Clostridium perfringens enterotoxin (encoded by the cpe gene) contributes to several important human, and possibly veterinary, enteric diseases. The current study investigated whether cpe locus organization in type C or D isolates resembles one of the three (one chromosomal and two plasmid-borne) cpe loci commonly found amongst type A isolates. Multiplex PCR assays capable of detecting sequences in those type A cpe loci failed to amplify products from cpe-positive type C and D isolates, indicating these isolates possess different cpe locus arrangements. Therefore, restriction fragments containing the cpe gene were cloned and sequenced from two type C isolates and one type D isolate. The obtained cpe locus sequences were then used to construct an overlapping PCR assay to assess cpe locus diversity amongst other cpe-positive type C and D isolates. All seven surveyed cpe-positive type C isolates had a plasmid-borne cpe locus partially resembling the cpe locus of type A isolates carrying a chromosomal cpe gene. In contrast, all eight type D isolates shared the same plasmid-borne cpe locus, which differed substantially from the cpe locus present in other C. perfringens by containing two copies of an ORF with 67% identity to a transposase gene (COG4644) found in Tn1546, but not previously associated with the cpe gene. These results identify greater diversity amongst cpe locus organization than previously appreciated, providing new insights into cpe locus evolution. Finally, evidence for cpe gene mobilization was found for both type C and D isolates, which could explain their cpe plasmid diversity.
Citation: Li J, Miyamoto K, Sayeed S, McClane BA (2010) Organization of the cpe Locus in CPE-Positive Clostridium perfringens Type C and D Isolates. PLoS ONE 5(6): e10932. https://doi.org/10.1371/journal.pone.0010932
Editor: David M. Ojcius, University of California Merced, United States of America
Received: April 1, 2010; Accepted: May 7, 2010; Published: June 3, 2010
Copyright: © 2010 Li et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This research was generously supported by grants R37-AI19844-27 and R01-AI05617706 from the National Institute of Allergy and Infectious Diseases. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Clostridium perfringens is an important pathogen of humans and domestic animals. The virulence of this organism is largely attributable to its producing at least 16 different potent toxins, although individual C. perfringens isolates never express this entire toxin arsenal , . This characteristic is exploited by a commonly-used classification system assigning C. perfringens isolates to one of five types (A–E) based upon their production of four typing toxins. While all C. perfringens types make alpha toxin, type B isolates also express both epsilon toxin and beta toxin, type C isolates also produce beta toxin, type D isolates also make epsilon toxin and type E isolates also express iota toxin , .
Besides those typing toxins, C. perfringens isolates often produce one or more additional toxins. Notably, about 1–5% of all C. perfringens isolates produce a toxin named C. perfringens enterotoxin (CPE) , . When expressed by type A isolates, CPE causes the gastrointestinal symptoms of the second most commonly-identified bacterial foodborne illness in the USA, ranking only behind Salmonella gastroenteritis , , . About 75–80% of all type A food poisoning isolates carry their enterotoxin gene (cpe) on the chromosome , , , , , . The chromosomal cpe locus present in most type A food poisoning isolates is highly conserved and includes an upstream IS1469 sequence and flanking IS1470 sequences , .
CPE-producing type A isolates also cause nonfoodborne human gastrointestinal (GI) diseases such as sporadic diarrhea or antibiotic associated diarrhea , . Those type A nonfoodborne human GI disease isolates typically possess a plasmid-borne cpe gene , . Two cpe plasmid families have been identified amongst most cpe-positive type A isolates , although rare type A soil isolates carry atypical cpe plasmids that have not yet been characterized . The two major cpe plasmid families share a conserved region, corresponding to ∼50% of each plasmid , that includes a tcp locus closely resembling the tcp locus proven to mediate the conjugative transfer of C. perfringens tetracycline resistance plasmid pCW3 . Carriage of this tcp locus likely explains the demonstrated conjugative transfer of the cpe plasmid from type A isolate F4969 .
The first of the two major cpe plasmid families of type A isolates, represented by the prototype plasmid pCPF5603, includes cpe plasmids that are typically ∼75 kb in size and also carry the cpb2 gene encoding beta2 toxin , . As discussed later, the cpe locus of these pCPF5603-like plasmids includes a cpe gene flanked by an upstream IS1469 sequence and a downstream IS1151 sequence , . The second major cpe plasmid family, represented by the prototype cpe plasmid pCPF4969, includes cpe plasmids that are usually ∼70 kb in size and carry bacteriocin genes, but no cpb2 gene , . The cpe locus in the pCPF4969-like plasmids is flanked by an upstream IS1469 sequence and also contains, rather than the downsteam IS1151 sequence found in the cpe locus of pCPF5603-like plasmids, a IS1470-like sequence downstream of the cpe gene , . Some evidence suggests that the insertion sequences flanking the cpe gene of type A isolates may mobilize these toxin genes via formation of circular transposition intermediates .
Type E isolates typically carry plasmid-borne cpe sequences immediately downstream of their iota toxin genes , , but those cpe sequences are silent. This loss of CPE expression in type E isolates likely involves insertion of a mobile genetic element carrying the iota toxin genes near the cpe promoter, thereby blocking cpe transcription . Flanking IS1151-like sequences present in the iota toxin locus may help to mobilize the iota toxin genes and, sometimes, the adjacent silent cpe sequences of type E isolates . The iota toxin plasmids of type E isolates are often related to the major cpe plasmid families found in type A isolates, suggesting a common evolutionary origin . However, the iota toxin plasmids are very large (>100 kb) due, in part, to their common carriage of lambda toxin genes and urease genes that are missing from cpe plasmids of type A isolates , .
In two recent surveys, ∼15% of 45 type C animal or human isolates and ∼25% of 39 type D animal disease isolates tested cpe-positive , . Many of those isolates were shown to express CPE during sporulation , , which is consistent with suggestions that CPE may, at minimum, contribute to some cases of human enteritis necroticans caused by type C isolates . However, the organization of the cpe locus in these type C and D isolates has not yet been studied. Therefore, the goal of the current study was to explore the relationship, if any, between the cpe locus of cpe-positive type A isolates vs. the cpe locus found in cpe-positive type C and D isolates.
