The co-purification of a lectin (BJcuL) with phospholipases A2 from Bothrops jararacussu snake venom by immunoaffinity chromatography with antibodies to crotoxin

Antigens of Bothrops jararacussu snake venom cross-reacting with specific antibodies against crotoxin, an Asp49 PLA(2)-containing heterodimeric complex from Crotalus durissus terrificus snake venom, were purified by two steps of immunoaffinity chromatography. The resulting fraction (Bj-F) was shown to be non-toxic (to mice and rabbits) and immunogenic to rabbits. Antibodies raised against Bj-F were able to protect mice against the lethal effect of both B. jararacussu and Crotalus durissus terrificus snake venoms. Then, the procedure developed showed to be useful for the rapid preparation of an antigen able to elicit neutralizing antibodies against the lethal activities of both venoms. Further fractionation of Bj-F revealed the concomitant presence of two major components: BJcuL, a lectin present in B. jararacussu venom, and BthTX-I, a Lys49 PLA(2) homolog, besides other molecules in minor amounts. Our data are discussed and raise the point that the presence of unrelated molecules may be taken into account when immuno-based methods are considered for purification purposes.

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.

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.

Crotapotin induced modification of T lymphocyte proliferative response through interference with PGE2 synthesis

The immunosuppressive property has been demonstrated for the venom of the Crotalus durissus terrificus. Using a simple, novel method for obtaining crotapotin and phospholipase A2 isoforms from venom, it was possible to demonstrate that the addition of crotapotin to cultures of isolated lymphocytes resulted in a significant inhibition of the cellular proliferative response to Concanavalin A. This reduction in blastogenic response of lymphocytes is accompanied by a significant increase in the production of PGE2 by macrophages. This effect on the innate immune response suggests that this compound may modify the subsequent adaptative immune response.

Contribution of crotoxin for the inhibitory effect of Crotalus durissus terrificus snake venom on macrophage function

Previous work of our group demonstrated that Crotalus durissus terrificus venom has a dual effect on macrophage function: it inhibits spreading and phagocytosis and stimulates hydrogen peroxide and nitric oxide production, antimicrobial activity and glucose and glutamine metabolism of these cells. Crotalid venom also induces analgesia and this effect is mediated by opioid receptors. The involvement of opioidergic mechanism and the determination of the active component responsible for the inhibitory effect of crotalid venom on macrophage function were investigated. The venom reduced the spreading and phagocytic activities of peritoneal macrophages. This effect was observed in vitro, 2 h after incubation of resident peritoneal macrophages with the venom, and in vivo, 2 h after subcutaneous injection of the venom. The inhibition of phagocytosis was not modified by naloxone, an antagonist of opioid receptors. Venom neutralization with crotalid antivenom abolished the inhibitory effect of the venom, indicating that venom toxins are involved in this effect. Crotoxin, the main toxin of crotalid venom, s.c. injected to rats or added to the medium of peritoneal cell incubation, inhibited macrophage function in a similar manner to that observed for crude venom. The present results suggest that crotoxin causes a direct inhibition of macrophage spreading and phagocytic activities and may contribute to the inhibitory effect of crotalid venom on macrophage function.

Neutralization of the pharmacological effects of bothropstoxin-I from Bothrops jararacussu (jararacuçu) venom by crotoxin antiserum and heparin

Bothropstoxin-I (BthTX-I), the principal myotoxin of Bothrops jararacussu venom, is devoid of phospholipase A(2) (PLA(2)) activity but capable of blocking neuromuscular transmission in mouse nerve-muscle preparations. In this study, the ability of crotoxin antiserum and heparin in preventing the neurotoxic and myotoxic effects of BthTX-I was investigated. Phrenic nerve-diaphragm preparations (PND) stimulated indirectly with supramaximal stimuli (0.2 ms, 0.1 Hz) were incubated with BthTX-I (20 microg/ml) alone or with BthTX-I preincubated with antiserum or heparin for 30 min at 37 degrees C prior to testing. Control preparations were incubated with Tyrode solution, antiserum or heparin alone. BthTX-I (20 microg/ml) produced 50% neuromuscular blockade in the PND preparations in 31+/-4min, with complete blockade occurring in 120 min. The antiserum and heparin significantly prevented the neuromuscular blockade caused by BthTX-I (84 +/- 4% and 100% protection, respectively). Light microscopy examination of the muscles at the end of the 120 min incubation showed that BthTX-I damaged 48 +/- 6% of the fibers. Preincubating the toxin with antivenom significantly reduced the extent of this damage (only 15 +/- 4% of fibers affected, corresponding to 69% protection, P<0.01) whereas heparin offered no protection (34 +/- 7% of fibers affected, not significantly different from that seen with toxin alone). These results show that the antivenom was more effective in neutralizing the myotoxic effects of BthTX-I than was heparin.

