Isolation of subunits, alpha, beta and gamma of the complex taipoxin from the venom of Australian taipan snake (Oxyuranus s. scutellatus): characterization of beta taipoxin as a potent mitogen.

The venom of Australian taipan snake (Oxyuranus s. scutellatus) is extremely potent due to the presence of taipoxin. The intact complex molecule of taipoxin having molecular weight 45.6 kDa is composed of alpha, beta and gamma subunits. This report describes the high pressure liquid chromatography (HPLC) separation of alpha, beta (beta-1 and beta-2) and gamma subunits from taipan crude venom. The fractions containing the taipoxin subunits were further purified to obtain homogeneous proteins. The toxicity in mice showed the alpha subunit as most toxic, the gamma subunit as moderately toxic and the beta-1 and beta-2 subunits were nontoxic. The proteins beta-1 and beta-2 were found to be mitogenic having neurotrophic activity on PC12 cells in culture similar to nerve growth factor. Immunologically, alpha, beta-1, beta-2 and gamma subunits were found to be different, showing cross reactivity, and beta-1 and beta-2 were found to be identical for biological properties and molecular weight. Further characterization of unexpected mitogenic activity of beta subunits is underway.     

A pharmacological examination of venom from the Papuan taipan (Oxyuranus scutellatus canni).

The Papuan taipan (Oxyuranus scutellatus canni) is the third most venomous terrestrial snake in the world, however, little is know about the pharmacology of the venom. In the chick biventer cervicis muscle, venom (10 μg/ml) abolished nerve-mediated twitches (time to 90% inhibition (t₉₀) 44±5 min, n=9). This inhibition was unaffected by prior incubation of the venom with the phospholipase A inhibitor 4-bromophenacyl bromide (4-BPB; 0.72 mM) (t₉₀ 48±7 min, n=8). The mouse phrenic nerve diaphragm preparation displayed greater sensitivity to venom (10 μg/ml) (t₉₀ 25±1 min, n=6). In the chick biventer muscle, venom (10 μg/ml) significantly inhibited responses to acetylcholine (1 mM) and carbachol (20 μM), but not KCl (40 mM), indicating activity at post-synaptic nicotinic receptors. Venom (10 μg/ml) did not affect direct muscle stimulation. Venom (3–30 μg/ml) produced dose-dependant contractions of the guinea-pig ileum. Contractile responses were significantly inhibited by indomethacin (1 μM) or prior incubation of the venom with 4-BPB (0.72 mM) indicating involvement of a PLA component. In rat phenylephrine (0.3 μM) precontracted aortae, venom (3–100 μg/ml) produced endothelium-independent relaxation which was unaffected by prior incubation of venom (30 μg/ml) with 4-BPB (0.72 mM). In anaesthetised rats, 10 μg/kg (i.v.) venom produced rapid respiratory and cardiovascular collapse while 5 μg/kg (i.v.) venom produced only a small transient decrease in mean arterial blood pressure. Prior administration of 5 μg/kg (i.v.) venom enabled subsequent administration of 10 and 100 μg/kg (i.v.) venom without respiratory or cardiovascular collapse. Further work is required to identify specific toxins with the above pharmacological activity.     

The mass of venom injected by two elapidae: the taipan (Oxyuranus scutellatus) and the Australian tiger snake (Notechis scutatus)

Using an enzyme immunoassay technique, a new method for measuring, in vivo, the mass of venom injected during snake bite, is presented. The venom injected into mice (as prey) and the venom left on the skin surface during bites by the two Australian Elapidae, the Taipan (Oxyuranus scutellatus) and the Tiger Snake (Notechus scutatus) has been measured. Venom delivery patterns vary significantly between these two species. In the case of the Tiger Snake (a total of 45 bites studied) the mean mass of venom injected in a first bite was 12.7 mg (S.E. 3.4 mg, median 8.1 mg); an average mass of 0.8 mg (S.E. 0.4 mg, median 0.17 mg) was left on the skin surface. A second bite delivered by the same snake yielded a mean venom mass only 27% of the first. In the case of the Taipan (a total of 24 bites) the mean venom mass injected in the first bite was 20.8 mg (S.E. 6.4 mg); with an average of 0.9 mg (S.E. 0.5 mg) left on the skin surface. In contrast to the situation observed with Tiger Snakes, second and third bites delivered in a rapid sequence yielded increasing masses of venom. The mean delivered in the third of a sequence of three bites was 48.8 mg (S.E. 23.8 mg). The ranges of venom mass, by species and by the sequence number of the bite, are also presented. In 66 of the 69 experimental bites studied in this report, venom could be easily detected, the species identified, and the absolute mass of venom measured.     

