Snake venom fibrin(ogen)olytic enzymes.

Snake venoms contain a number of serine and metalloproteinases and included among these are the fibrin(ogen)olytic proteinases. Some years ago it was postulated that the fibrin(ogen)olytic enzymes may be clinically useful. Over the past 150 years a substantial body of literature has been generated on the identification and characterization of fibrin(ogen)olytic enzymes from a broad spectrum of snake species. In this review we describe the two different classes of fibrin(ogen)olytic enzymes isolated from snake venom and we summarize a number of studies aimed at characterizing the purified enzymes and/or their derivatives. Two distinct classes of venom fibrin(ogen)olytic enzymes have been previously identified, the metalloproteinases and serine proteinases. These two classes of proteinases differ in their mechanism of action and they target different amino acid sequences in fibrin(ogen), but each perform the same role in nature. When a snake envenomates its prey it needs a mechanism to facilitate the spread of the toxic components throughout the circulation. Fibrin(ogen)olytic enzymes break down fibrin rich clots and help to prevent further clot formation by their action on fibrinogen. This characteristic feature has led to development of fibrin(ogen)olytic snake venom enzymes as potential clinical agents to treat occlusive thrombi. Fibrolase, a fibrinolytic metalloproteinase isolated from Agkistrodon contortrix contortrix venom and the serine beta-fibrinogenolytic proteinase from Vipera lebetina have been chosen as representative enzymes from the two classes, and their biochemical and physiochemical properties will be described in detail. Finally, the characterization and development of alfimeprase, a recombinant fibrinolytic enzyme derived from fibrolase, as a clinical agent is described citing the progression from the laboratory bench to its current status as having successfully completed Phase II clinical trials.

Alpha-fibrinogenases.

Snake venoms contain a number of serine and metalloproteinases, included among these are the fibrinolytic metalloproteinases. When the fibrinolytic enzymes were first isolated from viper venoms it was postulated that there may be a clinical application for these enzymes in the treatment of occlusive thrombi, such as those occurring in the great arteries and veins of cardiac and cerebral circulation as well as peripheral arteries and veins. In the ensuing years a substantial body of literature has been generated on the identification and characterization of the fibrinolytic enzymes from a broad spectrum of snake species. In this report we describe the biological properties and positive clinical features of the class of enzymes known as alpha-fibrinogenases. Fibrolase, a fibrinolytic metalloproteinase originally isolated from Agkistrodon contortrix contortrix venom, is the representative fibrinolytic enzyme used for the description and characterization of the alpha-fibrinogenases in this chapter. The biochemical and physiochemical properties and in vivo activity of the enzyme are described as well as in vitro studies using a platelet avid chimera of fibrolase. The chimera was formed by coupling fibrolase to an Arg-Gly-Asp (RGD) like peptide imparting inhibitory activity on platelet aggregation and thrombus formation, while maintaining full fibrinolytic activity. Fibrolase has also been modified through the adduction of polyethylene glycol to reduce the rate of clearance from the circulation. In this review we also include a description of alfimeprase, a recombinant fibrinolytic enzyme derived from fibrolase, and follow the development of the enzyme as a potential clinical agent in the clearance of occlusive thrombi. Alfimeprase is presently in clinical trials for two indications: the treatment of peripheral arterial occlusions (in which phase II is nearing successful completion), and for use in the clearance of occluded vascular access catheters in direct competition with plasminogen activators.

Three-dimensional structure of fibrolase, the fibrinolytic enzyme from southern copperhead venom, modeled from the X-ray structure of adamalysin II and atrolysin C.

