Surface-layer (S-layer) of Human and Animal Clostridium Difficile Strains and Their Behaviour in Adherence to Epithelial Cells and Intestinal Colonization

Clostridium difficile is a frequent cause of severe, recurrent post-antibiotic diarrhoea and pseudomembranous colitis. The surface layer (S-layer) is the predominant outer surface component of C. difficile which is involved in pathogen-host interactions critical to pathogenesis. In this study, we characterized the S-layer protein A (SIpA) of animal and human strains belonging to different PCR-ribotypes (PR) and compared the in vitro adherence and in vivo colonization properties of strains showing different SIpA variants. Since each SIpA variant has been recently associated with an S-layer cassette, we were able to deduce the cassette for each of our strains. In this study, an identity of 99-100% was found among the SIpA of isolates belonging to PR 012, 014/020, 045 and 078. One exception was the SIpA of a poultry isolate, PR 014/020, which showed 99% identity with that of strain 0160, another PR 014/020 which contains an S-layer cassette 6. Interestingly, this cassette has also been found in a PR 018 strain, an emerging virulent type currently predominant in Italy. Five other SIpA variants (v014/020a-e) were identified in strains PR 014/020. In vitro adherence assays and in vivo colonization experiments were performed on five PR 014/020 strains: human 1064 (v014/020e), human 4684/08 (v014/020b), human Ill 106 (v078a), poultry P30 (v014/020d) and poultry PB90 (v014/020b) strains. Adhesion assays indicate that C. difficile strains vary in their capacity to adhere to cells in culture and that adhesion seems to be independent of the SIpA variant. Colonization properties were assessed in vivo using a dixenic mouse model of colonization. The kinetics of faecal shedding and caecal colonization were similar when human 4684/08 (v014/020b) strain was compared with human 1064 (v014/020e) and poultry PB90 (v014/02013) strain. In contrast, poultry P30 (v014/020d) strain outcompeted both human 4684/08 (v014/020b) and IT1106 (v078a) strains and its adherence to caeca at day 7 was significantly higher. The peculiar characteristics of C. difficile P30 seem to advantage it in colonizing the intestinal mice niche, increasing its ability to compete and adapt. The results obtained underline the need of an increased attention to the genetic evolution of C. difficile to prevent and limit the consequences of the emergence of increasingly virulent strains

Clostridium difficile : étude du processus de colonisation et d’hypervirulence de la souche épidémique 027

