Acylation of the RTX Toxin MbxA stimulates host membrane disruption through a specific interaction with cholesterol

RTX toxins, characterized by their calcium-binding glycine-rich repeat regions, are known for their ability to disrupt host cell membranes. Although the acylation of specific lysine residues in these toxins is established as crucial for their hemolytic activity, the precise mechanisms underlying this enhancement remain unclear. In this study, we explore the role of acylation in the pore-forming behaviour of the RTX toxin MbxA by comparing the lytic activities of acylated MbxA and its non-acylated form, proMbxA, on in vitro membrane systems, as well as living cells. Our findings demonstrate that a cholesterol specific interaction promotes MbxA-induced membrane disruption in an acylation-dependent manner. Further analysis revealed that acylation is not necessary for initial membrane binding but markedly enhances pore formation. Overall, our results offer valuable insights into the molecular determinants that regulate RTX toxin activity, highlighting a complex interplay between lipid composition (sterols), acylation, and membrane disruption, thereby advancing our understanding of RTX toxin pathogenesis