Clostridium difficile strains not producing Toxin A,but producing Toxin B [toxA(-)tox B(+)]--etiologic agent of antibiotic associated diarrhoea (AAD) in Poland

Previously, toxin A-negative/toxin B-positive Clostridium difficile strains were not thought to be associated with clinically significant diseases. In our study among 159 tested C. difficile strains isolated from feacal samples from 413 patients with antibiotic associated diarrhoea (AAD) 17 strains (11%) were negative in the "Culturette Brand Toxin" CD (Becton-Dickinson) for detection toxin A and positive in the TOX A/B test, designed for detection of both toxins. The conserved regions of both toxin genes were detectable in all of isolates studied by the PCR. Nine of these C. difficile strains had a deletion in the A gene and remaining 8 strains, revealed an amplicon with the expected size of approximately 2500 bp. In this paper we described the first time the toxin A-negative/toxin B-positive C. difficile strains with deletion in toxin A gene, isolated from the faecal samples of patient with AAD in Poland.     

Evaluation of different methods for detection of Clostridium difficile toxins in Poland

The aim of this study was to compare different methods for C. difficile toxins detection. Fifty three stool samples taken from patients with antibiotic-associated diarrhoea were studied. TCD toxin A EIA (Becton Dickinson, USA), Tox A/B ELISA test (TechLab, USA), cytotoxicity and neutralization assay on McCoy cells and PCR for detection of both toxin A and B genes were performed in vivo (in stool samples) and in vitro (in isolated strains). Reference toxigenic and nontoxigenic and two Japanese toxin A-negative and toxin B-positive C. difficile strains were used as a controls. TCD toxin A EIA detected in vivo only 19 positive samples. Tox A/B test detected 52 positive samples out of 53 studied. All 53 stool samples were C. difficile culture positive (53 strains were cultured). Toxin B was detected in 52 strain-supernatants and in all controls (except the nontoxigenic one). Both toxin A and B genes were detected by PCR in all 53 isolated strains, Japanese and reference strain (except the nontoxigenic one). In vitro toxin A was detected by TCD toxin A EIA in 42 strains. These results were compared with those obtained in Tox A/B ELISA test. We observed 52 positive strains. Toxigenic reference strain and two Japanese toxA(-)/toxB(+) strains were also positive. Only 2 negative results were obtained with the nontoxigenic reference strain and unique nontoxigenic isolated strain. Tox A/B ELISA test seems to be the best for detection of C. difficile toxins in vivo and in vitro. Test avoids the false-negative results in the case of presence of toxin A-negative and toxin B-positive strain.     

Detection of Clostridium difficile toxin A by reversed passive latex agglutination.

A reversed passive latex agglutination (RPLA) assay for detecting Clostridium difficile toxin A is presented. Purified monoclonal antibody (mAb 37B5) was used for latex sensitization. The culture supernatants of 93 strains of C. difficile were tested by RPLA assay and the results compared with those of a commercially available latex agglutination test, PCR and cytotoxin assay with Vero cells. There was agreement between RPLA, cytotoxicity and PCR assays, but 29 strains were positive in the RPLA assay while 35 were positive in the cytotoxicity test and PCR using primer pair NK3-NK2 directed to the nonrepeating portion of the C. difficile toxin A gene. The 6 cytotoxic but RPLA-negative strains were demonstrated to be toxin A-negative/toxin B-positive strains in the PCR assay by using primer pair NK11-NK9 directed to the repeating portion of the C. difficile toxin A gene. There were no cross-reactions with culture supernatants of the other clostridial strains except for two strains of C. sordelli that produced hemorrhagic toxin (which is immunologically related to C. difficile toxin A).     

Identification of the syntrophic partners in a coculture coupling anaerobic methanol oxidation to Fe(III) reduction

The repeating sequences of the toxin A gene from toxin A-negative, toxin B-positive (toxin A-, toxin B+) strains of Clostridium difficile which were isolated in geographically separated facilities in Japan and Indonesia were determined. All six strains tested had identical repeating sequences with two deletions (1548 and 273 nucleotides in size) in the toxin A gene. A PCR method was designed to detect the deletions and the deletions were confirmed in all 50 toxin A-, toxin B+ strains examined by this method. Western immunoblot analysis revealed that polyclonal antiserum against native toxin A did not react with the concentrated culture filtrates of the toxin A-, toxin B+ strains. These results may suggest that toxin A-, toxin B+ strains have deletions of the two thirds of the repeating regions of the toxin A gene, which encodes the epitopes fully responsible for the reaction with the polyclonal antiserum.     

