Characterization of Cytolethal Distending Toxin of
http://www.100md.com
微生物临床杂志 2005年第2期
Department of Veterinary and Biomedical Sciences
Veterinary Diagnostic Center, University of Nebraska-Lincoln, Lincoln, Nebraska
Tulane National Primate Research Center, Covington, Louisiana
ABSTRACT
An association between certain Campylobacter species and enterocolitis in humans and nonhuman primates is well established, but the association between cytolethal distending toxin and disease is incompletely understood. The purpose of the present study was to examine Campylobacter species isolated from captive conventionally raised macaque monkeys for the presence of the cdtB gene and for cytolethal distending toxin activity. The identity of each isolate was confirmed on the basis of phenotypic and genotypic analyses. The presence of cytolethal distending toxin was confirmed on the basis of characteristic morphological changes in HeLa cells incubated with filter-sterilized whole-cell lysates of reference and monkey Campylobacter isolates and examinations by light microscopy, confocal microscopy, and flow cytometry. Although cdtB gene sequences were found in both Campylobacter jejuni and Campylobacter coli, the production of cytolethal distending toxin correlated positively (P < 0.0001) only with C. jejuni. We concluded that cytolethal distending toxin activity is a characteristic of C. jejuni. Our C. jejuni cdtB gene-specific PCR assay might be of assistance for differentiating toxigenic C. jejuni from C. coli in clinical laboratories.
INTRODUCTION
Members of the Campylobacter genus are motile, curved, gram-negative, phenotypically heterogeneous bacilli that colonize the mucus on the surface and crypts of the intestine, where certain species can cause epithelial damage and elicit host inflammatory and immune responses (21, 23, 55). Campylobacter jejuni is the leading cause of food-borne infectious diarrheal disease in humans in many developed countries, including the United States (47). The primary source of food-borne human Campylobacter species infections is contaminated chicken (15).
Campylobacter species account for a large percentage of diarrheal illnesses of colony-raised macaque monkeys (22, 37, 39, 43). Both the duration and the clinical presentation of diarrheal illness in rhesus macaques (Macaca mulatta) and pig-tailed macaques (Macaca nemestrina) experimentally challenged with C. jejuni are similar to those seen in humans (3, 9, 38, 40). The disease in macaques is characterized by diarrhea of variable severity and duration accompanied by prolonged intermittent fecal shedding of C. jejuni. Epidemiological studies of infant pig-tailed macaques kept in a nursery facility have further revealed that infection and reinfection with multiple strains of C. jejuni and Campylobacter coli are common, and as seen in humans (3), recovered monkeys are often asymptomatic (39).
Although several virulence determinants have been identified for pathogenic Campylobacter species, the significance of cytotoxins in disease is relatively poorly understood (54). A newly characterized heat-labile and trypsin-sensitive cytotoxin, known as cytolethal distending toxin (CDT), was first identified from Shigella, Escherichia coli, and C. jejuni isolated from human and nonhuman sources over 15 years ago (18-20). In the last decade, the gene encoding CDT, cdtB, has been found in most Campylobacter species (8, 27, 35, 56) and in several serotypes of E. coli (7, 32, 34, 42, 48). Homologues of cdtB and CDT activity have also been found among enterohepatic Helicobacter species that associate with the intestinal mucosa (4, 24) and, most recently, in Salmonella enterica serovar Typhi (13). Other gram-negative bacteria harboring the cdtB gene and producing CDT activity include the periodontopathogenic bacterium Actinobacillus actinomycetemcomitans (1, 44, 46, 57) and the venereal pathogen Haemophilus ducreyi (1, 5, 36).
With the exception of S. enterica serovar Typhi, in which only cdtB is found (13), in all other microbes CDT consists of a tripartite polypeptide complex of CdtA (30 kDa), CdtB (29 kDa), and CdtC (21 kDa), encoded by the corresponding genes cdtA, cdtB, and cdtC (26, 33). Although considerable divergence in the predicted amino acid sequences of each CDT subunit exists among different microbes, the cdtB genes have conserved structural similarities to the mammalian DNase I catalytic and Mg2-binding sites (6, 25). When it interacts with certain eukaryotic cells, the CDT holotoxin causes progressive cytoplasmic and nuclear distension accompanied by increased DNA contents, leading to growth arrest at the G2/M transition phase of the cell cycle and, ultimately, cell death (2, 5, 32, 44, 56).
There is some evidence that CDT is a virulence determinant for naturally occurring and experimentally induced enteric diseases associated with C. jejuni (11), E. coli (30), and Shigella dysenteriae (28). Experimental challenge studies support a role for C. jejuni as a cause of diarrheal disease in monkeys (9, 38), but Campylobacter strains isolated from monkeys have not been examined for the presence of the cdtB gene and for CDT activity. For this study, we examined Campylobacter strains isolated from captive conventionally raised macaques with and without clinical signs of diarrhea for the presence of the cdtB gene and CDT activity. We found that both C. jejuni and C. coli have the cdtB gene but that CDT activity was only present in C. jejuni.
CASE REPORTS
The clinical presentations and housing of 28 macaques investigated in the present study are outlined in Table 1. The sex distribution of 20 females versus 8 males reflects the natural distribution in the colony. The animals were kept at the Tulane National Primate Research Center in accordance with the standards of the Guide for the Care and Use of Laboratory Animals and the Association for Assessment and Accreditation of Laboratory Animal Care. The macaques were housed either in groups in outdoor breeding cages or individually indoors at biocontainment level 2. Stool specimens were collected either during routine health monitoring of the colony or from macaques with clinical manifestations of diarrheal illnesses of various durations (Table 1). Following an initial sampling in September 2003, rhesus macaque EB53 was treated with the broad-spectrum antibiotic tylosin at a dose of 10 mg/kg of body weight by intramuscular injections twice a day for 10 days and was resampled a month later when diarrhea was still present. The isolation of Campylobacter species from stool specimens was the main selection criterion for study assignment.
MATERIALS AND METHODS
Bacterial strains and growth conditions. Campylobacter strains were isolated from stool specimens by microaerobic incubation at 42°C on Campylobacter selective agar (BBL, Cockeysville, Md.) containing cefoperazone, vancomycin, and amphotericin B and then initially identified as previously described (43). The reference human strains C. jejuni subsp. jejuni VPI H840 (ATCC 29428 [50]) and LRA 094.06.89 (ATCC 49943), the porcine strains C. coli CIP 7080 (ATCC 33559 [45]) and LRA 069.05.89 (ATCC 49941), the human strain Arcobacter butzleri LMG 10828 (ATCC 49616 [51]), and the sheep strain Arcobacter skirrowii LMG 6621 (ATCC 51132 [51]) were used as controls. Stock cultures were propagated onto Trypticase soy agar with 5% (vol/vol) sheep blood (TSAB; Remel, Lenexa, Kans.) and incubated under microaerobic conditions (Mitsubishi Gas Chemical Co. Inc., New York, N.Y.) at either 24, 37, or 42°C or in Brucella broth (Difco, Detroit, Mich.) supplemented with 5% (vol/vol) sheep serum (Sigma Chemical Co., St. Louis, Mo.) with constant stirring at 37°C in an atmosphere consisting of 5% oxygen, 5% carbon dioxide, and 90% nitrogen. Chemically competent TOP10 E. coli cells transformed with the pCR4-TOPO cloning vector (Invitrogen Corp., Carlsbad, Calif.) were grown in Luria-Bertani medium containing ampicillin or kanamycin (Sigma) at 37°C overnight.
Phenotypic characterization. Each reference and macaque isolate was examined by wet mounting and gram staining and observed for growth at either 24, 37, or 42°C under microaerobic and aerobic conditions for up to 14 days postinoculation. Catalase and oxidase activities (Remel), the production of urease (Remel), the reduction of nitrate to nitrite (Remel), the hydrolysis of hippurate (Remel), and susceptibilities to nalidixic acid (30 μg) and cephalothin (30 μg) by disk diffusion (Becton Dickinson, Sparks, Md.) were determined by standard laboratory methods (10).
Genotypic identification. C. jejuni and C. coli were identified on the basis of PCR amplification of the species-specific ceuE gene (12). Briefly, 2 μl of bacterial suspension in sterile water was mixed with a total volume of 48 μl containing 1x PCR buffer, 3.5 mM MgCl2, a 0.2 mM concentration (each) of dATP, dTTP, dGTP, and dCTP, a 1.0 μM concentration (each) of the oligonucleotide primers JEJ1 and JEJ2 or COLI1 and COLI2, and 0.5 U of Taq DNA polymerase (GeneChoice, Inc., Frederick, Md.) in sterile, filtered, autoclaved water. Initial denaturing for 3 min at 94°C was followed by 30 cycles of 30 s at 94°C, 30 s at 57°C, and 1 min at 72°C, with a final extension for 5 min at 72°C, in a thermocycler (GeneAmp PCR System 9600; Perkin-Elmer Cetus, Norwalk, Conn.). The 783-bp C. jejuni and the 894-bp C. coli products were visualized after electrophoresis in 0.8% agarose gels run at 7.0 V/cm and staining with ethidium bromide. Identification of the Arcobacter genus and of A. butzleri was accomplished by a multiplex PCR method as previously described (14).
Amplification, cloning, and sequencing of cdtB gene. The cdtB genes of reference and macaque isolates were amplified by PCRs with the degenerative forward oligonucleotide primer VAT2, extending from base position 67 of C. jejuni strain 81-176 (GenBank accession no. U51121; National Center for Biotechnology Information, Bethesda, Md.) with the nucleotide sequence 5'-GTNGCNACBTGGAAYCTNCARGG-3', and the reverse oligonucleotide primer WMI1 at position 539, with the nucleotide sequence 5'-RTTRAARTCNCCYAADATCATCC-3', as previously described (35). Additionally, a C. jejuni cdtB gene-specific sequence was amplified with the forward oligonucleotide primer CjcdtBF, extending from position 93 of C. jejuni strain 81-176 with the nucleotide sequence 5'-ATCCGCAGCCACAGAAAGCAAATG-3', and the reverse oligonucleotide primer CjcdtBR at position 692, with the nucleotide sequence 5'-GCGGTGGAGTATAGGTTTGTTGTC-3'. Two microliters of bacterial suspension in sterile water was mixed with a total volume of 48 μl containing 1x PCR buffer, 1.5 mM MgCl2, a 0.2 mM concentration (each) of dATP, dTTP, dGTP, and dCTP, a 0.25 μM concentration of each oligonucleotide primer, and 2.0 U of Taq DNA polymerase (GeneChoice) in sterile, filtered, autoclaved water. The PCR parameters for amplification reactions were similar to those for the Campylobacter species-specific ceuE gene, except that annealing was done for 60 s at 50°C. The 495- and 623-bp amplified products, generated with the degenerative and C. jejuni cdtB gene-specific oligonucleotide primers, respectively, were visualized by electrophoresis in 0.8% agarose gels run at 7.0 V/cm after staining with ethidium bromide. The partial nucleotide sequence of the C. jejuni EB53-23-01 cdtB gene was determined. Briefly, each 495- and 623-bp amplified product was excised, purified (Zymoclean Gel DNA recovery kit; Zymo Research, Orange, Calif.), cloned into pCR4-TOPO, and transformed into chemically competent E. coli TOP10 cells according to the manufacturer's instructions. The nucleotide sequences of both strands from five clones of each product were sequenced at the Genomics Core Research Facility, University of Nebraska-Lincoln Center for Biotechnology, by use of an automated dideoxy sequencing method (41) and a commercial kit (CEQ DTCS quick start kit; Beckman Coulter, Fulton, Calif.) for fluorescence sequencing (CEQ 2000XL/8000 DNA sequencer; Beckman Coulter). A partial 602-bp consensus cdtB gene sequence extending from positions 90 to 691 was aligned and edited with the Wisconsin Package, version 9.0 (Genetics Computer Group, Madison, Wis.), and then compared with available sequences from other bacteria in GenBank by use of the BLAST program.
