Inhibition of Sendai virus by various snake venom.

Viperid, elapid and crotalid snake venoms were screened in vitro for antiviral activity against Sendai virus. The hemolysis of 10(8) human erythrocytes in 1 ml, caused by 70 HAU of Sendai virus, was abolished when the virions were pretreated with 10 ug of the viperid venom of Echis coloratus, and was considerably diminished when pretreated with 10 ug of the venom of Echis carinatus sochureki, the cobra venoms of Naja atra and Naja nigricollis nigricollis. These venoms did not affect the erythrocytes but inhibited the virions themselves irreversibly. All other examined snake venoms had low or no antiviral activity. There was no correlation between the proteolytic and the antiviral activity of the venoms.     

Isolation and characterization of a cytotoxin P4 from the venom of Naja nigricollis nigricollis preferentially active on tumor cells.

Cytotoxin P4 was isolated from the venom of Naja nigricollis nigricollis in three steps and contained 55% of the crude cytotoxic activity. It had a molecular weight of 8 KD, was stable over a pH range of 1-11 and in boiling water for at least 15 min. It had no measurable enzymatic activities, but was destroyed by proteases. Concentrations of 0.8, 1, 1.2, 25. 20 and 45 ug/ml, were needed to destroy murine melanoma B16 and WEHI 3B leukemia, rat chondrosarcoma, mouse erythrocytes and spleen cells, and human erythrocytes, respectively, thereby showing preferential cytotoxicity to the examined tumor cells. It also prevented the development of the melanoma, leukemia and chondrosarcoma tumors in vivo when mixed with the cells prior to the injection into the animal.     

Binding of cytotoxin P4 from Naja nigricollis nigricollis to B16F10 melanoma and WEHI-3B leukemia cells

Abstract Cobra venoms cause irreversible destruction of cells cultured in vitro [1,2]. The venom of Naja nigricollis nigricollis possessed the most potent cytotoxic activity towards B16F10 melanoma cells among various examined venoms [2]. The main cytotoxic factor (P4) isolated from this venom showed preferential activity on tumor cell lines and caused lysis at concentrations of 10⁻⁷ M (0.8–1 μg/ml) [3]. The present study examined the binding of cytotoxin P4 to melanoma B16F10 and WEHI-3B leukemia cell lines and found that, like cytotoxicity, it depended on concentration, temperature and incubation time. Cytotoxin concentrations that elicited no apparent damage to cells during the first hour of incubation caused lysis after a longer period of incubation, suggesting that a critical number of bound molecules is required in order to cause cell death. Bivalent ions, such as Mg²⁺, Ca²⁺ or Sr²⁺, which decreased binding to the cells also inhibited cytotoxicity. Competition experiments as well as the displacement of 75% of the bound radiolabelled cytotoxin with 'cold' cytotoxin, suggest the presence of specific binding sites for the toxin in the examined tumor cells. The non-specific binding of the cytotoxin P4 to sea urchin ova and sperm cells without affecting their fertility, even at high concentrations of 10⁻⁵ M, indicates that the specific binding to cells is probably a necessary condition for cell lysis.     

Short term effects of animal venoms on the mitotic index of the duodenal mucosa of albino rats.

Short term administration of the venoms of the snakes Naja haje, Naja nigricollis, and Cerastes vipera and of the scorpion Leiurus quinquestriatus on the mitotic index of the duodenal mucosal cells of the white rat, Rattus rattus, has been studied. All the venoms increased the number of dividing cells of the duodenal mucosa significantly. Naja haje crude venom was fractionated into three fractions. Fraction I had no effect on the mitotic index whereas fractions II and III increased it significantly. Treatment of rats with Naja haje venom fractions II and III after blocking the histamine or the serotonin receptors did not affect the stimulatory action of the two venom fractions on the mitotic index, which it increased significantly. It was suggested that the venoms of Naja haje, Naja nigricollis, Cerastes vipera, and Leiurus quinquestriatus and Naja haje venom fractions possessed a mitogenic activity. Fraction II of Naja haje venom acted through both the muscarinic and adrenergic receptors while fraction III acted on the adrenergic ones.     