R-Ras glucosylation and transient RhoA activation determine the cytopathic effect produced by toxin B variants from toxin A-negative strains of Clostridium difficile

Clostridium difficile induces antibiotic-associated diarrhea through the production of toxin A and toxin B; the former toxin has been assumed to be responsible for the symptoms of the disease. Several toxin A-negative strains from C. difficile have recently been isolated from clinical cases and have been reported to produce toxin B variants eliciting an atypical cytopathic effect. Ultrastructural analysis indicated these toxins induce a rounding cytopathic effect and filopodia-like structures. Toxin B variants glucosylated R-Ras, and transfection with a constitutively active mutant of this GTPase protected cells against their cytopathic effect. Treatment of cells with toxin B variants induced detachment from the extracellular matrix and blockade of the epidermal growth factor-mediated phosphorylation of extracellular-regulated protein kinases, demonstrating a deleterious effect on the R-Ras-controlled avidity of integrins. Treatment with toxin B variants also induced a transient activation of RhoA probably because of inactivation of Rac1. Altogether, these data indicate that the cytopathic effect induced by toxin B variants is because of cell rounding and detachment mediated by R-Ras glucosylation, and the induction of filopodia-like structures is mediated by RhoA activation. Implications for the pathophysiology of C. difficile-induced diarrhea are discussed.     

Binary toxin producing Clostridium difficile strains

Clostridium difficile produces three toxins, TcdA, TcdB and CDT. TcdA and TcdB are single-stranded molecules acting as glucosyltransferases specific for small GTPases. CDT is an actin specific ADP-ribosylating binary toxin characteristically composed of two independent components, enzymatic CDTa (48 kDa) and binding CDTb (99 kDa). The cdtA and cdtB genes were sequenced in two CDT-positive strains of C. difficile (CD 196 and 8864) and at least two CDT-negative strains with truncated form of binary toxin genes are known (VPI 10463 and C. difficile genome strain 630). The prevalence of binary toxin producing strains is estimated to be from 1.6% to 5.5%, although a much higher proportion has been reported in some studies. The role of the binary toxin as an additional virulence factor is discussed.     

Profile of toxigenicity of Clostridium difficile strains isolated from paediatric patients with clinical diagnosis of antibiotic associated diarrhea (AAD)

This study was performed to determine profile of toxigenicity of 18 Clostridium difficile strains isolated from paeditric patients suffering from antibiotic associated diarrhea (AAD). Toxigenicity of C. difficile strains was tested for detection toxin A and toxin B by phenotypic methods and for detection of the tcdA and tcdB genes using of PCR. Changes in the repeating regions of the tcdA genes were detected with the NK9/NKV011 primer pairs. For detection of binary toxin (CDT) cdtA and cdtB genes, cdtApos/cdtArev i cdtBpos/cdtBrev two pair primers in PCR was used. Among C. difficile strains was detected three profiles of toxigenicity: C. difficile strains possesing of tcdA and tcdB genes but not possesing cdtA and cdtB genes of binary toxin (A+B+CDT-), strains possesing tcdA and tcdB and cdtA and cdtB genes (A+B+CDT+), strains with deletion of toxin A gene (A-B+CDT-). This is the first report on the occurence of binary positive C. difficile strains isolated from paediatric patients.     

Clostridium difficile in emergency room

Clostridium difficile strains are known as etiological agents of pseudomembranous colitis (PMC), antibiotic-associated diarrhea (AAC) and colitis (AAC) and hospital-acquired infections. The aim of this study was to determine the frequency of C. difficile infection among patients in the emergency room and to compare isolated strains by phenotypic and genotypic characteristics. During a period of 11 months, 56 stool samples taken from diarrheic patients hospitalized in the emergency room of the Medical Center UC Davis and 14 environmental samples were cultured for isolation of C. difficile strains. Eighteen C. difficile strains were isolated from stool samples cultured on selective TCCCA plates and 5 strains from environmental samples using Rodac plates. Eleven toxigenic (TcdA+/TcdB+), 6 non-toxigenic (TcdA-/TcdB-) and unique toxin A-negative/toxin B-positive (TcdA-/TcdB+) C. difficile strains were detected among patients' isolates and 3 toxigenic and 2 non-toxigenic strains-among environmental samples. The majority of C. difficile-positive patients were treated previously by antibiotics. Four strains isolated from patients' fecal samples and one strain isolated from the environment demonstrated high-level resistance to erythromycin and clindamycin (MIC >256mug/mL). The results obtained by AP-PCR and PCR-ribotyping revealed genetic heterogeneity among the strains isolated from patients' fecal samples. However, similarity was observed among environmental strains and strains isolated from patients' fecal samples. Considering the importance of emergency room patients as a potential source of C. difficile strains, it appears to be important examine these patients for C. difficile before transfer to the other hospital units.     