The fibrinolytic enzyme from southern copperhead snake venom, fibrolase, contains 1 mole of zinc per mole of protein, belongs to the major family of metalloproteinases known as the metzincins, and has been shown to degrade fibrin clots in vitro and in vivo. The purpose of this study was to develop a 3-dimensional model of fibrolase to investigate the geometry of conserved and variable sequences between members of the snake venom metalloproteinases. When compared to atrolysin C (form D) or adamalysin II (metzincins with completely different substrate specificity), fibrolase has approximately 60% overall sequence identity and nearly 100% sequence similarity in the active site. We used the crystal structure of adamalysin II to build a 3-dimensional homology model of fibrolase. Three disulfide bonds were constructed (the highly conserved disulfide bond [118-198] was maintained from the adamalysin II structure and 2 new disulfide bonds were introduced between residues 158-182 and 160-165). We used Sculpt 2.5 and HyperChem 5.0 to "dock" a substrate fragment octapeptide (HTEKLVTS), and a water molecule into the active site cleft. We calculated the differential average homology profile for fibrolase compared to 8 hemorrhagic and 5 nonhemorrhagic metzincins. We then determined the sequence regions that might be responsible for their substrate specificity. Our 3-dimensional homology model shows that the variable sequences lie on the periphery of the identified active site region containing the His triangle; this indicates that substrate specificity may depend on surface residues that are not directly associated with the active site.

Effect of BJcuL (a lectin from the venom of the snake Bothrops jararacussu) on adhesion and growth of tumor and endothelial cells.

Lectins are polyvalent carbohydrate-binding proteins of non-immune origin. Recently, we have isolated and characterized a lectin from the venom of the snake Bothrops jararacussu. This lectin (BJcuL) has been shown to bind to lactose moieties and induce agglutination of erythrocytes. In the present work, we observed that cells from human metastatic breast cancer (MDA-MB-435) and human ovarian carcinoma (OVCAR-5) cell lines adhere, although weakly, to BJcuL. However, BJcuL did not inhibit adhesion of these cells to the extracellular matrix proteins fibronectin, laminin and type I collagen. Importantly, viability of these tumor cells and cells from other human tumor cell lines and a bovine brain endothelial cell line was suppressed by BJcuL. These findings suggest that the lectin BJcuL may serve as an interesting tool for combating tumor progression by inhibiting tumor cell and endothelial cell growth.

Differential regulation of tyrosine phosphorylation in tumor cells by contortrostatin, a homodimeric disintegrin, and monomeric disintegrins echistatin and flavoridin.

The homodimeric disintegrin contortrostatin was compared directly to the monomeric disintegrins echistatin and flavoridin for the ability to affect protein tyrosine phosphorylation in tumor cells. It was observed that contortrostatin had a dramatic effect on the tyrosine phosphorylation status of several proteins in T24 human bladder cancer cells, including robust induction of phosphorylation of proteins in the range of 120-140 kDa. Echistatin alone had no effect on tyrosine phosphorylation in T24 cells, but dose-dependently inhibits the effects of contortrostatin when both are added simultaneously. Among the proteins that undergo tyrosine phosphorylation in response to contortrostatin treatment is CAS, a 130 kDa adapter protein involved in integrin signaling. Flavoridin alone was found to have no effect on CAS, but can completely block contortrostatin-induced phosphorylation of this protein in MDA-MB-435 cells. These observations strongly suggest that the homodimeric structure of contortrostatin functionally distinguishes it from other monomeric members of the disintegrin family.

A novel snake venom disintegrin that inhibits human ovarian cancer dissemination and angiogenesis in an orthotopic nude mouse model.

OVCAR-5 is a human epithelial carcinoma cell line of the ovary, established from the ascitic fluid of a patient with progressive ovarian adenocarcinoma without prior cytotoxic treatment. The unique growth pattern of ovarian carcinoma makes it an ideal model for examining the anticancer activity of contortrostatin (CN), a homodimeric disintegrin from southern copperhead venom. FACS analysis revealed that OVCAR-5 is integrin alphavbeta3 negative, but alphavbeta5 positive. CN effectively blocks the adhesion of OVCAR-5 cells to several extracellular matrix proteins and inhibits tumor cell invasion through an artificial basement membrane. In a xenograft nude mouse model with intraperitoneal introduction of OVCAR-5 cells, intraperitoneal injection of CN was used for therapy. Tumor dissemination in CN-treated versus control groups was studied by gross examination, and antiangiogenic potential was examined by factor VIII immunohistochemistry and image analysis. CN not only significantly inhibited ovarian cancer dissemination in the nude mouse model, but it also dramatically prevented the recruitment of blood vessels to tumors at secondary sites.

