Fasciculins toxicity

Onchidal and fasciculins are natural toxins, which produce their toxicity in mammalian systems by virtue of primarily acetylcholinesterase (AChE) inhibition. AChE hydrolyzes and inactivates acetylcholine, thereby regidating the concentration of the transmitter at the synapse. Termination of activation is normally dependent on dissociation of acetylcholine from the receptor and its subsequent diffusion and hydrolysis, except in diseases where acetylcholine levels are limiting or under AChE inhibition, conditions that increase the duration of receptor activation (Silver, 1963). 

The fasciculins are a family of closely related peptides that are isolated from the venom of mambas and exert their toxic action by inhibiting AChE. The crystal structure of fasciculin 2 from green mamba Dendroaspis angusticeps) snake venom was first resolved in 1992 (Le Du et al., 1992). The three-dimensional (3D) structure of fasciculin 1 obtained from the US National Library of Medicine, National Center for Biotechnology Information, MMDB database is illustrated in Figure 11.2. 

There is limited information about the toxicity, toxicokinetics, and toxicological properties of onchidal and additional data are needed to make a health effects-based risk assessment of the natural compound. Although fasciculins are much better known, data on toxicological properties and toxicokinetics will be of interest and usefiil for risk assessments despite it being generally accepted that the toxicity of this proteinic toxin occurs at very low doses. 

Onchidal and fasciculins are interesting natural compounds and it is difficult to predict their toxicity. In the case of onchidal, in silico computational predictive modeling for toxic endpoints of interest may prove useful for risk assessment decision support. Likewise, it is a challenge to predict the mditary potential and human impact of these natural toxins since their affinity for enzyme inhibition depends upon the amount and duration of the human exposure. 

In order to maximise the toxic potential of their venoms, many snakes have several toxins in their venoms which act by different biochemical mechanisms. This is an ingenious ploy which means that more than one of the bod/s vital systems is hit by the venom so making death more certain than if only one were hit. The Black Mamba is an excellent example of a snake with multiple toxic components in its venom. In addition to the fasciculins. Mamba venom has dendrotoxins which inhibit neurotransmission by blocking the exchange of + and - ions across the neuronal membrane. This prevents passage of the nerve impulse. If the impulse is en route to the big toe the toe will be paralysed — this is certainly not life-threatening. However, if the impulse is to the pulmonary muscles, respiratory failure and death will result. The dendrotoxins from the Black Mamba are very much less toxic than the fasciculins (it would take 1.6 g to kill a person), however the combined effect of the two toxins is far more toxic than the toxicities of the individual components (this is termed synergy) which is why the Black Mamba is lethal to humans. 

---