Neurotransmitter receptors as targets for pesticides

Abstract

Nicotinic and muscarinic acetylcholine (ACh) receptors have been identified biochemically by means of their specific binding of [³H]α‐bungarotoxin ([³H]α‐BGT) and [³H]quinuclidinyl benzilate, respectively. There are some differences in the drug specificities, and sensitivities to active group reagents, of these receptors in insects when compared to those in vertebrates. Also, insect brain contains more nicotinic than muscarinic receptors, while the reverse is found in mammalian brain. Insect brain contains a third kind of putative ACh‐receptor that is relatively soluble and is both nicotinic and muscarinic in its pharmacology but does not bind α‐BGT. Toxic nicotine and analogs bind to it with high affinities. Several organophosphorus and carbamate insecticides and nereistoxin bind with high affinities to the nicotinic ACh‐receptor of the electric organ of Torpedo. A few chlorinated hydrocarbon insecticides and derivatives interact with Torpedo nicotinic ACh‐receptors, not at their ‘receptor’ sites but at their allosteric or ‘channel’ sites (which are identified by their specific binding of [³H]perhydrohistrionicotoxin). A few also bind to mammalian brain muscarinic receptors. The most potent on both receptors is the acaricide chlorobenzilate. Pyrethrins and synthetic pyrethroids also bind with high affinities to the channel sites of the Torpedo nicotinic ACh‐receptor, though not to its receptor sites. Another group that binds to ACh‐receptors is the organic and inorganic mercury compounds, which interact with both the Torpedo nicotinic and rat brain muscarinic receptors. Thus, neurotransmitter receptors act as molecular targets, primary or secondary for different pesticides.