Contortrostatin, a homodimeric disintegrin, actively disrupts focal adhesion and cytoskeletal structure and inhibits cell motility through a novel mechanism.

Integrins play a major role in the regulation of cell motility. They physically link the extracellular environment to the cytoskeleton and participate in large protein complexes known as focal adhesions. In this report, it is demonstrated that treatment of tumor cells with the homodimeric disintegrin contortrostatin induces integrin-mediated tyrosine phosphorylation events and causes severe disruptions in the actin cytoskeleton and disassembly of focal adhesion structures without affecting cellular adhesion to a reconstituted basement membrane. Included in this disruption is the tyrosine phosphorylation and altered subcellular localization of FAK. Through use of transfected 293 cells with specific integrin expression profiles and anti-alphavbeta3 mAbs, we demonstrate that these events are mediated exclusively by the alphavbeta3 integrin and are likely the result of contortrostatin-mediated crosslinking of this receptor at the cell surface, since monovalent disintegrins, flavoridin or echistatin do not induce such effects. Further, it is shown that contortrostatin potently inhibits motility in cells expressing the alphavbeta33 integrin. The results of this study describe a novel integrin-mediated mechanism by which cell motility can be inhibited and suggest an alternative approach to therapeutic intervention for cancer invasion and metastasis.

Action of metalloproteinases mutalysin I and II on several components of the hemostatic and fibrinolytic systems.

The zinc endopeptidases mutalysin I (100 kDa) and mutalysin II (22.5 kDa) have been previously isolated from bushmaster (Lachesis muta muta) snake venom. Hemorrhagic activity was observed with as little as 0.5 microg (2000 units/mg) and 17.8 microg (56.2 units/mg) for mutalysin I and II, respectively. Additionally, the proteases hydrolyse the Aalpha>Bbeta chain of fibrinogen without clot formation. The specific fibrinogenolytic activity was estimated as 5. 25 and 16.3 micromol fibrinogen/min/micromol protein for mutalysin I and II, respectively. In vitro, the enzymes act directly on fibrin and are not inhibited by serine proteinase inhibitors (SERPINS). Analysis by SDS-PAGE of fibrin hydrolysis by both enzymes showed that mutalysin II (0.22 microM) completely digested the alpha- and gamma-gamma chains and partially the beta-chain (in 120 min incubation). In contrast, mutalysin I (three fold higher concentration than mutalysin II) hydrolyzed selectively the alpha-chain of fibrin leaving the beta and gamma-gamma chains unaffected. Unlike with the plasminogen activator-based thrombolytic agents (e.g., streptokinase), mutalysins do not activate plasminogen. Neither enzyme had an effect on protein C activation. Mutalysin II does not inhibit platelet aggregation in human PRP induced by collagen or ADP. However, mutalysin I showed a selective inhibitory effect on collagen-induced aggregation of human PRP; it did not affect platelet aggregation with ADP as the agonist. The present investigation demonstrates that both native and EDTA-inactivated mutalysin I dose dependently blocked aggregation of human PRP elicited by 10 microg/mL of collagen with an IC(50) of 180 and 580 nM, respectively. These studies suggest that, in addition to the metalloprotease region of mutalysin I, the disintegrin-like domain also participates in the inhibitory effect. The proteolytic activity of mutalysin II against dimethylcasein and fibrin was completely abolished by alpha2-macroglobulin (alpha2-M). The stoichiometry of inhibition was 1.0 mol of enzyme per mol of alpha2-M. In contrast, the proteolytic effect of mutalysin I against the same substrates was not significantly inhibited by alpha2-M. Therefore, the data explain why mutalysin I contributes significantly not only to local but also to systemic bleeding associated with the observed pathological effects of the venom.

Contortrostatin, a dimeric disintegrin from Agkistrodon contortrix contortrix, inhibits breast cancer progression.