Isolation of toxigenic strains of Clostridium difficile and enterotoxin producing Bacteroides fragilis from fecal specimens of patients suspected of antibiotic associated diarrhoea

Fifty faecal samples from patients suspected of AAD (antibiotic associated diarrhoea) were studied for Clostridium difficile and enterotoxin producing Bacteroides fragilis (ETBF). Using TCD (Becton-Dickinson) and C. difficile Toxin A test (Oxoid) in 34% of specimens the presence of toxin A was detected. From all specimens 25 C. difficile strains were isolated. All isolated strains produced toxin B in vitro which was shown in Mc Coy cytotoxicity test. Eighteen strains only were toxin A positive in vitro. From all isolated C. difficile strains 28% were tox A (-) tox B (+). By means of PCR presence of toxin A and toxin B genes was tested directly in faecal samples and in strains. From the same 50 faecal samples 17 B. fragilis strains were isolated. Four of them produced the enterotoxin (fragilisin) which was detected on the HT 29/C1 cell line. Genes of fragilisin were found in strains and directly in faecal samples. Toxin producing C. difficile and B. fragilis (ETBF) together were found in 3 samples. From one faecal sample only ETBF was cultured.     

Clostridium difficile binary toxin (CDT) and diarrhea

Clostridium difficile is a major enteropathogen of humans. It produces two main virulence factors, toxins A and B. A third, less well known toxin, C. difficile toxin (CDT), is a binary toxin composed of distinct enzymatic (CdtA) and cell binding/translocation (CdtB) proteins. We used a novel enzyme linked immunoassay (EIA) to detect CdtB protein in feces and culture fluids. Additionally, PCR was used to assay C. difficile isolates from fecal samples for the CDT locus (CdtLoc). Although the results from 80 isolates suggest no relationship between toxin concentrations in situ and in vitro, there is a good correlation between PCR detection of the cdtB gene and EIA detection of CdtB protein in vitro. Possible implications of the detection of CDT in patients are discussed.     

Influence of selected Lactobacillus sp. on Clostridium difficile strains with different toxigenicity profile

This study was performed for determination of antagonistic activity of Lactobacillus spp. (L. plantarum 2017405, L. rhamnosus GG, L. acidophilus DSM 21007 and L. fernmentumn 353) on Clostridiunl difficile strains belonging to different toxigenicity profiles. Forty strains C. difficile isolated from patients suffering from antibiotic associated diarrhea (AAD) were used. Among C. difficile strains 13 produced toxin A and B (A+B+CDT-), 14 produced only toxin B (AB'CDT), 9 produced toxins A and B and possessing of binary toxin genes (A+B+CDT-) and 4 were non-toxigenic (A-B-CDT-). We did not observe relationship between degree of antagonistic activity Lactobacillus spp. and profile of toxigenicity of C. difficile strains.     

Simultaneous detection of toxin A and toxin B genetic determinants of Clostridium difficile using the multiplex polymerase chain reaction.

A multiplex polymerase chain reaction was developed to simultaneously detect the presence of toxin A and toxin B genes of Clostridium difficile. A 1050-bp fragment of the toxin B gene and a 1217-bp fragment of the toxin A gene were amplified from 42 toxic strains of C. difficile; however, from 10 nontoxic strains the toxin gene fragments were not amplified; these data demonstrate that this multiplex polymerase chain reaction procedure can be used to differentiate between toxic and nontoxic strains. This sensitive and specific multiplex polymerase chain reaction for C. difficile toxins may prove to be a valuable diagnostic procedure.     

