Efficacy of Bezlotoxumab in Trial Participants Infected With Clostridioides difficile Strain BI Associated With Poor Outcomes.

BACKGROUND: Bezlotoxumab reduced rates of recurrent Clostridioides difficile infection (rCDI) vs placebo in Monoclonal Antibodies for C. difficile Therapy (MODIFY) I/II trial participants receiving antibacterial drug treatment for CDI. A secondary objective of MODIFY I/II was to assess bezlotoxumab's efficacy against C. difficile strains associated with increased rates of morbidity and mortality. METHODS: In this post-hoc analysis of pooled MODIFY I/II data, efficacy endpoints were assessed in participants infected with restriction endonuclease analysis BI and non-BI strains of C. difficile at study entry. Treatment outcomes were compared between participants receiving bezlotoxumab (alone or with actoxumab [B, B+A]) and those receiving no bezlotoxumab (placebo or actoxumab [P, A]). RESULTS: From 2559 randomized participants, C. difficile was isolated from 1588 (67.2%) baseline stool samples. Participants with BI strains (n = 328) were older and had more risk factors for rCDI than non-BI strain participants (n = 1260). There were no differences in initial clinical cure rate between BI and non-BI strains in either group. The rCDI rate for BI strains treated with bezlotoxumab was lower than for the no bezlotoxumab group (B, B+A vs P, A: 23.6% vs 43.9%) and was also lower for the non-BI strains (B, B+A vs P, A: 21.4% vs 36.1%). Rates of 30-day CDI-associated rehospitalization were greater with BI vs non-BI strains in both groups. CONCLUSIONS: Infection with BI strains of C. difficile predicted poor outcomes in the MODIFY I/II trials. Bezlotoxumab (alone or with actoxumab) treatment was effective both in BI and non-BI subpopulations.

Unique Clindamycin-Resistant Clostridioides difficile Strain Related to Fluoroquinolone-Resistant Epidemic BI/RT027 Strain.

During a surveillance study of patients in a long-term care facility and the affiliated acute care hospital in the United States, we identified a Clostridioides difficile strain related to the epidemic PCR ribotype (RT) 027 strain associated with hospital outbreaks of severe disease. Fifteen patients were infected with this strain, characterized as restriction endonuclease analysis group DQ and RT591. Like RT027, DQ/RT591 contained genes for toxin B and binary toxin CDT and a tcdC gene of identical sequence. Whole-genome sequencing and multilocus sequence typing showed that DQ/RT591 is a member of the same multilocus sequence typing clade 2 as RT027 but in a separate cluster. DQ/RT591 produced a similar cytopathic effect as RT027 but showed delayed toxin production in vitro. DQ/RT591 was susceptible to moxifloxacin but highly resistant to clindamycin. Continued surveillance is warranted for this clindamycin-resistant strain that is related to the fluoroquinolone-resistant epidemic RT027 strain.

Characterization of Clostridioides difficile isolates recovered from two Phase 3 surotomycin treatment trials by restriction endonuclease analysis, PCR ribotyping and antimicrobial susceptibilities.

OBJECTIVES: To investigate the molecular epidemiology and antimicrobial susceptibility of Clostridioides difficile isolates from patients with C. difficile infection (CDI) from two Phase 3 clinical trials of surotomycin. METHODS: In both trials [Protocol MK-4261-005 (NCT01597505) conducted across Europe, North America and Israel; and Protocol MK-4261-006 (NCT01598311) conducted across North America, Asia-Pacific and South America], patients with CDI were randomized (1:1) to receive oral surotomycin (250 mg twice daily) or oral vancomycin (125 mg four times per day) for 10 days. Stool samples were collected at baseline and C. difficile isolates were characterized by restriction endonuclease analysis (REA) and PCR ribotyping. Susceptibility testing was performed by agar dilution, according to CLSI recommendations. RESULTS: In total, 1147 patients were included in the microbiological modified ITT population. Of 992 recovered isolates, 922 (92.9%) were typed. There was a high association between REA groups and their corresponding predominant PCR ribotype (RT) for BI, DH, G and CF strains. REA group A showed more diverse PCR RTs. Overall, the most common strain was BI/RT027 (20.3%) followed by Y/RT014/020 (15.0%) and DH/RT106 (7.2%). The BI/RT027 strain was particularly prevalent in Europe (29.9%) and Canada (23.6%), with lower prevalence in the USA (16.8%) and Australia/New Zealand (3.4%). Resistance was most prevalent in the BI/RT027 strain, particularly to metronidazole, vancomycin and moxifloxacin. CONCLUSIONS: A wide variation in C. difficile strains, both within and across different geographical regions, was documented by both REA and ribotyping, which showed overall good correlation.

