Neurotoxins venom

Watters (2005). Watters MR. Tropical marine neurotoxins venom to dmgs. Sem Neurol 2005 25(3) 278-289. 

Turning now to chemical attack, many predators immobilize their prey by injecting toxins, often neurotoxins, into them. Examples include venomous snakes, spiders, and scorpions. Some spider toxins (Quick and Usherwood 1990 Figure 1.3) are neurotoxic through antagonistic action upon glutamate receptors. The venom of some scorpions contains polypeptide neurotoxins that bind to the sodium channel. 

Neurotoxins from Sea Snake and Other Vertebrate Venoms... 

Neurotoxins present in sea snake venoms are summarized. All sea snake venoms are extremely toxic, with low LD5Q values. Most sea snake neurotoxins consist of only 60-62 amino acid residues with 4 disulOde bonds, while some consist of 70 amino acids with 5 disulfide bonds. The origin of toxicity is due to the attachment of 2 neurotoxin molecules to 2 a subunits of an acetylcholine receptor that is composed of a2 6 subunits. The complete structure of several of the sea snake neurotoxins have been worked out. Through chemical modification studies the invariant tryptophan and tyrosine residues of post-synaptic neurotoxins were shown to be of a critical nature to the toxicity function of the molecule. Lysine and arginine are also believed to be important. Other marine vertebrate venoms are not well known. 

All sea snakes are poisonous and their venoms are extremely toxic. The LD q for crude sea snake venom can be as low as 0.10 fig/g mouse body weight (i). For purified toxin the LD q is even lower, suggesting the high toxicity of sea snake toxins and venoms. This toxicity is derived from the presence of potent neurotoxins. Compared to snake venoms of terrestrial origin, sea snake venoms have been studied less. Different enzymes reported to be present or absent are summarized in Table I. 

Before discussing the structure of the neurotoxins, it is necessary to define the types of neurotoxins. Three types of neurotoxins have been found so far in snake venoms. The first one is a postsynaptic neurotoxin, the second is a presynaptic neurotoxin, and the last is a cholinesterase inhibiting neurotoxin. Most sea snake venoms seem to contain only the postsynaptic neurotoxin. Only in Enhydrina... 

Another type of neurotoxin found in sea snake venoms is a hybrid type structurally situated between the short-chain and long-chain types. As can be seen in Table IV, two toxins shown here have a long stretch of segment 4, yet there is no disulfide bond in this portion. 

A cloned complementary DNA to a neurotoxin precursor RNA extracted from the venom glands of Laticauda semifasciata was isolated and its nucleotide sequence was identified 11). The cloning of neurotoxin should aid the understanding of structure—function relationship eventually. 

The similarity of the primary structure of different sea snake venoms has already been discussed. Postsynaptic neurotoxins from Elapidae venom have been extensively studied. Elapidae include well-known snakes such as cobra, krait, mambas, coral snakes, and all Australian snakes. Like sea snake toxins, Elapidae toxins can also be grouped into short-chain (Type I) and long-chain (Type II) toxins. Moreover, two types of neurotoxins are also similar to cardiotoxins, especially in the positions of disulfide bonds. However, amino acid sequences between cardiotoxins and sea snake and Elapidae neurotoxins are quite different. In comparing the sequence of sea snake and Elapidae neurotoxins, there is a considerable conservation in amino acid sequence, but the difference is greater than among the various sea snake toxins. 

While most investigations show that sea snake neurotoxins are postsynaptic type, Gawade and Gaitonde (23) stated that Enhydrina schistosa major toxin has dual actions or postsynaptic as well as presynaptic toxicity. E, schistosa venom phospholipase A is both neurotoxic and myotoxic. Neurotoxic action of the enzyme is weak so that there is sufficient time for myonecrotic action to take place (24), Sea snake, L. semifasciata toxin also inhibits transmission in autonomic ganglia, but has no effect on transmission in choroid neurons. 

Mixture of neurotoxins that block the acetylcholine receptors. The /3-bungarotoxin is a pre-synaptic neural toxin, a-bungarotoxin is a postsynaptic neural toxin, and K-bungarotoxin is specific to the neuronal receptors in ganglions. They are obtained from the venom of the banded krait (Bungarus multicinctus). 

Neurotoxin that produces a massive release of transmitters from cholinergic and adrenergic nerve endings resulting in continuous stimulation of muscles. It also induces formation of an ion channel allowing the inward flow of calcium ions into the nerve cell. It is a white powder obtained from the venom of the black widow spider. 

