A cortex-specific penicillin-binding protein contributes to heat resistance in Clostridioides difficile spores

Background Sporulation is a complex cell differentiation programme shared by many members of the Firmicutes, the end result of which is a highly resistant, metabolically inert spore that can survive harsh environmental insults. Clostridioides difficile spores are essential for transmission of disease and are also required for recurrent infection. However, the molecular basis of sporulation is poorly understood, despite parallels with the well-studied Bacillus subtilis system. The spore envelope consists of multiple protective layers, one of which is a specialised layer of peptidoglycan, called the cortex, that is essential for the resistant properties of the spore. We set out to identify the enzymes required for synthesis of cortex peptidoglycan in C. difficile. Methods Bioinformatic analysis of the C. difficile genome to identify putative homologues of Bacillus subtilis spoVD was combined with directed mutagenesis and microscopy to identify and characterise cortex-specific PBP activity. Results Deletion of CDR20291_2544 (SpoVDCd) abrogated spore formation and this phenotype was completely restored by complementation in cis. Analysis of SpoVDCd revealed a three domain structure, consisting of dimerization, transpeptidase and PASTA domains, very similar to B. subtilis SpoVD. Complementation with SpoVDCd domain mutants demonstrated that the PASTA domain was dispensable for formation of morphologically normal spores. SpoVDCd was also seen to localise to the developing spore by super-resolution confocal microscopy. Conclusions We have identified and characterised a cortex specific PBP in C. difficile. This is the first characterisation of a cortex-specific PBP in C. difficile and begins the process of unravelling cortex biogenesis in this important pathogen

Amino Acids in the Bacillus subtilis Morphogenetic Protein SpoIVA with Roles in Spore Coat and Cortex Formation

Bacterial spores are protected from the environment by a proteinaceous coat and a layer of specialized peptidoglycan called the cortex. In Bacillus subtilis, the attachment of the coat to the spore surface and the synthesis of the cortex both depend on the spore protein SpoIVA. To identify functionally important amino acids of SpoIVA, we generated and characterized strains bearing random point mutations of spoIVA that result in defects in coat and cortex formation. One mutant resembles the null mutant, as sporulating cells of this strain lack the cortex and the coat forms a swirl in the surrounding cytoplasm instead of a shell around the spore. We identified a second class of six mutants with a partial defect in spore assembly. In sporulating cells of these strains, we frequently observed swirls of mislocalized coat in addition to a coat surrounding the spore, in the same cell. Using immunofluorescence microscopy, we found that in two of these mutants, SpoIVA fails to localize to the spore, whereas in the remaining strains, localization is largely normal. These mutations identify amino acids involved in targeting of SpoIVA to the spore and in attachment of the coat. We also isolated a large set of mutants producing spores that are unable to maintain the dehydrated state. Analysis of one mutant in this class suggests that spores of this strain accumulate reduced levels of peptidoglycan with an altered structure

Lipid Localization in Bacterial Cells through Curvature-Mediated Microphase Separation

Although many proteins are known to localize in bacterial cells, for the most part our understanding of how such localization takes place is limited. Recent evidence that the phospholipid cardiolipin localizes to the poles of rod-shaped bacteria suggests that targeting of some proteins may rely on the heterogeneous distribution of membrane lipids. Membrane curvature has been proposed as a factor in the polar localization of high-intrinsic-curvature lipids, but the small size of lipids compared to the dimensions of the cell means that single molecules cannot stably localize. At the other extreme, phase separation of the membrane energetically favors a single domain of such lipids at one pole. We have proposed a physical mechanism in which osmotic pinning of the membrane to the cell wall naturally produces microphase separation, i.e., lipid domains of finite size, whose aggregate sensitivity to cell curvature can support spontaneous and stable localization to both poles. Here, we demonstrate that variations in the strength of pinning of the membrane to the cell wall can also act as a strong localization mechanism, in agreement with observations of cardiolipin relocalization from the poles to the septum during sporulation in the bacterium Bacillus subtilis. In addition, we rigorously determine the relationship between localization and the domain-size distribution including the effects of entropy, and quantify the strength of domain-domain interactions. Our model predicts a critical concentration of cardiolipin below which domains will not form and hence polar localization will not take place. This observation is consistent with recent experiments showing that in Escherichia coli cells with reduced cardiolipin concentrations, cardiolipin and the osmoregulatory protein ProP fail to localize to the poles