Clostridioides difficile infection with isolates of cryptic clade C-II: a genomic analysis of polymerase chain reaction ribotype 151

Genomic analysis reveals the presence of hypervirulent and fluoroquinolone-resistant Clostridioides difficile in farmed mussels (Mytilus galloprovincialis) in Slovenia

Clostridioides difficile is one of the leading causes of antibiotic-associated diarrhea. In this study, we characterized 76C. difficile isolates, obtained from three Mediterranean mussel (Mytilus galloprovincialis) farms in Slovenia from November 2014 to October 2015 (sampling period 1) and from January to December 2021 (sampling period 2). The overall isolation rate of C. difficile from all the examined mussels was 59.8 %. A statistically significant trend of seasonal variation was observed, with a higher isolation rate in the colder months of the year (87.9 %; sea temperature ≤ 15 °C) compared with the warmer months (31.8 %; sea temperature > 15 °C). Whole-genome sequencing (WGS) revealed that the isolates belonged to 31 different sequence types (STs), which were associated with three clades (1, 4, and 5) and two cryptic clades (C-II and C-III). Five isolates, which belonged to ST11 (clade 5), harbored all the main toxin genes (A+B+CDT+) and chromosomal mutations conferring fluoroquinolone resistance. Core genome multilocus sequence typing (cgMLST) revealed four clusters of 2-3 isolates, three of which included isolates from different farms, suggesting that clonal C. difficile strains are circulating among the Slovenian mussel farms. The results highlight the presence of hypervirulent strains in mussels; therefore, at-risk population groups should be alerted to the risks associated with consuming shellfish.

Distribution of Clostridioides difficile ribotypes and sequence types across humans, animals and food in 13 European countries

Clostridioides difficile is a One Health pathogen found in humans, animals, and the environment, with food representing a potential transmission route. One Health studies are often limited to a single country or selected reservoirs and ribotypes. This study provides a varied and accessible collection of C. difficile isolates and sequencing data derived from human, animal, and food sources across 13 European countries. A total of 441 strains (human hospital- and community-associated cases n = 280, animal n = 96, food n = 65) were analysed by ribotyping, toxinotyping and whole-genome sequencing (WGS). We detected 83 sequence types (STs), with ST11 (n = 80 isolates) and ST1 (n = 54 isolates) being the most represented. Several STs included strains originating from all source combinations. Further genomic analysis confirmed close genetic relatedness in some of the STs. Additionally, the genomic analysis identified 10 strains from cryptic clades (C-I to C-III) and 4 of them were mono-toxigenic possessing only a variant form of tcdA gene. Amongst 106 ribotypes, 10 were shared between all 3 sources and 68 were source-specific. Some ribotypes were only found at the intersection of human and food source (RT023, RT027), or between human and animal source (RT009, RT045, RT046). C. difficile ribotypes and STs in Europe were diverse. In this collection, some ribotypes showed potential association with food or animal transmission routes. C. difficile strains from divergent clades CI-III, currently emerging in the human population, were rare and mostly food-associated.Trial registration: ClinicalTrials.gov identifier: NCT03503474.

Diversity of Clostridioides difficile PCR ribotypes isolated from freshwater sediments depends on the isolation method

Clostridioides difficile is an intestinal pathogen of humans and animals. In community-associated infections, the environment is suggested to play a significant role in overall transmission routes. Although the prevalence of C. difficile in freshwater and soil has been widely studied, little is known about its presence in sediments. In this study, we tested 15 sediment samples collected from various freshwater sources. C. difficile was isolated from all sampled sites, yielding a total of 171 strains grouped into 26 ribotypes, with 001/072 and 014/020 being the most prevalent. Genome sequencing of 37 isolates from 17 PCR ribotypes confirmed the presence of highly related strains in the geographically distant and unlinked water samples. Eight divergent PCR ribotypes from clades C-II and C-III were found in six samples. In each sample, the unbound fraction (supernatant after sediment wash) and bound fraction (sonicated sediment sample) were subjected to enrichment. Sonication was only slightly better than washing in terms of sample positivity (14 positive samples with sonication and 11 with washing). However, sonication substantially increased the diversity of the PCR ribotypes obtained (23 in sonicated samples vs nine in washed samples). In conclusion, sediments are a rich source for investigating the diversity of environmental C. difficile, including isolates from divergent lineages. Selection of the isolation method can significantly impact the diversity of captured PCR ribotypes.IMPORTANCEClostridioides difficile, a pathogenic bacterium that can cause intestinal infections in humans and animals, thrives in the gut but also disperses widely through spores found in the environment. Clinical and environmental strains often overlap with common PCR ribotypes, which are consistently isolated worldwide. Environmental studies have mostly focused on water and soil, but sediments have been very poorly studied. In this study, we investigated the presence of C. difficile in various freshwater sediments and evaluated the effectiveness of two different isolation approaches on positivity rates and strain diversity. C. difficile was found to be highly prevalent in sediments, with an isolation rate of 100%. Sonication proved to be more effective than simple washing for capturing a greater diversity of PCR ribotypes. Overall, this study underscores the widespread presence of C. difficile in freshwater sediments and emphasizes the importance of continued surveillance and monitoring to understand its ecology and transmission dynamics.