Role of crotoxin, a phospholipase A2 isolated from Crotalus durissus terrificus snake venom, on inflammatory and immune reactions

BACKGROUND

Crotoxin (CTX) is a potent neurotoxin from Crotalus durissus terrificus snake venom (CdtV) composed of two subunits: one without catalytic activity (crotapotin), and a basic phospolipase A2. Recent data have demonstrated that CdtV or CTX inhibit some immune and inflammatory reactions.

AIM

The aim of this paper was to investigate the mechanisms involved in these impaired responses.

MATERIALS AND METHODS

Male Swiss mice were bled before and at different intervals of time after subcutaneous injection of CTX or bovine serum albumin (BSA) (control animals). The effect of treatments on circulating leukocyte mobilisation and on serum levels of interleukin (IL)-6, IL-10, interferon (IFN)-gamma and corticosterone were investigated. Spleen cells from treated animals were also stimulated in vitro with concanavalin A to evaluate the profile of IL-4, IL-6, IL-10 or IFN-gamma secretion. Cytokine levels were determined by immunoenzymatic assay and corticosterone levels by radioimmunoassay. To investigate the participation of endogenous corticosteroid on the effects evoked by CTX, animals were treated with metyrapone, an inhibitor of glucocorticoid synthesis, previous to CTX treatment.

RESULTS

Marked alterations on peripheral leukocyte distribution, characterised by a drop in the number of lymphocytes and monocytes and an increase in the number of neutrophils, were observed after CTX injection. No such alteration was observed in BSA-treated animals. Increased levels of IL-6, IL-10 and corticosterone were also detected in CTX-injected animals. IFN-gamma levels were not modified after treatments. In contrast, spleen cells obtained from CTX-treated animals and stimulated with concanavalin A secreted less IL-10 and IL-4 in comparison with cells obtained from control animals. Metyrapone pretreatment was effective only to reverse the neutrophilia observed after CTX administration.

CONCLUSIONS

Our results suggest that CTX may contribute to the deficient inflammatory and immune responses induced by crude CdtV. CTX induces endogenous mechanisms that are responsible, at least in part, for these impaired responses.

Effect of membrane composition and of co-encapsulation of immunostimulants in a liposome-entrapped crotoxin

Crotoxin isolated from the venom of Crotalus durissus terrificus (South American rattlesnake) was incorporated into liposomes by the dehydration-rehydration vesicle method using different membrane compositions and the co-encapsulation of immunostimulants. Crotoxin was also encapsulated into liposomes formed from a non-phospholipid amphiphile, a mixture of polyoxyethylene 2-cetyl ether, dicetyl phosphate and cholesterol. The preparations were characterized in relation to stability, toxicity and the protection of mice against whole venom after immunization. All liposome preparations were quite stable, retaining more than 75% of the originally encapsulated crotoxin after 1 week of incubation at physiological temperature. Co-encapsulation with lipopolysaccharide increased the leakage of crotoxin. In contrast, co-encapsulation of the lipid moiety of lipopolysaccharide did not influence the stability of liposomes. Toxicity of liposomes was dependent on membrane composition. Liposomes made with phospholipids that were resistant to phospholipase A(2) activity were less toxic. Mice immunized with three doses of the 1 x LD50 of crotoxin encapsulated into liposomes, and with associated immunostimulants, were protected against challenge with 8 x subcutaneous LD50 of C. durissus terrificus venom. Using the same immunization schedule, liposomes made from a non-phospholipid mixture and without immunostimulants achieved 100% protection.