Materials and Methods
Bacterial strains, media, and reagents
This study examined four cpe-positive type A isolates, seven cpe-positive type C isolates, eight cpe-positive type D isolates and two type E isolates carrying cpe sequences, as listed in Table 1. The toxin genotypes of these isolates had been determined previously using a toxin typing gene-specific multiplex PCR assay , . Isolates were stored frozen in cooked-meat medium (Oxoid, Basingstock, England) or glycerol stocks. All isolates were grown overnight at 37°C in either FTG medium (fluid thioglycolate; Difco Laboratories, Michigan) or TGY medium (3% tryptic soy broth [Becton Dickinson and Company, Maryland], 2% glucose, 1% yeast extract [Difco], and 0.1% sodium thioglycolate [Sigma Chemical, Missouri]).
Pulsed-field gel electrophoresis (PFGE) and Southern blot analyses
Plugs of C. perfringens DNA were prepared as described previously , , . Briefly, selected isolates (CN2078, CN5388, CN1183, CN4003, 853, NCIB107481, F5603 and F4969) were grown overnight in FTG broth at 37°C. A 0.1 ml aliquot of each FTG culture was then inoculated into separate 10 ml tubes of TGY broth and grown overnight at 37°C. The overnight TGY cultures were washed with TES buffer, pelleted, and resuspended in 200 µl of TE buffer. A 200 µl aliquot of 2% pulsed-field gel electrophoresis (PFGE)-certified agarose (Bio-Rad Laboratories, California) was then added to the resuspended cells, for a final agarose concentration of 1%.
These plugs were then electrophoresed in a CHEF-DR II PFGE system (Bio-Rad Laboratories) in 0.5× Tris-borate-EDTA buffer (Bio-Rad Laboratiories) at 14°C. The running parameters were: initial pulse, 1 sec; final pulse, 25 sec; voltage, 6 V/cm, 24 h. Mid-Range PFGE markers (New England Biolabs) were used as molecular size markers. After PFGE, the gel was stained with ethidium bromide, washed with distilled water, and photographed.
Digoxigenin (DIG)-labeled cpe probes were constructed, as described previously , , , with a PCR DIG probe synthesis kit (Roche, New Jersey) and internal cpe ORF primers. After hybridization of the cpe probe, performed as described previously , the pulsed-field gel Southern blots were developed using reagents from the DIG labeling and detection kit (Roche).
Multiplex PCR genotyping analysis comparing cpe locus organization in cpe-positive type C or D isolates versus cpe-positive type A isolates
For these multiplex PCR reactions, template DNA was obtained, as described previously , from colony lysates of cpe-positive C. perfringens type A, C, and D isolates or from type E isolates carrying silent cpe sequences. Each PCR mixture contained 2 µl of template DNA, 10 µl of TAQ Complete 2× mix (New England Biolabs), and 1 µl of six multiple primers mix (final concentrations of 1 µM each for primers cpe4F, IS1470R1.3, IS1470-likeR1.6, and IS1151 and 0.2 µM each for primers 3F and 4R). The sequences of these primers have been reported previously . Primers 3F and 4R amplify a product of ∼0.6 kb from internal cpe sequences; primers cpe4F and IS1470-likeR1.6 amplify a product of ∼1.6 kb from the cpe locus containing IS1470-like sequences, as found in pCPF4969-like plasmids of type A isolates; primers cpe4F and IS1151R0.8 amplify a product of ∼0.8 kb from the cpe locus containing IS1151 sequences, as found in pCPF5603-like plasmids of type A isolates; and primers cpe4F and IS1470R1.3 amplify a product of ∼1.3 kb from the chromosomal cpe locus of type A isolates.
Each reaction mixture was subjected to the following PCR amplification conditions: cycle 1, 94°C for 2 min; cycles 2 through 40, 94°C for 30 sec, 61°C for 30 sec, and 68°C for 90 sec; with a final extension for 8 min at 68°C. An aliquot (20 µl) of each PCR sample was electrophoresed on a 1.5% agarose gel and then visualized by staining with ethidium bromide.
Restriction fragment length polymorphism (RFLP) Southern blot analyses
Using the MasterPure gram-positive DNA purification kit (Epicentre, Wisconsin), C. perfringens DNA was isolated from cpe-positive type A strains F4969, F5603, SM101 and NCTC8239; cpe-positive type C strains CN3758, CN3753, and CN5388; cpe-positive type D strains CN1183, CN3842, CN4003, CN3948, JGS1902 and JGS4152; or silent cpe sequence-carrying type E strain NCIB10748. Each isolated DNA sample was then digested overnight with XbaI according to the manufacturer's (New England Biolabs) instructions. The digested DNA samples were electrophoresed on a conventional 1% agarose gel. The separated DNA digestion products were then transferred onto a nylon membrane (Roche) for hybridization with a cpe probe, as described above.
Sequencing of the cpe ORF in representative type C and D strains
DNA was isolated from cpe-positive type C strains CN2078 and CN5388, or from cpe-positive type D strains JGS1902, JGS4139, CN1183, and CN4003, using the Master-Pure gram-positive DNA purification kit (Epicentre). PCR was then performed using Taq DNA polymerase from New England Biolabs and primers cpeF (5′-atgcttagtaacaatttaaatc-3′) and cpeR (5′-ttaaaatttttgaaataatattg -3′). The PCR reaction was performed in a Techne thermocycler (Techne, Germany) using the following conditions: 94°C for 2 min; 35 cycles of 94°C for 30 sec, 55°C for 40 sec, and 68°C for 1 min; with a single extension at 68°C for 5 min. The resultant 960 bp PCR products were then cloned into Topo® 2.1 vector (Invitrogen, California), and this insert was then sequenced at the University of Pittsburgh Core Sequencing facility. Results from these sequencing analyses are located in GenBank under accession numbers GQ225713, GQ225714, GQ225715, GQ225717, GQ225718, and GQ225719.