Neurotoxin obtained from the venom of the Australian taipan snake. 

Rapid-acting neurotoxin that binds to sodium channels in nerve tissue leading to an increase in the release of neurotransmitters. It is a solid obtained from the venom of the Brazilian scorpion Tityus serrulatus. 

It is of particular interest that polyamines closely related to CNS 2103 have been found not only in other spider species (29) but also in the venom of the solitary digger wasp Philanthus triangulum (32). The similarity of these wasp and spider neurotoxins provides a notable example of convergence in the evolution of secondary metabolites aimed at a common target. 

Since the rate constants of bimolecular diffusion-limited reactions in isotropic solution are proportional to T/ these data testify to the fact that the kt values are linearly dependent on the diffusion coefficient D in water, irrespective of whether the fluorophores are present on the surface of the macromolecule (human serum albumin, cobra neurotoxins, proteins A and B of the neurotoxic complex of venom) or are localized within the protein matrix (ribonuclease C2, azurin, L-asparaginase).1 36 1 The linear dependence of the functions l/Q and l/xF on x/t] indicates that the mobility of protein structures is correlated with the motions of solvent molecules, and this correlation results in similar mechanisms of quenching for both surface and interior sites of the macromolecule. 

Since predators of snakes (and humans) have to deal with snake venoms as defenses, they are included here, even though they serve in predation. Snake venoms are primarily enzymes (proteins), especially of the phospholipase A2 type, which breaks down cell membrane phospholipids hydrolytically. Other snake venoms such as cobrotoxin contain peptides with 60-70 amino acid residues. Pharmacologically, they have neurotoxic, cytotoxic, anticoagulant, and other effects. The neurotoxins, in turn, can have pre- or postsynaptic effects. Snake venoms with both neurotoxic and hemolytic effects on the heart are known as cardiotoxins. Cytotoxins attach to the cells of blood vessels and cause hemorrhage. Snake venom factors may stimulate or inhibit blood clotting. Finally, platelet-active factors can contribute to hemorrhage. 

Tsernoglou, D., Petsko, G. A., McQueen Jr., J. E. and Hermans J. (1977). Molecular graphics application to the structure determination of a snake venom neurotoxin. Science 197,1378-1380. 

Escoubas, P, Diochot, S. and Corzo, G. (2000). Structure and pharmacology of spider venom neurotoxins. Biochimie 82 893-907. 

Grishin, E. V. (1996). Neurotoxin from black widow spider venom. Structure and function. Advances in Experimental Medicine and Biology 391 231-236. 

Structure of erabutoxin b. Many snake venom neurotoxins have similar structures with conserved disulfide bridge positions. See Hatanaka, H. et. al.513... 

Bacteria, protozoa, and venomous animals synthesize numerous toxins that are used to kill their prey or to defend themselves. Sea anemones, jellyfish, cone snails, insects, spiders, scorpions, and snakes all make potent and highly specific neurotoxins. Plants form a host of alkaloids and other specialized products, some of which are specifically neurotoxic and able to deter predators. More than 500 species of marine cone snails of the genus Conus synthesize a vast array of polypeptide toxins (conotoxins), 487-489 some with unusual posttranslational modifications.490 491 The slow-moving snails are voracious predators that use their toxins, which they inject with a disposible harpoonlike tooth,492 to paralyze fish, molluscs, or worms.493... 

Presynaptic snake neurotoxins endowed with PLA2 activity (SPANs) are major components of the venom of four families of venomous snakes (Crotalidae, Elapidae, Hydrophiidae, and Viperidae). These neurotoxins play a crucial role in envenomation of the prey (Harris 1997) by causing a persistent blockade of neurotransmitter release from nerve terminals with a peripheral paralysis very similar to that of botulism (Connolly et al. 1995 Gutidrrez et al. 2006 Kularatne 2002 Prasampun et al. 2005 Theakston et al. 1990 Trevett et al. 1995 Warrell et al. 1983). 

Features of Envenoming from Bites of Snakes Producing Venoms Containing Large Amounts ofPLA2 Presynaptic Neurotoxins... 

Abe T, Alemd S, Miledi R (1977) Isolation and characterization of presynaptically acting neurotoxins from the venom of bungarus snakes. Eur J Biochem 80 1-12... 

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