Cloning and analysis of the Clostridium perfringens tetracycline resistance plasmid, pCW3

Clostridium perfringens strain CW92 carries pCW3, a conjugative 47-kb plasmid that confers inducible resistance to tetracycline. The plasmid was examined by restriction endonuclease analysis and by cloning each of the five ClaI fragments of pCW3 in Escherichia coli, using pBR322. Analysis of the recombinant plasmids allowed the deduction of a detailed restriction map of pCW3. The tetracycline resistance determinant of pCW3 was mapped by examining the phenotype of recombinant E. coli clones derived from the cloning, into pUC vector plasmids, of EcoRI fragments from pCW3. The C. perfringens tetracycline resistance determinant was expressed in E. coli and was shown to be located on two juxtaposed EcoRI fragments which together encompass a 4-kb region of pCW3. Deletion experiments showed that the tetracycline resistance gene, and/or its control regions, contained internal EcoRI and SphI sites. E. coli strains that carried recombinant plasmids with only the 4-kb region were found to express tetracycline resistance constitutively. In contrast, recombinant plasmids harboring a 10.5-kb ClaI fragment of pCW3, that included the 4-kb region, coded for an inducible tetracycline resistance phenotype. The existence of a negatively regulated resistance gene, similar to that proposed for several other bacteria is postulated.     

Worldwide distribution of the conjugative Clostridium perfringens tetracycline resistance plasmid, pCW3

The aim of this study was to test the hypothesis that all conjugative R-plasmids of Clostridium perfringens are closely related to the previously characterized tetracycline resistance plasmid, pCW3. Fourteen conjugative R-plasmids derived from 11 C. perfringens strains isolated in Australia, the United States, France, Belgium, and Japan were analyzed. Eleven of the plasmids encoded tetracycline resistance while three carried both tetracycline and chloramphenicol resistance. Each of these plasmids was compared, by restriction analysis, to the reference plasmid, pCW3. Seven of the tetracycline resistance plasmids had EcoRI, XbaI, and ClaI restriction profiles that were identical to those of the corresponding pCW3 digests. The seven remaining R-plasmids were different from pCW3. Comparison of partial restriction maps of these plasmids with a complete map of pCW3 indicated that they contained at least 17 kb of DNA that also was present in pCW3. Hybridization analysis confirmed that these plasmids shared substantial homology with pCW3. The three tetracycline and chloramphenicol resistance plasmids frequently lost a 6-kb chloramphenicol resistance segment during conjugation. Cloning experiments showed that the chloramphenicol resistance determinant was expressed in Escherichia coli and that the chloramphenicol resistance gene of one of these plasmids, pIP401, was contained within a 1.5-kb region of the 6-kb deletion segment. Hybridization analysis indicated that the deletion segment of pIP401 was related to those of the other two chloramphenicol resistance plasmids. During the course of this study, conjugative R-plasmids which appear to be identical to pCW3 or closely related to pCW3 were identified from C. perfringens strains from human, animal and environmental sources in five countries. It is concluded that C. perfringens strains in humans and animals throughout the world have overlapping gene pools and that all the conjugative C. perfringens R-plasmids examined probably evolved from a pCW3-like element.     

Hybridization analysis of the class P tetracycline resistance determinant from the Clostridium perfringens R-plasmid, pCW3

The tetracycline resistance determinant from pCW3, a conjugative plasmid from Clostridium perfringens, has been identified and the structural gene localized to within a 1.4-kb region. Hybridization analysis, which utilized an internal 0.8-kb specific gene probe, showed that eight nonconjugative tetracycline resistant C. perfringens strains all carried homologous resistance determinants. No homology was detected in DNA prepared from tetracycline resistant isolates of Clostridium difficile or Clostridium sporogenes. However, the one strain of Clostridium paraputrificum that was tested did contain an homologous determinant. No homology was found to any of the recognized classes of tetracycline resistance determinants. The C. perfringens tetracycline resistance determinant represents a new hybridization group, Class P.     

