Abstract
Among the toxic polypeptides secreted in the venom of sea anemones, actinoporins are the pore-forming toxins whose toxic activity relies on the formation of oligomeric pores within biological membranes. Intriguingly, actinoporins appear as multigene families that give rise to many protein isoforms in the same individual displaying high sequence identities but large functional differences. However, the evolutionary advantage of producing such similar isotoxins is not fully understood. Here, using sticholysins I and II (StnI and StnII) from the sea anemone Stichodactyla helianthus, it is shown that actinoporin isoforms can potentiate each other's activity. Through hemolysis and calcein releasing assays, it is revealed that mixtures of StnI and StnII are more lytic than equivalent preparations of the corresponding isolated isoforms. It is then proposed that this synergy is due to the assembly of heteropores because (i) StnI and StnII can be chemically cross-linked at the membrane and (ii) the affinity of sticholysin mixtures for the membrane is increased with respect to any of them acting in isolation, as revealed by isothermal titration calorimetry experiments. These results help us understand the multigene nature of actinoporins and may be extended to other families of toxins that require oligomerization to exert toxicity.
Highlights
The incorporation of actinoporins into the membrane largely depends on lipid bilayer composition and membrane physicochemical state (18, 24 –29)
StnI and StnII Show Synergistic Hemolytic Activity—A hemolysis experiment was designed to study the potential formation of StnI/StnII heteropores and its functional consequences
Sheep erythrocyte hemolysis was assayed in the presence of isolated StnI or StnII at different concentrations or for a mixture of StnI/StnII at 80:20 constant molar ratio (Fig. 1)
Summary
The incorporation of actinoporins into the membrane largely depends on lipid bilayer composition and membrane physicochemical state (18, 24 –29) Both factors influence the conformational changes occurring during the transition from the water media to the inserted states of the protein [30, 31]. Actinoporins have been isolated from more than 20 different sea anemone species [1, 3, 37– 41] in agreement with their rather ubiquitous distribution within the Actinaria order [1] They display high sequence identities (between 60 and 80%) and appear as multigene families, giving rise to many protein isoforms within the same individual [42– 46]. One possible explanation would be to expand the range of prey susceptible of being attacked [53] Such a strategy would extend and modulate the range of action of sea anemones. Active Actinoporin Heteropores establish functional heteropores, suggesting that actinoporins have a more deeply regulated physiological mode of action than previously believed
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