We report the results of a multidisciplinary study on the inhibitory effect of a snake venom disintegrin, contortrostatin, a 13.5 kDa homodimeric protein isolated from Agkistrodon contortrix contortrix (southern copperhead) venom, on breast cancer progression. We demonstrate that contortrostatin binds to integrins and blocks the adhesion of human breast cancer cells (MDA-MB-435) to extracellular matrix (ECM) proteins including fibronectin and vitronectin, but it has no effect on adhesion of the cells to laminin and Matrigel. Contortrostatin also prevents invasion of MDA-MB-435 cells through an artificial Matrigel basement membrane. Daily local injection of contortrostatin (5 microg per mouse per day) into MDA-MB-435 tumor masses in an orthotopic xenograft nude mouse model inhibits growth of the tumor by 74% (p = 0.0164). More importantly, it reduces the number of pulmonary macro-metastasis of the breast cancer by 68% (p < 0.001), and micro-metastasis by 62.4% (p < 0.001). Contortrostatin is not cytotoxic to cancer cells, and does not inhibit proliferation of the breast cancer cells in vitro. However, contortrostatin inhibits angiogenesis induced by the breast cancer, as shown by immunohistochemical quantitation of the vascular endothelial cells in tumor tissue removed from the nude mice. We have identified alpha(v)beta3, an important integrin mediating cell motility and tumor invasion, as one of the binding sites of contortrostatin on MDA-MB-435 cells. We conclude that contortrostatin blocks alpha(v)beta3, and perhaps other integrins, and thus inhibits in vivo progression.

Contortrostatin, a snake venom disintegrin, induces alphavbeta3-mediated tyrosine phosphorylation of CAS and FAK in tumor cells.

Contortrostatin is a homodimeric disintegrin that inhibits platelet aggregation and cell adhesion to extracellular matrix proteins by blocking integrins. The effect of contortrostatin on integrin-mediated signaling in tumor cells was investigated by studying tyrosine phosphorylation events and activation of specific signaling molecules. We found that at concentrations as low as 1 nM, soluble contortrostatin activates integrin signals leading to increased tyrosine phosphorylation of FAK and CAS, and that these signals are abolished by inhibiting Src family kinases. Using transfected 293 cells expressing specific integrins, it was determined that contortrostatin-generated signals are mediated exclusively by the alphavbeta3 integrin. This observation was extended by showing that cells lacking alphavbeta3, but expressing alphavbeta5 and alpha5beta1, do not respond in this way to contortrostatin treatment. In cells expressing alphavbeta3, blocking contortrostatin binding with antibodies against alphavbeta3 completely abrogates contortrostatin signals. Monovalent disintegrins echistatin and flavoridin were incapable of affecting tyrosine phosphorylation alone, but when added simultaneously with contortrostatin, completely inhibited contortrostatin-initiated signals. We propose that the homodimeric nature of contortrostatin imparts the ability to crosslink alphavbeta3 integrins, causing Src activation and hyperphosphorylation of FAK and CAS. This activity may represent a novel mechanism by which tumor cell motility can be inhibited.

Contortrostatin activates ERK2 and tyrosine phosphorylation events via distinct pathways.

We report that cells adhering to contortrostatin show transient increases in activation of Extracellular signal Regulated Kinase 2 (ERK2). The kinetics and degree of activation are similar to cells adhering to fibronectin or vitronectin. We have recently shown that contortrostatin induces tyrosine phosphorylation in tumor cells. Contortrostatin is shown here to stimulate activation of ERK2 in suspended cells, but this activation follows a different dose-response pattern than contortrostatin-induced tyrosine phosphorylation. Since contortrostatin induces tyrosine phosphorylation via alphavbeta3, we explored the effects of an alphavbeta3-blocking antibody, 7E3, on contortrostatin-stimulated ERK2 activation. While 7E3 completely blocks the effect of contortrostatin on tyrosine phosphorylation, this antibody had no effect on activation of ERK2. In cells lacking expression of alphavbeta3, tyrosine phosphorylation was unaffected by contortrostatin treatment, but ERK2 was activated. This is strong evidence that contortrostatin is regulating tyrosine phosphorylation events and ERK2 activation via separate pathways and through different integrin receptors.