Protein a production in coagulase-negative or clumping factor (CF)-negative isolates of Staphylococcus aureus

The aim of study was to determine a production of proteinA in coagulase-negative Staphylococcus aureus (CNSA) or CF-negative S. aureus (CFNSA) strains. 59 CNSA and 18 CFNSA strains were isolated between 1997 and 2003 from different clinical specimens. The Protein A production was determined by immunoblotting method. The presence of protein A gene (spa) was investigated using the polymerase chain reaction (PCR). Two sets of phages and RFLP (Restriction Fragment Lenth Polymorphism) of coa gene method were used for typing strains. The results proved that the lack of ability of protein A production occurs more frequently in protein A-negative CFNSA strains with compare to the CNSA, which are protein A-positive for the majority of strains. Deficiencies of protein A, doesn't seem to be caused by the loss of spa gene. Protein A-negative CFNSA strains have phagotypes, RFLP and antibiotic resistant patterns which differ them from protein A-negative CNSA strains. Almost all of protein A-negative CFNSA and CNSA strains are resistant to methicillin.     

Cloning and characterization of overlapping DNA fragments of the toxin A gene of clostridium difficile

Clostridium difficile, a human pathogen, produces two very large protein toxins, A and B (250-600 kDa), which resist dissociation into subunits. To clone the toxin A gene, a genomic library of 3-8 kb chromosomal DNA fragments of C. difficile strain VPI 10463 established in pUC12 was screened with a rabbit polyclonal toxin A antiserum. Thirty-five clones were isolated which carried 2.5-7.0 kb inserts representing a 10 kb region of the C. difficile genome. All the inserts were oriented in the same direction, suggesting that toxin A gene expression was under control of the lac promoter of the pUC12 vector. Western blot experiments revealed the presence of low amounts of fusion proteins of variable size (30-170 kDa) in Escherichia coli strains harbouring recombinant plasmids. As deduced from subcloning experiments, the DNA sequences encoding toxin A comprised about 4 kb, corresponding to about 140 kDa of the 300-600 kDa protein. This was either due to incomplete cloning of the gene or it might indicate a subunit composition of toxin A. No additional gene(s) with homology to the cloned toxin A gene was detected.     

Binary toxin production in Clostridium difficile is regulated by CdtR, a LytTR family response regulator

Clostridium difficile binary toxin (CDT) is an actin-specific ADP-ribosyltransferase that is produced by various C. difficile isolates, including the "hypervirulent" NAP1/027 epidemic strains. In contrast to the two major toxins from C. difficile, toxin A and toxin B, little is known about the role of CDT in virulence or how C. difficile regulates its production. In this study we have shown that in addition to the cdtA and cdtB toxin structural genes, a functional cdt locus contains a third gene, here designated cdtR, which is predicted to encode a response regulator. By introducing functional binary toxin genes into cdtR(+) and cdtR-negative strains of C. difficile, it was established that the CdtR protein was required for optimal expression of binary toxin. Significantly increased expression of functional binary toxin was observed in the presence of a functional cdtR gene; an internal deletion within cdtR resulted in a reduction in binary toxin production to basal levels. Strains that did not carry intact cdtAB genes or cdtAB pseudogenes also did not have cdtR, with the entire cdt locus, or CdtLoc, being replaced by a conserved 68-bp sequence. These studies have shown for the first time that binary toxin production is subject to strict regulatory control by the response regulator CdtR, which is a member of the LytTR family of response regulators and is related to the AgrA protein from Staphylococcus aureus.     

Nucleotide sequence of Clostridium difficile toxin A gene fragment and detection of toxigenic strains by polymerase chain reaction

A 1947 base pair (bp) fragment of the toxin A gene of Clostridium difficile was sequenced. A continuous open reading frame was found, which contained 4 distinct groups of repeat nucleotide sequence with 88 to 100% identity within each group. The arrangement of the groups (A, 81 bp, B, C and D, 63 bp) was ABCCCDABCDDABCCCDABCCDABCDABC. Based on nucleotide sequence data from the C repeat group, a pair of oligonucleotide primers were synthesised and used in the polymerase chain reaction (PCR) to amplify fragments from the toxin A gene. Several products of multiples of 63 bp length were amplified for all 33 toxigenic C. difficile strains tested in contrast to the 12 non-toxigenic strains tested which failed to amplify any product. This rapid technique is of potential use in the specific identification of toxigenic C. difficile strains in mixed culture and from clinical specimens.     