Non-human Clostridioides difficile Reservoirs and Sources: Animals, Food, Environment

Clostridioides difficile is ubiquitous and is found in humans, animals and in variety of environments. The substantial overlap of ribotypes between all three main reservoirs suggests the extensive transmissions. Here we give the overview of European studies investigating farm, companion and wild animals, food and environments including water, soil, sediment, wastewater treatment plants, biogas plants, air, and households. Studies in Europe are more numerous especially in last couple of years, but are still fragmented in terms of countries, animal species, or type of environment covered. Soil seem to be the habitat of divergent unusual lineages of C. difficile. But the most important aspect of animals and environment is their role in C. difficile transmissions and their potential as a source for human infection is discussed.

Diagnostic Guidance for C. difficile Infections

Diagnosis of Clostridioides difficile infection (CDI) can be challenging. First of all, there has been debate on which of the two reference assays, cell cytotoxicity neutralization assay (CCNA) or toxigenic culture (TC), should be considered the gold standard for CDI detection. Although the CCNA suffers most from suboptimal storage conditions and subsequent toxin degradation, TC is reported to falsely increase CDI detection rates as it cannot differentiate CDI patients from patients asymptomatically colonised by toxigenic C. difficile. Several rapid assays are available for CDI detection and fall into three broad categories: (1) enzyme immunoassays for glutamate dehydrogenase, (2) enzyme immunoassays or single-molecule array assays for toxins A/B and (3) nucleic acid amplification tests detecting toxin genes. All three categories have their own limitations, being suboptimal specificity and/or sensitivity or the inability to discern colonised patients from CDI patients. In light of these limitations, multi-step algorithmic testing has been advocated by international guidelines (IDSA/SHEA and ESCMID) in order to optimize diagnostic accuracy. As a result, a survey performed in 2018-2019 in Europe revealed that most of all hospital sites reported using more than one test to diagnose CDI. CDI incidence rates are also influenced by sample selection criteria, as several studies have shown that if not all unformed stool samples are tested for CDI, many cases may be missed due to an absence of clinical suspicion. Since methods for diagnosing CDI remain imperfect, there has been a growing interest in alternative testing strategies like faecal microbiota biomarkers, immune modulating interleukins, cytokines and imaging methods. At the moment, these alternative methods might play an adjunctive role, but they are not suitable to replace conventional CDI testing strategies.

Comparative Genomics of Clostridioides difficile

Clostridioides difficile, a Gram-positive spore-forming anaerobic bacterium, has rapidly emerged as the leading cause of nosocomial diarrhoea in hospitals. The availability of large numbers of genome sequences, mainly due to the use of next-generation sequencing methods, has undoubtedly shown their immense advantages in the determination of C. difficile population structure. The implementation of fine-scale comparative genomic approaches has paved the way for global transmission and recurrence studies, as well as more targeted studies, such as the PaLoc or CRISPR/Cas systems. In this chapter, we provide an overview of recent and significant findings on C. difficile using comparative genomic studies with implications for epidemiology, infection control and understanding of the evolution of C. difficile.

Revised Model for the Type A Glycan Biosynthetic Pathway in Clostridioides difficile Strain 630Δerm Based on Quantitative Proteomics of cd0241-cd0244 Mutant Strains

The bacterial flagellum is involved in a variety of processes including motility, adherence, and immunomodulation. In the Clostridioides difficile strain 630Δerm, the main filamentous component, FliC, is post-translationally modified with an O-linked Type A glycan structure. This modification is essential for flagellar function, since motility is seriously impaired in gene mutants with improper biosynthesis of the Type A glycan. The cd0240-cd0244 gene cluster encodes the Type A biosynthetic proteins, but the role of each gene, and the corresponding enzymatic activity, have not been fully elucidated. Using quantitative mass spectrometry-based proteomics analyses, we determined the relative abundance of the observed glycan variations of the Type A structure in cd0241, cd0242, cd0243, and cd0244 mutant strains. Our data not only confirm the importance of CD0241, CD0242, and CD0243 but, in contrast to previous data, also show that CD0244 is essential for the biosynthesis of the Type A modification. Combined with additional bioinformatic analyses, we propose a revised model for Type A glycan biosynthesis.

Update on Commonly Used Molecular Typing Methods for Clostridioides difficile

This review aims to provide a comprehensive overview of the significant Clostridioides difficile molecular typing techniques currently employed in research and medical communities. The main objectives of this review are to describe the key molecular typing methods utilized in C. difficile studies and to highlight the epidemiological characteristics of the most prevalent strains on a global scale. Geographically distinct regions exhibit distinct strain types of C. difficile, with notable concordance observed among various typing methodologies. The advantages that next-generation sequencing (NGS) offers has changed epidemiology research, enabling high-resolution genomic analyses of this pathogen. NGS platforms offer an unprecedented opportunity to explore the genetic intricacies and evolutionary trajectories of C. difficile strains. It is relevant to acknowledge that novel routes of transmission are continually being unveiled and warrant further investigation, particularly in the context of zoonotic implications and environmental contamination.