Preparation of bacterial cell lysates. Confluent cultures of reference and macaque bacterial isolates grown on TSAB for 2 to 3 days under microaerobic conditions at 42°C were harvested by washing the surface growth with phosphate-buffered saline (PBS; pH 7.2) and then centrifuging it at 800 x g for 20 min at 4°C. The pellet was suspended in 1.0 ml of ice-cold PBS and lysed by sonication as previously described (4). Unlysed bacteria and cell debris were removed by centrifugation at 6,000 x g for 20 min at 4°C, and the supernatant was filtered through 0.22-μm-pore-size filters and stored at –20°C until needed. The concentration of protein present in each filter-sterilized lysate was determined by use of a commercially available kit (BCA protein assay kit; Pierce, Rockford, Ill.).
HeLa cell culture and CDT bioassay. A human epithelioid cervical carcinoma HeLa cell line (ATCC CCL-2) was maintained in Eagle's minimum essential medium (MEM; Sigma) supplemented with 10% fetal bovine serum (FBS; Atlanta Biologicals, Norcross, Ga.) and gentamicin (50 μg/ml; Sigma) at 37°C in a humidified atmosphere of 5% carbon dioxide in air. The CDT bioassay was performed as previously described by Johnson and Lior (20), with some modifications. Approximately 2 x 104 cells in 10% FBS-MEM were placed in each well of a chamber slide (Lab-Tek II chamber slide system; Nalge Nunc International, Naperville, Ill.) and incubated for 3 h at 37°C in 5% carbon dioxide in air. Either 100 μl of PBS (negative control), 20, 40, or 80 μM (final concentration) apigenin (positive control; apigenin is a compound known to arrest the cell cycle at the G2/M phase [53]), or 10.0, 20.0, or 40.0 μl of filter-sterilized lysate obtained from a reference or macaque Campylobacter isolate or a reference Arcobacter strain was then added to individual wells and incubated for an additional 72 to 96 h. At the end of the incubation, each culture was washed with PBS, fixed with 10% neutral buffered formalin (VWR International, West Chester, Pa.), stained with hematoxylin and eosin, and examined under a light microscope. The mean diameter and standard deviation of nuclei from 10 HeLa cells in cultures incubated with either PBS or 10 μl of filter-sterilized lysate obtained from C. coli EB53-02-12 or C. jejuni EB53-23-01 were determined. The nuclear morphology of control and HeLa cells incubated with bacterial lysates was examined further by use of a confocal laser scanning microscope (model FV500; Olympus Optical Co., Tokyo, Japan) after staining with propidium iodide (PI; Sigma) as previously described (2). Lysates from reference and macaque Campylobacter isolates were examined in at least two separate experiments, and positive and negative controls were included in each assay.
Cell cycle analysis by FACS. The G2/M-phase cell cycle arrest of HeLa cells incubated with lysates obtained from reference and macaque Campylobacter isolates and reference Arcobacter strains was determined quantitatively by fluorescence-activated cell sorter (FACS) analysis and compared with that of either untreated cells or HeLa cells incubated with PBS (negative control) or apigenin (positive control). Confluent monolayers of HeLa cells were treated with 0.05% (wt/vol) trypsin-EDTA (Invitrogen), washed with PBS, suspended in 10% FBS-MEM to obtain 3 x 105 cells in 5.0 ml, and placed into 25-cm2 flasks (Costar, Cambridge, Mass.). After 3 h, either 100 μl of PBS, 20, 40, or 80 μM (final concentration) apigenin, or 1.0, 10.0, 100.0, or 200.0 μl of filter-sterilized bacterial cell lysate was added to the culture medium, and the cells were incubated for an additional 72 h. HeLa cells were prepared for FACS analysis as previously described (5), with some modifications. After being washed with PBS, the cells were treated with trypsin and centrifuged at 1,000 x g for 2 min. The cell pellet was then suspended in PBS, transferred to 70% ethanol, and held at –20°C for 5 min. The cells were harvested by centrifugation and rehydrated with 1.0 ml of PBS at room temperature for 15 min. Following centrifugation, the cells were suspended in PI staining buffer (3 μg of PI/ml, 0.02 mg of RNase A/ml, 100 mM Tris [pH 7.2], 150 mM NaCl, 1 mM CaCl2, 0.5 mM MgCl2, 0.1% Triton X-100) and incubated at room temperature in the dark for 15 min. For DNA content analysis, approximately 1.0 x 104 cells were examined by FACS analysis, with the excitation set at 488 nm and the emission set at 630 nm (FACScan flow cytometer; Becton Dickinson) and with the data analyzed by use of Cell Quest and ModFit LT software (Becton Dickinson). Lysates from reference and macaque Campylobacter isolates and reference Arcobacter strains were examined in at least two separate experiments, and positive and negative controls were included in each assay.
Data analysis. FACS analysis data for HeLa cells in G2/M phase were expressed as mean percentages of HeLa cells with 4N DNA contents ± standard deviations. An association between the presence of CDT and the species of Campylobacter was determined by using the Student t test. The significance of association was tested at an value of 0.05.
Nucleotide sequence accession number. The 602-bp partial nucleotide sequence of the C. jejuni EB53-23-01 cdtB gene has been deposited in GenBank under accession number AY652840.
RESULTS
Clinical findings. Although C. jejuni and C. coli were isolated from rhesus and pig-tailed macaques, diarrheal illness was present only in rhesus macaques. Approximately equal numbers of symptomatic and asymptomatic rhesus macaques were infected with C. jejuni or C. coli. At the initial clinical presentation in September 2003, a stool specimen taken from rhesus macaque EB53 contained C. coli (Table 2, strain EB53-02-12), while clinically this monkey showed weakness and dehydration. After antibiotic therapy, the clinical status of the monkey improved and diarrhea ceased, but recurrent episodes of diarrhea continued through April 2004, and a culture of a stool specimen taken in October 2003 yielded C. jejuni (Table 2, strain EB53-23-01).
Phenotypic and genotypic characterizations. The macaque Campylobacter isolates formed distinct gray colonies, but cultures of ET03, ET46, and ET51 also formed a spreading haze that was maintained after subculture (Table 2). All of the isolates grew under microaerobic conditions at 37 and 42°C, but not at 25°C or under aerobic conditions. They were gram negative with a curved-rod morphology and had darting motility. The biochemical and genotypic characteristics of each isolate are presented in Table 2. Additionally, the isolates produced catalase and oxidase but did not produce urease or reduce nitrate to nitrite. With the exception of isolates EN69-49-09 and ET03-26-15, all of the C. jejuni isolates hydrolyzed hippurate. All of the isolates were resistant to cephalothin, and while the C. jejuni and C. coli isolates were generally susceptible to nalidixic acid, five C. jejuni isolates and one C. coli isolate were resistant. None of the isolates yielded products in multiplex PCR assays for the Arcobacter 16S rRNA and A. butzleri 23S rRNA genes.
Detection and characterization of cdtB gene. A putative 495-bp cdtB gene product was obtained by PCR amplification of all of the Campylobacter isolates by use of the degenerative oligonucleotide primers VAT2 and WMI1 (Table 2 and Fig. 1A). Conversely, only the C. jejuni isolates generated the expected 623-bp product by PCR amplification with C. jejuni cdtB gene-specific oligonucleotide primers (Table 2 and Fig. 1B). With the exception of a single silent nucleotide substitution (C instead of T at position 126), the consensus sequence of the cloned products obtained by PCR amplification of EB53-23-01 with the cdtB gene-specific oligonucleotide primers was identical to the cdtB gene sequence of the reference human strains C. jejuni subsp. jejuni NCTC 11168 (AL139074) (31), C. jejuni 81-176 (U51121) (35), and C. jejuni CH5 (AF038283) (16).
Morphological changes in HeLa cells incubated with bacterial lysates. Significant changes were not observed in HeLa cells incubated with PBS (Fig. 2A) or in lysates obtained from either the reference and macaque C. coli isolates (Fig. 2B), the C. jejuni isolate EJ92, or the reference Arcobacter isolates at any of the times and concentrations examined. HeLa cells incubated with either apigenin or the reference and remaining macaque C. jejuni isolates displayed morphological changes that were characteristic of CDT in a time- and dose-dependent manner. HeLa cells incubated with 20 and 40 μM apigenin had larger cytoplasmic boundaries than control cells by 48 h, whereas cellular enlargement was apparent by 24 h with the 80 μM concentration. Between 48 and 72 h of incubation, the cellular enlargement became progressively more prominent. A marked enlargement of the cytoplasmic boundaries and the nucleus was first seen by 48 h for HeLa cells incubated with lysates obtained from the reference and macaque C. jejuni isolates. Between 72 and 96 h, the mean size of distended cells was approximately 2.0- to 2.5-fold that of control cells (Fig. 2C). By 96 h, nuclear fragmentation and cytoplasmic vacuolation were also seen. A dose effect similar to that for apigenin was seen with the C. jejuni lysates. Ten microliters of C. jejuni lysate was sufficient to exert a cytotoxic effect, whereas larger volumes caused more rapid and prominent morphological changes. Although the magnitude of the cellular changes over time varied among the C. jejuni isolates and with the protein concentration of the lysate, only the reference and macaque C. jejuni isolates produced detectable cellular and nuclear enlargement. In addition to the characteristic cellular enlargement, HeLa cells incubated with either apigenin or nearly all C. jejuni lysates, but not with the C. coli or Arcobacter isolates, contained between 1 and 2% multinucleated giant cells, depending on the isolate (Fig. 2C). When HeLa cells were incubated with either PBS, lysates from reference and macaque C. coli isolates, the C. jejuni isolate EJ92, or reference Arcobacter strains, stained with PI, and examined under a confocal laser scanning microscope, they had small nuclei with widely dispersed small nucleoli (Fig. 3A and B). In contrast, HeLa cells incubated with lysates from reference strains and the remaining macaque C. jejuni isolates had a mean nuclear size of approximately 1.5- to 2.0-fold that of control cells, contained fewer and more prominent nucleoli (Fig. 3C and D), and had occasional multinucleated giant cells (Fig. 3E and F) by 48 h.
Quantitative fluorescent cell cycle analysis of HeLa cells incubated with bacterial lysates. Approximately 10.6% ± 0.2% of the cells in untreated HeLa cell cultures and cultures incubated with PBS were in the G2/M phase (Fig. 4A). Conversely, HeLa cell cultures incubated in the presence of apigenin had an increase in the percentage of cells that were arrested at the G2/M phase in a dose-dependent manner: <10% of the cells were in the G2/M phase with 20 μM apigenin, whereas 57.0% ± 18.0% and 78.5% ± 16.2% of the cells were in the G2/M phase with 40 and 80 μM apigenin, respectively. For HeLa cells incubated with any concentration of lysate obtained from either the reference or macaque C. coli isolates, <7.6% ± 1.8% of the cells were in the G2/M phase (Fig. 4B). Similarly, for HeLa cells incubated with lysates obtained from the reference Arcobacter strains, <9.8% ± 0.3% of the cells were in the G2/M phase. In contrast, 81.1% ± 4.8% of HeLa cells were arrested in the G2/M phase when they were incubated with a lysate obtained from the reference strain C. jejuni ATCC 49943. The percentage of HeLa cells arrested in G2/M phase ranged between 35.6% ± 12.0% and 98.6% ± 0.2% after incubation with lysates obtained from the macaque-derived C. jejuni isolates (Fig. 4C). Compared with those from other isolates, the lysate obtained from the macaque C. jejuni isolate EJ92 did not cause a significant increase in the percentage of HeLa cells arrested in the G2/M phase of the cell cycle, with 17.1% ± 3.0% of the cells being in this phase. In all of the assays, the progressive increase in the percentage of cells in G2/M phase (4N DNA content) was accompanied by a corresponding decline in the number of cells in G1 phase (2N DNA content). The variable percentages of HeLa cells arrested in the G2/M phase with different C. jejuni lysates could not be attributed to the concentration of protein, but rather depended on the absolute amount of CDT produced by individual isolates. Thus, 1 μl of EB53-23-01 lysate containing approximately 3 μg of protein caused >96% of HeLa cells to arrest in the G2/M phase, whereas 20 μl of ET03-26-15 lysate containing approximately 40 μg of protein was required to achieve a similar level of arrest. In addition to HeLa cells with 4N DNA contents, cells with 8N DNA contents were seen after incubation with apigenin and lysates from reference and macaque C. jejuni isolates, but not with lysates from either reference and macaque C. coli or reference Arcobacter strains. The production of CDT was positively correlated with lysates obtained from C. jejuni (P < 0.0001) but not with those obtained from C. coli.
