An intact S-layer is advantageous toClostridioides difficilewithin the host

AbstractClostridioides difficileis responsible for substantial morbidity and mortality in antibiotically-treated, hospitalised, elderly patients, in which toxin production correlates with diarrhoeal disease. While the function of these toxins has been studied in detail, the contribution of other factors, including the paracrystalline surface layer (S-layer), to disease is less well known. Here, we highlight the essentiality of the S-layerin vivoby reporting the recovery of S-layer revertants, following infection with the S-layer-null strain, FM2.5. Sequencing of theslpA gene revealed either correction of the original point mutation or modification of the sequence upstream of the mutation, which restored the reading frame, and translation ofslpA. Selection of these strains was rapid, with up to 90% of isolates identified as revertants 24 h post infection.Two revertant isolates, RvA and RvB, showed modification of 3 and 13 amino acids respectively, compared to wild type sequence. Structural determination of SlpA from RvB revealed a different orientation of its domains, resulting in a reorganisation of the lattice assembly and changes in interacting interfaces which might result in functional differences. These revertants showed differing patterns of disease in vivo; RvA causing equivalent severity to R20291 and RvB an attenuated FM2.5-like phenotype. Comparative RNA sequencing (RNA-Seq) analysis ofin vitrogrown isolates showed large changes in differentially expressed genes (DEGs) between R20291 and FM2.5 namely in TcdA/TcdB expression, in transcripts associated with sporulation and those linked to cell wall integrity, which may account for attenuation observedin vivo. In comparison, smaller differences were observed between RvA/R20291, and RvB/FM2.5 respectively, which correlated with observed disease severityin vivo. Cumulatively, these data highlight that the S-layer plays a role inC. difficiledisease.Author SummaryThe S-layer ofC. difficileis a paracrystalline array that covers the outer surface of the bacterial cell but its contribution to overall disease remains unclear. A previously described, spontaneousslpA-null mutant, FM2.5, with a point mutation inslpA offered an opportunity to study the role of the S-layerin vivo. Here, we confirm that this strain is less virulentin vivodespite effectively colonising the host and producing toxin. We also showin vivoselection for sequence modifications that restoreslpA translation and produce an S-layer. While such modifications do not affect the overall 3D structure of individual SlpA (sub)domains, they can lead to altered orientation of the structural domains and subsequent S-layer assembly. Importantly, RNA-Seq analysisin vitroshowed large differences in gene expression between FM2.5 and R20291. Detected differences in transcription of genes involved in toxin expression and sporulation suggests that the S-layer provides a selective survival advantage within the host, which contributes to disease severity.