Effect of heating on the toxic, immunogenic and immunosuppressive activities of Crotalus durissus terrificus venom

The venom of South American rattlesnake Crotalus durissus terrificus is very toxic but poorly immunogenic and it has an immunosuppressive ability. The heating of venom at 56, 70 or 100 degrees C for 30 min caused a diminution in the lethal, phospholipase A(2) and myotoxic activities. SDS-PAGE analysis of the heated venom showed that the proteins of higher molecular weights were the most affected by heating whereas proteins with lower molecular weights (20,000-14, 000) were the most resistant to heating. The immunosuppressive effect was studied in mice immunized with human serum albumin (HSA) 1 h after receiving either heated venom or heated crotoxin. The heating of venom at 70 or 100 degrees C reduced its immunosuppressive effect whereas crotoxin had its suppressive effect reduced only when heated at 100 degrees C. The heating of venom at 56, 70 or 100 degrees C did not change its immunogenicity. These results suggest that heat treatment may be a useful technique to help in the production of antiserum to crotalid venom.

Combining phage display and molecular modeling to map the epitope of a neutralizing antitoxin antibody

Crotoxin is a potent presynaptic neurotoxin from the venom of the rattlesnake Crotalus durissus terrificus. It is composed of the noncovalent and synergistic association of a weakly toxic phospholipase A2, CB, and a nontoxic three-chain subunit, CA, which increases the lethal potency of CB. The A-56.36 mAb is able to dissociate the crotoxin complex by binding to the CA subunit, thereby neutralizing its toxicity. Because A-56.36 and CB show sequence homology and both compete for binding to CA, we postulated that A-56.36 and CB had overlapping binding sites on CA. By screening random phage-displayed libraries with the mAb, phagotopes bearing the (D/S)GY(A/G) or AAXI consensus motifs were selected. They all bound A-56.36 in ELISA and competed with CA for mAb binding, although with different reactivities. When mice were immunized with the selected clones, polyclonal sera reacting with CA were induced. Interestingly, the raised antibodies retained the crotoxin-dissociating effect of A-56.36, suggesting that the selected peptides may be used to produce neutralizing antibodies. By combining these data with the molecular modeling of CA, it appeared that the functional epitope of A-56.36 on CA was conformational, one subregion being discontinuous and corresponding to the first family of peptides, the other subregion being continuous and composed of amino acids of the second family. Phage-displayed peptides corresponding to fragments of the two identified regions on CA reacted with A-56.36 and with CB. Our data support the hypothesis that A-56.36 and CB interact with common regions of CA, and highlight residues which are likely to be critical for CA-CB complex formation.

Neutralizing human anti crotoxin scFv isolated from a nonimmunized phage library

Combinatorial phage display technology offers a new possibility for making human antibodies which could be used in immune therapy. We explored the use of this technology to make human scFvs specific for crotoxin, the main toxic component of the venom of the South-American rattlesnake Crotalus durissus terrificus. Crotoxin, a phospholipase A2 neurotoxin constituted by the association of two subunits, exerts its lethal action by blocking neuromuscular transmission. This is the first report of human anticrotoxin scFvs (scFv 1, scFv 6 and scFv 8) isolated from a naive library of more than 1010 scFv clones with in vivo neutralizing activity. Nevertheless, differences are observed at the level of biological and immunological effects. Only scFv 8 is able to reduce the myotoxicity induced by crotoxin and scFv 1 is capable of altering the in vitro enzymatic activity of this toxin. All three scFvs recognize a region of one subunit located at the junction with the other one. Moreover these scFvs share strong amino acid homologies at the level of either the heavy or the light chain. Taken together, our results suggest that the use of human anticrotoxin scFvs may lead to a new and less aggressive passive immune therapy against poisoning by the venom of Crotalus durissus terrificus.

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.