Identification of a transferable tetracycline resistance plasmid (pCW3) from Clostridium perfringens

A tetracycline- and chloramphenicol-resistant strain of Clostridium perfringens, CW92, was shown to carry two plasmids, pCW2 and pCW3. Twenty-four independently derived tetracycline-sensitive mutants were isolated using a variety of curing agents. All were missing pCW3 but still carried pCW2. Tetracycline resistance could be transferred to a sensitive recipient strain by what appears to be a conjugation-like process. The efficiency of transfer was 2.8 × 10⁻⁵ transcipients per viable donor cell after a 20-h mating. The transcipients transferred tetracycline resistance at a similar frequency. Ten independently derived tetracycline-resistant transcipients all carried pCW3 as shown by agarose gel electrophoresis. The identity of this plasmid in one of these strains was confirmed by electron microscopy and restriction endonuclease analysis. Therefore, pCW3 (30.6 megadaltons) is a transferable tetracycline-resistance plasmid. No chloramphenicol-sensitive mutants or chloramphenicol-resistant transcipients were isolated. Therefore, pCW2 (36.4 megadaltons) remains cryptic.     

Molecular analysis of transferable tetracycline resistance plasmids from Clostridium perfringens.

Conjugative tetracycline resistance plasmids from 15 Clostridium perfringens isolates from piggeries were analyzed by restriction endonuclease digestion and agarose gel electrophoresis. Seven isolates from one farm were found to carry a 47-kilobase pair (kb) plasmid, pJIR5, which had EcoRI, XbaI, and ClaI profiles that were identical to those of a previously characterized plasmid, pCW3. An isolate from a second farm was found to carry a plasmid, pJIR6, which also was indistinguishable from pCW3. Five additional isolates from a third farm carried a 67-kb plasmid, pJIR2, which had at least 29 kb of DNA in common with pCW3. Finally, two isolates from a fourth farm were found to carry a 50-kb plasmid pJIR4, which appeared to consist of an entire pCW3 molecule with a 3-kb insertion. Comparative restriction maps of pCW3, pJIR2, and pJIR4 that identified the regions of homology among these plasmids were constructed. We suggest that many conjugative tetracycline resistance plasmids in C. perfringens may contain a pCW3-like core.     

TcpA, an FtsK/SpoIIIE homolog, is essential for transfer of the conjugative plasmid pCW3 in Clostridium perfringens

The conjugative tetracycline resistance plasmid pCW3 is the paradigm conjugative plasmid in the anaerobic gram-positive pathogen Clostridium perfringens. Two closely related FtsK/SpoIIIE homologs, TcpA and TcpB, are encoded on pCW3, which is significant since FtsK domains are found in coupling proteins of gram-negative conjugation systems. To develop an understanding of the mechanism of conjugative transfer in C. perfringens, we determined the role of these proteins in the conjugation process. Mutation and complementation analysis was used to show that the tcpA gene was essential for the conjugative transfer of pCW3 and that the tcpB gene was not required for transfer. Furthermore, complementation of a pCW3DeltatcpA mutant with divergent tcpA homologs provided experimental evidence that all of the known conjugative plasmids from C. perfringens use a similar transfer mechanism. Functional genetic analysis of the TcpA protein established the essential role in conjugative transfer of its Walker A and Walker B ATP-binding motifs and its FtsK-like RAAG motif. It is postulated that TcpA is the essential DNA translocase or coupling protein encoded by pCW3 and as such represents a key component of the unique conjugation process in C. perfringens.     