Differential immunodetection of toxin B from highly virulent Clostridium difficile BI/NAP-1/027.

We developed a simple immunoassay capable of differentially detecting toxin B from highly virulent strains of Clostridium difficile (BI/NAP-1/027) in stool. This assay can simultaneously confirm the presence of in vivo toxin production and provide strain-related information relevant to infection control epidemiology and disease prognosis.

Development and Validation of Digital Enzyme-Linked Immunosorbent Assays for Ultrasensitive Detection and Quantification of Clostridium difficile Toxins in Stool.

The currently available diagnostics for Clostridium difficile infection (CDI) have major limitations. Despite mounting evidence that toxin detection is paramount for diagnosis, conventional toxin immunoassays are insufficiently sensitive and cytotoxicity assays too complex; assays that detect toxigenic organisms (toxigenic culture [TC] and nucleic acid amplification testing [NAAT]) are confounded by asymptomatic colonization by toxigenic C. difficile. We developed ultrasensitive digital enzyme-linked immunosorbent assays (ELISAs) for toxins A and B using single-molecule array technology and validated the assays using (i) culture filtrates from a panel of clinical C. difficile isolates and (ii) 149 adult stool specimens already tested routinely by NAAT. The digital ELISAs detected toxins A and B in stool with limits of detection of 0.45 and 1.5 pg/ml, respectively, quantified toxins across a 4-log range, and detected toxins from all clinical strains studied. Using specimens that were negative by cytotoxicity assay/TC/NAAT, clinical cutoffs were set at 29.4 pg/ml (toxin A) and 23.3 pg/ml (toxin B); the resulting clinical specificities were 96% and 98%, respectively. The toxin B digital ELISA was 100% sensitive versus cytotoxicity assay. Twenty-five percent and 22% of the samples positive by NAAT and TC, respectively, were negative by the toxin B digital ELISA, consistent with the presence of organism but minimal or no toxin. The mean toxin levels by digital ELISA were 1.5- to 1.7-fold higher in five patients with CDI-attributable severe outcomes, versus 68 patients without, but this difference was not statistically significant. Ultrasensitive digital ELISAs for the detection and quantification of toxins A and B in stool can provide a rapid and simple tool for the diagnosis of CDI with both high analytical sensitivity and high clinical specificity.

Toxin B is essential for virulence of Clostridium difficile.

Clostridium difficile is the leading cause of infectious diarrhoea in hospitals worldwide, because of its virulence, spore-forming ability and persistence. C. difficile-associated diseases are induced by antibiotic treatment or disruption of the normal gastrointestinal flora. Recently, morbidity and mortality resulting from C. difficile-associated diseases have increased significantly due to changes in the virulence of the causative strains and antibiotic usage patterns. Since 2002, epidemic toxinotype III NAP1/027 strains, which produce high levels of the major virulence factors, toxin A and toxin B, have emerged. These toxins have 63% amino acid sequence similarity and are members of the large clostridial glucosylating toxin family, which are monoglucosyltransferases that are pro-inflammatory, cytotoxic and enterotoxic in the human colon. Inside host cells, both toxins catalyse the transfer of glucose onto the Rho family of GTPases, leading to cell death. However, the role of these toxins in the context of a C. difficile infection is unknown. Here we describe the construction of isogenic tcdA and tcdB (encoding toxin A and B, respectively) mutants of a virulent C. difficile strain and their use in the hamster disease model to show that toxin B is a key virulence determinant. Previous studies showed that purified toxin A alone can induce most of the pathology observed after infection of hamsters with C. difficile and that toxin B is not toxic in animals unless it is co-administered with toxin A, suggesting that the toxins act synergistically. Our work provides evidence that toxin B, not toxin A, is essential for virulence. Furthermore, it is clear that the importance of these toxins in the context of infection cannot be predicted exclusively from studies using purified toxins, reinforcing the importance of using the natural infection process to dissect the role of toxins in disease.