A monoclonal antibody directed against the non-toxic subunit of a dimeric phospholipase A2 neurotoxin, crotoxin, neutralizes its toxicity

Crotoxin is the main toxic component of the venom of the South-American rattlesnake Crotalus durissus terrificus. It is a phospholipase A2 neurotoxin constituted by the association of two subunits: an acidic, non-toxic and non-enzymatic subunit (CA) and a basic, weakly toxic phospholipase A2 (CB). A murine monoclonal antibody directed to the non-toxic subunit CA, A-56.36, was shown to fully neutralize the toxicity of crotoxin. When the in vitro pharmacological properties of crotoxin were further tested, A-56.36 was shown to enhance the enzymatic activity on negatively-charged phospholipids and to increase the acetylcholine release triggered by crotoxin on Torpedo synaptosomes. These effects were explained by the fast dissociation of the crotoxin complex in the presence of the monoclonal antibody A-56.36 and the immunocomplexation of CA, with CB being released in solution. CB is less toxic than crotoxin, has a higher enzymatic activity and triggers a higher acetylcholine release than crotoxin, due to its strong enzymatic activity. A single-chain variable fragment antibody was prepared from monoclonal antibody A-56.36. It binds to CA with a similar affinity than the parental immunoglobulin and exhibits similar effects on the in vitro pharmacological properties of crotoxin.

Biologically active human anti-crotoxin scFv isolated from a semi-synthetic phage library

BACKGROUND

The display of repertoires of antibody fragments on the surface of filamentous bacteriophages offers a new way of making antibodies with predefined binding specificities.

OBJECTIVES

Here we explored the use of this technology to find human antibodies with biological properties. Phage-scFv specific for crotoxin, the main toxic component of the venom of the South-American rattlesnake Crotalus durissus terrificus, were isolated from a 'single pot' repertoire of more than 10(8) clones made in vitro from human V gene segments [1]. The crotoxin molecule is composed of two noncovalently linked subunits: a basic and weakly toxic phospholipase A2 (PLA2) called component B (CB) and an acidic, nonenzymatic and nontoxic subunit called component A (CA). CA is able to increase the toxicity as well as the specificity of action of CB simultaneously reducing its enzymatic activity.

STUDY DESIGN

Two clones were isolated (4-21 and 5-3-1) which are specific of the basic subunit CB, but of a moderate affinity (about 10(-7) M). Clones 4-21 and 5-3-1 have different amino acid sequences and different effects on CB properties suggesting that they are raised against different CB epitopes. Purely cholinergic synaptosomes isolated from Torpedo electric organs provide a suitable model to study the presynaptic effects of crotoxin. In this model, CB was shown to induce a larger acetylcholine release than crotoxin.

RESULTS

A dose-dependent increase of acetylcholine release was observed when crotoxin was incubated with increasing amounts of phage-scFv 4-21. This clone was also shown to increase the enzymatic activity of crotoxin. These observations suggest that phage-scFv might dissociate the complex CA-CB. It could be therefore a neutralizing antibody since CB is much less toxic than crotoxin. This shows that 'single pot' libraries are capable of providing not only immunochemical reagents of high specificity but also biological reagents of high quality. The use of this library appears to open new possibilities for immune passive therapy.

Encapsulation of native crotoxin in liposomes: a safe approach for the production of antivenom and vaccination against Crotalus durissus terrificus venom

Crotoxin, the neurotoxic component of Crotalus durissus terrificus (Cdt) venom that displays phospholipase A2 activity, was successfully encapsulated into dehydration-rehydration vesicles (DRV/crotoxin) and reverse-phase evaporation vesicles (REV/crotoxin) made from sphingomyelin and cholesterol. The encapsulation efficiency of native crotoxin was higher in DRV/crotoxin than in REV/crotoxin. DRV/crotoxin was not toxic when i.v. inoculated in mice at a dose of crotoxin as high as 91 times its L.D50 or when s.c. inoculated at 42 times its LD50. On the other hand, crotoxin released from DRV/crotoxin retained its original toxicity. REV/crotoxin was found to be at least 1.9 times more toxic than DRV/crotoxin. The fact that DRV/crotoxin retained crotoxin more efficiently than REV/crotoxin may account for the difference in acute toxicity between the two preparations. DRV/crotoxin, when s.c. inoculated in mice, induced anti-crotoxin antibodies that protected animals against the lethal effect of Cdt venom. Following immunization with three doses of DRV/crotoxin (3 x 20 micrograms of crotoxin/mouse) and challenge with 8 x LD50 of Cdt venom, 75% of mice were protected. The DRV/crotoxin preparation was compared to crotoxin emulsified in Freund's adjuvant (FCA/crotoxin). DRV/crotoxin was found to be less toxic than FCA/crotoxin, and to induce lower levels of anti-crotoxin antibodies but similar levels of protection when inoculated at high doses (20 or 70 micrograms crotoxin/mouse). When DRV/crotoxin was adsorbed to alum at the time of immunization, it induced antibody and protection levels comparable to those produced by FCA/crotoxin.

