Plant latex thrombin-like cysteine proteases alleviates bleeding by bypassing factor VIII in murine model.

Hemostasis is a tightly regulated process which maintains a fluid state of blood within the vasculature and provides thrombotic response upon tissue injury. Various scientific studies have implicated the role of plant latex proteases in hemostasis using in vitro experiments. However, in vivo models substantiate their role in hemostasis. Therefore, in the present study, the effect of plant latex thrombin-like proteases (PTLPs) on hemostasis was investigated systematically using mice tail bleeding as a preclinical model. In this direction, latex protease fractions (LPFs), which showed potent thrombin-like activity, were selected as they act directly on fibrinogen to form clot and quickly stop bleeding. Thrombin-like activity was exhibited mainly by cysteine proteases. Calotropis gigantea, Carica papaya, Jatropha curcas, Oxystelma esculentum, Tabernaemontana divaricata, and Vallaris solanacea LPFs and papain from C. papaya latex significantly reduced bleeding on a topical application in normal and aspirin administered mice. In addition, PTLPs accelerated the clotting of factor VIII deficient plasma, while, papain brought back the clotting time to normal levels acting like a bypassing agent. Further, papain failed to show activity in the presence of specific cysteine protease inhibitor iodoacetic acid; confirming protease role in all the activities exhibited. At the tested dose, PTLPs except C. gigantea did not show toxicity. Further, structural and sequence comparison between PTLPs and human thrombin revealed structural and sequence dissimilarity indicating their unique nature. The findings of the present study may open up a new avenue for considering PTLPs including papain in the treatment of bleeding wounds.

Purification and characterization of an anti-hemorrhagic protein from Naja naja (Indian cobra) venom.

Snake venom Kunitz-type proteins are well known to inhibit serine proteases but a few studies have also shown matrix metalloproteases (MMPs) inhibition. In view of the fact that MMPs and snake venom metalloproteases (SVMPs) have similar catalytic site, inhibition of SVMP activity by Kunitz-type proteins remains to be studied. Recent proteomic studies of Naja naja (N. naja) venom revealed the abundance of Kunitz-type proteins. In this regard, present study aimed at purification of a protease inhibitor from N. naja venom that inhibits the toxicity of SVMPs rich Echis carinatus (E. carinatus) venom. N. naja venom effectively inhibited E. carinatus venom-induced hemorrhage. Purification of the active principle responsible for anti-hemorrhagic effect was achieved by fractionation of N. naja venom in three successive chromatographic steps. SDS-PAGE revealed that purified anti-hemorrhagic protein (NNAh) has an apparent molecular mass of ∼44 kDa and single peak in RP-HPLC demonstrated its homogeneity. NNAh also inhibited myonecrosis induced by E. carinatus venom and reduced activity of creatine kinase in NNAh treated animal sera substantiated the anti-myonecrotic effect. Hemorrhage and myonecrosis inhibitory effects of NNAh were further supported by inhibition of E. carinatus venom-mediated gelatinolysis and collagenolysis. NNAh falls into the category of Kunitz-type serine protease inhibitor as determined by peptide mass fingerprinting and shown to be a strong inhibitor of chymotrypsin. Collectively our data signify that NNAh is a Kunitz-type chymotrypsin inhibitor which also inhibited metalloprotease activities of E. carinatus venom. In future, complete sequence of NNAh and peptide region(s) responsible for inhibition will assist to deduce the mechanism of action.

Differential action of medically important Indian BIG FOUR snake venoms on rodent blood coagulation.

Snakebite is a global health problem affecting millions of people. According to WHO, India has the highest mortality and/or morbidity due to snakebite. In spite of commendable research on Indian BIG FOUR venomous species; Naja naja and Bungarus caeruleus (elapid); Daboia russelii and Echis carinatus (viperid), no significant progress has been achieved in terms of diagnosis and management of biting species with appropriate anti-snake venom. Major hurdle is identification of offending species. Present study aims at differentiation of Indian BIG FOUR snake venoms based on their distinguish action on rodent blood coagulation. Assessment of coagulation alterations by elapid venoms showed negligible effect on re-calcification time, prothrombin time, activated partial thromboplastin time and factors assay (I, II, V, VIII and X) both in vitro and in vivo. However, viperid venoms demonstrated significant anticoagulant status due to their remarkable fibrinogen degradation potentials as supported by fibrinogenolytic activity, fibrinogen zymography and rotational thromboelastometry. Though results provide hint on probable alterations of Indian BIG FOUR snake venoms on blood coagulation, the study however needs validation from human victim's samples to ascertain its reliability for identification of biting snake species.