Comparative studies on three rattlesnake toxins

Toxins from the venoms of Crotalus durissus terrificus, Crotalus s. scutulatus and Crotalus viridis concolor were compared using gel filtration, ion-exchange chromatography on DEAE-Sephacel and denaturing and non-denaturing polyacrylamide gel electrophoresis. The three heterodimeric native toxins behaved similarly on each of the separation media, except that the C. d. terrificus toxin displayed a pronounced tendency to dissociate on DEAE-Sephacel, even in the absence of urea. In the presence of 6M urea, subunit dissociation was quantitative for all three toxins. Recombination of purified subunits resulted in toxins which eluted from the gel filtration column in identical fashion to native toxins. Non-denaturing polyacrylamide gel electrophoretic patterns of recombined toxins actually showed greater band resolution than did the native toxins. Six hybrid toxins were generated on polyacrylamide gels from cross-combinations of purified subunits, each with different mobilities than the parental toxins. Mobilities of the hybrid toxins depended principally upon the mobilities of the basic subunits. All three purified native toxins showed comparable LD50's in female mice (0.039-0.061 micrograms/g). The C. d. terrificus acidic X C. s. scutulatus basic hybrid toxin showed toxicity identical to that of the C. s. scutulatus recombined toxin. Phospholipase activity is associated with the basic subunit in all three toxins. Intact toxins show a distinctive lag in phospholipase activity which is not seen with purified basic subunits alone. These results indicate that the principal toxins in these three venoms are homologous.     

Venom characteristics as an indicator of hybridization between Crotalus viridis viridis and Crotalus scutulatus scutulatus in New Mexico

One hundred and thirteen venoms from 46 populations of Crotalus viridis viridis were screened by immunodiffusion for protein toxins antigenically similar to the phospholipase A2 (PLA) toxin 'Mojave toxin', using a polyclonal antibody to it's basic PLA subunit. Venom i.p. LD50 values in mice were recorded from 22 of the 46 populations. The venoms of three of 14 specimens from southwest (S.W.) New Mexico and one specimen from northern Arizona were immunologically positive by the immunodiffusion tests and produced low LD50 values (0.38-0.65 mg/kg) compared to all immunologically negative venoms (0.9-5.5 mg/kg). These four specimens were morphologically typical for C. v. viridis and their venoms were the only samples of 15 southern New Mexico specimens examined by reverse phase HPLC to exhibit peaks corresponding to the acidic and basic subunits of Mojave toxin. Alkaline polyacrylamide gel electrophoresis (PAGE) analysis of the recombined subunit peaks from the C.v. viridis venom from the S.W. New Mexico specimens showed more similarity to Mojave toxin from C.s. scutulatus venom than to similar toxins in C.v. concolor venom. The combined results of the immunodiffusion, lethal toxicity tests, HPLC profiles and PAGE analysis strongly suggest that the venoms of the three New Mexico specimens contain Mojave toxin(s), as a result of some previous hybridization with C.s. scutulatus. The northern Arizona specimen likely contains 'concolor toxin' through integration with C.v. concolor in its' genetic background.     

Cross-neutralization of the neurotoxicity of Crotalus durissus terrificus and Bothrops jararacussu venoms by antisera against crotoxin and phospholipase A2 from Crotalus durissus cascavella venom.

We have previously demonstrated that rabbit antisera raised against crotoxin from Crotalus durissus cascavella venom (cdc-crotoxin) and its PLA2 (cdc-PLA2) neutralized the neurotoxicity of this venom and its crotoxin. In this study, we examined the ability of these antisera to neutralize the neurotoxicity of Crotalus durissus terrificus and Bothrops jararacussu venoms and their major toxins, cdt-crotoxin and bothropstoxin-I (BthTX-I), respectively, in mouse isolated phrenic nerve-diaphragm preparations. Immunoblotting showed that antiserum to cdc-crotoxin recognized cdt-crotoxin and BthTX-I, while antiserum to cdc-PLA2 recognized cdt-PLA2 and BthTX-I. ELISA corroborated this cross-reactivity. Antiserum to cdc-crotoxin prevented the neuromuscular blockade caused by C. d. terrificus venom and its crotoxin at a venom/crotoxin:antiserum ratio of 1:3. Antiserum to cdc-PLA2 also neutralized the neuromuscular blockade caused by C. d. terrificus venom or its crotoxin at venom or toxin:antiserum ratios of 1:3 and 1:1, respectively. The neuromuscular blockade caused by B. jararacussu venom and BthTX-I was also neutralized by the antisera to cdc-crotoxin and cdc-PLA2 at a venom/toxin:antiserum ratio of 1:10 for both. Commercial equine antivenom raised against C. d. terrificus venom was effective in preventing the neuromuscular blockade typical of B. jararacussu venom (venom:antivenom ratio of 1:2), whereas for BthTX-I the ratio was 1:10. These results show that antiserum produced against PLA2, the major toxin in C. durissus cascavella venom, efficiently neutralized the neurotoxicity of C. d. terrificus and B. jararacussu venoms and their PLA2 toxins.     