Functional identification of conjugation and replication regions of the tetracycline resistance plasmid pCW3 from Clostridium perfringens

Clostridium perfringens causes fatal human infections, such as gas gangrene, as well as gastrointestinal diseases in both humans and animals. Detailed molecular analysis of the tetracycline resistance plasmid pCW3 from C. perfringens has shown that it represents the prototype of a unique family of conjugative antibiotic resistance and virulence plasmids. We have identified the pCW3 replication region by deletion and transposon mutagenesis and showed that the essential rep gene encoded a basic protein with no similarity to any known plasmid replication proteins. An 11-gene conjugation locus containing 5 genes that encoded putative proteins with similarity to proteins from the conjugative transposon Tn916 was identified, although the genes' genetic arrangements were different. Functional genetic studies demonstrated that two of the genes in this transfer clostridial plasmid (tcp) locus, tcpF and tcpH, were essential for the conjugative transfer of pCW3, and comparative analysis confirmed that the tcp locus was not confined to pCW3. The conjugation region was present on all known conjugative plasmids from C. perfringens, including an enterotoxin plasmid and other toxin plasmids. These results have significant implications for plasmid evolution, as they provide evidence that a nonreplicating Tn916-like element can evolve to become the conjugation locus of replicating plasmids that carry major virulence genes or antibiotic resistance determinants.     

Transferable tetracycline resistance in Clostridium perfringens strains of porcine origin

These studies represent the first systematic survey of the incidence of conjugative antibiotic resistance in Clostridium perfringens. Ninety-two antibiotic-resistant porcine strains were examined to see if they could donate their antibiotic-resistance determinants to sensitive recipient strains. Fifteen of the 89 tetracycline-resistant strains transferred their tetracycline resistance in mixed-plate mating experiments but no transfer of macrolide-lincosamide resistance was detected. The efficiencies of transfer of tetracycline resistance varied from 1.3 X 10(-3) to 1.9 X 10(-6) transconjugants per donor cell. Significantly higher transfer efficiencies were observed when both the donor and recipient strains were derivatives of strain CW 362. These values ranged from 3.7 X 10(-1) to 4.6 X 10(-2) transconjugants per donor cell. This high frequency transfer system should prove invaluable for further genetic studies on this microorganism.     

Repression of nitrogen fixation in Klebsiella pneumoniae at high temperature

Clostridium perfringens 11268 CDR (Rifr Tcs), the strain transformed in our experiments, was generated by curing a spontaneous, rifampicin-resistant mutant of C. perfringens 11268 (Rifr Tcr). High-temperature growth yielded tetracycline-sensitive, rifampicin-resistant cells which no longer contained pCW3, a 42.8-kilobase plasmid. The tetracycline-sensitive, rod-shaped cell was then converted to an L-phase variant by growth in the presence of penicillin G (10 micrograms/ml) and 0.4 M sucrose. After several passages, the antibiotic was removed from the medium, and cells continued to grow as L-phase variants. Another large plasmid, pJU124 (38.8 kilobases), which confers tetracycline resistance, was used for transformation. Transformation of L-phase variants of C. perfringens 11268 CDR (Rifr Tcs) was mediated by polyethylene glycol. Transformation frequency is a nonlinear function of DNA concentration. Restriction analysis showed that the plasmid isolated from the transformants was identical to that supplied. Stable L-phase variants do not revert to rod-shaped cells, but autoplasts can be both transformed and reverted.     

The peptidoglycan hydrolase TcpG is required for efficient conjugative transfer of pCW3 in Clostridium perfringens

Peptidoglycan hydrolases that are specifically associated with bacterial conjugation systems are postulated to facilitate the assembly of the transfer apparatus by creating a temporally and spatially controlled local opening in the peptidoglycan layer. To date little is known about the role of such enzymes in conjugation systems from Gram-positive bacteria. Conjugative plasmids from the Gram-positive pathogen Clostridium perfringens all encode two putative peptidoglycan hydrolases, TcpG and TcpI, within the conserved tcp transfer locus. Mutation and complementation analysis was used to demonstrate that a functional tcpG gene, but not the tcpI gene, was required for efficient conjugative transfer of pCW3. Furthermore, it was also shown that each of the two predicted catalytic domains of TcpG was functional in C. perfringens and that the predicted catalytic site residues, E-111, D-136, and C-238, present within these functional domains were required for optimal TcpG function. Escherichia coli cells producing TcpG demonstrated a distinctive autoagglutination phenotype and partially purified recombinant TcpG protein was shown to have peptidoglycan hydrolase-like activity on cognate peptidoglycan from C. perfringens. Based on these results it is suggested that TcpG is a functional peptidoglycan hydrolase that is required for efficient conjugative transfer of pCW3, presumably by facilitating the penetration of the pCW3 translocation complex through the cell wall.     