Digestive properties of the venom of the Australian Coastal Taipan, Oxyuranus scutellatus (Peters, 1867).

The digestive properties of Australian elapid snake venoms have not been studied to any great extent. To address this, the in vitro digestive properties of Oxyuranus scutellatus (Australian Coastal Taipan) venom were investigated in a simulation of the in vivo conditions using the parameters reported for the stomach of snakes and representative prey for this species. The amount of soluble protein released was measured over time using a bicinchoninic acid (BCA) assay. Dismembered mouse hindlegs were injected intramuscularly with 0.1 ml O. scutellatus venom (concentration 10 mg/ml) and maintained in a micro-anaerobic, acidic environment (pH approximately 1.2-1.7) at 25 degrees C. The bathing liquid was sampled every 24 h for 7 days, and assayed for soluble protein. Statistical analysis revealed that O. scutellatus venom increased the rate at which proteins were released when compared to a negative control suggesting the potential importance of envenomation in the digestion of whole prey.     

The neuromuscular activity of paradoxin: a presynaptic neurotoxin from the venom of the inland taipan (Oxyuranus microlepidotus)

The inland taipan is the world's most venomous snake. However, little is known about the neuromuscular activity of the venom or paradoxin (PDX), a presynaptic neurotoxin from the venom. Venom (10 μg/ml) and PDX (65 nM) abolished indirect twitches of the chick biventer cervicis and mouse phrenic nerve diaphragm preparations. The time to 90% inhibition by PDX was significantly increased by replacing Ca²⁺ (2.5 mM) in the physiological solution with Sr²⁺ (10 mM). In the biventer cervicis muscle, venom (10 μg/ml), but not PDX (65 nM), significantly inhibited responses to ACh (1 mM) and carbachol (20 μM), but not KCl (40 mM). In the mouse diaphragm (low Ca²⁺; room temperature), the inhibitory effect of PDX (6.5 nM) was delayed and a transient increase (746 ± 64%; n = 5) of contractions observed. In intracellular recording experiments using the mouse hemidiaphragm, PDX (6.5-65 nM) significantly increased quantal content and miniature endplate potential frequency prior to blocking evoked release of acetylcholine. In extracellular recording experiments using the mouse triangularis sterni, PDX (2.2-65 nM) significantly inhibited the voltage-dependent K⁺, but not Na⁺, waveform. In patch clamp experiments using B82 mouse fibroblasts stably transfected with rKv 1.2, PDX (22 nM; n = 3) had no significant effect on currents evoked by 10 mV step depolarisations from −60 to +20 mV. PDX exhibits all the pharmacology associated with β-neurotoxins, and appears to be one of the most potent, if not the most potent β-neurotoxin yet discovered.     

In vivo and in vitro cardiovascular effects of Papuan taipan (Oxyuranus scutellatus) venom: Exploring "sudden collapse"

'Sudden collapse' following envenoming by some Australasian elapids is a poorly understood cause of mortality. We have previously shown that Oxyuranus scutellatus venom causes cardiovascular collapse in anaesthetized rats. Prior administration of a sub lethal dose of venom attenuated the response to subsequent administration of higher (lethal) venom doses. In this study, we investigated the possible mechanisms mediating this 'protective effect'. Papuan taipan venom (5μg/kg, i.v.) produced a small transient hypotension in anaesthetized rats, while 10μg/kg resulted in a 73±12% decrease in arterial pressure. Venom (20μg/kg or 50μg/kg) produced cardiovascular collapse in all animals tested (n=12). Cardiovascular collapse by 50μg/kg venom was prevented by prior administration of 'priming' doses of venom (5, 10 and 20μg/kg). Also, prior administration of indomethacin (30mg/kg, i.v.) or heparin (300units/kg, i.v.) prevented sudden collapse induced by venom (20μg/kg). Venom was without effect in isolated hearts indicating that a direct cardiac effect was unlikely to be responsible for 'sudden collapse'. Venom induced endothelium-dependent and -independent relaxation in pre-contracted rat mesenteric artery rings which was inhibited by indomethacin, IbTx and Rp-8-CPT-cAMPs. This relaxation was markedly reduced upon second exposure. Our results indicate that cardiovascular collapse induced by O. scutellatus venom may be due to a combination of release of dilator autacoids and to direct relaxation of vascular smooth muscle involving the cAMP/protein kinase A cascade. Further work will involve identification of the venom component(s) responsible for this action and may provide insight into the management of envenomed patients.     