Nontoxigenic Clostridium difficile protects hamsters against challenge with historic and epidemic strains of toxigenic BI/NAP1/027 C. difficile.

Nontoxigenic Clostridium difficile (NTCD) has been shown to prevent fatal C. difficile infection in the hamster model when hamsters are challenged with standard toxigenic C. difficile strains. The purpose of this study was to determine if NTCD can prevent C. difficile infection in the hamster model when hamsters are challenged with restriction endonuclease analysis group BI C. difficile strains. Groups of 10 hamsters were given oral clindamycin, followed on day 2 by 10(6) CFU of spores of NTCD strain M3 or T7, and were challenged on day 5 with 100 CFU of spores of BI1 or BI6. To conserve animals, results for control hamsters challenged with BI1 or BI6 from the present study and controls from previous identical experiments were combined for statistical comparisons. NTCD strains M3 and T7 achieved 100% colonization and were 100% protective against challenge with BI1 (P ≤ 0.001). M3 colonized 9/10 hamsters and protected against BI6 challenge in the colonized hamsters (P = 0.0003). T7 colonized 10/10 hamsters, but following BI6 challenge, cocolonization occurred in 5 hamsters, 4 of which died, for protection of 6/10 animals (P = 0.02). NTCD colonization provides protection against challenge with toxigenic BI group strains. M3 is more effective than T7 in preventing C. difficile infection caused by the BI6 epidemic strain. Prevention of C. difficile infection caused by the epidemic BI6 strain may be more challenging than that of infections caused by historic BI1 and non-BI C. difficile strains.

Vaccination with parenteral toxoid B protects hamsters against lethal challenge with toxin A-negative, toxin B-positive clostridium difficile but does not prevent colonization.

Toxin A has historically been regarded as the primary virulence determinant in Clostridium difficile infection, but naturally occurring toxin A-negative, toxin B-positive (A-/B+) C. difficile strains are known to be virulent. To determine the role of toxin B in these strains, we immunized hamsters with a toxoid prepared from purified toxin B to determine whether they would be protected from lethal challenge with an A-/B+ strain of C. difficile.

Effective Colonization by Nontoxigenic Clostridioides difficile REA Strain M3 (NTCD-M3) Spores following Treatment with Either Fidaxomicin or Vancomycin.

Colonization with nontoxigenic Clostridioides difficile strain M3 (NTCD-M3) has been demonstrated in susceptible hamsters and humans when administered after vancomycin treatment. NTCD-M3 has also been shown to decrease risk of recurrent C. difficile infection (CDI) in patients following vancomycin treatment for CDI. As there are no data for NTCD-M3 colonization after fidaxomicin treatment, we studied the efficacy of NTCD-M3 colonization and determined fecal antibiotic levels in a well-studied hamster model of CDI. Ten of 10 hamsters became colonized with NTCD-M3 after 5 days of treatment with fidaxomicin when NTCD-M3 was administered daily for 7 days after treatment discontinuation. The findings were nearly identical to 10 vancomycin-treated hamsters also given NTCD-M3. High fecal levels of OP-1118, the major fidaxomicin metabolite, and vancomycin were noted during treatment with the respective agents and modest levels noted 3 days after treatment discontinuation at the time when most of the hamsters became colonized. These findings support the ongoing development of NTCD-M3 for the prevention of recurrent CDI. IMPORTANCE NTCD-M3 is a novel live biotherapeutic, that has been shown in a Phase 2 clinical trial to prevent recurrence of C. difficile infection (CDI) when administered shortly after antibiotic treatment of the initial CDI episode. Fidaxomicin was not, however, in widespread use at the time this study was conducted. A large multi-center Phase 3 clinical trial is now currently in the planning stage, and it is anticipated that many patients eligible for this study will be treated with fidaxomicin. Since efficacy in the hamster model of CDI has predicted success in patients with CDI, we studied the ability of NTCD-M3 to colonize hamsters after treatment with either fidaxomicin or vancomycin.

