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Neurotoxin attachment

In order to understand the exact mechanism of the neurotoxic action, it is important to know the secondary structure of the neurotoxins as well. It is now known that postsynaptic neurotoxins attach to the a-subunits of acetylcholine receptor (AChR). [Pg.338]

The AChR is composed of five subunits, ql2Pi - A neurotoxin attaches to the a subunit. Since there are 2 mol of the a subunits, 2 mol of neurotoxins attach to 1 mol of AChR. A neurotransmitter, acetylcholine (ACh), also attaches to the a subunit. When the ACh attaches to the AChR, the AChR changes conformation, opening up the transmembrane pore so that cations (Na" ", K ) can pass through. By this mechanism the depolarization wave from a nerve is now conveyed to a muscle. The difference between neurotoxin and ACh is that the former s attachment does not open the transmembrane pore. As a consequence, the nerve impulse from a nerve cannot be transmitted through the postsynaptic site (27). [Pg.344]

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. [Pg.336]

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. [Pg.257]

Tetanus is characterised by a prolonged contraction of skeletal muscle fibres the neurotoxin responsible is from Clostridium tetani. The toxin initially binds to peripheral nerve terminals and is then transported within the axon and across synaptic junctions until it reaches the central nervous system (CNS). Here it attaches to ganghosides at the presynaptic inhibitory motor nerve endings and is taken up into the axon by endocytosis. The effect of the toxin is to block the release of inhibitory neurotransmitters (glycine and gamma-amino butyric acid), which are required to check the nervous impulse, leading to the generalised muscular spasms characteristic of tetanus. [Pg.260]

Before further discussing the action of postsynaptic neurotoxins, it would be useful to review normal nerve transmission very briefly. When a normal nerve impulse (depolarization wave) passes through the axon and reaches the end of that axon, the calcium ion concentration is increased and the neurotransmitter, acetylcholine (ACh), is suddenly released from the vesicle at the end of the nerve. Acetylcholine moves across the synaptic crevice and reaches the acetylcholine receptor in the muscle. The AChR is composed of five subunits, a2,PyS. When two molecules of acetylcholine attach to the a-subunits, the AChR... [Pg.41]

Postsynaptic neurotoxins are composed mainly of an antiparallel (3-sheet and a p-tum structure, with only a small amount of a-helical structure (Yu et al., 1975 Tu, 1990 Betzel et al., 1991 LeGoas et al., 1992 Yu et al., 1990 Tu et al., 1976). The toxin is comprised of three loops. A, B, and C (Fig. 4). Loop B is considered most important, and it is believed that this loop is attached to the acetylcholine-binding site of the AChR. Loop B is also the antigenic determinant. [Pg.43]

Figure 6. Attachment of a neurotoxin to the same site as that of acetylcholine causes the AChR to fail in forming an ion channel in the membrane. Figure 6. Attachment of a neurotoxin to the same site as that of acetylcholine causes the AChR to fail in forming an ion channel in the membrane.
See other pages where Neurotoxin attachment is mentioned: [Pg.490]    [Pg.101]    [Pg.121]    [Pg.200]    [Pg.353]    [Pg.605]    [Pg.115]    [Pg.266]    [Pg.193]    [Pg.490]    [Pg.219]    [Pg.654]    [Pg.476]    [Pg.120]    [Pg.888]    [Pg.676]    [Pg.251]    [Pg.183]    [Pg.35]    [Pg.23]    [Pg.67]    [Pg.381]    [Pg.41]    [Pg.91]    [Pg.485]    [Pg.491]   
See also in sourсe #XX -- [ Pg.45 ]



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Neurotoxin

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