The effects of antivenom on the in vitro neurotoxicity of venoms from the taipans Oxyuranus scutellatus, Oxyuranus microlepidotus and Oxyuranus scutellatus canni.

The venoms of the inland (Oxyuranus microlepidotus), coastal (O. scutellatus) and Papuan (O. s. canni) taipans are among the most potent in the world. The present study compared the in vitro neurotoxic effects of these venoms and the protective effects of taipan antivenom. Venom (10 μg/ml) from all three snakes abolished nerve-mediated twitches of the chick biventer cervicis muscle preparation with the following rank order of potency (based on the time taken to inhibit 90% of the twitch response; t₉₀): O. microlepidotus (27±3 min)>O. scutellatus (42±3 min)=O. S. canni (48±5 min). This inhibitory effect of all three venoms was primarily postsynaptic in origin as evidenced by the inhibition of responses to exogenous acetylcholine (ACh; 1 mM) and carbachol (CCh; 20 μM), but not potassium chloride (40 mM). In contrast, the presynaptic neurotoxins taipoxin (3 μg/ml) and paradoxin (3 μg/ml) abolished nerve-mediated twitches without producing a significant effect on contractile responses to exogenous agonists. Prior incubation of the tissue with taipan antivenom (1 unit/ml for 10 min) markedly attenuated the inhibitory effects of taipoxin (3 μg/ml) and paradoxin (3 μg/ml), as well as O. scutellatus (10 μg/ml) and O. s. canni (10 μg/ml) venom. However, in the presence of antivenom, O. microlepidotus venom (10 μg/ml) still abolished nerve-mediated twitches and responses to ACh and CCh. The results of the current study indicate that taipan antivenom, raised against O. scutellatus venom, is effective, in vitro, against the neurotoxic effects of venom from the Papuan and coastal taipans, as well as the presynaptic effects of venom from the inland taipan. However, the antivenom appears less effective against the postsynaptic effects of the latter. It is possible that inland taipan venom contains a component not neutralised by the antivenom which may contribute to the extreme potency of this venom.     

A pharmacological examination of venom from the Papuan taipan: (Oxyuranus scutellatus canni)

The Papuan taipan (Oxyuranus scutellatus canni) is the third most venomous terrestrial snake in the world, however, little is know about the pharmacology of the venom. In the chick biventer cervicis muscle, venom (10 μg/ml) abolished nerve-mediated twitches (time to 90% inhibition (t₉₀) 44±5 min, n=9). This inhibition was unaffected by prior incubation of the venom with the phospholipase A inhibitor 4-bromophenacyl bromide (4-BPB; 0.72 mM) (t₉₀ 48±7 min, n=8). The mouse phrenic nerve diaphragm preparation displayed greater sensitivity to venom (10 μg/ml) (t₉₀ 25±1 min, n=6). In the chick biventer muscle, venom (10 μg/ml) significantly inhibited responses to acetylcholine (1 mM) and carbachol (20 μM), but not KCl (40 mM), indicating activity at post-synaptic nicotinic receptors. Venom (10 μg/ml) did not affect direct muscle stimulation. Venom (3–30 μg/ml) produced dose-dependant contractions of the guinea-pig ileum. Contractile responses were significantly inhibited by indomethacin (1 μM) or prior incubation of the venom with 4-BPB (0.72 mM) indicating involvement of a PLA component. In rat phenylephrine (0.3 μM) precontracted aortae, venom (3–100 μg/ml) produced endothelium-independent relaxation which was unaffected by prior incubation of venom (30 μg/ml) with 4-BPB (0.72 mM). In anaesthetised rats, 10 μg/kg (i.v.) venom produced rapid respiratory and cardiovascular collapse while 5 μg/kg (i.v.) venom produced only a small transient decrease in mean arterial blood pressure. Prior administration of 5 μg/kg (i.v.) venom enabled subsequent administration of 10 and 100 μg/kg (i.v.) venom without respiratory or cardiovascular collapse. Further work is required to identify specific toxins with the above pharmacological activity.     

