Toxin-glycolipid interactions measured by imaging surface plasmon resonance on artificial membranes predicts diffusion behavior and lipid dependence of binding to cells

Membrane-protein interactions mediate cellular invasion by toxins, and are thought to involve organized plasma membrane lipid domains, often containing glycolipids, other sphingolipids, and/or cholesterol. Here, we characterize an isolated glycolipid-interacting domain of the tetanus toxin heavy chain (Hc) as a fluorescently labelled peptide, TeNT46, and describe its membrane dynamics and binding characteristics on artificial bilayers and cellular membranes. We show that this novel ganglioside-interacting probe TeNT46 retains the glycolipid binding preferences of the parent toxin, using imaging-SPR (iSPR) on a micro-patterned hybrid bilayer surface. On live cell membranes, using fluorescence correlation spectroscopic (FCS) diffusion measurements to compare TeNT46 to the well-studied GM1-binding toxin CTxB, we find that both probes display ordered domain-binding characteristics, but distinct cholesterol and sphingolipid dependencies. Strikingly, the contrasting lipid requirements of TeNT46 from those of CTxB in cells are predicted by their iSPR binding preferences on hybrid synthetic membranes. Based on the combined findings from iSPR and FCS, we propose a model for toxin-membrane interaction whereby a unique lipid constellation determines optimum binding for each probe independently of lateral confinement, which is more generally imposed by cholesterol. Our resulting understanding of the specific lipid requirements of these toxin targets and their dynamics in cell membranes could be important for the future design of preventive membrane-based nano-decoys and cell-delivery tools.