Preparation of a crotoxin neutralizing monoclonal antibody

Crotoxin is a heterodimeric protein composed of an acidic and basic subunit from the venom of Crotalus durissus terrificus and is representative of a number of presynaptically acting neurotoxins found in the venom of rattlesnakes. Four different monoclonal antibodies, typed as IgG1 subclass, were raised against the basic subunit of this toxin. One was a potent neutralizing antibody of intact crotoxin, which could neutralize approximately 1.6 moles of purified crotoxin per mole of antibody. The monoclonal antibody enhanced the neutralizing ability of commercial polyvalent crotalid antivenom against the lethality of crude C. d. terrificus venom four-fold. Paradoxically, this monoclonal antibody by itself was ineffective against the lethality of crude C. d. terrificus venom. Using an enzyme-linked immunosorbent assay, we tested various proteins for competitive inhibition of binding of biotinylated-crotoxin to plates coated with the four individual monoclonal antibodies. Concolor toxin, vegrandis toxin, intact crotoxin, Mojave toxin, and the basic subunit of crotoxin showed increasing effectiveness as displacers of crotoxin from the neutralizing monoclonal antibody. None of the monoclonal antibodies reacted with purified phospholipase A2 enzymes from Crotalus atrox or Crotalus adamanteus, nor any of the components present in the crude venoms from four different elapids known to contain presynaptically acting neurotoxins, which show some sequence identity to crotoxin.     

Ability of rabbit antiserum against crotapotin to neutralize the neurotoxic, myotoxic and phospholipase A2 activities of crotoxin from Crotalus durissus cascavella snake venom.

The toxicity of crotoxin, the major toxin of Crotalus durissus terrificus (South American rattlesnake) venom, is mediated by its basic phospholipase A(2) (PLA(2)) subunit. This PLA(2) is non-covalently associated with crotapotin, an acidic, enzymatically inactive subunit of the crotoxin complex. In this work, rabbit antiserum raised against crotapotin purified from Crotalus durissus cascavella venom was tested for its ability to neutralize the neurotoxicity of this venom and its crotoxin in vitro. The ability of this antiserum to inhibit the enzymatic activity of the crotoxin complex and PLA(2) alone was also assessed, and its potency in preventing myotoxicity was compared with that of antisera raised against crotoxin and PLA(2). Antiserum to crotapotin partially neutralized the neuromuscular blockade caused by venom and crotoxin in electrically stimulated mouse phrenic nerve-hemidiaphragm preparations and prevented the venom-induced myotoxicity, but did not inhibit the enzymatic activity of crotoxin and purified PLA(2). In contrast, previous findings showed that antisera against crotoxin and PLA(2) from C. d. cascavella effectively neutralized the neuromuscular blockade and PLA(2) activity of this venom and its crotoxin. The partial neutralization of crotoxin-mediated neurotoxicity by antiserum to crotapotin probably reduced the binding of crotoxin to its receptor following interaction of the antiserum with the crotapotin moiety of the complex.     