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 x 10(-10) and 6.8 x 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.

Antipeptide antibodies directed to the C-terminal part of ammodytoxin A react with the PLA2 subunit of crotoxin and neutralize its pharmacological activity

Crotoxin and ammodytoxin A are snake venom neurotoxic phospholipases A2. Polyclonal antibodies against three synthetic peptides selected from the C-terminal part of the primary structure of ammodytoxin A were tested by ELISA for their interaction with crotoxin and its subunits, CA and CB. All three antipeptide antibodies reacted specifically with corresponding parts of ammodytoxin A and CB, either native or reduced. Conversely, polyclonal antibodies produced against ammodytoxin A and CB reacted strongly with all three peptides, suggesting that they constitute at least a part of natural epitopes in both proteins. All antipeptide antibodies reacted also with the corresponding peptides derived from CB by cyanogen bromide cleavage. The biological activity of the immune complexes was tested. No significant change in the enzymatic activity of CB, ammodytoxin A or crotoxin was observed with any of the three antipeptide antibodies. These antibodies were, however, able to protect mice against the lethal potency of CB and to prolong survival time of mice injected with crotoxin. These antipeptide antibodies were assayed in vitro for their protective effect against the action of CB or crotoxin on synaptosomes from Torpedo marmorata electric organ. They partly inhibited the acetylcholine release induced by both proteins. These results indicate that the C-terminal part of CB is likely to be involved in the pharmacological action of crotoxin.

Monoclonal antibodies to VRV-PL-VIIIa, a basic multitoxic phospholipase A2 from Vipera russelli venom

VRV-PL-VIIIa, the most basic phospholipase A2 (PLA2) from the venom of Vipera russelli, induces multiple toxic effects, including neurotoxicity, myotoxicity, edema and hemorrhage. Rabbit polyclonal anti-serum was raised against VRV-PL-VIIIa. The antiserum cross-reacted in enzyme-linked immunosorbant assay (ELISA) with two other PLA2 from the same venom, VRV-PL-V and VRV-PL-VI, and with ammodytoxin A, caudoxin and crotoxin. Twenty-two hybridoma cell lines secreting monoclonal antibodies against VRV-PL-VIIIa were isolated. The monoclonal antibodies exhibited apparent binding affinities in ELISA with VRV-PL-VIIIa ranging over two orders of magnitude. Most of the monoclonal antibodies cross-reacted moderately with VRV-PL-V and weakly with VRV-PL-VI. None of the antibodies cross-reacted with ammodytoxin, caudoxin or crotoxin. Reducing the disulfide bonds of VRV-PL-VIIIa lowered the ELISA signals of each monoclonal antibody to nonspecific levels, suggesting that all the antibodies recognize conformational epitopes. Four of the 22 antibodies neutralized the enzymatic activity of VRV-PL-VIIIa. Interestingly, two of the four exhibited the lowest affinities of the monoclonal antibody library for VRV-PL-VIIIa in ELISA, while the other two exhibited the highest. Each of the monoclonal antibodies was biotinylated and spatial binding relationships were evaluated by competition ELISA.