Clostridium difficile and enterotoxigenic Bacteroides fragilis strains isolated from patients with antibiotic associated diarrhoea

From the fecal samples of 332 patients with a clinical diagnosis of antibiotic associated diarrhoea (AAD), 131 Clostridium difficile strains were isolated. For detection of toxin A in the isolated strains the enzymatic immunoassay was used. The cytopathic effect was determined on McCoy cell line. PCR was used for the detection of non-repeating and repeating sequences of toxin A gene and non-repeating sequences of toxin B gene. One hundred and six isolated C. difficile strains were TcdA(+)TcdB(+), 10 strains TcdA(-)TcB(+) and 15 were non-toxigenic TcdA(-)TcdB(-). Out of the same fecal samples 50 Bacteroides fragilis strains were isolated. All B. fragilis strains were tested in PCR reaction for fragilysine gene detection (bft). In 9 strains (18%) this gene was detected and the strains could be assumed as enterotoxigenic Bacteroides fragilis (ETBF). In 4 fecal samples toxigenic C. difficile (TcdA(+)TcdB(+)) was found simultaneously with ETBF. One sample contained C. difficile (TcdA(-)TcdB(+)) and ETBF. Out of 4 fecal samples only ETBF was isolated. The cytotoxicity of ETBF strains was tested on HT29/C1 human colon carcinoma cell line. The cytotoxicity titer in the range of 20 and 80 was observed.     

A survey of metronidazole and vancomycin resistance in strains of Clostridium difficile isolated in Warsaw, Poland

The drug of choice used to treat Clostridium difficile-associated diarroea (CDAD) are metronidazole and vancomycin. Information about emergence of antimicrobial resistance among C. difficile strains to metronidazole and intermediate resistance to vancomycin in some countries are alarming. This study was performed to determine the susceptibility to metronidazole and vancomycin of 193 C. difficile strains isolated in our diagnostic laboratory between year 1998 and 2003 from patients adults and children suffering from CDAD. Among these strains, 142 produced toxin A and B (TcdA(+)TcdB(+)), 43 only B (TcdA(-)TcdB(+)) and 8 were nontoxigenic. We have not observed any differences in susceptibility to metronidazole and vancomycin between all C. difficile strains under investigation (toxinogenic and non-toxinogenic). Resistance to metronidazole and vancomycin was not observed.     

Effects of anti-inflammatory drugs on fever and neutrophilia induced by Clostridium difficile toxin B

This study investigated the ability of Clostridium difficile toxin B, isolated from the VPI 10463 strain, to induce fever and neutrophilia in rats. Intravenous injection of toxin B (0.005-0.5 mug/kg) evoked a dose-dependent increase in body temperature. The febrile response to 0.5 mug/kg of the toxin started in 2.5 h, peaked at 5 h, and subsided fully within 24 h. Toxin B also induced a dosedependent neutrophilia. Pretreatment with indomethacin (2 mg/kg, i.p.) did not affect the neutrophilia induced by toxin B, but significantly reduced the febrile response measured 4 to 8 h after toxin B injection. Dexamethasone (0.5 mg/ kg) also markedly diminished the febrile response induced by toxin B. These results show that Clostridium difficile toxin B induced a febrile response susceptible to inhibition by dexamethasone and indomethacin. Furthermore, they suggest that prostaglandins are not involved in the neutrophilia caused by this toxin.     

Precise manipulation of the Clostridium difficile chromosome reveals a lack of association between the tcdC genotype and toxin production

Clostridium difficile causes a potentially fatal diarrheal disease through the production of its principal virulence factors, toxin A and toxin B. The tcdC gene is thought to encode a negative regulator of toxin production. Therefore, increased toxin production, and hence increased virulence, is often inferred in strains with an aberrant tcdC genotype. This report describes the first allele exchange system for precise genetic manipulation of C. difficile, using the codA gene of Escherichia coli as a heterologous counterselection marker. It was used to systematically restore the Δ117 frameshift mutation and the 18-nucleotide deletion that occur naturally in the tcdC gene of C. difficile R20291 (PCR ribotype 027). In addition, the naturally intact tcdC gene of C. difficile 630 (PCR ribotype 012) was deleted and then subsequently restored with a silent nucleotide substitution, or "watermark," so the resulting strain was distinguishable from the wild type. Intriguingly, there was no association between the tcdC genotype and toxin production in either C. difficile R20291 or C. difficile 630. Therefore, an aberrant tcdC genotype does not provide a broadly applicable rationale for the perceived notion that PCR ribotype 027 strains are "high-level" toxin producers. This may well explain why several studies have reported that an aberrant tcdC gene does not predict increased toxin production or, indeed, increased virulence.