Molecular cloning and functional expression of contortrostatin, a homodimeric disintegrin from southern copperhead snake venom.

Contortrostatin is a unique dimeric disintegrin isolated from southern copperhead snake venom. Through antagonism of integrins alphaIIbbeta3, alpha5beta1, alphavbeta3, and alphavbeta5, contortrostatin inhibits platelet aggregation and disrupts cancer cell adhesion and invasion. We cloned cDNA from a library made from the venom gland cells of Agkistrodon contortrix contortrix using polymerase chain reaction. We found that the contortrostatin gene is part of a precursor composed of proprotein, metalloproteinase, and disintegrin domains. The precursor cDNA is 2027 bp with a 1449-bp open reading frame. The disintegrin domain is 195 bp encoding 65 amino acids. Like other members of the disintegrin family, each subunit of contortrostatin has an RGD site, and the cysteine alignment is conserved. The disintegrin domain of the cDNA has been expressed in a eukaryotic expression system as a homodimeric fusion protein with an immunoglobulin. The recombinant protein is recognized by an antiserum against native contortrostatin in Western blot. Both the native and recombinant proteins bind to integrins alphavbeta3 and alphavbeta5. Like native contortrostatin, the recombinant fusion protein inhibits platelet aggregation, blocks cancer cell adhesion to fibronectin and vitronectin, and prevents invasion of cancer cells through a Matrigel barrier. The success of functional expression not only validates the cDNA cloning of this disintegrin, but also provides adequate material for functional studies of contortrostatin.

Contortrostatin, a homodimeric disintegrin, binds to integrin alphavbeta5.

Contortrostatin is a homodimeric disintegrin from snake venom. We have shown that contortrostatin binds to integrins alphaIIbbeta3, alpha5beta1, and alphavbeta3. We now use several criteria to demonstrate the binding of contortrostatin to alphavbeta5. First, incubation of T24 cells, which express alphavbeta3 and alphavbeta5, with antibody against alphavbeta3 failed to completely inhibit adhesion of cells to vitronectin. However, pretreatment of the cells with contortrostatin or the combination of antibodies against alphavbeta3 and alphavbeta5 completely blocked adhesion to vitronectin. By contrast, either anti-alphavbeta5 alone or contortrostatin blocked adhesion of an alphavbeta3-negative T24 subline. Second, contortrostatin as well as anti-alphavbeta5 inhibits invasion of OVCAR-5, which express only alphavbeta5. Third, contortrostatin binds to purified alphavbeta5 in a saturable manner. Finally, radioligand binding assays yielded a K(d) value of 24 nM for [(125)I]contortrostatin binding to alphavbeta5. This investigation identifies alphavbeta5 as a binding site for contortrostatin. Blockage of alphavbeta5 by contortrostatin inhibits alphavbeta5-mediated adhesion and invasion.

Anti-invasive effect of contortrostatin, a snake venom disintegrin, and TNF-alpha on malignant glioma cells.

BACKGROUND: The snake venom disintegrin contortrostatin has been shown to bind to integrins alpha IIb beta 3, alpha v beta 3, alpha v beta 5, and alpha 5 beta 1 and to exert an anti-tumor activity in vitro and in vivo. The cytokine TNF-alpha has been demonstrated to have anti-invasive properties in vitro. MATERIALS AND METHODS: The human glioblastoma cell line T98G was treated with controtrostatin or colloidal gold-TNF-alpha (CG-TNF-alpha) alone, or in combination. Vitronectin- and fibronectin-dependent adhesion of untreated and treated glioma cells was studied and compared. Invasion through a reconstituted basement membrane (Matrigel) was also examined. RESULTS: Although both contortrostatin and CG-TNF-alpha inhibited invasion of T98G cells through Matrigel, the mechanism of inhibition appears to be different. Contortrostatin significantly decreased cell adhesion to vitronectin and fibronectin; CG-TNF-alpha did not. Contortrostatin binds to T98G integrins in an RGD-dependent manner, whereas protein kinase C (PKC) appears to be involved in CG-TNF-alpha actions, leading to inhibition of cell invasion. The efficiency of contortrostatin in inhibiting cell invasion was enhanced by combination with CG-TNF-alpha. CONCLUSION: The combined use of contortrostatin and CG-TNF-alpha may have potential for malignant glioma therapy by effectively inhibiting glioma cell invasion.