Decreased cure and increased recurrence rates for Clostridium difficile infection caused by the epidemic C. difficile BI strain.

BACKGROUND: An epidemic strain of Clostridium difficile designated by restriction endonuclease analysis (REA) as group BI has caused multiple outbreaks of severe C. difficile infection (CDI). The treatment response of patients infected with this strain is uncertain. METHODS: Clostridium difficile isolates were collected from 2 phase 3 clinical trials comparing fidaxomicin to vancomycin and typed using REA. Clinical cure and recurrence outcomes were analyzed by strain type of the infecting organism, BI and non-BI, using both univariate and multivariate analyses. RESULTS: From 999 patients, 719 isolates were available for typing (356 fidaxomicin treated and 363 vancomycin treated). BI was the most common REA group (34% of isolates). Patients infected with BI had lower cure rates (86.6%; 214 of 247) than those infected with non-BI strains (94.3%; 445 of 472) (P < .001). The cure rate difference between the BI and non-BI patients was significant for both vancomycin (P = .02) and fidaxomicin (P = .007). BI patients had a recurrence rate of 27.4% (51 of 186), compared with a recurrence rate of 16.6% (66 of 397) in non-BI patients (P = .002). By multivariate analysis, BI infection was statistically significant as a risk factor for reduced cure (odds ratio [OR], 0.48; 95% confidence interval [CI], .27-.85; P = .030) and for increased recurrence (OR, 1.57; 95% CI, 1.01-2.45; P = .046). CONCLUSIONS: The clinical cure rate of patients infected with the epidemic BI C. difficile strain is lower than the cure rate of those infected with non-BI strains whether treated with fidaxomicin or vancomycin. Similarly, the CDI recurrence rate is increased in patients with the BI strain compared with patients with other C. difficile strains.

Relapse versus reinfection: recurrent Clostridium difficile infection following treatment with fidaxomicin or vancomycin.

Our study sought to compare the strain types of Clostridium difficile causing initial and recurrent episodes of C. difficile infection (CDI) in adult patients with a first episode of CDI or 1 prior episode of CDI within the previous 90 days. Strains originated from patients who had been entered into two phase 3 randomized clinical trials of fidaxomicin versus vancomycin. Isolates of C. difficile from the initial and recurrent episodes within 28 (± 2) days of cure of CDI were compared using restriction endonuclease analysis (REA) typing. Paired isolates were available from 90 of 194 (46%) patients with recurrent CDI. Patients with isolates available were significantly younger (P = .008) and more likely to be from Canadian sites (P = .0001), compared with patients without isolates. In 75 of 90 subjects (83.3%), the identical REA type strain was identified at recurrence and the initial episode (putative relapse). Early recurrences (0-14 days after treatment completion) were relapses in 86.7% and a new strain (reinfection) in 13.3%. Later recurrences (15-31 days after treatment) were relapses in 76.7% and reinfections in 23.3%. Mean time (± standard deviation) to recurrence was 12.2 (± 6.4) days for relapses and 14.7 (± 6.8) days for reinfections (P = .177). The most common BI/NAP1/027 group and the previous US epidemic REA group J/NAP2/001 had a significantly higher combined rate of recurrence with the same strain (relapse), compared with the other REA groups (39 of 42 [93%] vs 36 of 48 [75%], respectively; P = .023). We found a higher than historic rate of recurrent CDI caused by the same isolate as the original episode, a finding that may be related to the relatively short observation period in this study and the high frequency of isolation of epidemic strains, such as groups BI and J, for which relapse rates may be higher than for other REA groups. Caution in generalizing these observations is required, because the patients studied were younger and more likely to be from Canadian sites than were patients with recurrence who did not provide isolates.