Differential Myotoxic and Cytotoxic Activities of Pre‐synaptic Neurotoxins from Papuan Taipan (Oxyuranus scutellatus) and Irian Jayan Death Adder (Acanthophis rugosus) Venoms

Pre‐synaptic PLA₂ neurotoxins are important components of many Australasian elapid snake venoms. These toxins disrupt neurotransmitter release. Taipoxin, a pre‐synaptic neurotoxin isolated from the venom of the coastal taipan (Oxyuranus scutellatus), causes necrosis and muscle degeneration. The present study examined the myotoxic and cytotoxic activities of venoms from the Papuan taipan (O. scutellatus) and Irian Jayan death adder (Acanthophis rugosus), and also tested their pre‐synaptic neurotoxins: cannitoxin and P‐EPTX‐Ar1a. Based on size‐exclusion chromatography analysis, cannitoxin represents 16% of O. scutellatus venom, while P‐EPTX‐Ar1a represents 6% of A. rugosus venom. In the chick biventer cervicis nerve‐muscle preparation, A. rugosus venom displayed significantly higher myotoxic activity than O. scutellatus venom as indicated by inhibition of direct twitches, and an increase in baseline tension. Both cannitoxin and P‐EPTX‐Ar1a displayed marked myotoxic activity. A. rugosus venom (50–300 μg/ml) produced concentration‐dependent inhibition of cell proliferation in a rat skeletal muscle cell line (L6), while 300 μg/ml of O. scutellatus venom was required to inhibit cell proliferation, following 24‐hr incubation. P‐EPTX‐Ar1a had greater cytotoxicity than cannitoxin, inhibiting cell proliferation after 24‐hr incubation in L6 cells. Lactate dehydrogenase levels were increased after 1‐hr incubation with A. rugosus venom (100–250 μg/ml), O. scutellatus venom (200–250 μg/ml) and P‐EPTX‐Ar1a (1–2 μM), but not cannitoxin (1–2 μM), suggesting venoms/toxin generated cell necrosis. Thus, A. rugosus and O. scutellatus venoms possess different myotoxic and cytotoxic activities. The proportion of pre‐synaptic neurotoxin in the venoms and PLA₂ activity of the whole venoms are unlikely to be responsible for these activities.     

Isolation of subunits, α, β and γ of the complex taipoxin from the venom of Australian taipan snake (Oxyuranus s. scutellatus): characterization of β taipoxin as a potent mitogen

The venom of Australian taipan snake (Oxyuranus s. scutellatus) is extremely potent due to the presence of taipoxin. The intact complex molecule of taipoxin having molecular weight 45.6 kDa is composed of α, β and γ subunits. This report describes the high pressure liquid chromatography (HPLC) separation of α, β (β-1 and β-2) and γ subunits from taipan crude venom. The fractions containing the taipoxin subunits were further purified to obtain homogeneous proteins. The toxicity in mice showed the α subunit as most toxic, the γ subunit as moderately toxic and the β-1 and β-2 subunits were nontoxic. The proteins β-1 and β-2 were found to be mitogenic having neurotrophic activity on PC12 cells in culture similar to nerve growth factor. Immunologically, α, β-1, β-2 and γ subunits were found to be different, showing cross reactivity, and β-1 and β-2 were found to be identical for biological properties and molecular weight. Further characterization of unexpected mitogenic activity of β subunits is underway.     

Presynaptic effects of snake venom toxins which have phospholipase A2 activity (beta-bungarotoxin, taipoxin, crotoxin)

The presynaptic effects of beta-bungarotoxin, crotoxin and taipoxin were studied in the mouse phrenic nerve-diaphragm preparation (27 degrees C). The phospholipase A2 activity, assayed by pH-stat titration, was reduced to 4-10% at 27 degrees C compared with that at 37 degrees C. The late neuromuscular blocking activity was also reduced by more than three fold for all toxins. In contrast, the early biphasic response to the toxins, i.e. immediate depression followed by facilitation, was not delayed. The evoked quantal release of acetylcholine was enhanced by all toxins at low Ca2+-concentrations during the phase of facilitation, without an increase of the maximal release. At the late phase of treatment with beta-bungarotoxin and taipoxin, the curve relating the quantal contents of endplate potentials with Ca2+-concentration was shifted parallel to the right at low Ca2+, but marked depression of the maximal release occurred at high Ca2+. When diaminopyridine was added at the time of the late phase block by beta-bungarotoxin, the quantal release could still be enhanced at low Ca2+-concentrations, even beyond control; however, the maximal release was not simultaneously restored. It is concluded that the late phase block, but not the early biphasic response, is due to an enzymatic action and the release mechanism is abolished when the hydrolysis of membrane phospholipids proceeds to a certain critical level.     