Proteolytic activities of cobra venoms based on inactivation of alpha 2-macroglobulin

The venoms of various cobra species showed a wide range of abilities to cleave hide powder azure, with Naja naja kaouthia and Ophiophagus hannah venoms showing the lowest activities and Naja nivea venom showing the greatest activity on this dye-linked substrate. The activities of the venoms on hide powder did not completely correlate with their ability to inactivate the alpha 2-macroglobulin of human serum. Incubation of 4-5 micrograms of Naja nigricollis venom per microliter of serum for 30 min caused loss of 95% of the alpha 2-macroglobulin activity of the serum. The inactivation was rapid, reaching 80% inactivation 5 min after mixing. This loss of alpha 2-macroglobulin activity was used to quantitate the weak proteolytic activity of N. nigricollis venom and a partially purified sample of the major fibrinogenolytic proteinase of the venom. The inactivation of alpha 2-macroglobulin was also used to compare the proteinase activities of venoms from seven species or subspecies of cobra. Based on alpha 2-macroglobulin inactivation, N. nigricollis had the highest proteinase activity among the tested venoms. The measurement of alpha 2-macroglobulin inactivation should provide a useful alternative to hide powder digestion for demonstration of weak proteolytic activities in venoms.     

The effect of several viper venoms on prothrombin Padua.

The effect of four viper venoms (Oxyuranus scutellatus, Notechis scutatus scutatus, Echis carinatus, Naja nigricollis) on prothrombin Padua has been studied. Using Oxyuranus scutellatus venom and Notechis scutatus scutatus venom, prothrombin activity resulted to be moderately decreased similarly to what observed with other one-stage and two-stage methods. On the contrary, using Echis carinatus venom a normal level was obtained. No clotting was observed using the Naja nigricollis venom, regardless of the concentration used. The normal level of factor II obtained with Echis carinatus venom as compared with the low levels obtained with the other venoms, suggests that it acts on a different site of the prothrombin molecule.     

Selective lysis of virus-infected cells by cobra snake cytotoxins: A sendai virus, human erythrocytes, and cytotoxin model.

By using a Sendai virus-human erythrocyte model, this work found that virus-infected cells were 10-fold more susceptible to lysis in two of five examined cobra venoms. Four cytotoxins were isolated from the venom of the cobra Naja nigricollis that also showed 10-fold higher cytotoxicity toward virus-infected cells than to untreated cells. As selective destruction of virus-infected cells is of immense importance in clinical practice, this work demonstrates the potential of cobra cytotoxins to serve as leading compounds for the generation of derivatives or fractions with high cytotoxic specificity toward virus-infected cells.     

Cross-reactivities of polyclonal antibodies against factor V activating enzyme, a serine proteinase from Vipera lebetina (snake) venom

Antibodies to the factor V activating enzyme from Vipera lebetina venom were produced by immunizing a rabbit with chromatographically purified factor V activating enzyme probes. The antibodies cross-reacted with different protein fractions in 23 snake venoms (ten viperid, eight crotalid, and five elapid venoms) as demonstrated by western immunoblotting. In the venom of Vipera russelli the antibodies recognized only one protein band which probably belonged to factor V activating enzyme.     

Toxicities, LD50 prediction and in vivo neutralisation of some elapid and viperid venoms.

Toxicity levels of elapid (Naja naja and Naja oxiana) viperid (Vipera lebetina and Vipera russelli) venoms for mice and rat for intraperitoneal intravenous and intramuscular routes have been determined. The data have been analysed using a mathematical expression to calculate lethal venom concentrations in human snake bite cases. Further, in vivo neutralisation of snake venom potency (after experimental injection) using high voltage-low current electric shock treatment has been attempted. This treatment postponed the death further by 60-90 min in mice in case of elapid envenomation. In case of viperid envenomation such a postponement of death time was not noticed. The death postponement induced by the shock treatment probably refers to structural impairments that occur at molecular level in venom components and their consequent altered interactions with the target tissue or system.     

