Intravascular hemolysis induced by phospholipases A(2) from the venom of the Eastern coral snake, Micrurus fulvius: Functional profiles of hemolytic and non- hemolytic isoforms

Abstract

A unique feature of the venom of Micrurus fulvius (Eastern coral snake) is its ability to induce severe intravascular hemolysis in particular species, such as dogs or mice. This effect was previously shown to be induced by distinct phospholipase A(2) (PLA(2)) isoforms which cause direct hemolysis in vitro, an uncommon finding for such enzymes. The functional profiles of PLA(2)-17, a direct hemolytic enzyme, and PLA(2)-12, a co-existing venom isoform lacking such effect, were compared. The enzymes differed not only in their ability to cause intravascular hemolysis: PLA(2)-17 additionally displayed lethal, myotoxic, and anticoagulant actions, whereas PLA(2)-12 lacked these effects. PLA(2)-12 was much more active in hydrolyzing a monodisperse synthetic substrate than PLA(2)-17, but the catalytic activity of latter was notably higher on a micellar substrate, or towards pure phospholipid artificial monolayers under controlled lateral pressures. Interestingly, PLA(2)-17 could hydrolyze substrate at a pressure of 20 mNm-1, in contrast to PLA(2)-12 or the non-toxic pancreatic PLA(2). This suggests important differences in the monolayer penetrating power, which could be related to differences in toxicity. Comparative examination of primary structures and predicted three-dimensional folding of PLA(2)-12 and PLA(2)-17, revealed that differences concentrate in their N-terminal and central regions, leading to variations of the surface properties at the membrane interacting interface. PLA(2)-17 presents a less basic interfacial surface than PLA(2)-12, but more bulky aromatic residues, which could be associated to its higher membrane-penetrating strength. Altogether, these structural and functional comparative observations suggest that the ability of PLA(2)s to penetrate substrate interfaces could be a major determinant of toxicity, perhaps more important than protein surface charge.