Sequencing of the cpe-carrying XbaI fragments in type C and D isolates
DNA was isolated from cpe-positive type C strains CN2078 and CN5388, or from cpe-positive type D strain CN4003, as described above. A 2.5 µg aliquot of each isolated DNA sample was then digested overnight with XbaI according to the manufacturer's (New England Biolabs) instructions. The digested DNA samples were electrophoresed on a conventional 1% agarose gel. Bands were cut from that agarose gel based upon RFLP Southern blot results, gel purified, and cloned into the Topo® 2.1 vector (Invitrogen). The primers cpeF and cpeR were used to perform colony PCR to identify clones carrying cpe inserts. Plasmids were extracted from the PCR-positive colonies using the Qiagen plasmid preparation kit. Inserts present in the extracted plasmids were sequenced at the University of Pittsburgh core sequencing facility, using the primers listed in Table 2, 3 and 4.
Sequencing of the dcm to cpe region in type C isolate CN2078
DNA was isolated from cpe-positive type C strain CN2078 as described above. PCR was then performed using the Long Range Taq DNA polymerase from New England Biolabs and primers dcmF and cpeseqMR (table 2). The PCR reaction was performed in a Techne thermocycler (Burkhardstdorf, Germany) and used the following conditions: 95°C for 2 min; 35 cycles of 95°C for 30 sec, 55°C for 40 sec, and 65°C for 5 min; with a single extension at 65°C for 10 min. The resultant 4 kb PCR product was cloned into the Topo® 2.1 vector. The plasmid insert was then sequenced at the University of Pittsburgh core sequencing facility using the primers listed in Table 2.
Sequencing of the region upstream of the cpe gene in type D isolate CN4003
DNA was isolated from cpe-positive type D strain CN4003 as described above. A 2.5 µg aliquot of each isolated DNA sample was then digested overnight with EcoRI and KpnI, according to the manufacturer's (New England Biolabs) instructions. The digested DNA samples were electrophoresed on a conventional 1% agarose gel. The separated DNA digestion products were then transferred onto a nylon membrane (Roche) for hybridization with a cpe promoter probe, which was prepared using DIG labeled the PCR product of cpe-pro-F (5′-gcttaactattcttgatagttatct-3′) and cpe-pro-R (5′-gcattttcgaacaccattggattt-3′) as described above. Bands were cut from that agarose gel according to sizes determined by cpe Southern blot analyses (see Results), gel purified, and cloned into the Topo 2.1® vector (Invitrogen). The primers cpeupF and cpeupR were used to perform colony PCR to identify clones carrying a cpe promoter insert. Plasmids were extracted from the PCR-positive colonies using the Qiagen plasmid preparation kit. Inserts present in the extracted plasmids were sequenced at the University of Pittsburgh core sequencing facility using the primers listed in Table 4.
Nucleotide sequence accession numbers for cpe locus sequences
Results from sequencing analyses of the cpe locus of type C isolates CN5388 and CN2078, or the type D CN4003 cpe locus sequence, are deposited in GenBank under accession numbers GQ225714, GQ225715 and GQ225713, respectively.
Overlapping PCR analyses to evaluate cpe locus diversity amongst type C or D cpe-positive isolates
For these short-range PCRs, template DNA was obtained from C. perfringens colony lysates as described previously . Each PCR mixture contained 2 µl of template DNA, 10 µl of TAQ Complete 2× mix (New England Biolabs), and 1 µl of each primer pair (1 µM final concentration). To compare the organization of the cpe locus present amongst different type C cpe-positive isolates, PCRs were performed that used overlapping primers for adjacent ORFs present in the cpe locus of either CN2078 (table 2) or CN5388 (table 3). These primers spanned from the dcm ORF in each cpe locus to the IS1151-like ORF downstream of the cpe ORF. For type D cpe-positive isolates, the overlapping PCRs were performed from the first transposase ORF upstream of the cpe gene to 2500 bp downstream of the cpe gene; primers are listed in Table 4. The design of these primers was based upon sequencing results obtained from the cpe locus of CN2078 (type C), CN5388 (type C) and CN4003 (type D), as determined above. The reaction mixtures, with a total volume of 20 µl, were placed in a thermocycler (Techne) and subjected to the following amplification conditions: one cycle of 95°C for 2 min; 35 cycles of 95°C for 30 sec, 55°C for 40 sec, and 68°C for 100 sec; and a single extension at 68°C for 10 min. PCR products were electrophoresed on a 1% agarose gel, which was then stained with ethidium bromide for product visualization.
PCR identification of possible circular transposition intermediates carrying the cpe ORF
Each PCR mixture contained 5 µl of template DNA, which was a freshly prepared lysate from an overnight BHI agar culture of cpe-positive type C isolate CN2078, or cpe-positive type D isolate CN4003, 25 µl of TAQ complete 2× Master Mix (New England Biolabs), and 1 µl of each primer pair (1 µM final concentration). Primers used in these studies included dcmRseq, 1027upNF2 and cpeMR (table 2). PCR amplification were then performed in a Techne thermocycler using the following conditions: 95°C for 2 min; 35 cycles of 95°C for 30 sec, 54°C for 30 sec, and 68°C for 2 min; with a single extension of 68°C for 5 min. PCR products were separated on 1.5% agarose gels and visualized with ethidium bromide staining. PCR products were then excised from the gel using Quantum Prep freeze ‘N squeeze DNA gel extraction spin columns (Bio-Rad), cloned into pCR®2.1-TOPO vector, and sequenced at the University of Pittsburgh core sequencing facility.
Pulsed-field gel Southern blot analyses of cpe location in type C isolates
Using well-established conditions that allow plasmids (but not chromosomal DNA) to enter a pulsed-field gel and migrate according to their molecular sizes, previous studies , , ,  had demonstrated that, i) some cpe-positive type A isolates carry a chromosomal cpe gene, while ii) other cpe-positive type A isolates and most, or all, cpe-positive type D isolates carry their cpe genes on large plasmids. Similarly, the silent cpe sequences of type E isolates are also carried by large plasmids . However, inter- and intra- type differences have been observed in the size of plasmids carrying cpe genes or silent cpe sequences in type A, D and E isolates. Specifically, most cpe plasmids of type A isolates were found to be ∼70 kb or ∼75 kb in size , the cpe plasmids of type D isolates were shown to range in size from ∼75 kb to ∼110 kb , and the plasmids carrying silent cpe sequences in type E isolates were determined to vary in size from ∼100 kb to ∼135 kb . A survey of type B isolates reported that these isolates rarely, if ever, are cpe-positive . The current study first confirmed those previous reports of size differences in the plasmids carrying a cpe gene or silent cpe sequences amongst representative type A, D and E isolates (Fig. 1A, Table 1).