Primary sequence determination of the most basic myonecrotic phospholipase A2 from the venom of Vipera russelli

The most basic phospholipase A2 (PLA2), VRV-PL-VIIIa, was purified from (Sri Lankan) Vipera russelli venom. It is a major component of the venom, contributing over 40% to the whole venom PLA2 activity. The purity of VRV-PL-VIIIa was ascertained by electrophoresis and by reverse phase high-pressure liquid-chromatography (RP-HPLC). VRV-PL-VIIIa had an apparent mol. wt of 13,000 and was a single polypeptide. The protein was reduced, pyridylethylated and subjected to sequence analysis. The N-terminal amino acid sequence was established up to the 39th residue. Pyridylethylated VRV-PL-VIIIa was digested with endoprotease Glu-C, and several peptides were purified by RP-HPLC; six purified peptides were sequenced. The sequence of the C-terminal was established by sequencing a CNBr-produced peptide purified by RP-HPLC. Several peptides were also generated by digestion with endoprotease Asp-N. Two peptides were sequenced to obtain overlapping regions. The complete structure was deduced from sequences of overlapping peptides and through homology with other group II PLA2 sequences. Sequence homology was greatest with ammodytoxin A: 99 amino acid residues out of 121 occurred in identical positions. Myotoxin III of Bothrops asper showed 73% homology, 89 out of 121 residues. In agreement with the sequence data, polyclonal antiserum against VRV-PL-VIIIa cross-reacted in ELISA with ammodytoxin A and, to a lesser extent, with caudoxin.

Snake-venom phospholipase A2 neurotoxins. Potentiation of a single-chain neurotoxin by the chaperon subunit of a two-component neurotoxin

The venoms from Crotalinae and Viperinae snakes contain only two kinds of phospholipase A2 neurotoxins (beta-neurotoxins): single-chain beta-neurotoxins, such as agkistrodotoxin and ammodytoxin-A, and dimeric beta-neurotoxins, which, in the case of the best studied ones, crotoxin-like toxins, consist of the non-covalent association of a phospholipase A2 (CB) and a non-enzymatic chaperon (CA). Possible evolutionary relationships of these beta-neurotoxins have been investigated by analyzing whether CA could behave as a chaperon toward agkistrodotoxin and ammodytoxin, as it does in the crotoxin complex. CA increased the lethal potency of agkistrodotoxin and modified its pharmacological effect on Torpedo synaptosomes. Sedimentation experiments proved that CA can form an heterocomplex with agkistrodotoxin. Agkistrodotoxin prevented the binding to CA of an anti-CA mAb which recognizes an epitope at the zone of interaction between crotoxin subunits, suggesting the association of CA and agkistrodotoxin implicated the same zone. A 10-fold molar excess of CA over ammodytoxin modified the effect of ammodytoxin on acetylcholine release but did not increase the lethal potency of ammodytoxin. Sedimentation experiments showed CA and ammodytoxin can form an heterocomplex which is less stable than CA.agkistrodotoxin. Ammodytoxin A did not compete with the anti-CA mAb. These observations are in good agreement with the sequence similarities between CB and agkistrodotoxin (80%) and ammodytoxin A (60%).

Immunochemical analysis of a snake venom phospholipase A2 neurotoxin, crotoxin, with monoclonal antibodies

Crotoxin is the major neurotoxic component of the venom of the South American rattlesnake, Crotalus durissus terrificus. The crotoxin molecule is composed of two subunits: a basic and weakly toxic phospholipase A2 (PLA2) called component-B (CB), and an acidic, nonenzymatic and nontoxic subunit called component-A (CA). Crotoxin exists as a mixture of several isoforms (or variants) resulting from the association of several subunit isoforms. We prepared monoclonal antibodies (MAbs) against each isolated subunit. Six anti-CA MAbs and eight anti-CB MAbs were tested for their cross-reactivities with each subunit and with other toxic and nontoxic PLA2s. Four of the six anti-CA MAbs cross-reacted with CB, whereas only one of the eight anti-CB MAbs cross-reacted with CA. Two anti-CB MAbs were found to cross-react with agkistrodotoxin, a single chain neurotoxic PLA2 purified from the venom of Agkistrodon blomhoffii brevicaudus. We determined the dissociation constants of each MAb for CA and CB isoforms and their capacities to neutralize the lethality and to inhibit the catalytic activity of crotoxin. We defined three epitopic regions on CA and four on CB, and used a schematic representation of the two subunits to characterize these epitopic regions with respect to: (1) the "toxic" and the "catalytic" sites of CB, and (2) the zone of interaction between the two subunits. We propose three-dimensional structures of the crotoxin subunits in which we localize amino acid residues that might be involved in the epitopic regions described here.