Snake venomics of African spitting cobras: toxin composition and assessment of congeneric cross-reactivity of the pan-African EchiTAb-Plus-ICP antivenom by antivenomics and neutralization approaches

Venomic analysis of the venoms of Naja nigricollis, N. katiensis, N. nubiae, N. mossambica, and N. pallida revealed similar compositional trends. The high content of cytotoxins and PLA(2)s may account for the extensive tissue necrosis characteristic of the envenomings by these species. The high abundance of a type I α-neurotoxin in N. nubiae may be responsible for the high lethal toxicity of this venom (in rodents). The ability of EchiTAb-Plus-ICP antivenom to immunodeplete and neutralize the venoms of African spitting cobras was assessed by antivenomics and neutralization tests. It partially immunodepleted 3FTx and PLA(2)s and completely immunodepleted SVMPs and CRISPs in all venoms. The antivenom neutralized the dermonecrotic and PLA(2) activities of all African Naja venoms, whereas lethality was eliminated in the venoms of N. nigricollis, N. mossambica, and N. pallida but not in those of N. nubiae and N. katiensis. The lack of neutralization of lethality of N. nubiae venom may be of medical relevance only in relatively populous areas of the Saharan region. The impaired activity of EchiTAb-Plus-ICP against N. katiensis may not represent a major concern. This species is sympatric with N. nigricollis in many regions of Africa, although very few bites have been attributed to it.     

Enzymatic digestion of human plasma inter-alpha-trypsin inhibitor by snake venom metalloproteinases

Incubation of human plasma inter-alpha-trypsin inhibitor with crotalid, viperid, colubrid or elapid venoms resulted in random cleavage of the intact inhibitor (200,000 mol. wt) and formation of inhibitor of 130,000, 77,000, 58,000, and 38,000 mol. wt, along with several minor products. The overall patterns of digestion varied among the venoms studied. However, a 77,000 mol. wt inhibitor cleavage product was formed by all venoms tested, and this fragment was resistant to proteolysis even after a 24 hr incubation with the venoms. Venom pre-treated with phenylmethylsulfonyl fluoride digested inter-alpha-trypsin inhibitor; however, pre-treatment with EDTA completely stopped the reaction, indicating that venom metalloproteinases were responsible for the inhibitor digestion. The inhibitor cleavage products retained the ability to inhibit trypsin, but had no inhibitory activity against venom proteinases.     

Nigexine, a phospholipase A2 from cobra venom with cytotoxic properties not related to esterase activity. Purification, amino acid sequence, and biological properties

The venoms of the Naja species are known to be cytotoxic. This toxicity has been attributed to the presence of small nonenzymatic polypeptides of 60 amino acid residues, designated as cardiotoxins or cytotoxins. We investigated the cytotoxic potency of Naja nigricollis venom fractions and isolated another type of cytotoxic component which is even more potent than cardiotoxins. This cytotoxic compound, which was designated as nigexine, was purified to homogeneity and its amino acid sequence was determined. Nigexine is a basic phospholipase A2 consisting of a single chain of 118 amino acids. A detailed investigation of the cytotoxic effects on epithelial FL cells, C-13T neuroblastoma cells, and promyelocytic leukemia HL 60 cells revealed that nigexine not only altered cell viability but also prevented cell proliferation. This is a property that was specific to nigexine since other phospholipases A2 from various sources had no detectable cytotoxic activity. The cytotoxic activity of nigexine was not dependent on the presence of divalent cations, unlike its enzymatic activity. In particular, the cytotoxic activity of nigexine was identical in the presence or absence of either 2 mM Ca2+ or Sr2+, or 6 mM EDTA. We also present evidence based on chemical modifications that cytotoxic activity was not correlated with enzymatic activity. Thus, modification with parabromophenacyl bromide totally abolished the enzymatic activity of nigexine, which nevertheless retained 6-20% of the cytotoxicity of native nigexine. Conversely, treatment with cyanogen bromide gave a compound that retained 7% of the enzymatic activity of the parent molecule but was devoid of detectable cytotoxicity.     