Immunological relationships of phospholipase A2 neurotoxins from snake venoms

Polyclonal rabbit antisera were raised against ten snake phospholipase A2 neurotoxins and one snake phospholipase A2 cytotoxin. Immunological cross-reactivities between these toxins, two other snake phospholipase A2 enzymes and pancreatic phospholipase A2 were studied using ELISA technology. All snake phospholipase A2 neurotoxins fell into two main antigenic classes. One antigenic class was composed of all the elapid toxins tested (textilotoxin, taipoxin, notexin, pseudexin and beta-bungarotoxin), the cytotoxic phospholipase A2 from Naja naja atra and pancreatic phospholipase A2. beta-Bungarotoxin seemed to be in an immunological subclass of its own compared to the rest of the elapid toxins. The second antigenic class was comprised of crotalid and viperid phospholipase A2 neurotoxins (crotoxin, concolor toxin, Mojave toxin, vegrandis toxin, ammodytoxin and caudoxin). Our data indicated that the viperid toxins, caudoxin and ammodytoxin, were an immunological subclass apart from the crotalid toxins.     

Monoclonal antibodies to Mojave toxin and use for isolation of cross-reacting proteins in Crotalus venoms

Hybridomas secreting monoclonal antibodies against Mojave toxin were established. The antibodies were used for identifying cross-reacting proteins in individual C. s. scutulatus and other Crotalus venoms and to isolate Mojave toxin. The antibodies recognized five bands with a pI range from 5.1 to 6.1 in immunoblots of electrofocused crude venom and Mojave toxin purified by immunoaffinity chromatography. The specificity of the antibodies was for the basic subunit of the toxin, which resolved into four bands of pI between 9.3 and 9.6. Individual C. s. scutulatus venoms of snakes from Texas and southern Arizona had multiple bands with pI's ranging from 4.9 to 6.3. Cross-reacting proteins were also recognized by the antibodies in the electrophoresed venoms of C. basiliscus, C. d. durissus, C. d. terrificus, C. h. horridus and C. v. concolor, and may be isolated by immunoaffinity chromatography with the monoclonal antibodies.     

The distribution among ophidian venoms of a toxin isolated from the venom of the Mojave rattlesnake (Crotalus scutulatus scutulatus)

A toxin analogous to Mojave toxin or protein K' was isolated from venom of the Mojave rattlesnake (Crotalus s. scutulatus) by anion exchange and gel permeation chromatography. This toxin has an apparent native molecular weight of 20,000-22,000, a subunit molecular weight of 14,000 and a pI of 4.9-5.0. The i.p. LD50 is 0.094 mg/kg for mice. A wide variety of ophidian venoms (crotaline, viperine, elapid, hydrophid and colubrid) were examined for the presence of this toxin using Ouchterlony, immunoelectrophoresis, ELISA and Western transfer. High concentrations were found in 4 of 6 C. scutulatus venom samples, 2 of 3 C. durissus samples and samples from C. viridis concolor and C. tigris. A moderate concentration was found in 1 of 3 C. durissus samples and low to trace concentrations in 1 C. durissus sample, 1 C. scutulatus sample, 2 of 12 C. atrox samples and a Trimeresurus flavoviridis sample, the latter being the only instance of detection of the toxin in a snake other than a rattlesnake. The toxin appears in at least two phylogenetic lines of rattlesnakes, and its geographic distribution in North American rattlesnake species resembles a mosaic.     

Mojave toxin: rapid purification, heterogeneity and resistance to denaturation by urea

This report establishes that purified Mojave toxin prepared from the snake venom of Crotalus scutulatus scutulatus contains multiple heterogeneous dimers (isoforms) differing slightly in isoelectric points. This conclusion is based upon chromatographic, immunological, sodium dodecyl sulfate--polyacrylamide gel electrophoretic and polyacrylamide isoelectric focusing experiments. The Mojave toxin-related proteins were rapidly purified from venom via a single chromatography step. Generation of Mojave toxin-related proteins from isolated subunits and immunoblots of these proteins subsequent to electrophoretic separation demonstrate that each of the proteins consists of acidic and phospholipase basic subunits. The analysis of venom in narrow range polyacrylamide isoelectric focusing gels at varying concentrations of urea, in conjunction with immunoblots utilizing antibodies specific to the basic subunit, demonstrates that the isoforms of Mojave toxin are native and not artifacts from isolation procedures. Analyses of venoms from Crotalus scutulatus scutulatus individuals indicate that each snake produces multiple isoforms of the neurotoxin. Additionally, the same predominant isoform of Mojave toxin is present in both individual and commercial venoms. The heterogeneity of the Mojave toxin-related proteins is largely due to differences in the acidic subunits and some of the forms may reflect post-translational processing of the protein. The Mojave toxin-related proteins demonstrate a resistance to urea denaturation by characteristically entering and focusing in polyacrylamide isoelectric focusing gels containing 0-6 M urea, but dissociating to constituent subunits in 8 M urea. Experimental evidence suggest that salt bridges may be important in stabilization of the Mojave toxin complex.     

