Morphological and biochemical evidence of blood vessel damage and fibrinogenolysis triggered by brown spider venom.

The venom of the brown spider is remarkable because it causes dermonecrotic injury, hemorrhagic problems, hemolysis, platelet aggregation and renal failure. The mechanism by which the venom causes hemorrhagic disorders is poorly understood. Rabbits intradermally exposed to the venom showed a local hemorrhage starting 1 h after inoculation and reaching maximum activity between 2 and 3 days. Biopsies examined by light and transmission electron microscopy showed subendothelial blebs, vacuoles and endothelial cell membrane degeneration in blood vessels, plasma exudation into connective tissue, and fibrin and thrombus formation within blood vessels. Loxosceles intermedia venom incubated with fibrinogen partially degrades Aalpha and Bbeta chains of intact fibrinogen, and significantly cleaves all Aalpha, Bbeta and gamma chains when they were separated or when fibrinogen is denatured by boiling. Proteolytic kinetic studies showed that the Aalpha chain is more susceptible to venom hydrolysis than the Bbeta chain. The fibrinogenolysis is blocked by ethylenediamine tetraacetic acid and 1,10-phenanthroline, but not by other protease inhibitors. Human plasma incubated with the venom had coagulation parameters such as prothrombin time, activated partial thromboplastin time and thrombin time increased. Through molecular sieve chromatography, we isolated a venom toxin of 30 kDa with fibrinogenolytic activity. We propose that the local and systemic hemorrhagic disorders evoked in loxoscelism are consequences of direct venom fibrinogenolysis together with cytotoxicity to subendothelial structures and endothelial cells in blood vessels.

Identification of high molecular weight serine-proteases in Loxosceles intermedia (brown spider) venom.

High molecular weight serine-proteases have been identified in Loxosceles intermedia (brown spider) venom. The mechanism by which Loxosceles spp venoms cause dermonecrotic injury (a hallmark of loxoscelism) is currently under investigation, but it seems to be molecularly complex and in some instance proteases might be expected to play a role in this skin lesion. In the present investigation, when we submitted L. intermedia venom to linear gradient 3-20% SDS-PAGE stained by a monochromatic silver method we detected a heterogeneous protein profile in molecular weight, ranging from 850- to 5-kDa. In an attempt to detect zymogen molecules of proteolytic enzymes, venom aliquots were treated with several exogenous proteases. Among them, trypsin activated two gelatinolytic molecules of 85- and 95-kDa in the venom. In experiments of hydrolysis inactivation using different protease inhibitors for four major class of proteases, we detected that only serine-type protease inhibitors were able to inactivate the 85- and 95-kDa enzymes in the venom. An examination of the 85- and 95-kDa gelatinolytic activities as a function of pH showed that these proteases had no apparent activities at pH below 5.0 and higher than 9.0 and displayed little activity at pH 6.0. with the optimal pH for their activities ranging from 7.0 to 8.0. Evaluation of the functional specificities of the 85- and 95-kDa venom proteases showed that these proteases efficiently degrade gelatin (denatured collagen) but have no proteolytic activity on hemoglobin, immunoglobulin, albumin, librinogen or laminin, suggesting specificity of their proteolytic actions. We describe here two serine-proteases activities in L. intermedia venom probably involved in the harmful effects of the venom.