DISCUSSION
Phenotypic and genotypic characterizations of Campylobacter strains isolated from captive conventionally raised macaques revealed that cdtB gene sequences were present in both C. jejuni and C. coli but that CDT activity was only present in the 2 reference human C. jejuni isolates and 15 of the 16 C. jejuni isolates from macaques. This is consistent with previous reports indicating that although the cdtB gene is present in both C. jejuni and C. coli (8), the production of CDT is a characteristic of C. jejuni (16, 35). A previous study found CDT activity in C. jejuni strains isolated from 13 of 14 humans, 3 of 4 cows, a goat, and a lamb, whereas C. coli strains isolated from 10 humans, a cow, and a sheep had no significant CDT activity (35). Our data extend these previous observations to include Campylobacter strains isolated from nonhuman primates. Because the membrane fraction of C. jejuni, but not C. coli, can elicit the release of interleukin-8 by human intestinal epithelial cells (16), the absence of CDT activity in macaque C. coli isolates and the C. jejuni isolate EJ92 might be attributable to either an inability to produce CDT or the production of abnormal or inactive CDT in these isolates. Alternatively, as recently suggested for A. actinomycetemcomitans (57), polymorphisms in the cdtABC flanking regions might account for the absence of CDT activity in some strains. The absence of the cdtB gene and of CDT activity in the reference Arcobacter strains was consistent with a previous report indicating that these strains do not have this virulence determinant (17).
Although CDT has been suggested as a virulence determinant, four of eight rhesus macaques and four pig-tailed macaques with toxigenic C. jejuni did not exhibit clinical signs of enteric disorders. This may be attributable to either (i) sampling prior to clinical disease, (ii) sampling after recovery from infection while the animals were subclinically infected, or (iii) a requirement for either additional or other virulence determinants for clinical diarrhea associated with C. jejuni infection. On the basis of experimental challenge studies, the possibility that macaques are not susceptible to C. jejuni infection is unlikely (9, 38, 40). However, because C. jejuni-specific immunity can prevent reinfection of recovered hosts, including macaques (3, 9, 38), and because the four asymptomatic rhesus macaques were older than those with clinical diarrhea (mean age ± standard deviation, 3.52 ± 0.93 versus 1.33 ± 0.76), prior exposure and protective immunity might explain the absence of clinical signs in these monkeys. Conversely, two of the pig-tailed macaques were less than a year old, suggesting that maternal immunity might have prevented clinical disease in these monkeys. It is likely that virulence determinants other than CDT play a role in diarrheal disease caused by C. jejuni. Because the toxigenic C. jejuni isolates were not examined for virulence determinants other than the presence of the ceuE gene (12), it is unknown whether or not these isolates lack other determinants required for disease expression in their natural host. Nevertheless, CDT alone was recently shown to play an essential role in disease by use of an NF-B-deficient mouse model of campylobacteriosis (11).
Stool cultures taken from six rhesus macaques with diarrhea had C. coli only. Although C. coli can cause diarrhea in susceptible hosts, including monkeys, the possibility that C. jejuni or some other enteropathogen was responsible for chronic diarrhea cannot be ruled out completely. As seen with rhesus macaque EB53, from which repeated stool cultures yielded C. coli at the first sampling and toxigenic C. jejuni a month later, a single stool culture might not be sufficient in order to assess the role of Campylobacter species in diarrhea of colony-raised macaques. As previously shown, continuous exposure to pathogenic Campylobacter and reinfection with different strains over time are common among conventionally raised macaques kept in close contact in primate colonies (39, 43).
Although most of the macaque C. jejuni and C. coli isolates conformed to their respective phenotypic characteristics, three macaques had C. jejuni isolates that either grew as a spreading haze or formed individual colonies, two others had isolates that did not hydrolyze hippurate, and six had C. jejuni or C. coli isolates that were resistant to nalidixic acid. Isolates of C. jejuni with a spreading haze phenotype might represent motility variants (3). The ability of C. jejuni to hydrolyze hippurate into benzoic acid and glycine is commonly used for rapid laboratory differentiation between C. jejuni and C. coli or other, less common Campylobacter species (10, 29). The isolation of a macaque C. jejuni strain that did not hydrolyze hippurate was consistent with previous reports indicating that certain C. jejuni strains isolated from humans and other hosts, including macaques, do not hydrolyze hippurate (39, 49, 52). In spite of these various phenotypes, CDT activity was found exclusively among C. jejuni isolates. As suggested previously (8, 35), the cdtB genes of C. jejuni and C. coli appear to be sufficiently divergent to allow the differentiation of each species by use of a C. jejuni cdtB gene-specific PCR assay. In contrast with the variability of phenotypes for the hydrolysis of hippurate, the C. jejuni cdtB gene-specific PCR assay might be useful for differentiating toxigenic C. jejuni from C. coli in clinical laboratories.
In addition to the progressive cytoplasmic and nuclear enlargement and G2/M-phase cell cycle arrest characteristic of CDT, HeLa cell cultures incubated with either apigenin or lysates obtained from reference and macaque C. jejuni strains contained cells with 8N DNA according to FACS analysis. These cells with four times the normal amount of DNA likely corresponded to the 1 to 2% of multinucleated giant cells seen by direct microscopic examination. The presence of multinucleated giant cells in HeLa cell cultures treated with CDT was originally reported by Johnson and Lior (20) as a feature of Campylobacter fetus subsp. fetus. Similar multinucleated giant cells have also been found in HeLa cell cultures treated with lysates from certain enterohepatic Helicobacter species (4, 24) and E. coli (2, 48). An interruption of cytokinesis while nuclear division continues has been suggested as a possible mechanism for the formation of multinucleated cells in the presence of CDT (2). In addition to nuclear enlargement, HeLa cells incubated with C. jejuni lysates and examined by confocal laser scanning microscopy had nuclei with few but expanded nucleoli, suggesting that there was enhanced ribosome biogenesis.
In conclusion, we found the cdtB gene and CDT activity in C. jejuni strains isolated from healthy macaques and from macaques with clinical signs of diarrhea. Although the cdtB gene was also present in C. coli strains isolated from symptomatic and asymptomatic macaques, only lysates obtained from the C. jejuni isolates caused cytoplasmic and nuclear enlargement together with the cell cycle arrest of HeLa cells in the G2/M phase that is characteristic of CDT activity.
ACKNOWLEDGMENTS
We thank Michael J. Cole, Melinda Martin, and Maurice Duplantis of the Tulane National Primate Research Center (TNPRC), Paul Nabity and Debra Royal of the Veterinary Diagnostic Center, and Jennifer Flores of the Center for Biotechnology (UNL) for their excellent technical assistance. We thank Andrew A. Lackner and James Blanchard for providing the resources at the TNPRC through an RR00164 base grant. The pig-tailed macaques were the property of the Washington National Primate Research Center.
This work was partially supported by funds provided by the USDA/CSREES, National Research Initiative, Competitive Grants Program, project NEB 14-114, by Multi-State Research Project NC-1007, and by Animal Health Project NEB-14-118 to G.E.D.
This is paper no. 14670 of the Agriculture Research Division, Institute of Agriculture and Natural Resources, University of Nebraska-Lincoln.
REFERENCES
Ahmed, H. J., L. A. Svensson, L. D. Cope, J. L. Latimer, E. J. Hansen, K. Ahlman, J. Bayat-Turk, D. Klamer, and T. Lagergrd. 2001. Prevalence of cdtABC genes encoding cytolethal distending toxin among Haemophilus ducreyi and Actinobacillus actinomycetemcomitans strains. J. Med. Microbiol. 50:860-864.
Aragon, V., K. Chao, and L. A. Dreyfus. 1997. Effect of cytolethal distending toxin on F-actin assembly and cell division in Chinese hamster ovary cells. Infect. Immun. 65:3774-3780.
Black, R. E., M. M. Levine, M. L. Clements, T. P. Hughes, and M. J. Blaser. 1988. Experimental Campylobacter jejuni infection in humans. J. Infect. Dis. 157:472-479.
Chien, C., N. S. Taylor, Z. Ge, D. B. Schauer, V. B. Young, and J. G. Fox. 2000. Identification of cdtB homologues and cytolethal distending toxin activity in enterohepatic Helicobacter spp. J. Med. Microbiol. 49:525-534.
Cortes-Bratti, X., E. Chaves-Olarte, T. Lagergrd, and M. Thelestam. 1999. The cytolethal distending toxin from the chancroid bacterium Haemophylus ducreyi induces cell-cycle arrest in the G2 phase. J. Clin. Investig. 103:107-115.
Elwell, C. A., and L. A. Dreyfus. 2000. DNase I homologous residues in cdtB are critical for cytolethal distending toxin-mediated cell cycle arrest. Mol. Microbiol. 37:952-963.
Elwell, C., K. Chao, K. Patel, and L. Dreyfus. 2001. Escherichia coli cdtB mediates cytolethal distending toxin cell cycle arrest. Infect. Immun. 69:3418-3422.
Eyigor, A., K. A. Dawson, B. E. Langlois, and C. L. Pickett. 1999. Detection of cytolethal distending toxin activity and cdt genes in Campylobacter spp. isolated from chicken carcasses. Appl. Environ. Microbiol. 65:1501-1505.
Fitzgeorge, R. B., A. Baskerville, and K. P. Lander. 1981. Experimental infection of rhesus monkeys with a human strain of Campylobacter jejuni. J. Hyg. Camb. 86:343-351.
Forbes, B. A., D. F. Sahm, and A. S. Weissfield. 1998. Campylobacter, Arcobacter, and Helicobacter, p. 570-572. In B. A. Forbes, D. F. Sahm, and A. S. Weissfield (ed.), Diagnostic microbiology, 10th ed. Mosby, New York, N.Y.
Fox, J. G., A. B. Rogers, M. T. Whary, Z. Ge, N. S. Taylor, S. Xu, B. H. Horwitz, and S. E. Erdman. 2004. Gastroenteritis in NF-B-deficient mice is produced with wild-type Campylobacter jejuni but not with C. jejuni lacking cytolethal distending toxin despite persistent colonization with both strains. Infect. Immun. 72:1116-1125.
Gonzalez, I., K. A. Grant, P. T. Richardson, S. F. Park, and M. D. Collins. 1997. Specific identification of the enteropathogens Campylobacter jejuni and Campylobacter coli by using a PCR test based on the ceuE gene encoding a putative virulence determinant. J. Clin. Microbiol. 35:759-763.
Haghjoo, E., and J. E. Galán. 2004. Salmonella typhi encodes a functional cytolethal distending toxin that is delivered into host cells by a bacterial-internalization pathway. Proc. Natl. Acad. Sci. USA 101:4614-4619.
Harmon, K. M., and I. V. Wesley. 1997. Multiplex PCR for the identification of Arcobacter and differentiation of Arcobacter butzleri from other arcobacters. Vet. Microbiol. 58:215-227.
Harris, N. V., N. S. Weiss, and C. M. Nolan. 1986. The role of poultry and meats in the etiology of Campylobacter jejuni/coli enteritis. Am. J. Public Health 76:407-411.
Hickey, T. E., A. L. McVeigh, D. A. Scott, R. E. Michielutti, A. Bixby, S. A. Carroll, A. L. Bourgeois, and P. Guerry. 2000. Campylobacter jejuni cytolethal distending toxin mediates release of interleukin-8 from intestinal epithelial cells. Infect. Immun. 68:6535-6541.
Johnson, L. G., and E. A. Murano. 2002. Lack of a cytolethal distending toxin among Arcobacter isolates from various sources. J. Food Prot. 65:1789-1795.
Johnson, W. M., and H. Lior. 1987. Production of Shiga toxin and a cytolethal distending toxin (CLDT) by serogroups of Shigella spp. FEMS Microbiol. Lett. 48:235-238.
Johnson, W. M., and H. Lior. 1988. A new heat-labile cytolethal distending toxin (CLDT) produced by Escherichia coli isolates from clinical material. Microb. Pathog. 4:103-113.
Johnson, W. M., and H. Lior. 1988. A new heat-labile cytolethal distending toxin (CLDT) produced by Campylobacter spp. Microb. Pathog. 4:115-126.
