Some effects on muscle and nerve of crude venom from the gastropod Conus striatus

A perspective on toxicology of Conus venom peptides

The evolutionarily unique and ecologically diverse family Conidae presents fundamental opportunities for marine pharmacology research and drug discovery. The focus of this investigation is to summarize the worldwide distribution of Conus and their species diversity with special reference to the Indian coast. In addition, this study will contribute to understanding the structural properties of conotoxin and therapeutic application of Conus venom peptides. Cone snails can inject a mix of various conotoxins and these venoms are their major weapon for prey capture, and may also have other biological purposes, and some of these conotoxins fatal to humans. Conus venoms contain a remarkable diversity of pharmacologically active small peptides; their targets are an iron channel and receptors in the neuromuscular system. Interspecific divergence is pronounced in venom peptide genes, which is generally attributed to their species specific biotic interactions. There is a notable interspecific divergence observed in venom peptide genes, which can be justified as of biotic interactions that stipulate species peculiar habitat and ecology of cone snails. There are several conopeptides used in clinical trials and one peptide (Ziconotide) has received FDA approval for treatment of pain. This perspective provides a comprehensive overview of the distribution of cone shells and focus on the molecular approach in documenting their taxonomy and diversity with special reference to geographic distribution of Indian cone snails, structure and properties of conopeptide and their pharmacological targets and future directions.

The marine biologist—Bob Endean

Bob Endean was a dedicated marine biologist with an extensive knowledge of coral reef communities in the Great Barrier Reef and fauna in subtropical Queensland waters. He commenced a study of venomous and poisonous marine animals dangerous to man at a time when the field was new, employing a variety of techniques to investigate the venom apparatus, mode of delivery of venom or toxin, mode of toxic action on excitable tissues, and biochemistry of venom or toxin. Determination of the pharmacological properties of crude venom from Conus marine snails advanced characterization of conotoxins by later workers. A study of four types of nematocysts from the box-jellyfish Chironex fleckeri provided information as to their structure, function, and mechanism of discharge; myotoxins T1 and T2 were isolated from microbasic mastigophores. Endean studied poisonous stonefish (Synanceia trachynis) and, with Ann Cameron, scorpionfish (Notesthes robusta); investigations of ciguatera and of paralytic shellfish poisoning were initiated. He organized the collection of Australian frogs which led to the isolation of caerulein by Erspamer in Italy. Endean highlighted the ecological danger of the population explosion of the crown-of-thorns starfish (Acanthaster planci) and provided the impetus for the creation of the Great Barrier Reef Marine Park.

The strategy used by some piscivorous cone snails to capture their prey: the effects of their venoms on vertebrates and on isolated neuromuscular preparations

Three piscivorous Conus species, C. ermineus, C. consor and C. catus were acclimatized in aquaria. The study of their strategy to capture the prey and details of their radula's morphology revealed that all of them used a 'hook and line' strategy which consists of immobilizing the prey rapidly before engulfing it. The venoms from these piscivorous species clearly elicit, when injected into fish, an excitotoxic shock characterized by a sudden tetanus of the prey. In mammals, the venoms induce both flaccid paralysis via i.p. injection and seizures via i.c.v. injection. Intracellular recordings from frog nerve-muscle preparations revealed that the venoms from these Conus species first caused spontaneous synaptic potentials which in turn triggered muscle action potentials. Such spontaneous activity is due to an increased nerve terminal excitability. In addition, the venoms suppressed neuromuscular transmission probably by blocking postsynaptic nicotinic acetylcholine receptors. No direct effect of these Conus venoms was observed on the membrane of skeletal muscle fibres. In conclusion, C. ermineus, C. consor and C. catus, which have not securely tethered their prey used a mixture of toxins which target both pre-and postsynaptic elements of the neuromuscular junction and which produce rapid immobilization of their prey.

The mechanism of the inotropic action of striatoxin, a novel polypeptide toxin from a marine snail, in isolated cardiac muscle