Absence of toxin gene transfer from Clostridioides difficile strain 630Δerm to nontoxigenic C. difficile strain NTCD-M3r in filter mating experiments.

Nontoxigenic Clostridioides difficile strain M3 (NTCD-M3) protects hamsters and humans against C. difficile infection. Transfer in vitro of the pathogenicity locus (PaLoc) to nontoxigenic strain CD37 has been reported. We repeated these conjugations using toxigenic strain 630Δerm as donor and NTCD-M3 and CD37 as recipients. In order to conduct these matings we induced rifampin resistance (50ug/ml) in NTCD-M3 by serial passage on rifampin-containing media to obtain strain NTCD-M3r. 630Δerm/CD37 matings produced 21 PaLoc transconjugants in 5.5 x 109 recipient CFUs; a frequency of 3.8 x 10-9. All transconjugants carried the tcdB gene and produced toxin. 630Δerm/NTCD-M3r matings produced no transconjugants in 5 assays with a total of 9.4 x 109 NTCD-M3r recipient cells. Toxin gene transfer to NTCD-M3r could not be demonstrated under conditions that demonstrated transfer to strain CD37.

Comparative susceptibilities to fidaxomicin (OPT-80) of isolates collected at baseline, recurrence, and failure from patients in two phase III trials of fidaxomicin against Clostridium difficile infection.

A 10-day course of oral fidaxomicin (200 mg twice a day [b.i.d.]), a potent new macrocyclic drug, was compared to vancomycin (125 mg four times a day [q.i.d.]) in 1,164 adults (1,105 in the modified intent-to-treat [mITT] population) with Clostridium difficile infection in two phase III randomized, double-blind trials at sites in North America and 7 European countries. Of 1,105 mITT patients, 792 (71.7%), including 719/999 (72.0%) in the per-protocol (PP) population, provided a C. difficile strain at baseline, of whom 356 received fidaxomicin with 330 cures (92.7%) and 363 received vancomycin with 329 cures (90.6%). The susceptibilities (MIC(90)) of baseline isolates did not predict clinical cure, failure, or recurrence for fidaxomicin (MIC(90), 0.25 µg/ml for both; range, ≤ 0.007 to 1 µg/ml), but there was a one-dilution difference in the MIC(90) (but not the MIC(50)) for vancomycin (MIC(90), 2 µg/ml [range, 0.25 to 8 µg/ml] for cure and 4.0 µg/ml [range, 0.5 to 4 µg/ml] for failures). A total of 65 (7.9%) "rifaximin-resistant" (MIC > 256 µg/ml) strains were isolated in both treatment groups on enrollment, which increased to 25% for failures at the end of therapy. No resistance to either fidaxomicin or vancomycin developed during treatment in either of the phase III studies, although a single strain isolated from a cured patient had an elevated fidaxomicin MIC of 16 µg/ml at the time of recurrence. All isolates were susceptible to ≤ 4 µg/ml of metronidazole. When analyzed by restriction endonuclease analysis (REA) type, 247/719 (34.4%) isolates were BI group isolates, and the MICs were generally higher for all four drugs tested (MIC(90)s: fidaxomicin, 0.5; vancomycin, 2.0; metronidazole, 2.0; and rifaximin, >256 µg/ml) than for the other REA types. There was no correlation between the MIC of a baseline clinical isolate and clinical outcome. MIC(90)s were generally low for fidaxomicin and vancomycin, but BI isolates had higher MICs than other REA group isolates.

Susceptibility of hamsters to infection by historic and epidemic BI Clostridium difficile strains during daily administration of three fluoroquinolones.