(A) DNA from type A, C, D or E isolates was subjected to PFGE prior to Southern blotting and hybridization with a DIG-labeled, cpe-specific probe. (B) DNA from type A (F5603) or type C (CN2076, CN3748, CN3758, CN3763 and CN3753) isolates was subjected to PFGE prior to Southern blotting and hybridization with a DIG-labeled, cpe-specific probe. The migration of molecular size markers is indicated on the left of the blot.
To our knowledge, the location (chromosomal vs. plasmid-borne) of the cpe gene in cpe-positive type C isolates has not yet been evaluated. Therefore, DNA from seven cpe-positive type C isolates was subjected to PFGE, followed by Southern blotting with a cpe-specific probe. As shown in Fig. 1A and 1B (and summarized in Table 1), this analysis localized the cpe gene of all surveyed type C isolates to plasmids, which ranged in size from 70–75 kb up to 110 kb. For comparison, Fig. 1A also shows type A isolates F5603 and F4969, which are known to carry cpe plasmids of 75 kb and 70 kb, respectively .
Nucleotide sequencing of the cpe ORF in cpe-positive type C and D isolates
Having established that, as for cpe-positive type D isolates , the cpe gene is plasmid-borne in most, if not all, cpe-positive type C isolates, this study next investigated the here-to-fore unstudied cpe loci of cpe-positive type C and D isolates. This work initiated by sequencing the cpe ORF from two type C and four type D strains, which revealed that each of these isolates carries a cpe ORF nucleotide sequence that is identical to the highly conserved cpe ORF nucleotide sequence present amongst type A isolates , .
Application of a multiplex PCR type A cpe locus subtyping assay to begin evaluating type C and D cpe locus organization
This study next assessed whether the upstream and downstream sequences flanking the cpe gene in cpe-positive type C or D isolates resemble a characterized cpe locus found amongst cpe-positive type A isolates. This possibility was first evaluated using a previously described multiplex PCR assay  that is capable of distinguishing amongst the three characterized cpe loci commonly found in cpe-positive type A isolates (Fig. 2). As expected, this multiplex PCR assay correctly amplified an ∼0.6 kb internal cpe product using culture lysates of all three control type A cpe positive isolates. It also correctly amplified  an ∼0.8 kb product from culture lysates of type A isolate F5603, which carries an IS1151 sequence downstream of its plasmid cpe gene; an ∼1.3 kb product from culture lysates of type A cpe positive isolate SM101, which carries a chromosomal cpe gene; and an ∼1.6 kb product from culture lysates of type A isolate F4969, which carries an IS1470-like sequence downstream of its plasmid cpe gene. Also consistent with previous studies , this multiplex PCR amplified the 0.6 kb internal cpe product, but no other products, from type E isolates carrying their plasmid-borne silent cpe sequences in a locus organized differently from those found in cpe-positive type A isolates.
Representative results obtained with this assay are shown for type A isolates known to carry a chromosomal cpe gene (SM101), a plasmid cpe gene with an associated IS1470-like sequence (F4969), or a plasmid cpe gene with an associated IS1151 sequence (F5603). Also shown are representative results for this assay using culture lysates from cpe-positive type C isolates (CN2078, NCTC5388), cpe-positive type D isolates (CN4003) and type E isolates carrying silent cpe sequences (853 and NCIB10748). The migration of molecular size markers is indicated on the left of the blot.
Having confirmed the reliability of this multiplex PCR assay for differentiating amongst the three common cpe loci found amongst type A isolates, the assay was then applied to seven cpe-positive type C and eight cpe-positive D isolates. These analyses amplified the ∼0.6 kb internal cpe product from all surveyed isolates (Fig. 2 and data not shown), further confirming that these type C and D isolates are each cpe-positive. However, no other products were amplified from lysates of any surveyed cpe-positive type C or D isolates, suggesting that their cpe loci are not organized similarly as the type A chromosomal cpe locus, the pCPF4969-like cpe locus or the pCPF5603-like cpe locus.
RFLP analyses of cpe locus heterogeneity amongst cpe-positive type C and D isolates
Fig. 2 results were consistent with the existence of organizational differences between the cpe loci found in type A isolates vs. the cpe loci found in the surveyed type C or D isolates. This suggestion was then further explored by RFLP analyses.
As reported previously , , , , the cpe gene localized (Fig. 2) to an ∼5.7 kb XbaI fragment in type A isolates, such as NCTC8239 and SM101, known to carry a chromosomal cpe gene. As also reported , , , the cpe gene was detected on larger XbaI fragments in type A isolates known to carry a plasmid-borne cpe gene, i.e., in type A isolates F5603 and F4969 the cpe gene localized to ∼6.6 kb or ∼8.3 kb XbaI fragments, respectively. Also consistent with previous sequencing and PCR analyses , these analyses showed that type E isolate NCIB10748 carries its silent cpe sequences on a 7.1 kb XbaI fragment (Table 1).
When eight cpe-positive type D isolates were similarly surveyed by RFLP, no size diversity was noted amongst their cpe-carrying XbaI fragments, i.e., all of these isolates were found to carry their cpe gene on an ∼5 kb XbaI fragment. In contrast. the surveyed cpe-positive type C isolates showed limited heterogeneity in the size of their cpe-carrying XbaI fragments. Specifically, CN5388 carried cpe on an ∼6.5 kb XbaI fragment, while the other surveyed type C isolates all carried their cpe gene on an ∼3 kb XbaI fragment (Table 1 and Fig. 3).
Sequencing of cpe loci in type C isolates
In combination, the Fig. 2 and 3 results suggested that the cpe locus is often organized differently between cpe-positive type C isolates versus cpe-positive type A or D strains or even amongst cpe-positive type C strains. Therefore, the ∼3 kb cpe-carrying CN2078 XbaI fragment and ∼6.5 kb cpe-carrying CN5388 XbaI fragment were sequenced. Because the short, ∼3 kb CN2078 XbaI fragment did not include dcm, which is usually located near the cpe gene in type A isolates , , a long range PCR reaction was performed to attempt linking of dcm to cpe using CN2078 strain DNA. A product of ∼4 kb was successfully obtained from this PCR and then sequenced.
