-producing plasmid pWS12, a Tn903 derivative of ColV2-K94, was found to be incompatible with the IncFI plasmids KLF1 and R386. It was compatible with the IncFII plasmids R538 and R100. Three overlapping mini-ColV derivatives, pWS15, pWS16 and pWS17, were obtained by restriction digestion of pWS12. Unlike pWS12, pWS16 exhibited incompatibility with both IncFI and IncFII plasmids, whereas the pWS15 and pWS17 plasmids expressed IncFII incompatibility but not the IncFI incompatibility of their parental ColV plasmid. We show that, although pWS12 has an IncFII replicon, Rep1, it does not normally express IncFII incompatibility because a second replicon, Rep2 (homologous to the secondary replicon of F), functions during the stable coexistence of the plasmid with IncFII plasmids. When Rep2 is deleted (as in the mini-ColV plasmids) or made nonfunctional (as in a PolA mutant strain), ColV then behaves as an IncFII plasmid.     

Evidence that IncG (IncP-6) and IncU plasmids form a single incompatibility group

The Escherichia coli IncG and IncU plasmid incompatibility groups were assigned in 1980 and 1981, respectively. Complete plasmid sequences have recently been published for both these groups, and revealed that their replication proteins are related. We show that when cloned at high-copy-number, putative iterons from the previously identified IncG replicon cause strong incompatibility with IncU plasmids. Incompatibility, albeit weaker, was also demonstrated between the two replicons at their normal low-copy-number. This suggests that a single incompatibility group exists. The only known IncG plasmid, Rms149, can replicate in Pseudomonas species where it is designated IncP-6. We recommend that the combined group be known as IncU (IncP-6 in Pseudomonas spp.).     

Spread and survival of promiscuous IncP-1 plasmids

Plasmids classified to the IncP-1 incompatibility group belong to the most stably maintained mobile elements among low copy number plasmids known to date. The remarkable persistence is achieved by various tightly controlled stability mechanisms like active partitioning, efficient conjugative transfer system, killing of plasmid-free segregants and multimer resolution. The unique feature of IncP-1 plasmids is the central control operon coding for global regulators which control the expression of genes involved in vegetative replication, stable maintenance and conjugative transfer. The multivalent regulatory network provides means for coordinated expression of all plasmid functions. The current state of knowledge about two fully sequenced plasmids RK2 and R751, representatives of the IncP-1alpha and IncP-1beta subgroups, is presented.     

The use of mini-Gal plasmids for rapid incompatibility grouping of conjugative R plasmids

The galactose operon of Escherichia coli K-12 has been used as a phenotypic marker for miniplasmids derived in vitro from R plasmids representing six incompatibility groups. This has enabled the development of a rapid incompatibility typing scheme in which the miniplasmids are used as incompatibility exemplars, their presence in strains being monitored on galactose fermentation indicator media.     

Inhibition and facilitation of transfer among Pseudomonas aeruginos R plasmids.

Esamining 12 plasmids in Pseudomonas aeruginosa, we found two types of interaction in their transfer (inhibition and facilitation), using donor cells carrying two compatible plasmids. (i) Ten plasmids representing incompatibility groups P-1, P-2, P-5, P-6, and P-7 were all transmissible at a high frequency, 10-2 to 10-1, except for one with a lower frequency of about 10-3. The transfer of P-5 plasmids was inhibited by P-2 plasmids reciprocally or unilaterally, and the unilateral transfer inhibition was observed in other combinations between plasmids belonging to groups P-1, P-2, P-6, and P-7. It was characteristic of Pseudomonas plasmids that most plasmids with high transferability inhibited the transfer of other coexisting plasmids without distinct inhibition of their own transfer. (ii) Two plasmids, Rms149 of P-8 group and Rlb679, which was not classified, were transmissible at an exceptionally low frequency of 10-7 to 10-6, but their transfer was facilitated by plasmids with high transferability.     

New incompatibility groups for Staphylococcus aureus plasmids

Incompatibility relationships between naturally occurring staphylococcal plasmids conferring erythromycin or kanamycin resistance have been studied making use of recombinants between these plasmids and pSA0301, a temperature-sensitive mutant plasmid determining tetracycline resistance. The four plasmids encoding kanamycin resistance fall in two incompatibility groups; similarly, the three plasmids responsible for erythromycin resistance belong to two other incompatibility groups. This brings the number of distinct incompatibility groups reported for Staphylococcus aureus plasmids to 13.     

Diversity of Pseudomonas plasmids: To what extent?

Results obtained in studies of the biology of Pseudomonas plasmids are presented here as a mini-review. These data indicate that plasmids are ubiquitous in Pseudomonas, but the frequency of their occurrence varies greatly in particular species, or groups of species and in different microbial habitats. Some species of Pseudomonas, for instance P. aeruginosa, possess great diversity of plasmids both from the viewpoint of their incompatibility properties and their ability to endow bacteria with additional features such as resistance to antibiotics or heavy metals, degradation of xenobiotics or inhibition of phage development.     

Incidence of the H2 group of plasmids in chloramphenicol-sensitive salmonella isolated in 1974 from clinical sources in Ontario.