Induction of chloramphenicol and tetracycline resistance in Flexibacter sp. strain FS-1.

The gliding bacterium Flexibacter sp. strain FS-1 exhibits inducible resistance to chloramphenicol (Cmr) and tetracycline (Tcr). Either chloramphenicol or tetracycline alone induced a Cmr Tcr phenotype. The resistance is apparently not plasmid encoded.     

Characterization and construction of molecular cloning vehicles within Staphylococcus aureus.

Four chloramphenicol resistance (Cm) and four tetracycline resistance (Tc) plasmids from Staphylococcus aureus were characterized by restriction endonuclease mapping. All four Tc plasmids had molecular masses of 2.9 megadaltons (Mdaltons) and indistinguishable responses to seven different restriction endonucleases. The four Cm plasmids (pCW6, pCW7, pCW8, and pC221) had molecular masses of 2.6, 2.8, 1.9, and 2.9 Mdaltons, respectively. The four Cm plasmids also differed both in the level of resistance to Cm and in susceptibility to retriction endonucleases. Single restriction endonuclease sites contained within each plasmid included the following: in pCW6 for HindIII, XbaI, HpaII, and BstEII; in pCW7 for HindIII, BstEII, BglII, HaeIII, and HpaII; in pCW8 for HindIII, HaeIII, and HpaII; in pC221 for HindIII, BstEII, and EcoRI. The molecular cloning capabilities of pCW8 and pC221 were determined. Cm and erythromycin resistance (Em) recombinant plasmids pCW12, PCW13, and pCW14 were constructed and used to transform S. aureus 8325-4. A 2.8-Mdalton HindIII fragment from plasmid pI258 was found to encode Em resistance and contain single sites for the retriction endonucleases BglII, PstI, HaeIII, and HpaII. The largest EcoRI fragment (8 Mdaltons) from pI258 contained the HindIII fragment encoding Em resistance intact. Cloning of DNA into the BglII site of pCW14 did not alter Em resistance. Cloning of DNA into the HindIII site of pCW8 and the HindIII and EcoRI sites of pC221 did not disrupt either plasmid replication of Cm resistance.     

Two Novel Membrane Proteins,TcpD and TcpE,Are Essential for Conjugative Transfer of pCW3 in Clostridium perfringens

The anaerobic pathogen Clostridium perfringens encodes either toxin genes or antibiotic resistance determinants on a unique family of conjugative plasmids that have a novel conjugation region, the tcp locus. Studies of the paradigm conjugative plasmid from C. perfringens, the 47-kb tetracycline resistance plasmid pCW3, have identified several tcp-encoded proteins that are involved in conjugative transfer and form part of the transfer apparatus. In this study, the role of the conserved hypothetical proteins TcpD, TcpE, and TcpJ was examined. Mutation and complementation analyses showed that TcpD and TcpE were essential for the conjugative transfer of pCW3, whereas TcpJ was not required. To analyze the TcpD and TcpE proteins in C. perfringens, functional hemagglutinin (HA)-tagged derivatives were constructed. Western blots showed that TcpD and TcpE localized to the cell envelope fraction independently of the presence of other pCW3-encoded proteins. Finally, examination of the subcellular localization of TcpD and TcpE by immunofluorescence showed that these proteins were concentrated at both poles of C. perfringens donor cells, where they are postulated to form essential components of the multiprotein complex that comprises the transfer apparatus.     

Tetracycline-inducible transfer of tetracycline resistance in Bacteroides fragilis in the absence of detectable plasmid DNA.