The presynaptic activity of huwentoxin-I, a neurotoxin from the venom of the chinese bird spider Selenocosmia huwena.

Three different types of isolated nerve-synapse preparations, guinea pig ileum, rat vas deferens and toad heart, were used to investigate the physiological activity of Huwentoxin-I, a neurotoxin from the venom of the spider Selenocosmia huwena. The twitch response of isolated guinea pig ileum induced by electrical stimulus can be inhibited by HWTX-I. After blockage, contraction of the ileum can be induced by exogenously applied acetylcholine. HWTX-I caused the inhibition of the twitch response to electrical nerve stimulation in the rat vas deferens. After the twitch was completely inhibited, noradrenaline triggered rhythmic contraction of the vas deferens. The inhibitory effect on heart of toad induced by stimulating sympathetic-vagus nerve can be reversed by HWTX-I, although exogenously applied acetylcholine still acts as an effective inhibitor. All of these results support the conclusion that HWTX-I has the presynaptic activity that effects the release of neurotransmitter from the nerve endings of both the cholinergic synapse and the adrenergic synapse.     

Myotoxic activity of an acidic phospholipase A2 isolated from Lachesis muta (Bushmaster) snake venom.

An acidic phospholipase A2 isolated from Lachesis muta snake venom denoted LM-PLA2, showed neither toxic nor anticoagulant activities in contrast to a potent inhibitory effect of collagen-induced platelet aggregation [Fuly, A.L., Machado. O.L.T., Alves, E.W. and Carlini, C.R., 1997. Thromb. Haemost 78, 1372-1380.]. Now, the myotoxicity induced by LM-PLA2 was investigated by using both in vivo and in vitro experiments. LM-PLA2 induced in vitro a dose- and time-dependent release of creatine-kinase (CK) from mouse Extensor Digitorium Longus (EDL) muscles and also increased the plasma CK activity in treated animals. Histopathological studies confirm myonecrosis of mouse skeletal muscles as a major effect. Edema could also be seen in muscle tissue. The amino-terminal sequence of LM-PLA2 (previously reported) indicates an aspartic acid residue located at position 49, together with other conserved amino acids present in the Asp-49 phospholipases, such as Tyr-28, Gly-30, Gly-32, His-48. Chemical modification of the protein moiety was also performed. Histidine alkylation with p-bromophenacyl bromide and lysine acetylation with acetic anhydride, abolished both indirect hemolytic and myotoxic activities of LM-PLA2. On the other hand, contrarily to what has been observed with several basic myotoxic phospholipases, the myotoxic effect induced by LM-PLA2 was not abolished by heparin.     

Paralizing activity of the Parawixia bistriata crude venom in termites: a new bioassay.

Spider venoms have high specificity to neuronal elements. Therefore, the use of venom has been important in the characterisation of mammal and insect nervous systems. The evaluation of insect paralysis has been an important tool for distinguishing the biological effects of venom. In this study we describe the paralysing effect of a spider crude venom (Parawixia bistriata) in termites, utilising a new bioassay. The crude venom of P. bistriata caused an irreversible and dose-dependent paralysis in the animals in the following doses: 2.10(-5) U; 2.10(-4) U; 2.10(-3) U; 2.10(-2) U and 0.12 U (1 U = 1 gland). This bioassay will allow for easy and direct evaluation of biological effects from different venoms and purified fractions.     

Myotoxic effects of mastoparan from Polybia paulista (Hymenoptera, Epiponini) wasp venom in mice skeletal muscle.