Mojave toxin in venom of Crotalus helleri (Southern Pacific Rattlesnake): molecular and geographic characterization.

Mojave toxin (MT) was detected in five of 25 Crotalus helleri (Southern Pacific rattlesnake) sampled using anti-MT antibodies and nucleotide sequence analysis. All of the venoms that were positive for MT were collected from Mt San Jacinto in Riverside Co., California. Since this population is geographically isolated from C. scutulatus scutulatus (Mojave rattlesnake), it is unlikely that this finding is due to recent hybridization. MT concentration differences between C. helleri and C. s. scutulatus reflected the presence of 'isoforms' of the toxin in the venom. Whereas C. s. scutulatus generally has several isoforms of the toxin (detected by Western blotting), only one 'isoform' that focused at pI 5.1 was detected in C. helleri. Both acidic and basic subunits of MT sequences were obtained from C. helleri DNA with primers specific for MT, but only from snakes that had MT in their venom. The sequence identity of the C. helleri acidic subunit to the C. s. scutulatus subunit was 84.9%, whereas the sequence identity of the C. helleri basic subunit was 97% to the C. s. scutulatus basic subunit. Using casein, fibrin, and hide powder azure as substrates, assays for proteolytic activity suggested that C. helleri possesses several different types of metalloproteinases in their venom. However, proteolytic activity was not detected, or present in reduced amounts, in specimens having MT. Clinical neurotoxicity following envenomation by certain populations of C. helleri may be due to MT.     

Specific binding of crotoxin to brain synaptosomes and synaptosomal membranes

Crotoxin, the presynaptic neurotoxin from Crotalus durissus terrificus, was iodinated and used to demonstrate high affinity, specific binding to guinea-pig (Cavia porcellus) brain synaptosomes and synaptosomal membrane fragments. 125I-crotoxin binding to the membrane fragments displays two binding plateaus, (Kd1 = 4 nM and Kd2 = 87 nM, Bmax1 = 2 and Bmax2 = 4 pmoles/mg membrane protein), but binding to whole synaptosomes revealed only one plateau (Kd = 2 nM and Bmax = 5 pmoles/mg membrane protein). Rosenthal analyses of Scatchard plots yielded similar binding constants in the presence or absence of 0.025% Triton X-100. In addition to equilibrium analyses, kinetic analyses of 125I-crotoxin binding to synaptosomal membrane fragments gave a Kd-value of 3 nM. The Kd value was not significantly changed by the exclusion of added calcium, but the binding site number was lowered. Crotoxin binding was inhibited by the acidic subunit of crotoxin and several presynaptic neurotoxins, which were classified according to their inhibitory properties as, strong (acidic subunit of crotoxin, Mojave toxin, concolor toxin, taipoxin and pseudexin), moderate (ammodytoxin A and textilotoxin), weak (notexin and scutoxin A), very weak (notechis II-5) and non-inhibitory (basic subunit of crotoxin, beta-bungarotoxin, Crotalus atrox and porcine pancreatic phospholipases A2, dendrotoxin, and notechis III-4). Purified acidic subunit of crotoxin, the most potent competitor of crotoxin binding, was somewhat more competitive than intact crotoxin and the other strong inhibitors on a molar basis. Strong, moderate and weak inhibitor groups each differed from the preceding group by requiring about a ten fold increase in concentration to effect a 50% inhibition of crotoxin binding. The weak group was therefore at least two-orders of magnitude less effective than the strong inhibition shown by the acidic subunit of crotoxin. Treatment of synaptosomal membranes with protease K lowered 125I-crotoxin binding, whereas treatment with trypsin did not. Iodinated, phospholipase A2 from C. atrox venom showed no specific binding to whole synaptosomes. Our results demonstrate the presence and describe some of the properties of high affinity, specific binding sites in brain tissue for crotoxin and related presynaptic neurotoxins.     