Ketley, J. M. 1997. Pathogenesis of enteric infection by Campylobacter. Microbiology 143:5-21.
Kolashnikova, V. A., E. K. Dzsikidze, Z. K. Stasilevich, and M. G. Chikobava. 2002. Detection of Campylobacter jejuni in healthy monkeys and monkeys with enteric infections by PCR. Bull. Exp. Med. 134:299-300.
Konkel, M. E., M. R. Monteville, V. Rivera-Amill, and L. A. Joens. 2001. The pathogenesis of Campylobacter jejuni-mediated enteritis. Curr. Issues Intest. Microbiol. 2:55-71.
Kostia, S., P. Veijalainen, U. Hirvi, and M. L. Hnninen. 2003. Cytolethal distending toxin B gene (cdtB) homologues in taxa 2, 3 and 8 and in six canine isolates of Helicobacter sp. flexispira. J. Med. Microbiol. 52:103-108.
Lara-Tejero, M., and J. E. Galán. 2000. A bacterial toxin that controls cell cycle progression as a deoxyribonuclease I-like protein. Science 290:354-357.
Lara-Tejero, M., and J. E. Galán. 2002. Cytolethal distending toxin: limited damage as a strategy to modulate cellular functions. Trends Microbiol. 10:147-152.
Mooney, A., M. Clyne, T. Curran, D. Doherty, B. Kilmartin, and B. Bourke. 2001. Campylobacter upsaliensis exerts a cytolethal distending toxin effect on HeLa cells and T lymphocytes. Microbiology 147:735-743.
Okuda, J., M. Fukomoto, Y. Takeda, and M. Nishibushi. 1997. Examination of diarrheagenicity of cytolethal distending toxin: suckling mouse response to the products of the cdtABC genes of Shigella dysenteriae. Infect. Immun. 65:428-433.
On, S. L. W. 1996. Identification methods for campylobacters, helicobacters, and related organisms. Clin. Microbiol. Rev. 9:405-422.
Pandey, M., A. Khan, S. C. Das, B. Sarka, S. Kahali, S. Chakraborty, S. Chattopadhyay, S. Yamasaki, Y. Takeda, G. B. Nair, and T. Ramamurthy. 2003. Association of cytolethal distending toxin locus cdtB with enteropathogenic Escherichia coli isolated from patients with acute diarrhea in Calcutta, India. J. Clin. Microbiol. 41:5277-5281.
Parkhill, J., B. W. Wren, K. Mungall, J. M. Ketley, C. Churcher, D. Basham, T. Chillingworth, R. M. Davies, T. Feltwell, S. Holroyd, K. Jagels, A. Karlyshev, S. Moule, M. J. Pallen, C. W. Penn, M. Quail, M. A. Rajandream, K. M. Rutherford, A. VanVliet, S. Whitehead, and B. G. Barrell. 2000. The genome sequence of the food-borne pathogen Campylobacter jejuni reveals hypervariable sequences. Nature 403:665-668.
Peres, S. Y., O. Marches, F. Daigle, J. P. Nougayrede, F. Herault, C. Tasca, J. De Rycke, and E. Oswald. 1997. A new cytolethal distending toxin (CDT) from Escherichia coli producing CNF2 blocks HeLa cell division in G2/M phase. Mol. Microbiol. 24:1095-1107.
Pickett, C. L., and C. A. Whitehouse. 1999. The cytolethal distending toxin family. Trends Microbiol. 7:292-297.
Pickett, C. L., D. L. Cottle, E. C. Pesci, and G. Bikah. 1994. Cloning, sequencing, and expression of the Escherichia coli cytolethal distending toxin genes. Infect. Immun. 62:1046-1051.
Pickett, C. L., E. C. Pesci, D. L. Cottle, G. Russell, A. N. Erdem, and H. Zeytin. 1996. Prevalence of cytolethal distending toxin production in Campylobacter jejuni and relatedness of Campylobacter sp. cdtB genes. Infect. Immun. 64:2070-2078.
Puven, M., and T. Lagergrd. 1992. Haemophilus ducreyi, a cytotoxin-producing bacterium. Infect. Immun. 60:1156-1162.
Russell, R. G., S. L. Rosenkranz, L. A. Lee, H. Howard, R. F. DiGiacomo, M. A. Bronsdon, G. A. Blakley, C.-C. Tsai, and W. R. Morton. 1987. Epidemiology and etiology of diarrhea in colony-born Macaca nemestrina. Lab. Anim. Sci. 37:309-316.
Russell, R. G., M. J. Blaser, J. I. Sarmiento, and J. Fox. 1989. Experimental Campylobacter jejuni infection in Macaca nemestrina. Infect. Immun. 57:1438-1444.
Russell, R. G., J. I. Sarmiento, J. Fox, and P. Panigrahi. 1990. Evidence of reinfection with multiple strains of Campylobacter jejuni and Campylobacter coli in Macaca nemestrina housed under hyperendemic conditions. Infect. Immun. 58:2149-2155.
Russell, R. G., M. O'Donnoghue, D. C. Blake, Jr., J. Zulty, and L. J. DeTolla. 1993. Early colonic damage and invasion of Campylobacter jejuni in experimentally challenged infant Macaca mulatta. J. Infect. Dis. 168:210-215.
Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467.
Scott, D. A., and J. B. Kaper. 1994. Cloning and sequencing of the genes encoding Escherichia coli cytolethal distending toxin. Infect. Immun. 62:244-251.
Sestak, K., C. K. Merritt, J. Borda, E. Saylor, S. R. Schwamberger, F. Cogswell, E. S. Didier, P. J. Didier, G. Plauche, R. P. Bohm, P. P. Aye, P. Alexa, R. L. Ward, and A. A. Lackner. 2003. Infectious agent and immune response characteristics of chronic enterocolitis in captive rhesus macaques. Infect. Immun. 71:4079-4086.
Shenker, B. J., T. McKay, S. Datar, M. Miller, R. Chowhan, and D. Demuth. 1999. Actinobacillus actinomycetemcomitans immunosuppressive protein is a member of the family of cytolethal distending toxins capable of causing a G2 arrest in human T cells. J. Immunol. 162:4773-4780.
Skerman, V. B. D., V. McGowan, and P. H. A. Sneath. 1980. Approved lists of bacterial names. Int. J. Syst. Bacteriol. 30:225-420.
Sugai, M., T. Kawamoto, S. Peres, Y. Ueno, H. Komatsuzawa, T. Fujiwara, H. Kurihara, H. Suginaka, and E. Oswald. 1998. The cell cycle-specific growth-inhibitory factor produced by Actinobacillus actinomycetemcomitans is a cytolethal distending toxin. Infect. Immun. 66:5008-5019.
Tauxe, R. V. 1997. Emerging foodborne diseases: an evolving public health challenge. Emerg. Infect. Dis. 3:425-434.
Toth, I., F. Herault, L. Beutin, and E. Oswald. 2003. Production of cytolethal distending toxins by pathogenic Escherichia coli strains isolated from human and animal sources: establishment of the existence of a new cdt variant (type IV). J. Clin. Microbiol. 41:4285-4291.
Totten, P. A., C. M. Patton, F. C. Tenover, T. J. Barrett, W. E. Stamm, A. G. Steigerwalt, J. Y. Lin, K. K. Holmes, and D. J. Brenner. 1987. Prevalence and characterization of hippurate-negative Campylobacter jejuni in King County, Washington. J. Clin. Microbiol. 25:1747-1752.
Vandamme, P., E. Falsen, R. Rossau, B. Hoste, P. Segers, R. Tytgat, and J. de Ley. 1991. Revision of Campylobacter, Helicobacter and Wolinella taxonomy: emendation of generic descriptions and proposal of Arcobacter gen. nov. Int. J. Syst. Bacteriol. 41:88-103.
Vandamme, P., M. Vancanneyt, B. Pot, L. Mels, B. Hoste, D. Dewettinck, L. Vlaes, C. van den Borre, R. Higgins, J. Hommez, K. Kersters, J. P. Butzler, and H. Goossens. 1992. Polyphasic taxonomic study of the emended genus Arcobacter with Arcobacter butzleri comb. nov. and Arcobacter skirrowii sp. nov., an aerotolerant bacterium isolated from veterinary specimens. Int. J. Syst. Bacteriol. 42:344-356.
Wain, M., D. D. Bang, M. Lund, S. Nordentoft, J. S. Andersen, K. Pedersen, and M. Madsen. 2003. Identification of campylobacteria isolated from Danish broilers by phenotypic tests and species-specific PCR assays. J. Appl. Microbiol. 95:649-655.
Wang, W., L. Heideman, C. S. Chung, J. C. Pelling, K. J. Koehler, and D. F. Bert. 2000. Cell cycle arrest at G2/M and growth inhibition by apigenin in human carcinoma cell lines. Mol. Carcinog. 28:102-110.
Wassenaar, T. M. 1997. Toxin production by Campylobacter spp. Clin. Microbiol. Rev. 10:466-476.
Wassenaar, T. M., and M. J. Blaser. 1999. Pathophysiology of Campylobacter jejuni infections of humans. Microb. Infect. 1:1023-1033.
Whitehouse, C. A., P. A. Balbo, E. C. Pesci, D. L. Cottle, P. M. Mirabito, and C. L. Pickett. 1998. Campylobacter jejuni cytolethal distending toxin causes a G2-phase cell cycle block. Infect. Immun. 66:1934-1940.