In a previous study, we showed that the Polybia paulista wasp venom causes strong myonecrosis. This study was undertaken to characterize the myotoxic potency of mastoparan (Polybia-MPII) isolated from venom (0.25 microg/microl) and injected in the tibial anterior (TA) muscle (i.m.) of Balb/c mice. The time course of the changes was followed at muscle degenerative (3 and 24h) and regenerative (3, 7, and 21 days) periods (n=6) after injection and compared to matched controls by calculation of the percentage of cross-sectional area affected and determination of creatine kinase (CK) activity (n=10). The results showed that although MP was strongly myotoxic, its capacity for regeneration was maintained high. Since the extent of tissue damage was not correlated with the CK serum levels, which remained very low, we raised the hypothesis that the enzyme underwent denaturation by the peptide. Evidence suggested that MP induced the death of TA fibers by necrosis and apoptosis and had the sarcolemma as its primordial target. Given its amphiphilic polycationic nature and based on the vast spectrum of functions attributed to the peptide, we suggest that MP interaction with cell membrane impaired the phosphorylation of dystrophin essential for sarcolemma mechanical stability, and disturbed Ca2+ mobilization with obvious implications on sarcoplasmic reticulum and mitochondrial functioning.     

The effects of the subcutaneous injection of the crude venom of the Australian common brown snake, Pseudonaja textilis on the skeletal neuromuscular system.

1 The effects of the crude venom of the Australian common brown snake on the mammalian neuromuscular system have been investigated. 2 The venom was injected subcutaneously into the dorso-lateral aspect of one hind limb of the rat. The limb was paralyzed within 90 min and remained paralysed for 2 to 3 days. 3 The exposed muscles failed to respond to indirect excitation, and individual fibres were not depolarized at the nerve-muscle junction by exposure to carbachol. 4 The wet weight, histological appearance, resting potential and input resistance of the muscle fibres and their ability to generate directly elicited action potentials were unaffected by exposure to the venom. 5 Administration of venom to isolated preparations caused a reduction in the amplitude of miniature endplate potentials, with no change in frequency. The quantal content of evoked endplate potentials was unchanged. 6 It was concluded that the crude venom was largely devoid of presynaptic activity and myotoxicity, and that its primary site of neurotoxicity was directed to the postsynaptic membrane.     

Isolation and characterization of Jingzhaotoxin-V, a novel neurotoxin from the venom of the spider Chilobrachys jingzhao.

Jingzhaotoxin-V (JZTX-V), a 29-residue polypeptide, is derived from the venom of the spider Chilobrachys jingzhao. Its cDNA determined by rapid amplification of 3' and 5'-cDNA ends encoded an 83-residue precursor with a pro-region of 16 residues. JZTX-V inhibits tetrodotoxin-resistant and tetrodotoxin-sensitive sodium currents in rat dorsal root ganglion neurons with IC50 values of 27.6 and 30.2 nM, respectively. Moreover, the toxin exhibits high affinity to the resting closed states of the channels. JZTX-V also inhibits Kv4.2 potassium currents expressed in Xenpus Laevis oocytes (IC50=604.2 nM), but has no effects on outward delay-rectified potassium channels expressed in Xenopus laevis oocytes. JZTX-V alters the gating properties of sodium channels by shifting the activation curves to the depolarizing direction and the inactivation curves to the hyperpolarizing direction. Small unilamellar vesicles binding assays show that the partitioning of JZTX-V into lipid bilayer requires negatively charged phospholipids. The phospholipid membrane binding activity of JZTX-V is also verified using intrinsic tryptophan fluorescence analysis as well as acrylamide-quenching assays. Importantly, human multiple sodium channel subtypes are attractive targets for treatment of pain, highlighting the importance of JZTX-V as potential lead for drug development.     

Primary structure of gamma-bungarotoxin, a new postsynaptic neurotoxin from venom of Bungarus multicinctus.

The primary structure of gamma-bungarotoxin, a new toxin from Bungarus multicinctus venom, was determined using mass spectrometry and Edman degradation. The toxin has a mass of 7524.7 D and consists of 68 residues having the following sequence: MQCKTCSFYT CPNSETCPDG KNICVKRSWT AVRGDGPKRE IRRECAATCP PSKLGLTVFC CTTDNCNH. Gamma-bungarotoxin is structurally similar to both kappa-bungarotoxin and elapid long postsynaptic neurotoxins. Its C-terminal nine residues are identical to those of the kappa-toxins. Its disulfide bond locations appear identical to those of several elapid toxins of unknown pharmacology and its hydrophobicity profile is also strikingly similar. However, with an LD50 of 0.15 microg/g i.v. in mice, gamma-bungarotoxin is 30-150-fold more toxic than other members of this latter class. Its toxicity is comparable to those of alpha-nicotinic acetylcholine receptor antagonists.