Immunochemical cross-reactivity of two phospholipase A2 neurotoxins, agkistrodotoxin and crotoxin

Polyclonal rabbit antisera were raised against the phospholipase A2 neurotoxin agkistrodotoxin (AGTX) from Agkistrodon blomhoffii brevicaudus venom and against the phospholipase A2 subunit (component-B, CB) of crotoxin from Crotalus durissus terrificus venom. Anti-AGTX antibodies cross-reacted strongly with crotoxin and crotoxin-like molecules and more weakly with other phospholipases A2 from the venoms of Viperidae and Crotalidae. On the other hand, anti-CB antibodies cross-reacted with AGTX, and also recognized ammodytoxin A and the phospholipase A2 from Vipera berus venom, but not other phospholipases A2 from Crotalidae and Viperidae. Anti-AGTX and anti-CB antibodies were able to inhibit the phospholipase A2 activity and to neutralize the lethal potency of the homologous and heterologous toxins (AGTX or crotoxin). Immunoaffinity chromatography columns were used to isolate anti-AGTX antibodies which recognized CB (91% of the total anti-AGTX antibodies), and anti-CB antibodies which recognized AGTX (52% of the total anti-CB antibodies). Immunochemical investigations performed with each type of antibody indicated that the majority of AGTX antigenic determinants are present on crotoxin component-B and on phospholipases A2 from Viperidae venoms, and that some of these determinants are involved in the neutralization of lethal potency and in the inhibition of enzymatic activity of AGTX and crotoxin.     

Anti-sera raised in rabbits against crotoxin and phospholipase A2 from Crotalus durissus cascavella venom neutralize the neurotoxicity of the venom and crotoxin.

Crotoxin, the principal neurotoxin in venom of the South American rattlesnakes Crotalus durissus terrificus and Crotalus durissus cascavella, contains a basic phospholipase A2 (PLA2) and an acidic protein, crotapotin. In this work, we examined the ability of rabbit anti-sera against crotoxin and its PLA2 subunit to neutralize the neurotoxicity of venom and crotoxin from C. d. cascavella in mouse phrenic nerve-diaphragm and chick biventer cervicis preparations. Immunoblotting showed that the anti-sera recognized C. d. cascavella crotoxin and PLA2. This was confirmed by ELISA, with both anti-sera having end-point dilutions of 3 x 10(-6). Anti-crotoxin serum neutralized the neuromuscular blockade in phrenic nerve-diaphragm muscle preparations at venom or crotoxin:anti-serum ratios of 1:2 and 1:3, respectively. Anti-PLA2 serum also neutralized this neuromuscular activity at a venom or crotoxin:anti-serum ratio of 1:1. In biventer cervicis preparations, the corresponding ratio for anti-crotoxin serum was 1:3 for venom and crotoxin, and 1:1 and 1:2 for anti-PLA2 serum. The neutralizing capacity of the sera in mouse preparations was comparable to that of commercial anti-serum raised against C. d. terrificus venom. These results show that anti-sera against crotoxin and PLA2 from C. d. cascavella venom neutralized the neuromuscular blockade induced by venom and crotoxin in both nerve-muscle preparations, with the anti-serum against crotoxin being slightly less potent than that against crotoxin.     

Mojave toxin affects fusion of myoblasts and viability of myotubes in cell cultures.

Mojave toxin is a neurotoxic, heterodimeric phospholipase isolated from the venom of Crotalus scutulatus scutulatus. Responses of primary rat muscle cell cultures and clonal muscle cell lines to treatment with Mojave toxin and its constituent subunits were examined. Continuous exposure of cells to 0.5 microM or 1.0 microM Mojave toxin or the basic subunit, added 24 hr after plating, prevented fusion of primary myoblasts and C2 myoblasts to multinucleate myotubes. Under the same experimental conditions, some myotube formation was observed when RMo cells were used, but the number and size of the myotubes were reduced substantially compared to untreated controls. The addition of Mojave toxin to established myotubes that arose from differentiation of primary myoblasts or C2 myoblasts essentially led to total disappearance of the myotubes from the cell layer within 48 hr. Myotubes from RMo cells treated in the same manner, however, did not disappear, but they were smaller and less numerous than comparable controls. Similar results were generated by exposure of myotubes to the basic subunit of Mojave toxin under the same conditions. The underlying layer of mononucleate cells was retained in both instances. Toxin-free cultures continued to develop in the usual manner. Treatment with 1.0 microM concentrations of the acidic subunit, pancreatic phospholipase A2 or a non-neurotoxic phospholipase from Naja naja atra gave results indistinguishable from untreated control cultures.     