Tetracycline resistance of three Bacteroides fragilis strains was shown to be inducible by subinhibitory concentrations of tetracycline. Tetracycline resistance markers could be transferred to another B. fragilis strain by filter mating. The transferability was inducible by subinhibitory concentrations of tetracycline and did not take place in the absence of tetracycline. The optimum concentration of tetracycline for induction of transfer was about 2 microgram/ml. The transfer was shown to be a conjugation-like process requiring cell-to-cell contact between donor and recipient. Screening of parental donor strains for the presence of plasmid DNA did not demonstrate any detectable plasmids in two of the strains. A 3.0-megadalton plasmid, designated pBY5, was present in the third donor strain. Mobilization of pBY5 by another plasmid (pBF4) showed that pBY5 did not carry the genes responsible for tetracycline resistance. It appears that the genes responsible for resistance to tetracycline as well as those responsible for conjugal transfer may be carried on the chromosome in all three donor strains.     

Transmission of the R-plasmids and expression of their genes in Proteus mirabilis]

Resistance markers to individual antibiotics are transmitted in E. coli with the same frequency in the shape of a uniform linkage group, and in Proteus mirabilis--with a different one. Possibly in Proteus mirabilis plasmide R6 dissociated, this being expressed in a different incidence of transconjugates, characterized by a different set of antibiotic resistance genes. Tetracyclin resistance gene can be transmitted in P. mirabilis without being bound with other resistance determinants and with the functioning Tra-operon. The expression of individual antibiotic resistance genes of plasmide R6 in P. mirabilis differed, i.e. tetracycline resistance was inducible, and to kanamycin and chloramphenicol--constitutional. The level of expression of the gene controlling the tetracycline resistance was in noninduced condition in P. mirabilis, lower than in E. coli, P. mirabilis containing no R-factor possessed an inducible resistance mechanism to tetracycline, as in case of P. mirabilis strains containing R-factors.     

Two independent conjugal transfer systems operating in Bacteroides fragilis V479-1.

Bacteroides fragilis V479-1 (also designated strain 92) has previously been shown to contain a conjugative plasmid, pBF4, that specifies resistance to clindamycin (Cc). A report of inducible tetracycline (Tc) resistance in this strain suggested that this phenotype was also plasmid associated (G. Privitera et al., Nature [London] 278:657-659, 1979) and prompted further investigation. Mating experiments with V469-1 and a Cc-sensitive derivative of V479-1, V598, showed that Tc resistance transfer occurred by a conjugation-like event which was insensitive to DNase, was not mediated by donor culture cell-free filtrates, and required cell-to-cell contact. Results from transfer experiments with V479-1 indicated that Tc and Cc resistance determinants were not linked and segregated independently in matings. Progeny recovered from matings with the V479-1 or V598 donor strain were able to transfer the Tc resistance marker in secondary crosses. Tc resistance transfer from V479-1 or V598 was greatly stimulated by pregrowth in the presence of Tc but not Cc. pBF4-mediated Cc resistance transfer was not affected by pregrowth in the presence of Cc or Tc. Filter blot DNA hybridization studies revealed that pBF4 sequences were not involved in either the Tc resistant phenotype or its associated conjugal transfer properties. The Tc resistance transfer element was not associated with pBF4 or any other extrachromosomal DNA element.     

Transformation of Clostridium perfringens L forms with shuttle plasmid DNA

L-form (L-phase) cultures of Clostridium perfringens were tested for their transformability with plasmid DNA. Three L-form strains were transformable, but one, strain L-13, was superior to the others. This strain was easily and reproducibly transformed with previously described shuttle vectors which were derived from either C. perfringens or Escherichia coli. Strain L-13 was transformable by a variety of methods, and a new micromethod worked well under both aerobic and anaerobic conditions. The maximal number of transformants was attained after strain L-13 was exposed for 4 h to the transforming DNA and polyethylene glycol. Viable counts determined in tubes of semisolid brain heart infusion medium containing 10% sucrose, with or without 2 micrograms of tetracycline per ml, showed a transformation rate of 3.9 X 10(-5) (transformants per viable cells).