Chimeric derivative of fibrolase, a fibrinolytic enzyme from southern copperhead venom, possesses inhibitory activity on platelet aggregation.

Fibrolase, a metalloproteinase isolated from the venom of Agkistrodon contortrix contortrix (southern copperhead snake), is a direct acting fibrinolytic enzyme that has been used to digest occlusive blood clots in animal models. The snake venom enzyme directly degrades fibrin associated with platelet rich blood clots and does not rely on plasminogen activation. Rethrombosis is a serious complication that is experienced in a significant percentage of patients treated with thrombolytic agents to remove occlusive vascular thrombi. The involvement of platelets in the initiation of rethrombosis is well known. Arg-Gly-Asp-(RGD)-containing agents have been shown to inhibit rethrombosis following thrombus dissolution by plasminogen activators. In an effort to create a more effective fibrinolytic enzyme and to target the enzyme to platelet-rich thrombi, thereby decreasing the potential for rethrombosis, a chimeric derivative of fibrolase has been produced. This report describes the construction and biochemical characterization of the chimeric enzyme and an evaluation of its in vitro activities. The chimera was formed by covalently incorporating an RGD-like peptide into fibrolase. The site of peptide attachment was determined to be a single lysine residue remote from the enzymes active site. Covalent modification of fibrolase with the RGD-like peptide did not inhibit either fibrinolytic activity of the enzyme nor platelet aggregation inhibitory activity of the peptide. The chimera not only retained the same level of enzymatic activity as native fibrolase, but also acquired the ability to inhibit platelet aggregation by binding to the fibrinogen receptor (integrin alphaIIbbeta3) on platelets.

Contortrostatin, a dimeric disintegrin from Agkistrodon contortrix contortrix, inhibits angiogenesis.

Contortrostatin, a 13.5 kDa disulfide-linked homodimeric polypeptide possessing an Arg-Gly-Asp sequence, was isolated from venom of the southern copperhead snake. Daily injection of contortrostatin into the primary tumor of human breast cancer MDA-MB-435 carried in nude mice significantly inhibited tumor growth and neovascularization of the tumor tissue. On the chick embryo chorioallantoic membrane, contortrostatin inhibited angiogenesis induced by MDA-MB-435 cells, basic fibroblast growth factor, and vascular endothelial growth factor. In addition, contortrostatin effectively blocked adhesion of human umbilical vein endothelial cells (HUVEC) to immobilized vitronectin and significantly inhibited invasion of HUVEC through a Matrigel barrier. Competitive binding assays and adhesion assays with different integrin antibodies suggested that integrin alpha(v)beta3 is a binding site for contortrostatin on vascular endothelial cells. Detachment of HUVEC from vitronectin by contortrostatin induced apoptosis. HUVEC adhered and spread well on immobilized contortrostatin without undergoing apoptosis, suggesting that it is the inhibition of adhesion and spreading of HUVEC on extracellular matrix proteins, rather than binding of contortrostatin to integrins per se, that triggers apoptosis. We conclude that contortrostatin binds to alpha(v)beta3, and interferes with the anchorage-dependent survival mechanism of the vascular endothelial cells, and the mobility of the cells. The consequent suppression of angiogenesis is an important component of the antineoplastic activity of contortrostatin.

Snake venoms and the hemostatic system.