BACKGROUND: The recent epidemic of Clostridium difficile infection (CDI) has been attributed largely to the REA strain group BI (aka NAP1/027). Current isolates of the BI group differ from historic non-epidemic BI strains in that they have developed resistance to the newer fluoroquinolone (FQ), moxifloxacin. The acquisition of moxifloxacin resistance has been associated with the rise in frequency of CDI caused by these isolates. In order to explore the effect of FQ resistance on CDI we compared colonization and mortality in hamsters challenged with a historic (BI1 - susceptible to moxifloxacin) and a recent epidemic (BI17 - resistant to moxifloxacin) BI strain of CD during continuous administration of 3 different FQs. METHODS: Groups of 6 hamsters were treated with a 5 day course of ciprofloxacin, levofloxacin, or moxifloxacin given orally once per day. Each hamster was then challenged with 1 × 10(4) CFU of either BI1 or BI17 on day 3 or day 5. Colonization and time to death were recorded. RESULTS: Colonization efficiency (CE) following moxifloxacin (92%) was significantly greater than following levofloxacin (50%, p < 0.01) or ciprofloxacin (42%, p < 0.01) for both strains combined. The CE of BI17 was higher than BI1 for ciprofloxacin (67% vs 17%, p = 0.04) and levofloxacin (83% vs 17%, p < 0.01), but not moxifloxacin (100% and 83%, p = 0.48) administration. BI17 also showed a shorter time from inoculation to death than BI1 following moxifloxacin administration (1.8 days vs 3.9 days, p < 0.01). Moxifloxacin shortened the time from inoculation to death compared to ciprofloxacin in hamsters challenged with BI17 (1.8 days vs 4.0 days, p < 0.01) but not levofloxacin (1.8 days vs 2.0 days, p = NS). CONCLUSIONS: For the epidemic BI17 strain, ciprofloxacin, levofloxacin and moxifloxacin have similar colonization rates, suggesting that the acquisition of high-level FQ resistance increases colonization rates in association with any FQ. Historic strain BI1 which does not carry high-level FQ resistance colonized efficiently only in the presence of moxifloxacin, possibly explaining lower rates of CDI historically prior to the widespread clinical use of moxifloxacin (and gatifloxacin). Current high rates and severity of CDI from 2000 to 2010 may in part be associated with the acquisition of high-level FQ resistance in BI strains and higher patient exposure rates of all FQs, especially moxifloxacin.

Multilocus variable-number tandem-repeat analysis and multilocus sequence typing reveal genetic relationships among Clostridium difficile isolates genotyped by restriction endonuclease analysis.

Numbers of Clostridium difficile infections have increased worldwide in the past decade. While infection with C. difficile remains predominantly a health care-associated infection, there may also be an increased incidence of community-associated infections. C. difficile strains of public health significance continue to emerge, and reliable genotyping methods for epidemiological investigations and global surveillance of C. difficile are required. In this study, multilocus sequence typing (MLST) and multilocus variable-number tandem-repeat analysis (MLVA) were performed on a set of 157 spatially and temporally diverse C. difficile isolates that had been previously genotyped by restriction endonuclease analysis (REA) to determine the concordance among these genotyping methods. In addition, sequence analysis of the tcdC genotype was performed to investigate the association of allelic variants with epidemic C. difficile isolates. Overall, the MLST and MLVA data were concordant with REA genotyping data. MLST was less discriminatory than either MLVA or REA, yet this method established C. difficile genetic lineage. MLVA was highly discriminatory and demonstrated relationships among the MLST genetic lineages and REA genotypes that were previously unrecognized. Several tcdC genotypes were specific to epidemic clones, highlighting the possible importance of toxin misregulation in C. difficile disease pathogenesis. This study demonstrates that a combination of MLST and MLVA may prove useful for the investigation and surveillance of emergent C. difficile clones of global public health concern.

The Relative Role of Toxins A and B in the Virulence of Clotridioides difficile.