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.

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

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%.

Preliminary fractionation of tiger rattlesnake (Crotalus tigris) venom

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.

Pharmacologic experiments on the interaction between crotoxin and the mammalian neuromuscular junction

Crotoxin and its two subunits were tested for their neuromuscular blocking activity on the phrenic nerve-hemidiaphragm preparation. Two types of experimental paradigms were used, the first of which separated the toxin binding step from subsequent events in paralysis and the second of which did not. In both paradigms the toxin produced concentration-dependent blockade of transmission. However, the results with low concentrations were variable, and in some cases complete neuromuscular blockade did not develop. The isolated acidic and basic subunits possessed little toxicity. In experiments designed to characterize binding, the intact toxin displayed the following properties: 1) the apparent half-time for tissue association was about 22 min; 2) binding was not affected by low temperature, the presence or absence of nerve stimulation and the substitution of strontium for calcium; and 3) when binding was allowed to go to completion, reversibility was negligible. Pretreatment of tissues with the isolated subunits of crotoxin did not enhance or inhibit the binding of the parent molecule. Modification of one histidine residue in the isolated basic subunit, followed by reconstitution with unmodified acidic subunit, generated a molecule that possessed only about 10% of the neurotoxicity of the native toxin. The modified toxin could not be used to antagonize binding of the native toxin. Both polyclonal and monoclonal antibodies were generated that neutralized the biologic activity of crotoxin. In experiments that separated the binding step from later events in paralysis, the polyclonal preparation continued to locate and partially neutralize tissue-bound toxin. In experiments that initiated events that follow binding, polyclonal antibodies were progressively less effective with time in neutralizing toxin.(ABSTRACT TRUNCATED AT 250 WORDS)

Neutralization of lethal potency and inhibition of enzymatic activity of a phospholipase A2 neurotoxin, crotoxin, by non-precipitating antibodies (Fab)

Rabbit antibodies were prepared against both purified catalytic (component-B) and purified non-catalytic (component-A) subunits of crotoxin, the major phospholipase A2 neurotoxin from the South American rattlesnake. They cross-react with crotoxin-like toxins from the venom of several Crotalus species as well as with single-chain phospholipase A2 neurotoxins from Crotalid and Viperid venoms (agkistrodontoxin and ammodytoxin A) but not from Elapid venoms (notexin). Immunological cross-reactions of anti-component-A and anti-component-B sera with crotoxin and with its isolated components A and B showed that component-A exposes determinants of low immunogenicity which are present on component-B, whereas the major antigenic determinants of component-B are not present on component-A. Anti-component-B antibodies, but not anti-component-A antibodies, neutralize the lethal potency of crotoxin and inhibit its enzymatic activity. Furthermore, non-precipitating anti-component-B Fab fragments were as potent as antibodies, indicating that crotoxin neutralization results from the binding of the antibodies to the catalytic subunit, rather than the formation of an immunoprecipitate.

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.

Cross-reactivity and neutralization by rabbit antisera raised against crotoxin, its subunits and two related toxins

Antisera were raised against intact crotoxin (Crotalus durissus terrificus), Mojave toxin (Crotalus scutulatus scutulatus) and concolor toxin (Crotalus viridis concolor), as well as the subunits of crotoxin. Double immunodiffusion and enzyme-linked immunosorbent assays (ELISA) demonstrated antigenic similarity between these three purified toxins and their subunits. Additionally, when crotoxin antisera were pre-incubated with each of the three toxins before injection, the lethal activity of all were neutralized equally well. Antiserum was considerably more effective in neutralizing crotoxin in vivo when the toxin was injected i.m. than when injected i.v. Antisera against both intact crotoxin and its basic subunit were an order of magnitude more effective than crotoxin acidic subunit antiserum in crotoxin neutralization. Purified phospholipase A2 from Crotalus adamanteus and Crotalus atrox showed weak cross-reactivity with antisera raised against intact crotoxin and its subunits in the ELISA. Our results suggest that crotalid neurotoxins can be detected and neutralized by polyclonal antibodies raised against any intact toxin or basic subunit in this group of homologous toxins.