Global analysis of trimeric autotransporters reveals phylogenetically restricted secretion mechanism adaptations

Autotransporters are important diderm bacterial cell-surface proteins and are virulence factors enabling surface attachment and adhesion to other bacteria. These proteins are composed of a signal peptide, a {beta}-barrel that serves as an anchor in the outer membrane, and an extracellular passenger domain responsible for adhesion. Autotransporters rely on BamA for their insertion in the outer membrane (OM), but specific helper proteins, such as TpgA and SadB have been described to promote the surface exposure of trimeric autotransporters (TAAs), a specialized subclass of autotransporters forming homotrimer adhesins. To identify domains or proteins that could help TAAs secretion, we analyzed a recent dataset of all trimeric autotransporters found across the bacterial tree of life. While we did not find additional potential helper proteins for OM translocation, we found that the extended signal peptide (ESPR), sometimes found in TAAs, is associated with longer adhesins both for TAAs and type Va autotransporter adhesins. ESPRs are found in all bacteria but Fusobacteriia and Alphaproteobacteria. We also identified in Burkholderia, Veillonellales and Pasteurellales a DUF2827 domain proteins as potential glycosyltransferases constantly associated with TAAs. Finally, e describe the existence of extra periplasmic domains in some TAAs, featuring either a coiled-coil domain or a peptidoglycan-binding domain. Our research show that there is a strong phylogenetic separation between Terrabacteria, almost invariably displaying additional periplasmic domains, and Gracilicutes (represented by Proteobacteria) where they are largely absent. This suggests that the presence these domains might be correlated with specific Terrabacteria OM features. Using the diderm Firmicute Veillonella parvula as a model, we demonstrate that the absence of periplasmic domains in TAAs leads to a significant protein degradation, yet they are not essential for adhesin trimerization or secretion. Additionnaly, we show that the SLH domains of V. parvula TAAs excludes them from the septum during division, but that this exclusion is not crucial for adhesin function or stability in the tested conditions. Altogether, these results illuminate the genetic flexibility and modularity of autotransporters, enhancing our understanding of this important class of adhesins in diderm bacteria.