As shown in Fig. 4, these sequencing analyses revealed that the CN2078 cpe locus bears some resemblance to the type A chromosomal cpe locus, i.e., the CN2078 cpe locus contains an IS1469 and two IS1470 sequences and it also has a cpe ORF situated between two IS1470 genes. However, two differences were identified between the chromosomal cpe locus of type A isolate SM101 and the plasmid-borne cpe locus of type C isolate CN2078; i) the IS1469 sequence present in the CN2078 cpe locus is situated differently with respect to the IS1470 sequence present upstream of cpe and ii) the IS1151-like sequence located downstream of cpe in CN2078 is absent from the type A chromosomal cpe locus. Sequencing results for the ∼7 kb CN5388 XbaI fragment showed that this unusual (by RFLP analysis) type C cpe locus is missing the two copies of IS1470 that are present in the cpe locus of CN2078.
A) Organization of plasmid cpe loci. B) Organization of the type A chromosome cpe locus. Each box represents an ORF. * indicates a region with sequence similarity to sequences present downstream of cpe in F4969, except for the absence of an IS1470-like gene. Sequences of cpe loci in F4969, F5603, NCIB10748, NCTC8239 and SM101 have been reported previously , , . Sequences of CN2078, CN5388 and CN4003 are based upon results of this study. The arrows show predicted enzyme (EcoRI, XbaI and KpnI) cleavage sites used in this study.
Overlapping PCR analyses to evaluate cpe locus diversity amongst type C cpe-positive isolates
Based upon the sequence obtained for the type C CN2078 cpe locus, an overlapping PCR assay (8 reactions) was developed to evaluate the presence of this cpe locus in other cpe-positive type C isolates. This assay was then applied to assess cpe loci diversity in six type C cpe positive isolates that, like CN2078, carry their cpe gene on an ∼2.9 kb XbaI fragment (Fig. 3 and Table 1). In this experiment, DNA from all six surveyed type C isolates supported full or partial amplification of the expected PCR products. In particular, DNA from type C isolates CN3753 and CN3748 gave exactly the same amplification pattern as was obtained using CN2078 DNA (Fig. 5). DNA from the other three isolates showed some amplification pattern differences for sequences upstream of the cpe gene, but supported conserved amplification of products corresponding to sequences immediately adjacent to, or downstream of, the cpe gene.
An overlapping PCR assay specific for amplification of the type C isolate CN2078 cpe locus region (R1 to R8) was performed using the primer battery shown in Table 2. (A) Map depicting the relationship between CN2078 cpe locus ORFs and reactions comprising this overlapping PCR battery. (B) PCR products produced by these reactions using DNA from type C isolates: CN2078, CN3753 and CN3748. (C) PCR products produced by these reactions using DNA from type C isolates: CN2076, CN3758 and CN3763. Numbers at left of each gel indicate migration of size markers in kb.
Sequencing had shown that CN5388 possesses a very different cpe locus from that found in the other surveyed type C isolates (Fig. 4) and also indicated that the CN5388 cpe locus sequence shares some resemblance to the plasmid borne cpe locus of pCPF5603 carried by type A isolate F5603 (Fig. 4). This finding was consistent with results obtained using an overlapping PCR assay based upon the CN5388 cpe locus sequence (Fig. 6A and B). Therefore, given their cpe locus similarity, it was possible that the CN5388 cpe locus might be present on a similar plasmid as pCPF5603. However, an overlapping PCR assay for the conserved region of pCPF5603 (and pCPF4969) amplified only the tra region from CN5388 DNA (Fig. 6C and data not shown).
(A) Map depicting the relationship between ORFs and reactions in the cpe locus overlapping PCR battery (reactions R1 to R6) was performed using the primer battery show in Table 3. (B) Products of these reactions amplified by PCR using DNA from type C isolate CN5388 and CN2078 or type A isolates F5603. Arrows indicate that IS1151 sequences are oppositely oriented in CN5388 vs. F5603. (C) Products obtained when DNA from CN5388 or F5603 were subjected to a previously described  overlapping PCR assay specific for the conserved region of type A cpe plasmids pCPF5603 and pCPF4969. Numbers at left of each gel indicate migration of size markers in kb.
Sequencing of the cpe locus in type D isolate CN4003
Results from the Fig. 3 RFLP analyses demonstrated that all of the surveyed type D isolates possess a cpe-carrying XbaI fragment of the same ∼5 kb size. Therefore, the ∼5 kb XbaI fragment carrying the cpe gene of type D isolate CN4003 was cloned into the pPCR2.1®-TOPO vector and sequenced. Efforts to PCR link the dcm gene to cpe in type D isolates were unsuccessful (data not shown). Consequently, additional upstream sequence in the type D cpe locus was obtained by cloning and sequencing an ∼3 kb EcoR1/KpnI fragment containing sequences upstream of the XbaI site in the cpe locus of CN4003.
Together, these sequencing analyses revealed that CN4003 possesses a novel cpe locus organization different from that found in any other characterized cpe-positive C. perfringens (Fig. 4). Specifically, CN4003 was found to possess, upstream of its cpe gene, two copies of an ORF with 67% identity to a transposase gene (COG4644) found in Tn1546, but not previously associated with the cpe gene. This CN4003 cpe locus also has sequences found downsteam of the cpe gene in type A isolate F4969, except for the absence of an IS1470-like insertion sequence (Fig. 4).
Overlapping PCR analyses to evaluate cpe locus diversity amongst type D cpe-positive isolates
Based upon the sequence obtained for the type D CN4003 cpe locus, an overlapping PCR assay (7 reactions) was developed to specifically evaluate the presence of this cpe locus in other type D isolates. When this assay was applied to assess the diversity of cpe loci in seven other type D cpe positive isolates, the amplification pattern obtained was identical for each isolate (Fig. 7 and data not shown). This result strongly suggested that many, if not all, type D cpe-positive isolates share a very similar cpe locus, consistent with the Fig. 3 RFLP results.
An overlapping PCR assay specific for amplification of the type D isolate CN4003 cpe locus region (R1 to R7) was performed using the primer battery shown in Table 4. (A) Map depicting the relationship between ORFs and each reaction in this overlapping PCR battery. * indicates a region with sequence similarity to sequences downstream of cpe in F4969, except for the absence of IS1470-like gene. (B) Products of these reactions using DNA from two representative type D isolates: CN4003 and JGS1902. Numbers at left of each gel indicate migration of size markers in kb.
