Antigenic and Substrate Preference Differences between Scorpion and Spider Dermonecrotic Toxins, a Comparative Investigation.

The Hemiscorpius lepturus scorpion and brown spider Loxosceles intermedia represent a public health problem in Asia and America, respectively. Although distinct, these organisms contain similar toxins responsible for the principal clinical signs of envenomation. To better understand the properties of these toxins, we designed a study to compare recombinant Heminecrolysin (rHNC) and rLiD1, the major phospholipase D toxins of scorpion and spider venom, respectively. Using a competitive ELISA and a hemolytic inhibition test, we come to spot a cross reaction between scorpion and spider venoms along with an epitopic similarity between rHNC and rLiD1 associated with neutralizing antibodies. Results show that the ability of the rHNC to hydrolyze lysophosphatidylcholine (LPC) is equivalent to that of rLiD1 to hydrolyze sphingomyelin and vice-versa. rHNC exclusively catalyze transphosphatidylation of LPC producing cyclic phosphatidic acid (cPA). The in-silico analysis of hydrogen bonds between LPC and toxins provides a possible explanation for the higher transphosphatidylase activity of rHNC. Interestingly, for the first time, we reveal that lysophosphatidic acid (LPA) can be a substrate for both enzymes using cellular and enzymatic assays. The finding of the usage of LPA as a substrate as well as the formation of cPA as an end product could shed more light on the molecular basis of Hemiscorpius lepturus envenomation as well as on loxoscelism.

Heminecrolysin, a potential immunogen for monospecific antivenom production against Hemiscorpius lepturus scorpion.

Serotherapy against Hemiscorpius (H.) lepturus scorpion sting is based on the administration of equine polyvalent antivenom prepared against a mixture of six venoms. In a previous study, we reported the identification of Heminecrolysin, a 33 kDa H. lepturus venom protein endowed with a sphingomyelinase D, hemolytic and dermonecrotic activities. We aimed herein to investigate the capacity of Heminecrolysin to generate antibodies able to neutralize the major physiopathological properties of H. lepturus envenomation, e.g. hemolysis and dermonecrosis. The efficiency of anti-Heminecrolysin antibodies was compared to that of anti-whole venom. Our results demonstrated that Heminecrolysin elicits high levels of specific IgGs. Anti-Heminecrolysin, similarly to anti-whole venom antibodies, totally inhibited H. lepturus hemolytic effect when up to 5 times the half maximal effective concentration of venom were used. Phosphatidylserine exposure on the external lipid monolayer of human red blood cells treated with whole venom was also fully blocked by both anti-sera. Experimental envenomation of rabbits showed that anti-Heminecrolysin antibodies were as potent as anti-H. lepturus antibodies to neutralize dermonecrotic effects when up to 4 times the minimal necrotic dose of venom were injected. However, inflammatory reaction was better controlled with anti-whole venom sera. In conclusion, Heminecrolysin elicits protective antibodies of comparable potency to those elicited by immunization with whole venom.