Most pathogenic strains of C. difficile possess two large molecular weight single unit toxins with four similar functional domains. The toxins disrupt the actin cytoskeleton of intestinal epithelial cells leading to loss of tight junctions, which ultimately manifests as diarrhea in the host. While initial studies of purified toxins in animal models pointed to toxin A (TcdA) as the main virulence factor, animal studies using isogenic mutants demonstrated that toxin B (TcdB) alone was sufficient to cause disease. In addition, the natural occurrence of TcdA-/TcdB+ (TcdA-/B+)mutant strains was shown to be responsible for cases of C. difficile infection (CDI) with symptoms identical to CDI caused by fully toxigenic (A+/B+) strains. Identification of these cases was delayed during the period when clinical laboratories were using immunoassays that only detected TcdA (toxA EIA). Our hospital laboratory at the time performed culture as well as toxA EIA on patient stool samples. A total of 1.6% (23/1436) of all clinical isolates recovered over a 2.5-year period were TcdA-/B+ variants, the majority of which belonged to the restriction endonuclease analysis (REA) group CF and toxinotype VIII. Despite reports of serious disease due to TcdA-/B+ CF strains, these infections were typically mild, often not requiring specific treatment. While TcdB alone may be sufficient to cause disease, clinical evidence suggests that both toxins have a role in disease.

Distribution of Clostridium difficile strains from a North American, European and Australian trial of treatment for C. difficile infections: 2005-2007.

Clostridium difficile is a widely distributed pathogen with multiple strain types as determined by restriction endonuclease analysis (REA) and by PCR ribotyping, two well-characterized typing systems. In this study, REA typing was performed on 894C. difficile isolates from patients enrolled from 16 countries on three continents in two large, recently conducted clinical treatment trials of C. difficile infection. REA group BI (Ribotype 027) isolates were the most common strains identified and were widely distributed throughout North America, but restricted to three of thirteen countries in Europe. REA group J (Ribotype 001) isolates were the most common strains identified in Europe and non-specific REA groups (historically less frequent) were the most common strains identified in Australia. REA groups BI, J, G and CF correlated with specific PCR ribotypes whereas more than one ribotype was found within REA groups Y, BK, and K. International surveillance of C. difficile strains is important to document the changing epidemiology of this enteric pathogen that continues to cause healthcare facility outbreaks and sporadic infections in other settings.

Rifampin and rifaximin resistance in clinical isolates of Clostridium difficile.

Rifaximin, a poorly absorbed rifamycin derivative, is a promising alternative for the treatment of Clostridium difficile infections. Resistance to this agent has been reported, but no commercial test for rifaximin resistance exists and the molecular basis of this resistance has not been previously studied in C. difficile. To evaluate whether the rifampin Etest would be a suitable substitute for rifaximin susceptibility testing in the clinical setting, we analyzed the in vitro rifaximin susceptibilities of 80 clinical isolates from our collection by agar dilution and compared these results to rifampin susceptibility results obtained by agar dilution and Etest. We found rifaximin susceptibility data to agree with rifampin susceptibility; the MICs of both antimicrobials for all isolates were either very low or very high. Fourteen rifaximin-resistant (MIC, > or = 32 microg/ml) unique isolates from patients at diverse locations in three countries were identified. Molecular typing analysis showed that nine (64%) of these isolates belonged to the epidemic BI/NAP1/027 group that is responsible for multiple outbreaks and increased disease severity in the United Kingdom, Europe, and North America. The molecular basis of rifaximin and rifampin resistance in these isolates was investigated by sequence analysis of rpoB, which encodes the beta subunit of RNA polymerase, the target of rifamycins. Resistance-associated rpoB sequence differences that resulted in specific amino acid substitutions in an otherwise conserved region of RpoB were found in all resistant isolates. Seven different RpoB amino acid substitutions were identified in the resistant isolates, which were divided into five distinct groups by restriction endonuclease analysis typing. These results suggest that the amino acid substitutions associated with rifamycin resistance were independently derived rather than disseminated from specific rifamycin-resistant clones. We propose that rifaximin resistance in C. difficile results from mutations in RpoB and that rifampin resistance predicts rifaximin resistance for this organism.