1. Striatoxin (StTX), a novel polypeptide from a marine snail, caused a dose-dependent increase in contractility in the isolated atria of guinea-pig and rat in the concentration-range of 2 x 10(-9) to 3 x 10(-8)M and 3 x 10(-6)M, respectively. 2. In guinea-pig atria, the StTX-induced inotropic effect was inhibited by tetrodotoxin but not by cimetidine or chlorpheniramine. Practolol, propranolol or reserpine caused only partial block of this inotropic action. 3. In isolated single cells from rat hearts, StTX caused an increase in the degree and the rate of contraction. 4. In guinea-pig atria, StTX provoked action potentials with a plateau phase of long duration without affecting the maximum rate of rise, the amplitude of action potential and the resting membrane potential. This prolongation was also reversed by tetrodotoxin. 5. In guinea-pig cardiac myocytes, whole-cell patch-clamp experiments showed that StTX slowed Na channel inactivation without affecting the time course of channel activation. The voltage dependence of Na currents was not altered by StTX. 6. The residual currents, but not peak currents were markedly enhanced by StTX. 7. These results suggest that StTX causes prolongation of the action potential duration probably due to slowed inactivation of Na inward currents and enhanced residual currents and that this may result in an increase in Ca2+ availability in cardiac muscle cells. This could explain the cardiotonic action of StTX.

Effects of venom from Conus striatus on the delayed rectifier potassium current of molluscan neurons

The effect of crude venom extracted from venom ducts of Conus striatus on the delayed rectifier potassium current (IK) of the marine mollusc Aplysia californica was studied using voltage clamp techniques. Initial experiments indicated that the venom had phospholipase activity which destroyed the cells. The use of phospholipase inhibitors prevented destruction of the cell and permitted long-term electrophysiological measurements to be made. Application of the venom to unclamped cells caused a dramatic increase in the frequency of action potentials associated with a depolarization of the membrane potential. A broadening of the action potential was also observed. Three separate effects of the venom were observed on IK in voltage clamped cells: an increase in peak current (effect I), a slowing of both the activation and inactivation kinetics (effect K) and a decrease in the peak current (effect D). All three effects were dose dependent and both effects on peak current were greater at more depolarized membrane potentials. The data suggest that the three effects on IK are caused by different components of the venom. Effect D appears to be caused by a heat-labile compound of molecular weight greater than 50,000, effect I by a heat-stable compound of less than 50,000 and effect K by a heat-stable compound of intermediate molecular size.

The Bushman arrow toxin, Diamphidia toxin: isolation from pupae of Diamphidia nigro-ornata

The Bushmen of the Kalahari Desert in Botswana use the pupae of the beetle Diamphidia nigro-ornata Ståhl to poison their arrows. Sequential aqueous extraction, ammonium sulfate precipitation, ultrafiltration and chromatofocusing have given an apparently homogeneous active protein from these pupae with an approximate mol. wt of 54,000, an isoelectric point of about 8.0 pH and a lethal potency (minimum lethal dose, MLD) between 5 and 20 micrograms/kg (i.p. mouse). Preliminary pharmacological studies on less purified material show that, after a delay, this Diamphidia toxin causes sustained contraction of isolated intestinal smooth muscle. This contraction is not blocked by atropine or mepyramine and, therefore, is not due to release of acetylcholine or histamine. Results on the phrenic nerve - hemidiaphragm preparation demonstrate that in the presence of the toxin, contraction in response to indirect stimulation gradually fails and is accompanied by contracture. Since direct stimulation of the muscle still elicits a contraction, the toxin apparently does not affect the contractile mechanism itself. We conclude that Diamphidia pupae contain a protein toxin that is responsible for its lethality. Although this toxin appears to differ in some properties from the toxins reported by Mebs et al., de la Harpe et al. and Kündig, these protein preparations undoubtedly correspond to each other. We did not find any evidence of the low molecular weight toxic component reported by Mebs et al.

Excitatory and inhibitory effects of a myotoxin from Conus magus venom on the mouse diaphragm, the guinea-pig atria, taenia caeci, ileum and vas deferens

A myotoxin purified from Conus magus venom elicited complete loss of contractile response of the mouse diaphragm to electrical stimulation followed by a gradual rise in the baseline, an increase in the contractile force of the guinea-pig left atria, a tonic contraction of the guniea-pig taenia caeci and powerful rhythmic contractions of the guinea-pig ileum and vas deferens. These excitatory effects of the toxin were blocked by treatment with tetrodotoxin, suggesting that these effects were due to an increase in Na+ permeability of the cell membrane.

Biphasic mechanical responses of the guinea-pig isolated ileum to the venom of the marine snail Conus striatus

Venom extract of Conus striatus elicited a rhythmic, transient contraction of the guinea-pig isolated ileum followed by a relaxation at concentrations greater than 1 microgram/ml, which was abolished by tetrodotoxin and a low-Na medium. The contraction induced by the venom was inhibited by atropine but not mecamylamine, whereas the relaxation was not affected by bretylium, guanethidine or phentolamine. These results suggest that the contraction of the ileum induced by the venom is due to the excitation of cholinergic nerves, while the relaxation is mediated through non-adrenergic inhibitory nerves.