PCR identification of possible circular transposition intermediates carrying the cpe ORF
The results presented above indicated that the cpe gene present in many, if not all, type C and D isolates is closely associated with several different insertion sequences, including (for type D isolates) some not previously associated with the cpe gene. Since IS elements in type A isolates can apparently mediate excision and formation of possible cpe-containing circular transposition intermediates that might facilitate cpe gene mobilization , primers in opposite orientations were used in PCR reactions to evaluate whether similar cpe-containing circular intermediates might also form in cpe-positive type C and D isolates. Primers dcmRseq and cpemR consistently amplified a strong 1.7 kb PCR product from cpe-positive type C isolate CN2078. When this PCR product was sequenced, it corresponded to sequences containing cpe, one intact IS1470 insertion sequence and one partial IS1470 insertion sequence (Fig. 8). Similarly, PCR primers from all three surveyed type D cpe positive isolates amplified a strong 0.6 kb PCR product. Sequencing showed that this PCR product contains a partial cpe ORF and some sequence upstream of cpe but no insertion sequence (Fig. 8).
(A) Diagram of the cpe locus in type C isolate CN2078 and type D isolate CN4003. (B) PCR amplification of cpe-containing circular intermediates using the primers dcmRseq and cpeMR with CN2078 DNA or primers 1027upNF2 and cpeMR with CN4003 DNA. (C) Diagram derived from sequencing the CN2078 loop product of panel B that was amplified using primers dcmRseq and cpeMR. Black regions of the circle correspond to the amplified product. (D) Diagram derived from sequencing the product from CN4003 loop product of pane B that was amplified using primers 1027upNF2 and cpeMR. Black regions of the circle correspond to the amplified product.
Except for the cpb2 ORF encoding beta2 toxin , , the ORF sequences of most C. perfringens toxin genes are usually highly conserved from isolate-to-isolate. For example, only limited sequence diversity has been observed for the cpa (plc) ORF encoding alpha toxin, the cpb ORF encoding beta toxin, the ORFs of the iap/ibp genes encoding iota toxin, and the etx ORF encoding epsilon toxin , , , , . Similarly, previous studies  had revealed that the cpe ORF sequence amongst surveyed type A isolates is invariant, regardless of whether this toxin gene is chromosomal or plasmid-borne. The current study now extends that earlier finding by showing that the cpe sequence is identical amongst type A, C and D isolates. This exceptional conservation of the cpe ORF sequence is particularly remarkable given the considerable diversity between sequences flanking the cpe gene in many type A, C and D isolates, as discussed below. Collectively, these observations might suggest that CPE protein functionality is intolerant of most mutations, causing selective pressure to maintain an invariant cpe ORF sequence amongst CPE-producing type A, C and D isolates. The single known exception to this pattern of invariant cpe sequences occurs with type E isolates, where a genetic element carrying the iota toxin gene has apparently inserted near the cpe promoter, silencing the cpe gene. Upon this silencing, a number of missense, nonsense and frame-shift mutations accumulated in the silent cpe ORF of type E isolates. Since the same mutations are present in the cpe sequences of most or all type E isolates , , this cpe silencing is thought to have occurred relatively recently . One possibility is that acquisition of iota toxin genes may have compensated for the loss of a functional cpe gene by providing type E isolates a selective advantage in a new pathogenic niche, particularly since cpe expression occurs only during sporulation while iota toxin is produced by vegetative cells.
Previous studies have localized the cpe gene near a dcm gene on both the pCPF4969-like and pCPF5603-like plasmids of type A isolates, , . The current study now demonstrates that a dcm gene is also proximal to the plasmid-borne cpe gene in many, if not all, type C isolates. One previously proposed  explanation for this strong association between dcm and cpe is that the dcm region of plasmids represent a hot-spot for insertion of certain mobile genetic elements, including some carrying a cpe gene. Consistent with this hypothesis, the cpe gene has now been localized near dcm in those cpe loci where the cpe gene is flanked by various combinations of IS1469, IS1470, IS1470-like, IS1151 or IS1151-like sequences . The possibility that the dcm region of C. perfringens plasmids represents a hot spot for insertion of mobile genetic elements consisting of certain IS elements and adjacent toxin genes receives further support from the established proximity of dcm to, i) plasmid-borne IS1151-iota toxin gene sequences in type E isolates and ii) plasmid-borne IS1151-etx sequences in type B and D isolates , , .
However, the current study may have also identified the first exception to the general association between dcm, insertion sequences, and plasmid-borne C. perfringens toxin genes. Specifically, attempts to PCR-link dcm and cpe proved unsuccessful in the surveyed cpe-positive type D isolates. If future studies confirm that dcm and cpe are not proximal in type D isolates, this could be explainable by our observation that the cpe gene of type D isolates is flanked by unique transposase sequences not previously associated with C. perfringens toxin genes. These transposase sequences share 67% identity to the transposase (COG4644) of Tn1546, which is a Tn3-related transposon commonly distributed amongst plasmids found in Gram-positive bacteria, including several Bacillus spp, Staphylococcus aureus and Enterococcus faecium . Conceivably, these unique transposase sequences flanking the cpe gene in many, if not all, type D isolates may mobilize cpe and prefer integrating into other plasmid sequences rather than integrating near the dcm gene.
Experimental support for possible IS-mediated mobilization of adjacent toxin genes in C. perfringens has largely been provided by studies demonstrating that primers in opposite orientations support PCR amplification of toxin gene-containing circular DNAs, which may represent transposition intermediates , , , . Prior to the current study, possible circular transposition intermediates had been detected that carry the cpe genes of type A isolates, the iota toxin genes of type E isolates, the cpb-tpeL genes of type B isolates and the etx genes of type D isolates , , , . Results presented in the current study support the possibility that the cpe genes of many type C and D isolates, although often present in differently organized loci from those found in type A isolates, can also be mobilized by adjacent sequences to form possible circular transposition intermediates.