Taxonomic distribution and quantitative analysis of free purine and pyrimidine nucleosides in snake venoms

The nucleoside content of 32 elapid and viperid venoms was examined. Free purines, principally adenosine (ADO), inosine (INO), and guanosine (GUA), comprised as much as 8.7% of the solid components of some venoms. Thus, purines are far more abundant in some venoms than many proteinaceous toxins. Hypoxanthine (HYP) was found in about half of elapid and viperine venoms, in which it is a relatively minor constituent (<60 microg/g). Adenosine monophosphate (AMP) was tentatively identified in only three elapid and two viperid venoms. The pyrimidines, uridine (URI) and cytidine (CYT), were also found in most elapid and viperine venoms. In most of these, the amount of uridine was substantially greater than that of cytidine. Thymidine (THY) was not found in any venom, indicating that DNA from disintegration of glandular cells is not the source of venom nucleosides. In contrast to elapid and viperine venoms, most crotaline venoms are devoid of free nucleosides. Elapid and viperine venoms also contained other minor, low molecular weight constituents that could not be positively identified. Some had spectra identical to those of adenosine, nicotinamide adenine dinucleotide (NAD), inosine, xanthosine (XAN), and guanosine, while others had unique spectra. There is no apparent correlation between quantities of venom nucleosides and literature values for the three dominant venom enzymes that release endogenous nucleosides, 5'-nucleotidase (5NUC), phosphodiesterase (PDE), and alkaline phosphomonoesterase (PME).     

The effect of post-translational modifications on the hemorrhagic activity of snake venom metalloproteinases

Metalloproteinases (MPs) are Zn(+)-dependent endoproteolytic enzymes, abundant in crotalid and viperid snake venoms. Most snake venom metalloproteinases (svMPs) are active on extracellular matrix components and this effect is thought to result in bleeding as a consequence of the basement membrane disruption in capillaries. Jararhagin and ACLH are hemorrhagic svMPs from Bothrops jararaca and Agkistrodon contortrix laticinctus venom, respectively. Both enzymes demonstrate proteolytic activity on fibrinogen and fibronectin and jararhagin inhibits collagen-induced platelet aggregation in vitro. This work describes the expression, purification and successful refolding of the recombinant ACLH zymogen (rPRO-ACLH) as well as the catalytic domain of jararhagin (rCDJARA). The heterologous proteins were produced in E. coli, an in vivo expression system that does not make post-translational modifications. The recombinant refolded proteins did not show any hemorrhagic activity in mice skin, as well as the native deglycosylated jararhagin and ACLH. However, they preserved their proteolytic activity on fibrinogen and fibronectin. It seems that the hemorrhagic properties of these hemorrhagins are dependent on post-translational modifications, whereas their proteolytic activity is not dependent on such modifications.     

Basic phospholipase from the venom of Naja nigricollis is cytotoxic

The basic phospholipase A2 purified from the venom of Naja nigricollis (Institut Pasteur), possesses an intense cytotoxic activity toward fetal cells from FL strain. At a concentration equal to 1.6 x 10(-6) M, the PLA2 lyses 50% of the cells present in a suspension containing 3.5 x 10(6) cells per millilitre. Other PLA2 from various origins do not exhibit such cytotoxic activity.     

Analysis of the effects of snake venom proteinases on the activity of human plasma C1 esterase inhibitor, alpha 1-antichymotrypsin and alpha 2-antiplasmin

Incubation of C1 esterase inhibitor with Crotalid, Viperid and Colubrid snake venoms resulted in enzymatic inactivation of the inhibitor. Intact inhibitor (104 kDa) was converted into an active intermediate species of 89 kDa and then a further cleavage resulted in formation of an 86-kDa inactive inhibitor. In contrast, C1 esterase inhibitor did not lose activity during incubation with Elapid venoms; however, the intact inhibitor was gradually converted to an active species of 89 kDa during the incubation. Human alpha 1-antichymotrypsin was inactivated by all venoms tested, including those from the Elapid family. The 67-kDa intact inhibitor was converted by the venom proteinases to an inactive 63-kDa form. The results suggest that this acute-phase plasma protein is readily susceptible to inactivation by venom proteinases. Human alpha 2-antiplasmin (68 kDa) was cleaved to form a 61-kDa active intermediate, which then underwent a second cleavage to produce an inactive 53-kDa product. Elapid venoms had no effect on alpha 2-antiplasmin activity and did not cleave this inhibitor. All inhibitors were inactivated with catalytic amounts of venom proteinases. No stable proteinase-proteinase inhibitor complexes were detected, and no random proteolysis of the inhibitors occurred.     