An epidemic, toxin gene-variant strain of Clostridium difficile.

BACKGROUND: Recent reports suggest that the rate and severity of Clostridium difficile-associated disease in the United States are increasing and that the increase may be associated with the emergence of a new strain of C. difficile with increased virulence, resistance, or both. METHODS: A total of 187 C. difficile isolates were collected from eight health care facilities in six states (Georgia, Illinois, Maine, New Jersey, Oregon, and Pennsylvania) in which outbreaks of C. difficile-associated disease had occurred between 2000 and 2003. The isolates were characterized by restriction-endonuclease analysis (REA), pulsed-field gel electrophoresis (PFGE), and toxinotyping, and the results were compared with those from a database of more than 6000 isolates obtained before 2001. The polymerase chain reaction was used to detect the recently described binary toxin CDT and a deletion in the pathogenicity locus gene, tcdC, that might result in increased production of toxins A and B. RESULTS: Isolates that belonged to one REA group (BI) and had the same PFGE type (NAP1) were identified in specimens collected from patients at all eight facilities and accounted for at least half of the isolates from five facilities. REA group BI, which was first identified in 1984, was uncommon among isolates from the historic database (14 cases). Both historic and current (obtained since 2001) BI/NAP1 isolates were of toxinotype III, were positive for the binary toxin CDT, and contained an 18-bp tcdC deletion. Resistance to gatifloxacin and moxifloxacin was more common in current BI/NAP1 isolates than in non-BI/NAP1 isolates (100 percent vs. 42 percent, P<0.001), whereas the rate of resistance to clindamycin was the same in the two groups (79 percent). All of the current but none of the historic BI/NAP1 isolates were resistant to gatifloxacin and moxifloxacin (P<0.001). CONCLUSIONS: A previously uncommon strain of C. difficile with variations in toxin genes has become more resistant to fluoroquinolones and has emerged as a cause of geographically dispersed outbreaks of C. difficile-associated disease.

Comparison of seven techniques for typing international epidemic strains of Clostridium difficile: restriction endonuclease analysis, pulsed-field gel electrophoresis, PCR-ribotyping, multilocus sequence typing, multilocus variable-number tandem-repeat analysis, amplified fragment length polymorphism, and surface layer protein A gene sequence typing.

Using 42 isolates contributed by laboratories in Canada, The Netherlands, the United Kingdom, and the United States, we compared the results of analyses done with seven Clostridium difficile typing techniques: multilocus variable-number tandem-repeat analysis (MLVA), amplified fragment length polymorphism (AFLP), surface layer protein A gene sequence typing (slpAST), PCR-ribotyping, restriction endonuclease analysis (REA), multilocus sequence typing (MLST), and pulsed-field gel electrophoresis (PFGE). We assessed the discriminating ability and typeability of each technique as well as the agreement among techniques in grouping isolates by allele profile A (AP-A) through AP-F, which are defined by toxinotype, the presence of the binary toxin gene, and deletion in the tcdC gene. We found that all isolates were typeable by all techniques and that discrimination index scores for the techniques tested ranged from 0.964 to 0.631 in the following order: MLVA, REA, PFGE, slpAST, PCR-ribotyping, MLST, and AFLP. All the techniques were able to distinguish the current epidemic strain of C. difficile (BI/027/NAP1) from other strains. All of the techniques showed multiple types for AP-A (toxinotype 0, binary toxin negative, and no tcdC gene deletion). REA, slpAST, MLST, and PCR-ribotyping all included AP-B (toxinotype III, binary toxin positive, and an 18-bp deletion in tcdC) in a single group that excluded other APs. PFGE, AFLP, and MLVA grouped two, one, and two different non-AP-B isolates, respectively, with their AP-B isolates. All techniques appear to be capable of detecting outbreak strains, but only REA and MLVA showed sufficient discrimination to distinguish strains from different outbreaks.