This putative mobilization of toxin genes by adjacent IS sequences may help to explain why the same C. perfringens toxin gene can be found on different plasmid backbones. For example, the etx gene is almost always localized on a ∼65 kb plasmid in type B isolates, yet only a minority of type D isolates carry that ∼65 kb etx plasmid . Instead, type D isolates carry a diverse range of etx plasmids, some also carrying the cpe gene . Since potential circular transposition intermediates carrying either the cpe or etx genes have now been identified (this study, ), it is possible that the toxin plasmid diversity of type D isolates reflects this mobility of toxin gene-carrying mobile genetic elements.
The major finding of the current study is the provision of new insights into the diversity of cpe loci found amongst C. perfringens isolates. All surveyed cpe-positive type D isolates were shown to carry the same plasmid-borne cpe locus. This conclusion holds for type D isolates previously shown  to carry cpe and etx on the same plasmid, as well as type D isolates that carry those two toxin genes on distinct plasmids. These observations could indicate that a similar mobile genetic element has mobilized this conserved cpe locus from a progenitor cpe-carrying plasmid present in a type D isolate onto other plasmids present in that same isolate or, after conjugative transfer, in other type D isolates.
With respect to type C isolates, the current study suggests that many of these isolates also share a relatively conserved cpe locus, although the cpe locus of CN5388 is more divergent since it lacks the IS1470 sequences that flank the cpe gene in the other surveyed type C isolates. The type C cpe locus variants identified in this study generally resemble the cpe loci found in type A isolates by sharing many of the same IS elements, although in different arrangements . This may suggest a common evolutionary origin for the cpe loci of many type A and C isolates that is distinct from the cpe locus found in many type D isolates. Of particular note is the extensive similarity between the type A chromosomal cpe locus and the common plasmid-borne cpe locus present in CN2078 and most of the other surveyed type C isolates. One possible explanation for this similarity is that the chromosomal cpe locus of a type A isolate may have excised as a mobile genetic element and, after some recombination, integrated into a conjugative plasmid, which then transferred to a type C isolate. Alternatively, IS elements may have mobilized the plasmid-borne type C cpe locus so it could then integrate onto the C. perfringens chromosome, followed later by loss of the cpb plasmid to convert the isolate back to a type A isolate. If this second possibility is true, this chromosomal integration of a cpe-carrying mobile genetic element must have occurred rarely since most, if not all, chromosomal cpe type A isolates appear to be related, as assessed by MLST analyses , .
A final interesting observation from the current study is that the single variant cpe locus observed amongst the surveyed type C isolates involved an isolate causing human pigbel (enteritis necroticans). Although such clinical isolates are difficult to obtain, it would be interesting to evaluate whether other cpe-positive, type C pigbel isolates also carry this same variant cpe locus, possibly suggesting virulence significance or a common evolutionary origin. Additional clarification of these and other issues about cpe locus diversity and evolution are the subject of additional studies ongoing in our laboratory.
Conceived and designed the experiments: JL KM BAM. Performed the experiments: JL KM SS. Analyzed the data: JL KM BAM. Wrote the paper: JL BAM.
- 1. McClane BA (2007) Clostridium perfringens. In: Doyle MP, Beuchat LR, editors. Food Microbiology. 3rd ed. Washington D.C.: ASM press. pp. 423–444.
- 2. McClane BA, Uzal FA, Miyakawa MF, Lyerly D, Wilkins T (2006) The Enterotoxic Clostridia. In: Dworkin M, Falkow S, Rosenburg E, Schleifer H, Stackebrandt E, editors. The Prokaryotes. 3rd ed. New York: Springer NY. pp. 688–752.
- 3. Kokai-Kun JF, Songer JG, Czeczulin JR, Chen F, McClane BA (1994) Comparison of Western immunoblots and gene detection assays for identification of potentially enterotoxigenic isolates of Clostridium perfringens. J Clin Microbiol 32: 2533–2539.
- 4. Bos J, Smithee L, McClane BA, Distefano RF, Uzal F, et al. (2005) Fatal necrotizing enteritis following a foodborne outbreak of enterotoxigenic Clostridium perfringens type A infection. Clin Infect Dis 15: 78–83.
- 5. Collie RE, Kokai-Kun JF, McClane BA (1998) Phenotypic characterization of enterotoxigenic Clostridium perfringens isolates from non-foodborne human gastrointestinal diseases. Anaerobe 4: 69–79.
- 6. Grant K, Kenyon S, Nwafor I, Plowman J, Ohai C, et al. (2008) The identification and characterization of Clostridium perfringens by real-time PCR, location of enterotoxin gene, and heat resistance. Foodborne Pathog Dis 5: 629–639.
- 7. Hlkinhelmo A, Lindstrom M, Granum PE, Korkeala H (2006) Humans as reservoir for enterotoxin gene-carrying Clostridium perfringens type A. Emerging Infectious Diseases 12: 1724–1729.
- 8. Miki Y, Miyamoto K, Kaneko-Hirano I, Fujiuchi K, Akimoto S (2008) Prevalence and characterization of enterotoxin gene-carrying Clostridium perfringens isolates from retail meat products in Japan. Appl Environ Microbiol 74: 5366–5372.
- 9. Miyamoto K, Chakrabarti G, Morino Y, McClane BA (2002) Organization of the plasmid cpe locus of Clostridium perfringens type A isolates. Infect Immun 70: 4261–4272.
- 10. Cornillot E, Saint-Joanis B, Daube G, Katayama S, Granum PE, et al. (1995) The enterotoxin gene (cpe) of Clostridium perfringens can be chromosomal or plasmid-borne. Molec Microbiol 15: 639–647.
- 11. Miyamoto K, Fisher DJ, Li J, Sayeed S, Akimoto S, et al. (2006) Complete sequencing and diversity analysis of the enterotoxin-encoding plasmids in Clostridium perfringens type A non-food-borne human gastrointestinal disease isolates. J Bacteriol 188: 1585–1598.
- 12. Brynestad S, Synstad B, Granum PE (1997) The Clostridium perfringens enterotoxin gene is on a transposable element in type A human food poisoning strains. Microbiology 143: 2109–2115.
- 13. Fisher DJ, Miyamoto K, Harrison B, Akimoto S, Sarker MR, et al. (2005) Association of beta2 toxin production with Clostridium perfringens type A human gastrointestinal disease isolates carrying a plasmid enterotoxin gene. Molec Microbiol 56: 747–762.