Prey specificity, comparative lethality and compositional differences of coral snake venoms

Toxicities of crude venoms from 49 coral snake (Micrurus sp.) populations, representing 15 nominal taxa, were examined in both laboratory mice and in native prey animals and compared with data gathered from two non-micrurine elapids and a crotalid, which served as outgroups. These venoms were further compared on the basis of 23 enzymatic activities. Both toxicities and enzymatic activities were analyzed with respect to natural prey preferences, as determined from stomach content analyses and literature reports. Venoms of nearly all Micrurus for which prey preferences are known, are more toxic to natural prey than to non-prey species. Except for amphisbaenians, prey are more susceptible to venoms of Micrurus that feed upon them, than to venoms of those that eat other organisms. All venoms were more toxic i.v.>i.p.>i.m. Route-specific differences in toxicity are generally greatest for preferred prey species. Cluster analyses of venom enzymatic activities resulted in five clusters, with the fish-eating M. surinamensis more distant from other Micrurus than even the crotalid, Bothrops moojeni. Ophiophagous and amphisbaenian-eating Micrurus formed two close subclusters, one allied to the outgroup species Naja naja and the other to the fossorial, ophiophagous Bungarus multicinctus. Prey preference is shown to be the most important determinant of venom composition in Micrurus.     

A novel prothrombin activator from the venom of Micropechis ikaheka: isolation and characterization

A novel prothrombin activator, Mikarin, has been isolated from Micropechis ikaheka venom. It is a single polypeptide chain metalloproteinase with the apparent molecular weight of 47kDa. Mikarin exhibits Ca(2+)-independent prothrombin activation, but no effects on other blood coagulation factors, such as factor X and fibrinogen. Mikarin is the first member of group I prothrombin activators from elapid venom. Like other high-molecular-weight snake venom proteinases, it has three structural domains, metalloproteinase and disintegrin-like and Cys-rich domains, and belongs to the P-III class of snake venom metalloproteinases. The N-terminal of Mikarin exhibits 76% sequence identity with Cobrin, a metalloproteinase identified from Naja naja venom, but very lower identities were found when compared with those from viperid and crotalid venom. In addition, the presence of disintegrin-like and Cys-rich domains in snake venom metalloproteinases with diverse biological activities suggests that these domains may be important for their function.     

The anticoagulant activity of Malayan cobra (Naja naja sputatrix) venom and venom phospholipase A2 enzymes

Malayan cobra (Naja naja sputatrix) venom was found to exhibit an in vitro anticoagulant activity that was much stronger than most common cobra (genus Naja) venoms. The most potent anticoagulants of the venom are two lethal phospholipase A2 enzymes with pI's of 6.15 and 6.20, respectively. The anticoagulant activity of the venom is due to the synergistic effect of the venom phospholipase A2 enzymes and polypeptide anticoagulants. Bromophenacylation of the two phospholipase A2 enzymes reduced their enzymatic activity with a concomitant drop in both the lethal and anticoagulant activities.     

Effect of alkylation of tryptophan residues on the enzymatic and pharmacological properties of snake venom phospholipase A2

Snake venom phospholipases A2 show a remarkable degree of amino acid sequence homology yet differ markedly in enzymatic and pharmacological activities. The basic phospholipase A2 from Naja nigricollis venom has much greater lethal potency, cardiotoxicity, hemolytic and anticoagulant activity than the acidic or neutral enzymes from Naja naja atra or Hemachatus haemachatus venoms, respectively, even though it has lower enzymatic activity than the latter two enzymes. Previous studies in which we selectively modified lysine and free carboxyl groups suggested that the pharmacological and enzymatic active sites are not identical. Tryptophan residues have been suggested as being involved in substrate binding although some phospholipases have no tryptophan. We investigated the effect of alkylating the tryptophans in N. nigricollis, N. n. atra, and H. haemachatus phospholipases A2 with 2-hydroxy-5-nitrobenzyl bromide. Chemical modification caused decreases in enzymatic activity, although the extent of inactivation varied with the enzyme and with the substrate (lecithin micelles, egg yolk, heart homogenates). The specificity of the enzymes for individual phospholipid substrates was not affected. Alkylation of the tryptophans also caused decreases in lethal, hemolytic, anticoagulant, and cardiotoxic potencies, which were similar to the extents of decrease in enzymatic activity. Our results suggest that tryptophans are not specifically associated with either the enzymatic or the pharmacological active site nor are essential for either activity.