Yamano, R., M. Ohara, S. Nishikubo, T. Fujiwara, T. Kawamoto, Y. Ueno, H. Komatsuzawa, K. Okuda, H. Kurihara, H. Suginaka, E. Oswald, K. Tanne, and M. Sugai. 2003. Prevalence of cytolethal distending toxin production in periodontopathogenic bacteria. J. Clin. Microbiol. 41:1391-1398.(Rohana P. Dassanayake, Yo)
婵犵數鍎戠徊钘壝洪悩璇茬婵犻潧娲ら閬嶆煕濞戝崬鏋ゆい鈺冨厴閺屾稑鈽夐崡鐐差潾闁哄鏅滃Λ鍐蓟濞戞ǚ鏋庨煫鍥ㄦ尨閸嬫挻绂掔€n亞鍔﹀銈嗗坊閸嬫捇鏌涢悩宕囥€掓俊鍙夊姇閳规垿宕堕埞鐐亙闁诲骸绠嶉崕鍗炍涘☉銏犵劦妞ゆ帒顦悘锔筋殽閻愬樊鍎旀鐐叉喘椤㈡棃宕ㄩ鐐靛搸婵犵數鍋犻幓顏嗗緤閹灐娲箣閻樺吀绗夐梺鎸庣箓閹峰宕甸崼婢棃鏁傜粵瀣妼闂佸摜鍋為幐鎶藉蓟閺囥垹骞㈤柡鍥╁Т婵′粙鏌i姀鈺佺仩缂傚秴锕獮濠囨晸閻樿尙鐤€濡炪倖鎸鹃崑鐔哥閹扮増鈷戦柛锔诲帎閻熸噴娲Χ閸ヮ煈娼熼梺鍐叉惈閹冲氦绻氶梻浣呵归張顒傜矙閹烘鍊垫い鏂垮⒔绾惧ジ鏌¢崘銊モ偓绋挎毄濠电姭鎷冮崟鍨杹閻庢鍠栭悥鐓庣暦濮椻偓婵℃瓕顦抽柛鎾村灦缁绘稓鈧稒岣块惌濠偽旈悩鍙夋喐闁轰緡鍣i、鏇㈡晜閽樺鈧稑鈹戦敍鍕粶濠⒀呮櫕缁瑦绻濋崶銊у幐婵犮垼娉涢敃銈夊汲閺囩喐鍙忛柣鐔煎亰濡偓闂佽桨绀佺粔鎾偩濠靛绀冩い顓熷灣閹寸兘姊绘担绛嬪殐闁哥姵鎹囧畷婵婄疀濞戣鲸鏅g紓鍌欑劍宀e潡鍩㈤弮鍫熺厽闁瑰鍎戞笟娑㈡煕閺傚灝鏆i柡宀嬬節瀹曟帒顫濋鐘靛幀缂傚倷鐒﹂〃鍛此囬柆宥呯劦妞ゆ帒鍠氬ḿ鎰磼椤旇偐绠婚柨婵堝仱閺佸啴宕掑鍗炴憢闂佽崵濞€缂傛艾鈻嶉敐鍥╃煋闁割煈鍠撻埀顒佸笒椤繈顢橀悩顐n潔闂備線娼уú銈吤洪妸鈺佺劦妞ゆ帒鍋嗛弨鐗堢箾婢跺娲寸€规洏鍨芥俊鍫曞炊閵娿儺浼曢柣鐔哥矌婢ф鏁Δ鍜冪稏濠㈣埖鍔栭崑锝夋煕閵夘垰顩☉鎾瑰皺缁辨帗娼忛妸褏鐣奸梺褰掝棑婵炩偓闁诡喗绮撻幐濠冨緞婢跺瞼姊炬繝鐢靛仜椤曨厽鎱ㄦィ鍐ㄦ槬闁哄稁鍘奸崹鍌炴煏婵炵偓娅嗛柛瀣ㄥ妼闇夐柨婵嗘噹閺嗙喐淇婇姘卞ⅵ婵﹥妞介、鏇㈡晲閸℃瑦顓婚梻浣虹帛閹碱偆鎹㈠┑瀣祦閻庯綆鍠栫粻锝嗙節婵犲倸顏柟鏋姂濮婃椽骞愭惔锝傛闂佸搫鐗滈崜鐔风暦閻熸壋鍫柛鏇ㄥ弾濞村嫬顪冮妶鍡楃瑐闁绘帪绠撳鎶筋敂閸喓鍘遍梺鐟版惈缁夋潙鐣甸崱娑欑厓鐟滄粓宕滃顒夋僵闁靛ň鏅滈崑鍌炴煥閻斿搫孝閻熸瑱绠撻獮鏍箹椤撶偟浠紓浣插亾濠㈣泛鈯曡ぐ鎺戠闁稿繗鍋愬▓銈夋⒑缂佹ḿ绠栭柣鈺婂灠閻g兘鏁撻悩鑼槰闂佽偐鈷堥崜姘额敊閹达附鈷戦悹鍥b偓铏亖闂佸憡鏌ㄦ鎼佸煝閹捐绠i柣鎰綑椤庢挸鈹戦悩璇у伐闁哥噥鍨堕獮鍡涘磼濮n厼缍婇幃鈺呭箵閹烘繂濡锋繝鐢靛Л閸嬫捇鏌熷▓鍨灓缁鹃箖绠栭弻鐔衡偓鐢登瑰暩閻熸粎澧楅悡锟犲蓟濞戙垹绠抽柡鍌氱氨閺嬪懎鈹戦悙鍙夊櫣闂佸府绲炬穱濠囧箻椤旇姤娅㈤梺璺ㄥ櫐閹凤拷Veterinary Diagnostic Center, University of Nebraska-Lincoln, Lincoln, Nebraska
Tulane National Primate Research Center, Covington, Louisiana
ABSTRACT
An association between certain Campylobacter species and enterocolitis in humans and nonhuman primates is well established, but the association between cytolethal distending toxin and disease is incompletely understood. The purpose of the present study was to examine Campylobacter species isolated from captive conventionally raised macaque monkeys for the presence of the cdtB gene and for cytolethal distending toxin activity. The identity of each isolate was confirmed on the basis of phenotypic and genotypic analyses. The presence of cytolethal distending toxin was confirmed on the basis of characteristic morphological changes in HeLa cells incubated with filter-sterilized whole-cell lysates of reference and monkey Campylobacter isolates and examinations by light microscopy, confocal microscopy, and flow cytometry. Although cdtB gene sequences were found in both Campylobacter jejuni and Campylobacter coli, the production of cytolethal distending toxin correlated positively (P < 0.0001) only with C. jejuni. We concluded that cytolethal distending toxin activity is a characteristic of C. jejuni. Our C. jejuni cdtB gene-specific PCR assay might be of assistance for differentiating toxigenic C. jejuni from C. coli in clinical laboratories.
INTRODUCTION
Members of the Campylobacter genus are motile, curved, gram-negative, phenotypically heterogeneous bacilli that colonize the mucus on the surface and crypts of the intestine, where certain species can cause epithelial damage and elicit host inflammatory and immune responses (21, 23, 55). Campylobacter jejuni is the leading cause of food-borne infectious diarrheal disease in humans in many developed countries, including the United States (47). The primary source of food-borne human Campylobacter species infections is contaminated chicken (15).
Campylobacter species account for a large percentage of diarrheal illnesses of colony-raised macaque monkeys (22, 37, 39, 43). Both the duration and the clinical presentation of diarrheal illness in rhesus macaques (Macaca mulatta) and pig-tailed macaques (Macaca nemestrina) experimentally challenged with C. jejuni are similar to those seen in humans (3, 9, 38, 40). The disease in macaques is characterized by diarrhea of variable severity and duration accompanied by prolonged intermittent fecal shedding of C. jejuni. Epidemiological studies of infant pig-tailed macaques kept in a nursery facility have further revealed that infection and reinfection with multiple strains of C. jejuni and Campylobacter coli are common, and as seen in humans (3), recovered monkeys are often asymptomatic (39).
Although several virulence determinants have been identified for pathogenic Campylobacter species, the significance of cytotoxins in disease is relatively poorly understood (54). A newly characterized heat-labile and trypsin-sensitive cytotoxin, known as cytolethal distending toxin (CDT), was first identified from Shigella, Escherichia coli, and C. jejuni isolated from human and nonhuman sources over 15 years ago (18-20). In the last decade, the gene encoding CDT, cdtB, has been found in most Campylobacter species (8, 27, 35, 56) and in several serotypes of E. coli (7, 32, 34, 42, 48). Homologues of cdtB and CDT activity have also been found among enterohepatic Helicobacter species that associate with the intestinal mucosa (4, 24) and, most recently, in Salmonella enterica serovar Typhi (13). Other gram-negative bacteria harboring the cdtB gene and producing CDT activity include the periodontopathogenic bacterium Actinobacillus actinomycetemcomitans (1, 44, 46, 57) and the venereal pathogen Haemophilus ducreyi (1, 5, 36).
With the exception of S. enterica serovar Typhi, in which only cdtB is found (13), in all other microbes CDT consists of a tripartite polypeptide complex of CdtA (30 kDa), CdtB (29 kDa), and CdtC (21 kDa), encoded by the corresponding genes cdtA, cdtB, and cdtC (26, 33). Although considerable divergence in the predicted amino acid sequences of each CDT subunit exists among different microbes, the cdtB genes have conserved structural similarities to the mammalian DNase I catalytic and Mg2-binding sites (6, 25). When it interacts with certain eukaryotic cells, the CDT holotoxin causes progressive cytoplasmic and nuclear distension accompanied by increased DNA contents, leading to growth arrest at the G2/M transition phase of the cell cycle and, ultimately, cell death (2, 5, 32, 44, 56).
There is some evidence that CDT is a virulence determinant for naturally occurring and experimentally induced enteric diseases associated with C. jejuni (11), E. coli (30), and Shigella dysenteriae (28). Experimental challenge studies support a role for C. jejuni as a cause of diarrheal disease in monkeys (9, 38), but Campylobacter strains isolated from monkeys have not been examined for the presence of the cdtB gene and for CDT activity. For this study, we examined Campylobacter strains isolated from captive conventionally raised macaques with and without clinical signs of diarrhea for the presence of the cdtB gene and CDT activity. We found that both C. jejuni and C. coli have the cdtB gene but that CDT activity was only present in C. jejuni.
CASE REPORTS
The clinical presentations and housing of 28 macaques investigated in the present study are outlined in Table 1. The sex distribution of 20 females versus 8 males reflects the natural distribution in the colony. The animals were kept at the Tulane National Primate Research Center in accordance with the standards of the Guide for the Care and Use of Laboratory Animals and the Association for Assessment and Accreditation of Laboratory Animal Care. The macaques were housed either in groups in outdoor breeding cages or individually indoors at biocontainment level 2. Stool specimens were collected either during routine health monitoring of the colony or from macaques with clinical manifestations of diarrheal illnesses of various durations (Table 1). Following an initial sampling in September 2003, rhesus macaque EB53 was treated with the broad-spectrum antibiotic tylosin at a dose of 10 mg/kg of body weight by intramuscular injections twice a day for 10 days and was resampled a month later when diarrhea was still present. The isolation of Campylobacter species from stool specimens was the main selection criterion for study assignment.
MATERIALS AND METHODS
Bacterial strains and growth conditions. Campylobacter strains were isolated from stool specimens by microaerobic incubation at 42°C on Campylobacter selective agar (BBL, Cockeysville, Md.) containing cefoperazone, vancomycin, and amphotericin B and then initially identified as previously described (43). The reference human strains C. jejuni subsp. jejuni VPI H840 (ATCC 29428 [50]) and LRA 094.06.89 (ATCC 49943), the porcine strains C. coli CIP 7080 (ATCC 33559 [45]) and LRA 069.05.89 (ATCC 49941), the human strain Arcobacter butzleri LMG 10828 (ATCC 49616 [51]), and the sheep strain Arcobacter skirrowii LMG 6621 (ATCC 51132 [51]) were used as controls. Stock cultures were propagated onto Trypticase soy agar with 5% (vol/vol) sheep blood (TSAB; Remel, Lenexa, Kans.) and incubated under microaerobic conditions (Mitsubishi Gas Chemical Co. Inc., New York, N.Y.) at either 24, 37, or 42°C or in Brucella broth (Difco, Detroit, Mich.) supplemented with 5% (vol/vol) sheep serum (Sigma Chemical Co., St. Louis, Mo.) with constant stirring at 37°C in an atmosphere consisting of 5% oxygen, 5% carbon dioxide, and 90% nitrogen. Chemically competent TOP10 E. coli cells transformed with the pCR4-TOPO cloning vector (Invitrogen Corp., Carlsbad, Calif.) were grown in Luria-Bertani medium containing ampicillin or kanamycin (Sigma) at 37°C overnight.
Phenotypic characterization. Each reference and macaque isolate was examined by wet mounting and gram staining and observed for growth at either 24, 37, or 42°C under microaerobic and aerobic conditions for up to 14 days postinoculation. Catalase and oxidase activities (Remel), the production of urease (Remel), the reduction of nitrate to nitrite (Remel), the hydrolysis of hippurate (Remel), and susceptibilities to nalidixic acid (30 μg) and cephalothin (30 μg) by disk diffusion (Becton Dickinson, Sparks, Md.) were determined by standard laboratory methods (10).
Genotypic identification. C. jejuni and C. coli were identified on the basis of PCR amplification of the species-specific ceuE gene (12). Briefly, 2 μl of bacterial suspension in sterile water was mixed with a total volume of 48 μl containing 1x PCR buffer, 3.5 mM MgCl2, a 0.2 mM concentration (each) of dATP, dTTP, dGTP, and dCTP, a 1.0 μM concentration (each) of the oligonucleotide primers JEJ1 and JEJ2 or COLI1 and COLI2, and 0.5 U of Taq DNA polymerase (GeneChoice, Inc., Frederick, Md.) in sterile, filtered, autoclaved water. Initial denaturing for 3 min at 94°C was followed by 30 cycles of 30 s at 94°C, 30 s at 57°C, and 1 min at 72°C, with a final extension for 5 min at 72°C, in a thermocycler (GeneAmp PCR System 9600; Perkin-Elmer Cetus, Norwalk, Conn.). The 783-bp C. jejuni and the 894-bp C. coli products were visualized after electrophoresis in 0.8% agarose gels run at 7.0 V/cm and staining with ethidium bromide. Identification of the Arcobacter genus and of A. butzleri was accomplished by a multiplex PCR method as previously described (14).