- 14. Carman RJ (1997) Clostridium perfringens in spontaneous and antibiotic-associated diarrhoea of man and other animals. Rev Med Microbiol 8: supplement 1S43–S45.
- 15. Collie RE, McClane BA (1998) Evidence that the enterotoxin gene can be episomal in Clostridium perfringens isolates associated with nonfoodborne human gastrointestinal diseases. J Clin Microbiol 36: 30–36.
- 16. Li J, Sayeed S, McClane BA (2007) Prevalence of enterotoxigenic Clostridium perfringens isolates in Pittsburgh (Pennsylvania) area soils and home kitchens. Appl Environ Microbiol 73: 7218–7224.
- 17. Bannam TL, Teng WL, Bulach D, Lyras D, Rood JI (2006) Functional identification of conjugation and relication regions of the tetracycline resistance plasmid pCW3 from Clostridium perfringens. J Bacteriol 188: 4942–4951.
- 18. Brynestad S, Sarker MR, McClane BA, Granum PE, Rood JI (2001) The enterotoxin (CPE) plasmid from Clostridium perfringens is conjugative. Infect Immun 69: 3483–3487.
- 19. Brynestad S, Granum PE (1999) Evidence that Tn5565, which includes the enterotoxin gene in Clostridium perfringens, can have a circular form which may be a transposition intermediate. FEMS Microbiol Lett 170: 281–286.
- 20. Billington SJ, Wieckowski EU, Sarker MR, Bueschel D, Songer JG, et al. (1998) Clostridium perfringens type E animal enteritis isolates with highly conserved, silent enterotoxin sequences. Infect Immun 66: 4531–4536.
- 21. Li J, Miyamoto K, McClane BA (2007) Comparison of virulence plasmids among Clostridium perfringens type E isolates. Infect Immun 75: 1811–1819.
- 22. Fisher DJ, Fernandez-Miyakawa ME, Sayeed S, Poon R, Adams V, et al. (2006) Dissecting the contributions of Clostridium perfringens type C toxins to lethality in the mouse intravenous injection model. Infect Immun 74: 5200–5210.
- 23. Sayeed S, Fernandez-Miyakawa ME, Fisher DJ, Adams V, Poon R, et al. (2005) Epsilon-toxin is required for most Clostridium perfringens type D vegetative culture supernatants to cause lethality in the mouse intravenous injection model. Infect Immun 73: 7413–7421.
- 24. Lawrence GW (1997) The pathogenesis of enteritis necroticans. In: Rood JI, McClane BA, Songer JG, Titball RW, editors. The Clostridia: Molecular Genetics and Pathogenesis. London: Academic Press. pp. 198–207.
- 25. Sayeed S, Li J, McClane BA (2007) Virulence plasmid diversity in Clostridium perfringens type D isolates. Infect Immun 75: 2391–2398.
- 26. Miyamoto K, Wen Q, McClane BA (2004) Multiplex PCR genotyping assay that distinguishes between isolates of Clostridium perfringens type A carrying a chromosomal enterotoxin gene (cpe) locus, a plasmid cpe locus with an IS1470-like sequence or a plasmid cpe locus with an IS1151 sequence. J Clin Microbiol 41: 1552–1558.
- 27. Miyamoto K, Li J, Sayeed S, Akimoto S, McClane BA (2008) Sequencing and diversity analyses reveal extensive similarities between some epsilon-toxin-encoding plasmids and the pCPF5603 Clostridium perfringens enterotoxin plasmid. J Bacteriol 190: 7178–7188.
- 28. Sayeed S, Li J, McClane BA (2010) Characterization of virulence plasmid diversity among Clostridium perfringens type B isolates. Infect Immun 78: 495–504.
- 29. Czeczulin JR, Hanna PC, McClane BA (1993) Cloning, nucleotide sequencing, and expression of the Clostridium perfringens enterotoxin gene in Escherichia coli. Infect Immun 61: 3429–3439.
- 30. Wen Q, Miyamoto K, McClane BA (2003) Development of a duplex PCR genotyping assay for distinguishing Clostridium perfringens type A isolates carrying chromosomal enterotoxin (cpe) genes from those carrying plasmid-borne enterotoxin (cpe) genes. J Clin Microbiol 41: 1494–1498.
- 31. Jost BH, Billington SJ, Trinh HT, Bueschel DM, Songer JG (2005) Atypical cpb2 genes, encoding beta2-toxin in Clostridium perfringens isolates of nonporcine origin. Infect Immun 73: 652–656.
- 32. Fernandez-Miyakawa ME, Fisher DJ, Poon R, Sayeed S, Adams V, et al. (2007) Both epsilon-toxin and beta-toxin are important for the lethal properties of Clostridium perfringens type B isolates in the mouse intravenous injection model. Infect Immun 75: 1443–1452.
- 33. Titball RW, Naylor CE, Basak AK (1999) The Clostridium perfringens alpha-toxin. Anaerobe 5: 51–64.
- 34. Arthur M, Molinas C, Depardieu F, Courvalin P (1993) Characterization of Tn1546, a Tn3-related transposon conferring glycopeptide resistance by synthesis of depsipeptide peptidoglycan precursors in Enterococcus faecium BM4147. J Bacteriol 175: 117–127.
- 35. Sayeed S, Uzal FA, Fisher DJ, Saputo J, Vidal JE, et al. (2008) Beta toxin is essential for the intestinal virulence of Clostridium perfringens type C disease isolate CN3685 in a rabbit ileal loop model. Molec Microbiol 67: 15–30.
- 36. Miyamoto K, Li J, Akimoto S, McClane BA (2009) Molecular approaches for detecting enterotoxigenic Clostridium perfringens. Res Adv in Appl & Environ, Microbiol 2: 1–7.
- 37. Deguchi A, Miyamoto K, Kuwahara T, Miki Y, Kaneko-Hirano I, et al. (2009) Genetic characterization of type A enterotoxigenic Clostridium perfringens strains. PLos One 4: e5598.
- 38. Myers GS, Rasko DA, Cheung JK, Ravel J, Seshadri R, et al. (2006) Skewed genomic variability in strains of the toxigenic bacterial pathogen, Clostridium perfringens. Genome Res 16: 1031–1040.