Preliminary fractionation of tiger rattlesnake (Crotalus tigris) venom

S. A. Weinstein and L. A. Smith. Preliminary fractionation of tiger rattlesnake (Crotalus tigris) venom. Toxicon28, 1447–1455, 1990.—Tiger rattlesnake (Crotalus tigris) venom was fractioned by using fast protein liquid chromatography (FPLC). The crude venom had low protease activity, lacked hemolytic activity and had an i.p. ld₅₀ of 0.070 mg/kg for mice. Lethal fractions obtained by anion and cation exchange were examined for antigenic identity with crotoxin and Mojave toxin. Four toxins were obtained by anion exchange chromatography which showed immunoidentity with these toxins, and one fraction caused rear limb paresis in mice. A lethal toxin (about 10% of total venom protein) purified further with Superose-12 FPLC (molecular sieve) had an i.p. ld₅₀ of 0.050 mg/kg for mice, reacted strongly with anti-crotoxin and anti-Mojave toxin antiserum in ELISA and immunoelectrophoresis. This toxin also showed complete immunoidentity with crotoxin and Mojave toxin in immunodiffusion assays with anti-crotoxin antiserum. The results indicated the presence of crotoxin and/or Mojave toxin isoforms in this venom. Although this species has a low venom yield (average 10 mg per snake), the venom is highly toxic and contains high concentrations of several neurotoxic isotoxins.     

Specificity and binding affinity of an anti-crotoxin combinatorial antibody selected from a phage-displayed library

A crotoxin-specific, monoclonal, high-affinity, single-chain antibody variable region (scFv) was generated by combinatorial methods using Pharmacia's Recombinant Phage Antibody System. A high-affinity clone, designated A10G, was selected, and its DNA sequence was determined. Protein A10G showed high reaction specificity, with only the closely related rattlesnake neurotoxins, concolor toxin and Mojave toxin, showing cross-reactivity out of eleven group II phospholipase A₂s (PLA₂s) screened. No group I PLA₂s cross-reacted in enzyme-linked immunosorbent assays. The gene coding for A10G was subcloned into an expression vector, and the resulting expressed nonfusion protein, designated A10GPE, was renatured and purified to apparent homogeneity. Dissociation constants of A10G with intact crotoxin and crotoxin basic subunit were determined to be 7 × 10⁻¹⁰ and 6.8 × 10⁻⁹ M, respectively. When A10GPE was preincubated with either the basic subunit or intact crotoxin at molar ratios of up to 5:1, no inhibition of phospholipase activity was observed. Expressed protein, however, could partially neutralize the lethality of Mojave toxin, a crotoxin homolog, in mice.     

Neutralizing capacity of antisera raised in horses and rabbits against Crotalus durissus terrificus (South American rattlesnake) venom and its main toxin, crotoxin.

Crotalus durissus terrificus (South American rattlesnake) venom possesses myotoxic and neurotoxic activities, both of which are also expressed by crotoxin, the principal toxin of this venom. We have investigated the ability of commercial equine antivenom and antivenoms raised in rabbits against C. d. terrificus venom and crotoxin to neutralize the physiological and morphological changes induced by this venom and crotoxin in electrically-stimulated phrenic nerve-diaphragm (PND) and extensor digitorum longus (EDL) preparations of mice. The time required to produce 50% neuromuscular blockade in the PND and EDL preparations was, respectively, 103+/-9 and 59+/-6 min for C. d. terrificus venom (10 microg/ml) and 75+/-9 and 110+/-7 min for crotoxin (10 microg/ml). The antivenoms dose-dependently inhibited this neuromuscular activity of the venom and crotoxin. At a venom:antivenom ratio of 1:3, the rabbit antivenoms were as effective as the commercial equine antivenom. The creatine kinase (CK) concentrations in the organ bath containing EDL muscle were 290 and 1020 U/l following a 120 min exposure to C. d. terrificus venom and crotoxin, respectively. All of the antivenoms neutralized the release of CK by crotoxin, but were ineffective against C. d. terrificus venom. Histological analysis of the two preparations showed that rabbit anticrotoxin antivenom protected against the myotoxic action of C. d. terrificus venom and crotoxin better than the other antivenoms. We conclude that antisera raised in rabbits are better than equine antiserum in neutralizing the neurotoxic and myotoxic activities of C. d. terrificus venom and crotoxin.     