Amplification, cloning, and sequencing of cdtB gene. The cdtB genes of reference and macaque isolates were amplified by PCRs with the degenerative forward oligonucleotide primer VAT2, extending from base position 67 of C. jejuni strain 81-176 (GenBank accession no. U51121; National Center for Biotechnology Information, Bethesda, Md.) with the nucleotide sequence 5'-GTNGCNACBTGGAAYCTNCARGG-3', and the reverse oligonucleotide primer WMI1 at position 539, with the nucleotide sequence 5'-RTTRAARTCNCCYAADATCATCC-3', as previously described (35). Additionally, a C. jejuni cdtB gene-specific sequence was amplified with the forward oligonucleotide primer CjcdtBF, extending from position 93 of C. jejuni strain 81-176 with the nucleotide sequence 5'-ATCCGCAGCCACAGAAAGCAAATG-3', and the reverse oligonucleotide primer CjcdtBR at position 692, with the nucleotide sequence 5'-GCGGTGGAGTATAGGTTTGTTGTC-3'. Two microliters of bacterial suspension in sterile water was mixed with a total volume of 48 μl containing 1x PCR buffer, 1.5 mM MgCl2, a 0.2 mM concentration (each) of dATP, dTTP, dGTP, and dCTP, a 0.25 μM concentration of each oligonucleotide primer, and 2.0 U of Taq DNA polymerase (GeneChoice) in sterile, filtered, autoclaved water. The PCR parameters for amplification reactions were similar to those for the Campylobacter species-specific ceuE gene, except that annealing was done for 60 s at 50°C. The 495- and 623-bp amplified products, generated with the degenerative and C. jejuni cdtB gene-specific oligonucleotide primers, respectively, were visualized by electrophoresis in 0.8% agarose gels run at 7.0 V/cm after staining with ethidium bromide. The partial nucleotide sequence of the C. jejuni EB53-23-01 cdtB gene was determined. Briefly, each 495- and 623-bp amplified product was excised, purified (Zymoclean Gel DNA recovery kit; Zymo Research, Orange, Calif.), cloned into pCR4-TOPO, and transformed into chemically competent E. coli TOP10 cells according to the manufacturer's instructions. The nucleotide sequences of both strands from five clones of each product were sequenced at the Genomics Core Research Facility, University of Nebraska-Lincoln Center for Biotechnology, by use of an automated dideoxy sequencing method (41) and a commercial kit (CEQ DTCS quick start kit; Beckman Coulter, Fulton, Calif.) for fluorescence sequencing (CEQ 2000XL/8000 DNA sequencer; Beckman Coulter). A partial 602-bp consensus cdtB gene sequence extending from positions 90 to 691 was aligned and edited with the Wisconsin Package, version 9.0 (Genetics Computer Group, Madison, Wis.), and then compared with available sequences from other bacteria in GenBank by use of the BLAST program.
Preparation of bacterial cell lysates. Confluent cultures of reference and macaque bacterial isolates grown on TSAB for 2 to 3 days under microaerobic conditions at 42°C were harvested by washing the surface growth with phosphate-buffered saline (PBS; pH 7.2) and then centrifuging it at 800 x g for 20 min at 4°C. The pellet was suspended in 1.0 ml of ice-cold PBS and lysed by sonication as previously described (4). Unlysed bacteria and cell debris were removed by centrifugation at 6,000 x g for 20 min at 4°C, and the supernatant was filtered through 0.22-μm-pore-size filters and stored at –20°C until needed. The concentration of protein present in each filter-sterilized lysate was determined by use of a commercially available kit (BCA protein assay kit; Pierce, Rockford, Ill.).
HeLa cell culture and CDT bioassay. A human epithelioid cervical carcinoma HeLa cell line (ATCC CCL-2) was maintained in Eagle's minimum essential medium (MEM; Sigma) supplemented with 10% fetal bovine serum (FBS; Atlanta Biologicals, Norcross, Ga.) and gentamicin (50 μg/ml; Sigma) at 37°C in a humidified atmosphere of 5% carbon dioxide in air. The CDT bioassay was performed as previously described by Johnson and Lior (20), with some modifications. Approximately 2 x 104 cells in 10% FBS-MEM were placed in each well of a chamber slide (Lab-Tek II chamber slide system; Nalge Nunc International, Naperville, Ill.) and incubated for 3 h at 37°C in 5% carbon dioxide in air. Either 100 μl of PBS (negative control), 20, 40, or 80 μM (final concentration) apigenin (positive control; apigenin is a compound known to arrest the cell cycle at the G2/M phase [53]), or 10.0, 20.0, or 40.0 μl of filter-sterilized lysate obtained from a reference or macaque Campylobacter isolate or a reference Arcobacter strain was then added to individual wells and incubated for an additional 72 to 96 h. At the end of the incubation, each culture was washed with PBS, fixed with 10% neutral buffered formalin (VWR International, West Chester, Pa.), stained with hematoxylin and eosin, and examined under a light microscope. The mean diameter and standard deviation of nuclei from 10 HeLa cells in cultures incubated with either PBS or 10 μl of filter-sterilized lysate obtained from C. coli EB53-02-12 or C. jejuni EB53-23-01 were determined. The nuclear morphology of control and HeLa cells incubated with bacterial lysates was examined further by use of a confocal laser scanning microscope (model FV500; Olympus Optical Co., Tokyo, Japan) after staining with propidium iodide (PI; Sigma) as previously described (2). Lysates from reference and macaque Campylobacter isolates were examined in at least two separate experiments, and positive and negative controls were included in each assay.
Cell cycle analysis by FACS. The G2/M-phase cell cycle arrest of HeLa cells incubated with lysates obtained from reference and macaque Campylobacter isolates and reference Arcobacter strains was determined quantitatively by fluorescence-activated cell sorter (FACS) analysis and compared with that of either untreated cells or HeLa cells incubated with PBS (negative control) or apigenin (positive control). Confluent monolayers of HeLa cells were treated with 0.05% (wt/vol) trypsin-EDTA (Invitrogen), washed with PBS, suspended in 10% FBS-MEM to obtain 3 x 105 cells in 5.0 ml, and placed into 25-cm2 flasks (Costar, Cambridge, Mass.). After 3 h, either 100 μl of PBS, 20, 40, or 80 μM (final concentration) apigenin, or 1.0, 10.0, 100.0, or 200.0 μl of filter-sterilized bacterial cell lysate was added to the culture medium, and the cells were incubated for an additional 72 h. HeLa cells were prepared for FACS analysis as previously described (5), with some modifications. After being washed with PBS, the cells were treated with trypsin and centrifuged at 1,000 x g for 2 min. The cell pellet was then suspended in PBS, transferred to 70% ethanol, and held at –20°C for 5 min. The cells were harvested by centrifugation and rehydrated with 1.0 ml of PBS at room temperature for 15 min. Following centrifugation, the cells were suspended in PI staining buffer (3 μg of PI/ml, 0.02 mg of RNase A/ml, 100 mM Tris [pH 7.2], 150 mM NaCl, 1 mM CaCl2, 0.5 mM MgCl2, 0.1% Triton X-100) and incubated at room temperature in the dark for 15 min. For DNA content analysis, approximately 1.0 x 104 cells were examined by FACS analysis, with the excitation set at 488 nm and the emission set at 630 nm (FACScan flow cytometer; Becton Dickinson) and with the data analyzed by use of Cell Quest and ModFit LT software (Becton Dickinson). Lysates from reference and macaque Campylobacter isolates and reference Arcobacter strains were examined in at least two separate experiments, and positive and negative controls were included in each assay.
Data analysis. FACS analysis data for HeLa cells in G2/M phase were expressed as mean percentages of HeLa cells with 4N DNA contents ± standard deviations. An association between the presence of CDT and the species of Campylobacter was determined by using the Student t test. The significance of association was tested at an value of 0.05.
Nucleotide sequence accession number. The 602-bp partial nucleotide sequence of the C. jejuni EB53-23-01 cdtB gene has been deposited in GenBank under accession number AY652840.
RESULTS
Clinical findings. Although C. jejuni and C. coli were isolated from rhesus and pig-tailed macaques, diarrheal illness was present only in rhesus macaques. Approximately equal numbers of symptomatic and asymptomatic rhesus macaques were infected with C. jejuni or C. coli. At the initial clinical presentation in September 2003, a stool specimen taken from rhesus macaque EB53 contained C. coli (Table 2, strain EB53-02-12), while clinically this monkey showed weakness and dehydration. After antibiotic therapy, the clinical status of the monkey improved and diarrhea ceased, but recurrent episodes of diarrhea continued through April 2004, and a culture of a stool specimen taken in October 2003 yielded C. jejuni (Table 2, strain EB53-23-01).
Phenotypic and genotypic characterizations. The macaque Campylobacter isolates formed distinct gray colonies, but cultures of ET03, ET46, and ET51 also formed a spreading haze that was maintained after subculture (Table 2). All of the isolates grew under microaerobic conditions at 37 and 42°C, but not at 25°C or under aerobic conditions. They were gram negative with a curved-rod morphology and had darting motility. The biochemical and genotypic characteristics of each isolate are presented in Table 2. Additionally, the isolates produced catalase and oxidase but did not produce urease or reduce nitrate to nitrite. With the exception of isolates EN69-49-09 and ET03-26-15, all of the C. jejuni isolates hydrolyzed hippurate. All of the isolates were resistant to cephalothin, and while the C. jejuni and C. coli isolates were generally susceptible to nalidixic acid, five C. jejuni isolates and one C. coli isolate were resistant. None of the isolates yielded products in multiplex PCR assays for the Arcobacter 16S rRNA and A. butzleri 23S rRNA genes.
Detection and characterization of cdtB gene. A putative 495-bp cdtB gene product was obtained by PCR amplification of all of the Campylobacter isolates by use of the degenerative oligonucleotide primers VAT2 and WMI1 (Table 2 and Fig. 1A). Conversely, only the C. jejuni isolates generated the expected 623-bp product by PCR amplification with C. jejuni cdtB gene-specific oligonucleotide primers (Table 2 and Fig. 1B). With the exception of a single silent nucleotide substitution (C instead of T at position 126), the consensus sequence of the cloned products obtained by PCR amplification of EB53-23-01 with the cdtB gene-specific oligonucleotide primers was identical to the cdtB gene sequence of the reference human strains C. jejuni subsp. jejuni NCTC 11168 (AL139074) (31), C. jejuni 81-176 (U51121) (35), and C. jejuni CH5 (AF038283) (16).
Morphological changes in HeLa cells incubated with bacterial lysates. Significant changes were not observed in HeLa cells incubated with PBS (Fig. 2A) or in lysates obtained from either the reference and macaque C. coli isolates (Fig. 2B), the C. jejuni isolate EJ92, or the reference Arcobacter isolates at any of the times and concentrations examined. HeLa cells incubated with either apigenin or the reference and remaining macaque C. jejuni isolates displayed morphological changes that were characteristic of CDT in a time- and dose-dependent manner. HeLa cells incubated with 20 and 40 μM apigenin had larger cytoplasmic boundaries than control cells by 48 h, whereas cellular enlargement was apparent by 24 h with the 80 μM concentration. Between 48 and 72 h of incubation, the cellular enlargement became progressively more prominent. A marked enlargement of the cytoplasmic boundaries and the nucleus was first seen by 48 h for HeLa cells incubated with lysates obtained from the reference and macaque C. jejuni isolates. Between 72 and 96 h, the mean size of distended cells was approximately 2.0- to 2.5-fold that of control cells (Fig. 2C). By 96 h, nuclear fragmentation and cytoplasmic vacuolation were also seen. A dose effect similar to that for apigenin was seen with the C. jejuni lysates. Ten microliters of C. jejuni lysate was sufficient to exert a cytotoxic effect, whereas larger volumes caused more rapid and prominent morphological changes. Although the magnitude of the cellular changes over time varied among the C. jejuni isolates and with the protein concentration of the lysate, only the reference and macaque C. jejuni isolates produced detectable cellular and nuclear enlargement. In addition to the characteristic cellular enlargement, HeLa cells incubated with either apigenin or nearly all C. jejuni lysates, but not with the C. coli or Arcobacter isolates, contained between 1 and 2% multinucleated giant cells, depending on the isolate (Fig. 2C). When HeLa cells were incubated with either PBS, lysates from reference and macaque C. coli isolates, the C. jejuni isolate EJ92, or reference Arcobacter strains, stained with PI, and examined under a confocal laser scanning microscope, they had small nuclei with widely dispersed small nucleoli (Fig. 3A and B). In contrast, HeLa cells incubated with lysates from reference strains and the remaining macaque C. jejuni isolates had a mean nuclear size of approximately 1.5- to 2.0-fold that of control cells, contained fewer and more prominent nucleoli (Fig. 3C and D), and had occasional multinucleated giant cells (Fig. 3E and F) by 48 h.