Clostridium difficile is an enteropathogenic bacterium that causes post-antibiotic nosocomial diarrhea and pseudomembranous colitis. During the last decade, the incidence and the severity of C. difficile infections have significantly increased in America and Europe. This evolution seems to be related to the emergence and to the rapid dissemination of a particularly virulent clone of PCR-ribotype 027. The main virulence factors of C. difficile are the TcdA and TcdB cytotoxins which are responsible for intestinal lesions. However, the intestinal colonization by the bacterium is considered as an indispensible step for infection.To better understand the hypervirulence mechanisms of strain 027, we focused on the study of intestinal colonization process of this strain compared to the colonization process of the non-epidemic strain 630Δerm. First, we studied the role of the fibronectin binding protein FbpA. In vitro and in vivo characterization of a mutant FbpA showed the involvement of this protein in the colonization process of the non-epidemic strain 630Δerm. The difficulty of obtaining a mutant in the epidemic strain R20291 027 does not allow us to compare the adhesive properties of FbpA between the two strains.In a second step, we studied the characteristics of flagellar proteins FliC, FliD, FlgE and MotB. We showed that the flagella have a role in the adhesion and colonization of strain 027 and that this role is less important in strain 630Δerm. We also showed that flagella are involved in other cellular processes than adhesion and colonization. A transcriptomic study of a FliC mutant in 027 R20291 shows that flagellin is also involved in toxin production, sporulation and in the adaptation of bacteria to stress conditions. Further study should be performed to better understand the regulation system that governs these different cellular processes. Finally, we performed a transcriptomic analysis of the kinetic of in vivo colonization of the 027 R20291 strain. The study revealed a very early expression of toxin and sporulation genes during the first stages of the infection process. This analysis also allowed us to identify some genes, specific to 027 strains, which appeared regulated during the infection process. These genes could be involved in the virulence of C. difficile 027 strains and could provide new issues of study to better understand C. difficile virulence.Clostridium difficile est une bactérie entéropathogène responsable de diarrhées nosocomiales post-antibiotiques et de colites pseudomembraneuses. Ces dernières années, l'incidence et la gravité des infections à C. difficile ont significativement augmenté en Amérique et en Europe. Cette évolution semble être liée à l'émergence puis à la dissémination très rapide d'un clone particulièrement virulent de PCR-ribotype 027. Les facteurs de virulence majeurs de C. difficile sont les toxines TcdA et TcdB qui sont responsables des lésions intestinales. Cependant, l’étape de colonisation de l’intestin par la bactérie est considérée comme un pré-requis à l’infection. Afin de mieux comprendre les mécanismes d’hypervirulence de la souche 027, nous nous sommes focalisés sur l’étude du processus de colonisation intestinal de cette souche en le comparant à celui de la souche non épidémique 630∆erm. Dans un premier temps, nous avons étudié le rôle de la protéine de liaison à la fibronectine FbpA. La caractérisation in vitro et in vivo d’un mutant d’inactivation de fbpA, nous a permis de montrer l’implication de cette protéine dans le processus de colonisation de la souche non épidémique 630∆erm. La difficulté à obtenir un mutant dans la souche épidémique 027 R20291 ne nous a pas permis de comparer les propriétés adhésives de FbpA entre les deux souches. Dans un deuxième temps, nous avons étudié les caractéristiques des protéines flagellaires FliC, FliD, FlgE et MotB. Nous avons montré que les flagelles agissent en tant qu’adhésines chez la souche 027 et que ce rôle est moins important chez la souche 630∆erm. Nous avons également montré que les flagelles sont impliqués dans des processus cellulaires autres que l’adhésion et la colonisation. Selon une étude transcriptomique d’un mutant ∆FliC de la souche 027 R20291, il s’est avéré que la flagelline est aussi impliquée dans la production de toxines, la sporulation et dans l’adaptation de la bactérie aux conditions de stress. Une étude complémentaire serait nécessaire afin de mieux comprendre le système de régulation qui régi ces différents processus cellulaires.Finalement, nous avons effectué une analyse transcriptomique de la cinétique de colonisation in vivo de la souche 027. L’étude a révélé l’expression précoce des gènes de toxines et de sporulation au cours du processus d’infection. Elle nous a également permis d’identifier des gènes spécifiques à la souche 027 qui sont exprimés lors du processus infectieux. Ces gènes pourraient éventuellement être impliqués dans la virulence de C. difficile 027 et pourraient constituer de nouvelles pistes d’étude

Deciphering Adaptation Strategies of the Epidemic Clostridium difficile 027 Strain during Infection through In Vivo Transcriptional Analysis

International audienceClostridium difficile is responsible for a wide spectrum of infection from asymptomatic carriage to severe, relapsing colitis. Since 2003, C. difficile infections have increased with a higher morbidity and mortality due to the emergence of epidemic and hypervirulent C. diffi-cile strains such as those of the epidemic lineage 027/BI/NAP1. To decipher the hyperviru-lence and epidemicity of 027 strains, we analyzed gene expression profiles of the R20291 027 strain using a monoxenic mouse model during the first 38h of infection. A total of 741 genes were differentially expressed during the course of infection. They are mainly distributed in functional categories involved in host adaptation. Several genes of PTS and ABC transporters were significantly regulated during the infection, underlying the ability of strain R20291 to adapt its metabolism according to nutrient availability in the digestive tract. In this animal model, despite the early sporulation process, sporulation efficiency seems to indicate that growth of R20291 vegetative cells versus spores were favored during infection. The bacterial mechanisms associated to adaptability and flexibility within the gut environment , in addition to the virulence factor expression and antibiotic resistance, should contribute to the epidemicity and hypervirulence of the C. difficile 027 strains