Protection against the lethal effects of Crotalus durissus terrificus (South American rattlesnake) venom in animals immunized with crotoxin

T. V. Freitas, C. L. Fortes-Dias and C. R. Diniz. Protection against the lethal effects of Crotalus durissus terrificus (South American rattlesnake) venom in animals immunized with crotoxin. Toxicon28, 1491–1496, 1990.—Mice and rabbits were immunized against crotoxin (the neurotoxic component isolated from Crotalus durissus terrificus venom) using small amounts of antigen in a water-in-oil emulsion. Following boosting (three times at 21-day intervals) a high titre of antibodies against crotoxin was obtained. Crotoxin immunoglobulin G antibody recognizes whole venom antigen at a level comparable with that of crotoxin antigen, using the ELISA method for antibody detection. The antibodies generated by crotoxin were capable of providing 100% protection against challenge with 11 and 50 i.p. ld₅₀ doses of whole venom in mice. When 100 i.p. ld₅₀ doses of whole venom were injected survival was 77.8%.     

Lipoxygenase-derived eicosanoids are involved in the inhibitory effect of Crotalus durissus terrificus venom or crotoxin on rat macrophage phagocytosis.

Crotalus durissus terrificus snake venom and its major toxin, crotoxin or type II PLA2 subunit of this toxin, induce an inhibitory effect on spreading and phagocytosis in 2h incubated macrophages. The involvement of arachidonate-derived mediators on the inhibitory action of the venom or toxins on rat peritoneal macrophage phagocytosis was presently investigated. Peritoneal cells harvested from naive rats and incubated with the venom or toxins or harvested from the peritoneal cavity of rats pre-treated with the toxins were used. Zileuton, a 5-lipoxygenase inhibitor but not indomethacin, a cyclooxygenase inhibitor, given in vivo and in vitro abolished the inhibitory effect of venom or toxins on phagocytosis. Resident peritoneal macrophages incubated with the venom or toxins showed increased levels of prostaglandin E2 and lipoxin A4, with no change in leukotriene B4. These results suggest that lipoxygenase-derived eicosanoids are involved in the inhibitory effect of C.d. terrificus venom, crotoxin or PLA2 on macrophage phagocytosis.     

Intergradation of two different venom populations of the Mojave rattlesnake (Crotalus scutulatus scutulatus) in Arizona

Two distinct venom populations of Crotalus scutulatus scutulatus exist in Arizona. The venom of one population (venom A) contains the toxin 'Mojave toxin' and is lacking in hemorrhagic and specific proteolytic activities. The other population (venom B) does not contain Mojave toxin but does produce hemorrhagic and proteolytic activities. The venoms of 15 Crotalus scutulatus scutulatus from regions between the venom A and venom B populations in Arizona were examined for the presence of Mojave toxin by immunochemical assay, lethality by mouse i.p. LD50, proteolytic activity and hemorrhagic activity in mice. Venom protein constituents were analyzed using reverse-phase HPLC. Seven venoms contained both the Mojave toxin of venom A and the proteolytic and hemorrhagic activities of venom B. The i.p. LD50 values of the A + B venoms were 0.4-2.6 mg/kg, compared to 0.2-0.5 mg/kg for venom A individuals and 2.1-5.3 mg/kg for the venom B individuals. HPLC illustrated that the A + B venoms exhibited a combined protein profile of venom A and venom B. These data indicate that an intergrade zone exists between the two venom types which arcs around the western and southern regions of the venom B population. Within these regions, three major venom types can occur in Crotalus s. scutulatus.