Quantitative fluorescent cell cycle analysis of HeLa cells incubated with bacterial lysates. Approximately 10.6% ± 0.2% of the cells in untreated HeLa cell cultures and cultures incubated with PBS were in the G2/M phase (Fig. 4A). Conversely, HeLa cell cultures incubated in the presence of apigenin had an increase in the percentage of cells that were arrested at the G2/M phase in a dose-dependent manner: <10% of the cells were in the G2/M phase with 20 μM apigenin, whereas 57.0% ± 18.0% and 78.5% ± 16.2% of the cells were in the G2/M phase with 40 and 80 μM apigenin, respectively. For HeLa cells incubated with any concentration of lysate obtained from either the reference or macaque C. coli isolates, <7.6% ± 1.8% of the cells were in the G2/M phase (Fig. 4B). Similarly, for HeLa cells incubated with lysates obtained from the reference Arcobacter strains, <9.8% ± 0.3% of the cells were in the G2/M phase. In contrast, 81.1% ± 4.8% of HeLa cells were arrested in the G2/M phase when they were incubated with a lysate obtained from the reference strain C. jejuni ATCC 49943. The percentage of HeLa cells arrested in G2/M phase ranged between 35.6% ± 12.0% and 98.6% ± 0.2% after incubation with lysates obtained from the macaque-derived C. jejuni isolates (Fig. 4C). Compared with those from other isolates, the lysate obtained from the macaque C. jejuni isolate EJ92 did not cause a significant increase in the percentage of HeLa cells arrested in the G2/M phase of the cell cycle, with 17.1% ± 3.0% of the cells being in this phase. In all of the assays, the progressive increase in the percentage of cells in G2/M phase (4N DNA content) was accompanied by a corresponding decline in the number of cells in G1 phase (2N DNA content). The variable percentages of HeLa cells arrested in the G2/M phase with different C. jejuni lysates could not be attributed to the concentration of protein, but rather depended on the absolute amount of CDT produced by individual isolates. Thus, 1 μl of EB53-23-01 lysate containing approximately 3 μg of protein caused >96% of HeLa cells to arrest in the G2/M phase, whereas 20 μl of ET03-26-15 lysate containing approximately 40 μg of protein was required to achieve a similar level of arrest. In addition to HeLa cells with 4N DNA contents, cells with 8N DNA contents were seen after incubation with apigenin and lysates from reference and macaque C. jejuni isolates, but not with lysates from either reference and macaque C. coli or reference Arcobacter strains. The production of CDT was positively correlated with lysates obtained from C. jejuni (P < 0.0001) but not with those obtained from C. coli.
DISCUSSION
Phenotypic and genotypic characterizations of Campylobacter strains isolated from captive conventionally raised macaques revealed that cdtB gene sequences were present in both C. jejuni and C. coli but that CDT activity was only present in the 2 reference human C. jejuni isolates and 15 of the 16 C. jejuni isolates from macaques. This is consistent with previous reports indicating that although the cdtB gene is present in both C. jejuni and C. coli (8), the production of CDT is a characteristic of C. jejuni (16, 35). A previous study found CDT activity in C. jejuni strains isolated from 13 of 14 humans, 3 of 4 cows, a goat, and a lamb, whereas C. coli strains isolated from 10 humans, a cow, and a sheep had no significant CDT activity (35). Our data extend these previous observations to include Campylobacter strains isolated from nonhuman primates. Because the membrane fraction of C. jejuni, but not C. coli, can elicit the release of interleukin-8 by human intestinal epithelial cells (16), the absence of CDT activity in macaque C. coli isolates and the C. jejuni isolate EJ92 might be attributable to either an inability to produce CDT or the production of abnormal or inactive CDT in these isolates. Alternatively, as recently suggested for A. actinomycetemcomitans (57), polymorphisms in the cdtABC flanking regions might account for the absence of CDT activity in some strains. The absence of the cdtB gene and of CDT activity in the reference Arcobacter strains was consistent with a previous report indicating that these strains do not have this virulence determinant (17).
Although CDT has been suggested as a virulence determinant, four of eight rhesus macaques and four pig-tailed macaques with toxigenic C. jejuni did not exhibit clinical signs of enteric disorders. This may be attributable to either (i) sampling prior to clinical disease, (ii) sampling after recovery from infection while the animals were subclinically infected, or (iii) a requirement for either additional or other virulence determinants for clinical diarrhea associated with C. jejuni infection. On the basis of experimental challenge studies, the possibility that macaques are not susceptible to C. jejuni infection is unlikely (9, 38, 40). However, because C. jejuni-specific immunity can prevent reinfection of recovered hosts, including macaques (3, 9, 38), and because the four asymptomatic rhesus macaques were older than those with clinical diarrhea (mean age ± standard deviation, 3.52 ± 0.93 versus 1.33 ± 0.76), prior exposure and protective immunity might explain the absence of clinical signs in these monkeys. Conversely, two of the pig-tailed macaques were less than a year old, suggesting that maternal immunity might have prevented clinical disease in these monkeys. It is likely that virulence determinants other than CDT play a role in diarrheal disease caused by C. jejuni. Because the toxigenic C. jejuni isolates were not examined for virulence determinants other than the presence of the ceuE gene (12), it is unknown whether or not these isolates lack other determinants required for disease expression in their natural host. Nevertheless, CDT alone was recently shown to play an essential role in disease by use of an NF-B-deficient mouse model of campylobacteriosis (11).
Stool cultures taken from six rhesus macaques with diarrhea had C. coli only. Although C. coli can cause diarrhea in susceptible hosts, including monkeys, the possibility that C. jejuni or some other enteropathogen was responsible for chronic diarrhea cannot be ruled out completely. As seen with rhesus macaque EB53, from which repeated stool cultures yielded C. coli at the first sampling and toxigenic C. jejuni a month later, a single stool culture might not be sufficient in order to assess the role of Campylobacter species in diarrhea of colony-raised macaques. As previously shown, continuous exposure to pathogenic Campylobacter and reinfection with different strains over time are common among conventionally raised macaques kept in close contact in primate colonies (39, 43).
Although most of the macaque C. jejuni and C. coli isolates conformed to their respective phenotypic characteristics, three macaques had C. jejuni isolates that either grew as a spreading haze or formed individual colonies, two others had isolates that did not hydrolyze hippurate, and six had C. jejuni or C. coli isolates that were resistant to nalidixic acid. Isolates of C. jejuni with a spreading haze phenotype might represent motility variants (3). The ability of C. jejuni to hydrolyze hippurate into benzoic acid and glycine is commonly used for rapid laboratory differentiation between C. jejuni and C. coli or other, less common Campylobacter species (10, 29). The isolation of a macaque C. jejuni strain that did not hydrolyze hippurate was consistent with previous reports indicating that certain C. jejuni strains isolated from humans and other hosts, including macaques, do not hydrolyze hippurate (39, 49, 52). In spite of these various phenotypes, CDT activity was found exclusively among C. jejuni isolates. As suggested previously (8, 35), the cdtB genes of C. jejuni and C. coli appear to be sufficiently divergent to allow the differentiation of each species by use of a C. jejuni cdtB gene-specific PCR assay. In contrast with the variability of phenotypes for the hydrolysis of hippurate, the C. jejuni cdtB gene-specific PCR assay might be useful for differentiating toxigenic C. jejuni from C. coli in clinical laboratories.
In addition to the progressive cytoplasmic and nuclear enlargement and G2/M-phase cell cycle arrest characteristic of CDT, HeLa cell cultures incubated with either apigenin or lysates obtained from reference and macaque C. jejuni strains contained cells with 8N DNA according to FACS analysis. These cells with four times the normal amount of DNA likely corresponded to the 1 to 2% of multinucleated giant cells seen by direct microscopic examination. The presence of multinucleated giant cells in HeLa cell cultures treated with CDT was originally reported by Johnson and Lior (20) as a feature of Campylobacter fetus subsp. fetus. Similar multinucleated giant cells have also been found in HeLa cell cultures treated with lysates from certain enterohepatic Helicobacter species (4, 24) and E. coli (2, 48). An interruption of cytokinesis while nuclear division continues has been suggested as a possible mechanism for the formation of multinucleated cells in the presence of CDT (2). In addition to nuclear enlargement, HeLa cells incubated with C. jejuni lysates and examined by confocal laser scanning microscopy had nuclei with few but expanded nucleoli, suggesting that there was enhanced ribosome biogenesis.
In conclusion, we found the cdtB gene and CDT activity in C. jejuni strains isolated from healthy macaques and from macaques with clinical signs of diarrhea. Although the cdtB gene was also present in C. coli strains isolated from symptomatic and asymptomatic macaques, only lysates obtained from the C. jejuni isolates caused cytoplasmic and nuclear enlargement together with the cell cycle arrest of HeLa cells in the G2/M phase that is characteristic of CDT activity.
ACKNOWLEDGMENTS
We thank Michael J. Cole, Melinda Martin, and Maurice Duplantis of the Tulane National Primate Research Center (TNPRC), Paul Nabity and Debra Royal of the Veterinary Diagnostic Center, and Jennifer Flores of the Center for Biotechnology (UNL) for their excellent technical assistance. We thank Andrew A. Lackner and James Blanchard for providing the resources at the TNPRC through an RR00164 base grant. The pig-tailed macaques were the property of the Washington National Primate Research Center.
This work was partially supported by funds provided by the USDA/CSREES, National Research Initiative, Competitive Grants Program, project NEB 14-114, by Multi-State Research Project NC-1007, and by Animal Health Project NEB-14-118 to G.E.D.
This is paper no. 14670 of the Agriculture Research Division, Institute of Agriculture and Natural Resources, University of Nebraska-Lincoln.
REFERENCES
Ahmed, H. J., L. A. Svensson, L. D. Cope, J. L. Latimer, E. J. Hansen, K. Ahlman, J. Bayat-Turk, D. Klamer, and T. Lagergrd. 2001. Prevalence of cdtABC genes encoding cytolethal distending toxin among Haemophilus ducreyi and Actinobacillus actinomycetemcomitans strains. J. Med. Microbiol. 50:860-864.
Aragon, V., K. Chao, and L. A. Dreyfus. 1997. Effect of cytolethal distending toxin on F-actin assembly and cell division in Chinese hamster ovary cells. Infect. Immun. 65:3774-3780.
Black, R. E., M. M. Levine, M. L. Clements, T. P. Hughes, and M. J. Blaser. 1988. Experimental Campylobacter jejuni infection in humans. J. Infect. Dis. 157:472-479.
Chien, C., N. S. Taylor, Z. Ge, D. B. Schauer, V. B. Young, and J. G. Fox. 2000. Identification of cdtB homologues and cytolethal distending toxin activity in enterohepatic Helicobacter spp. J. Med. Microbiol. 49:525-534.
Cortes-Bratti, X., E. Chaves-Olarte, T. Lagergrd, and M. Thelestam. 1999. The cytolethal distending toxin from the chancroid bacterium Haemophylus ducreyi induces cell-cycle arrest in the G2 phase. J. Clin. Investig. 103:107-115.
Elwell, C. A., and L. A. Dreyfus. 2000. DNase I homologous residues in cdtB are critical for cytolethal distending toxin-mediated cell cycle arrest. Mol. Microbiol. 37:952-963.
Elwell, C., K. Chao, K. Patel, and L. Dreyfus. 2001. Escherichia coli cdtB mediates cytolethal distending toxin cell cycle arrest. Infect. Immun. 69:3418-3422.
Eyigor, A., K. A. Dawson, B. E. Langlois, and C. L. Pickett. 1999. Detection of cytolethal distending toxin activity and cdt genes in Campylobacter spp. isolated from chicken carcasses. Appl. Environ. Microbiol. 65:1501-1505.
Fitzgeorge, R. B., A. Baskerville, and K. P. Lander. 1981. Experimental infection of rhesus monkeys with a human strain of Campylobacter jejuni. J. Hyg. Camb. 86:343-351.
Forbes, B. A., D. F. Sahm, and A. S. Weissfield. 1998. Campylobacter, Arcobacter, and Helicobacter, p. 570-572. In B. A. Forbes, D. F. Sahm, and A. S. Weissfield (ed.), Diagnostic microbiology, 10th ed. Mosby, New York, N.Y.