Snake venoms are complex mixtures containing many different biologically active proteins and peptides. A number of these proteins interact with components of the human hemostatic system. This review is focused on those venom constituents which affect the blood coagulation pathway, endothelial cells, and platelets. Only highly purified and well characterized snake venom proteins will be discussed in this review. Hemostatically active components are distributed widely in the venom of many different snake species, particularly from pit viper, viper and elapid venoms. The venom components can be grouped into a number of different categories depending on their hemostatic action. The following groups are discussed in this review: (i) enzymes that clot fibrinogen; (ii) enzymes that degrade fibrin(ogen); (iii) plasminogen activators; (iv) prothrombin activators; (v) factor V activators; (vi) factor X activators; (vii) anticoagulant activities including inhibitors of prothrombinase complex formation, inhibitors of thrombin, phospholipases, and protein C activators; (viii) enzymes with hemorrhagic activity; (ix) enzymes that degrade plasma serine proteinase inhibitors; (x) platelet aggregation inducers including direct acting enzymes, direct acting non-enzymatic components, and agents that require a cofactor; (xi) platelet aggregation inhibitors including: alpha-fibrinogenases, 5'-nucleotidases, phospholipases, and disintegrins. Although many snake venoms contain a number of hemostatically active components, it is safe to say that no single venom contains all the hemostatically active components described here. Several venom enzymes have been used clinically as anticoagulants and other venom components are being used in pre-clinical research to examine their possible therapeutic potential. The disintegrins are an interesting group of peptides that contain a cell adhesion recognition motif, Arg-Gly-Asp (RGD), in the carboxy-terminal half of their amino acid sequence. These agents act as fibrinogen receptor (integrin GPIIb/IIIa) antagonists. Since this integrin is believed to serve as the final common pathway leading to the formation of platelet-platelet bridges and platelet aggregation, blockage of this integrin leads to inhibition of platelet aggregation regardless of the stimulating agent. Clinical trials suggest that platelet GPIIb/IIIa blockade is an effective therapy for the thrombotic events and restenosis frequently accompanying cardiovascular and cerebrovascular disease. Therefore, because of their clinical poten tial, a large number of disintegrins have been isolated and characterized.

Chimeric fibrolase: covalent attachment of an RGD-like peptide to create a potentially more effective thrombolytic agent.

We have prepared an agent possessing both thrombolytic and antiplatelet properties, by conjugating fibrolase, a direct-acting fibrinolytic enzyme isolated from southern copperhead venom, to a peptide which inhibits platelet aggregation. Heterobifunctional coupling reagents, N-succinimidyl 3-(2-pyridyldithio) propionate (SPDP) or sulfosuccinimidyl 6-[alpha-methyl-alpha-(2-pyridyldithio)-toluamido]hexanoate (Sulfo-LC-SMPT), were used in a molar ratio of 10:1 (coupling agent/fibrolase). The N-hydroxy-succinimide of the coupling agent reacts with surface epsilon-amino groups of lysine residues on fibrolase and provides a dithio group that is highly reactive with small thiol compounds. The derivatives obtained in the first reaction contain approximately two moles of 2-pyridyl disulphide per mole of enzyme. These derivatives were then reacted with the free thiol group in an antiplatelet peptide at a molar ratio of 2:1 (peptide/fibrolase). The peptide-fibrolase conjugate was purified by cation exchange HPLC and analyzed by amino acid analysis. The conjugate contains one mole peptide per mole of fibrolase and retains approximately 85% fibrinolytic activity. The IC50 for inhibition of platelet aggregation in human PRP is 300 nM for the conjugate and 67 nM for the antiplatelet peptide. These results demonstrate the successful formation of a novel chimeric protein with bifunctional activity.

Snake venoms.

Snake venoms are complex mixtures containing many different biologically active proteins and peptides. A number of these proteins act on components of the haemostatic system in humans. The paper focuses on those venom constituents that affect the blood coagulation pathway, endothelial cells and platelets. Several highly purified venom enzymes have been used clinically as anticoagulants, and other venom proteins are being used in preclinical research to investigate their possible therapeutic potential. Haemostatically active components are distributed widely in the venom of many different snake species. In no case are all the components described below found in any single venom. Venom components can be grouped into several categories depending on their haemostatic effect. The following haemostatically active components are discussed in this chapter: enzymes that cause fibrinogen coagulation: enzymes that degrade fibrin(ogen); plasminogen activator; prothrombin activators; factor V activator; factor X activator; anticoagulant activities: enzymes with haemorrhagic activity; platelet aggregation inducers: and platelet aggregation inhibitors.