The flagellin FliC of Clostridium difficile is responsible for pleiotropic gene regulation during in vivo infection

Clostridium difficile is the main agent responsible for hospital acquired antibiotic associated diarrhoea. In recent years, epidemic strains have emerged causing more severe infections. Whilst C. difficile has two major virulence factors, toxins TcdA and TcdB, it is generally accepted that other virulence components of the bacterium contribute to disease. Previously, it has been suggested that flagella expression from pathogenic bacteria might be implicated in virulence. In a recent study, we observed an increased mortality in a gnotobiotic mouse model when animals were colonized with an isogenic fliC mutant constructed in the PCR-ribotype 027 (B1/NAP1) strain R20291, while animals survived when colonized by the parental strain or after colonization by other high-toxin-producing C. difficile strains. To understand the reasons for this increased virulence, we compared the global gene expression profiles between the fliC-R20291 mutant and its parental strain using an in vitro and in vivo transcriptomic approach. The latter made use of the gnotobiotic mouse model. Interestingly, in the fliC mutant, we observed considerable up-regulation of genes involved in mobility, membrane transport systems (PTS, ABC transporters), carbon metabolism, known virulence factors and sporulation. A smaller but significant up-regulation of genes involved in cell growth, fermentation, metabolism, stress and antibiotic resistance was also apparent. All of these genes may be associated with the increased virulence of the fliC-R20921 mutant. We confirmed that the fliC mutation is solely responsible for the observed changes in gene expression in the mutant strain since expression profiles were restored to that of the wild-type strain in the fliC-complemented strain. Thus, the absence of FliC is directly or indirectly involved in the high mortality observed in the fliC mutant infected animals. Therefore, we provide the first evidence that when the major structural component of the flagellum is neutralized, deregulation of gene expression can occur during infection

Kinetics of sporulation rate in <i>C</i>. <i>difficile</i> associated mice.

<p>Mice were orally challenged with 1x10⁸ CFUs of vegetative cells. Vegetative cells were enumerated on BHI agar plates and spores after a heat shock treatment on BHI containing 0.1% of taurocholate sodium salt. </p

Validation of microarray data by qRT-PCR.

<p>Fold changes in in vivo gene expression at 4, 6, 14 and 38h post-infection, compared to the in vivo expression at 8h post-infection, were measured by microarray and qRT-PCR. Data are plotted as log₂ ratios of microarrays data (<i>x</i>-axis) compared with those of qRT-PCR (<i>y</i>-axis).</p

Regulation of toxin genes during the kinetics of infection.

<p>Regulation of toxin genes during the kinetics of infection.</p

Deciphering Adaptation Strategies of the Epidemic <i>Clostridium difficile</i> 027 Strain during Infection through <i>In Vivo</i> Transcriptional Analysis

<div><p><i>Clostridium difficile</i> is responsible for a wide spectrum of infection from asymptomatic carriage to severe, relapsing colitis. Since 2003, <i>C</i>. <i>difficile</i> infections have increased with a higher morbidity and mortality due to the emergence of epidemic and hypervirulent <i>C</i>. <i>difficile</i> strains such as those of the epidemic lineage 027/BI/NAP1. To decipher the hypervirulence and epidemicity of 027 strains, we analyzed gene expression profiles of the R20291 027 strain using a monoxenic mouse model during the first 38h of infection. A total of 741 genes were differentially expressed during the course of infection. They are mainly distributed in functional categories involved in host adaptation. Several genes of PTS and ABC transporters were significantly regulated during the infection, underlying the ability of strain R20291 to adapt its metabolism according to nutrient availability in the digestive tract. In this animal model, despite the early sporulation process, sporulation efficiency seems to indicate that growth of R20291 vegetative cells versus spores were favored during infection. The bacterial mechanisms associated to adaptability and flexibility within the gut environment, in addition to the virulence factor expression and antibiotic resistance, should contribute to the epidemicity and hypervirulence of the <i>C</i>. <i>difficile</i> 027 strains.</p></div