Chloramphenicol resistance in salmonella obtained from clinical sources in Ontario was previously found to be often mediated by R plasmids of the H2 incompatibility group. In the present study 40 salmonella strains resistant to one or more of kanamycin, streptomycin, sulfonamides, or tetracycline but sensitive to chloramphenicol, were investigated to determine if they contained R plasmids. Self-transmissible plasmids were isolated from 17 of the strains, and 7 of those showed the bacteriophage inhibition and thermosensitive mechanism of transfer characteristic of H2 plasmids. Entry exclusion and incompatibility experiments confiremd their classification. The results demonstrate that in this population of salmonella, R plasmids of the H2 group are prevalent. Experiments with plasmid-specific phages indicate that the plasmids of this sample, which are not in the H2 group, do not belong to any of the F, I, N, P, or W incompatibility groups.     

The molecular relatedness among alpha-hemolytic plasmids from various incompatibility groups

Deoxyribonucleic acid (DNA) reassociation studies among α-hemolytic (Hly) plasmids from FVI and FIII–IV incompatibility groups showed a close similarity between the nucleotide sequences of plasmids from the same group. With respect to R plasmids from the F overgroup, they have 20–26 Mdal in common, an amount of DNA close to the amount involved in the traF operon. No more extensive sequence homology was found between pSU316 (IncFIII–IV) and the incompatible plasmids ColB-K98 (IncFIII) or R124 (IncFIV). The IncIα I2 plasmid pSU5 has only the α-hemolytic region (5 Mdal) in common with plasmid pSU316 but it is much more closely related to IncFVI plasmids where the DNA in common amounts to 22 Mdal. Finally, the genetically unrelated plasmid pSU233 shares 66% of its nucleotide sequences (40 Mdal) with the IncFVI plasmids and has 16–23 Mdal in common with various F-like plasmids.     

The distribution of beta-lactamase genes on plasmids found in Pseudomonas.

Seven types of β-lactamases distinguished by analytic isoelectric focusing have been found on 24 Pseudomonas plasmids belonging to at least eight incompatibility groups. TEM-1- and TEM-2-type enzymes that are determined by transposable genetic elements are distributed among five different incompatibility groups. The other β-lactamase types are found on plasmids in single incompatibility groups. β-Lactamases unique to Pseudomonas plasmids occur on plasmids not transmissible to enterobacteria by conjugation.     

Incompatibility and transforming efficiency of ColE1 and related plasmids

Summary Replicons derived from the ColE1 plasmid are incompatible with one another, but are compatible with their naturally occurring relatives ColK and CloDF13. The incompatibility results in loss, by segregation, of one or the other ColE1 plasmid. In most cases, the smaller derivatives tend to displace the larger ones, and the rate of displacement depends on the difference in size. One mini-plasmid retains only 19% of the sequences of ColE1, yet it exrrts strong incompatibility: other ColE1 plasmids are rapidly lost when it is introduced into the host. The region essential for ColE1 incompatibility is deduced to lie within 700 base pairs of the origin of replication.The transforming efficiency of any ColE1 plasmid is markedly lowered when another incompatible replicon is resident in the competent cells, even when the transforming plasmid is much smaller than the resident.A model of incompatibility is proposed to account for these effects.     

Salmonella plasmids of the pre-antibiotic era.

In order to provide a profile of the plasmid gene pool in Salmonella prior to the clinical use of antibiotics, a molecular genetic analysis was made of plasmids in strains collected by E.D.G. Murray between 1917 and 1954. These pre-antibiotic era (PAE) salmonellae contain conjugative plasmids of the same incompatibility groups as contemporary enterobacterial plasmids. Upon analysis of total plasmid content, 42 plasmids, sized between 23 and 72 MDa, were found. We defined and investigated six groups of these PAE Salmonella plasmids in terms of three groups of genes; those involved in plasmid maintenance and incompatibility, DNA repair and virulence. Of the five groups, three were replicon-typed to groups IncI1, IncX and IncFII; one group exhibited no homology to contemporary Inc/Rep probes, and one group represented virulence plasmids containing a common plasmid-partitioning locus. The results indicated that most of the PAE groups were progenitors of contemporary R-plasmids, except for the virulence plasmids, which have generally not evolved as vectors of antibiotic resistance.     

Homology among nearly all plasmids infecting three Bacillus species.

We have surveyed naturally occurring plasmids in strains of Bacillus subtilis and the closely related species B. mojavensis and B. licheniformis. Previous studies have failed to find host-benefitting functions for plasmids of these species, suggesting that these plasmids are nonmutualistic. Only one type of plasmid was found in each plasmid-bearing strain, suggesting that most of the plasmids infecting these Bacillus species are in the same incompatibility group. A sample of 18 plasmids from these species ranged in size from 6.9 to 16 kb, with all but 6 plasmids falling into three size groups. These groups differed in the sizes of their host ranges and geographical ranges. All but 1 of the 18 plasmids from these three host species are homologous with one another. The cryptic plasmids from these three species are far less diverse than are plasmids (from other species) that are known to benefit their bacterial hosts. The low-level diversity among these cryptic plasmids is consistent with the hypothesis that host-benefitting adaptations play an important role in fostering the coexistence of plasmid populations, but other explanations for the low-level plasmid diversity are possible. Comparison of the phylogenies of the plasmids with those of their hosts suggests that Bacillus plasmids are horizontally transferred in nature at a low rate similar to that found for the colicin plasmids of Escherichia coli.