Fox, J. G., A. B. Rogers, M. T. Whary, Z. Ge, N. S. Taylor, S. Xu, B. H. Horwitz, and S. E. Erdman. 2004. Gastroenteritis in NF-B-deficient mice is produced with wild-type Campylobacter jejuni but not with C. jejuni lacking cytolethal distending toxin despite persistent colonization with both strains. Infect. Immun. 72:1116-1125.
Gonzalez, I., K. A. Grant, P. T. Richardson, S. F. Park, and M. D. Collins. 1997. Specific identification of the enteropathogens Campylobacter jejuni and Campylobacter coli by using a PCR test based on the ceuE gene encoding a putative virulence determinant. J. Clin. Microbiol. 35:759-763.
Haghjoo, E., and J. E. Galán. 2004. Salmonella typhi encodes a functional cytolethal distending toxin that is delivered into host cells by a bacterial-internalization pathway. Proc. Natl. Acad. Sci. USA 101:4614-4619.
Harmon, K. M., and I. V. Wesley. 1997. Multiplex PCR for the identification of Arcobacter and differentiation of Arcobacter butzleri from other arcobacters. Vet. Microbiol. 58:215-227.
Harris, N. V., N. S. Weiss, and C. M. Nolan. 1986. The role of poultry and meats in the etiology of Campylobacter jejuni/coli enteritis. Am. J. Public Health 76:407-411.
Hickey, T. E., A. L. McVeigh, D. A. Scott, R. E. Michielutti, A. Bixby, S. A. Carroll, A. L. Bourgeois, and P. Guerry. 2000. Campylobacter jejuni cytolethal distending toxin mediates release of interleukin-8 from intestinal epithelial cells. Infect. Immun. 68:6535-6541.
Johnson, L. G., and E. A. Murano. 2002. Lack of a cytolethal distending toxin among Arcobacter isolates from various sources. J. Food Prot. 65:1789-1795.
Johnson, W. M., and H. Lior. 1987. Production of Shiga toxin and a cytolethal distending toxin (CLDT) by serogroups of Shigella spp. FEMS Microbiol. Lett. 48:235-238.
Johnson, W. M., and H. Lior. 1988. A new heat-labile cytolethal distending toxin (CLDT) produced by Escherichia coli isolates from clinical material. Microb. Pathog. 4:103-113.
Johnson, W. M., and H. Lior. 1988. A new heat-labile cytolethal distending toxin (CLDT) produced by Campylobacter spp. Microb. Pathog. 4:115-126.
Ketley, J. M. 1997. Pathogenesis of enteric infection by Campylobacter. Microbiology 143:5-21.
Kolashnikova, V. A., E. K. Dzsikidze, Z. K. Stasilevich, and M. G. Chikobava. 2002. Detection of Campylobacter jejuni in healthy monkeys and monkeys with enteric infections by PCR. Bull. Exp. Med. 134:299-300.
Konkel, M. E., M. R. Monteville, V. Rivera-Amill, and L. A. Joens. 2001. The pathogenesis of Campylobacter jejuni-mediated enteritis. Curr. Issues Intest. Microbiol. 2:55-71.
Kostia, S., P. Veijalainen, U. Hirvi, and M. L. Hnninen. 2003. Cytolethal distending toxin B gene (cdtB) homologues in taxa 2, 3 and 8 and in six canine isolates of Helicobacter sp. flexispira. J. Med. Microbiol. 52:103-108.
Lara-Tejero, M., and J. E. Galán. 2000. A bacterial toxin that controls cell cycle progression as a deoxyribonuclease I-like protein. Science 290:354-357.
Lara-Tejero, M., and J. E. Galán. 2002. Cytolethal distending toxin: limited damage as a strategy to modulate cellular functions. Trends Microbiol. 10:147-152.
Mooney, A., M. Clyne, T. Curran, D. Doherty, B. Kilmartin, and B. Bourke. 2001. Campylobacter upsaliensis exerts a cytolethal distending toxin effect on HeLa cells and T lymphocytes. Microbiology 147:735-743.
Okuda, J., M. Fukomoto, Y. Takeda, and M. Nishibushi. 1997. Examination of diarrheagenicity of cytolethal distending toxin: suckling mouse response to the products of the cdtABC genes of Shigella dysenteriae. Infect. Immun. 65:428-433.
On, S. L. W. 1996. Identification methods for campylobacters, helicobacters, and related organisms. Clin. Microbiol. Rev. 9:405-422.
Pandey, M., A. Khan, S. C. Das, B. Sarka, S. Kahali, S. Chakraborty, S. Chattopadhyay, S. Yamasaki, Y. Takeda, G. B. Nair, and T. Ramamurthy. 2003. Association of cytolethal distending toxin locus cdtB with enteropathogenic Escherichia coli isolated from patients with acute diarrhea in Calcutta, India. J. Clin. Microbiol. 41:5277-5281.
Parkhill, J., B. W. Wren, K. Mungall, J. M. Ketley, C. Churcher, D. Basham, T. Chillingworth, R. M. Davies, T. Feltwell, S. Holroyd, K. Jagels, A. Karlyshev, S. Moule, M. J. Pallen, C. W. Penn, M. Quail, M. A. Rajandream, K. M. Rutherford, A. VanVliet, S. Whitehead, and B. G. Barrell. 2000. The genome sequence of the food-borne pathogen Campylobacter jejuni reveals hypervariable sequences. Nature 403:665-668.
Peres, S. Y., O. Marches, F. Daigle, J. P. Nougayrede, F. Herault, C. Tasca, J. De Rycke, and E. Oswald. 1997. A new cytolethal distending toxin (CDT) from Escherichia coli producing CNF2 blocks HeLa cell division in G2/M phase. Mol. Microbiol. 24:1095-1107.
Pickett, C. L., and C. A. Whitehouse. 1999. The cytolethal distending toxin family. Trends Microbiol. 7:292-297.
Pickett, C. L., D. L. Cottle, E. C. Pesci, and G. Bikah. 1994. Cloning, sequencing, and expression of the Escherichia coli cytolethal distending toxin genes. Infect. Immun. 62:1046-1051.
Pickett, C. L., E. C. Pesci, D. L. Cottle, G. Russell, A. N. Erdem, and H. Zeytin. 1996. Prevalence of cytolethal distending toxin production in Campylobacter jejuni and relatedness of Campylobacter sp. cdtB genes. Infect. Immun. 64:2070-2078.
Puven, M., and T. Lagergrd. 1992. Haemophilus ducreyi, a cytotoxin-producing bacterium. Infect. Immun. 60:1156-1162.
Russell, R. G., S. L. Rosenkranz, L. A. Lee, H. Howard, R. F. DiGiacomo, M. A. Bronsdon, G. A. Blakley, C.-C. Tsai, and W. R. Morton. 1987. Epidemiology and etiology of diarrhea in colony-born Macaca nemestrina. Lab. Anim. Sci. 37:309-316.
Russell, R. G., M. J. Blaser, J. I. Sarmiento, and J. Fox. 1989. Experimental Campylobacter jejuni infection in Macaca nemestrina. Infect. Immun. 57:1438-1444.
Russell, R. G., J. I. Sarmiento, J. Fox, and P. Panigrahi. 1990. Evidence of reinfection with multiple strains of Campylobacter jejuni and Campylobacter coli in Macaca nemestrina housed under hyperendemic conditions. Infect. Immun. 58:2149-2155.
Russell, R. G., M. O'Donnoghue, D. C. Blake, Jr., J. Zulty, and L. J. DeTolla. 1993. Early colonic damage and invasion of Campylobacter jejuni in experimentally challenged infant Macaca mulatta. J. Infect. Dis. 168:210-215.
Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-terminating inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467.
Scott, D. A., and J. B. Kaper. 1994. Cloning and sequencing of the genes encoding Escherichia coli cytolethal distending toxin. Infect. Immun. 62:244-251.
Sestak, K., C. K. Merritt, J. Borda, E. Saylor, S. R. Schwamberger, F. Cogswell, E. S. Didier, P. J. Didier, G. Plauche, R. P. Bohm, P. P. Aye, P. Alexa, R. L. Ward, and A. A. Lackner. 2003. Infectious agent and immune response characteristics of chronic enterocolitis in captive rhesus macaques. Infect. Immun. 71:4079-4086.
Shenker, B. J., T. McKay, S. Datar, M. Miller, R. Chowhan, and D. Demuth. 1999. Actinobacillus actinomycetemcomitans immunosuppressive protein is a member of the family of cytolethal distending toxins capable of causing a G2 arrest in human T cells. J. Immunol. 162:4773-4780.
Skerman, V. B. D., V. McGowan, and P. H. A. Sneath. 1980. Approved lists of bacterial names. Int. J. Syst. Bacteriol. 30:225-420.
Sugai, M., T. Kawamoto, S. Peres, Y. Ueno, H. Komatsuzawa, T. Fujiwara, H. Kurihara, H. Suginaka, and E. Oswald. 1998. The cell cycle-specific growth-inhibitory factor produced by Actinobacillus actinomycetemcomitans is a cytolethal distending toxin. Infect. Immun. 66:5008-5019.
Tauxe, R. V. 1997. Emerging foodborne diseases: an evolving public health challenge. Emerg. Infect. Dis. 3:425-434.
Toth, I., F. Herault, L. Beutin, and E. Oswald. 2003. Production of cytolethal distending toxins by pathogenic Escherichia coli strains isolated from human and animal sources: establishment of the existence of a new cdt variant (type IV). J. Clin. Microbiol. 41:4285-4291.
Totten, P. A., C. M. Patton, F. C. Tenover, T. J. Barrett, W. E. Stamm, A. G. Steigerwalt, J. Y. Lin, K. K. Holmes, and D. J. Brenner. 1987. Prevalence and characterization of hippurate-negative Campylobacter jejuni in King County, Washington. J. Clin. Microbiol. 25:1747-1752.
Vandamme, P., E. Falsen, R. Rossau, B. Hoste, P. Segers, R. Tytgat, and J. de Ley. 1991. Revision of Campylobacter, Helicobacter and Wolinella taxonomy: emendation of generic descriptions and proposal of Arcobacter gen. nov. Int. J. Syst. Bacteriol. 41:88-103.
Vandamme, P., M. Vancanneyt, B. Pot, L. Mels, B. Hoste, D. Dewettinck, L. Vlaes, C. van den Borre, R. Higgins, J. Hommez, K. Kersters, J. P. Butzler, and H. Goossens. 1992. Polyphasic taxonomic study of the emended genus Arcobacter with Arcobacter butzleri comb. nov. and Arcobacter skirrowii sp. nov., an aerotolerant bacterium isolated from veterinary specimens. Int. J. Syst. Bacteriol. 42:344-356.
Wain, M., D. D. Bang, M. Lund, S. Nordentoft, J. S. Andersen, K. Pedersen, and M. Madsen. 2003. Identification of campylobacteria isolated from Danish broilers by phenotypic tests and species-specific PCR assays. J. Appl. Microbiol. 95:649-655.
Wang, W., L. Heideman, C. S. Chung, J. C. Pelling, K. J. Koehler, and D. F. Bert. 2000. Cell cycle arrest at G2/M and growth inhibition by apigenin in human carcinoma cell lines. Mol. Carcinog. 28:102-110.
Wassenaar, T. M. 1997. Toxin production by Campylobacter spp. Clin. Microbiol. Rev. 10:466-476.
Wassenaar, T. M., and M. J. Blaser. 1999. Pathophysiology of Campylobacter jejuni infections of humans. Microb. Infect. 1:1023-1033.
Whitehouse, C. A., P. A. Balbo, E. C. Pesci, D. L. Cottle, P. M. Mirabito, and C. L. Pickett. 1998. Campylobacter jejuni cytolethal distending toxin causes a G2-phase cell cycle block. Infect. Immun. 66:1934-1940.
Yamano, R., M. Ohara, S. Nishikubo, T. Fujiwara, T. Kawamoto, Y. Ueno, H. Komatsuzawa, K. Okuda, H. Kurihara, H. Suginaka, E. Oswald, K. Tanne, and M. Sugai. 2003. Prevalence of cytolethal distending toxin production in periodontopathogenic bacteria. J. Clin. Microbiol. 41:1391-1398.(Rohana P. Dassanayake, Yo)