John E. Casida

Neuroactive insecticides: targets, selectivity, resistance, and secondary effects.

Neuroactive insecticides are the principal means of protecting crops, people, livestock, and pets from pest insect attack and disease transmission. Currently, the four major nerve targets are acetylcholinesterase for organophosphates and methylcarbamates, the nicotinic acetylcholine receptor for neonicotinoids, the γ-aminobutyric acid receptor/chloride channel for polychlorocyclohexanes and fiproles, and the voltage-gated sodium channel for pyrethroids and dichlorodiphenyltrichloroethane. Species selectivity and acquired resistance are attributable in part to structural differences in binding subsites, receptor subunit interfaces, or transmembrane regions. Additional targets are sites in the sodium channel (indoxacarb and metaflumizone), the glutamate-gated chloride channel (avermectins), the octopamine receptor (amitraz metabolite), and the calcium-activated calcium channel (diamides). Secondary toxic effects in mammals from off-target serine hydrolase inhibition include organophosphate-induced delayed neuropathy and disruption of the cannabinoid system. Possible associations between pesticides and Parkinsons and Alzheimers diseases are proposed but not established based on epidemiological observations and mechanistic considerations.

Two classes of pyrethroid action in the cockroach

Abstract Pyrethroids are divided into two classes (Types I and II) based on their effects on the cercal sensory nerves recorded in vivo and in vitro and on the symptomology they produce in dosed cockroaches, Periplaneta americana . Type I compounds include pyrethrins, S -bioallethrin, [1 R,cis ]resmethrin, kadethrin, the 1 R,trans and 1 R,cis isomers of tetramethrin, phenothrin, and permethrin, and an oxime O -phenoxybenzyl ether. Electrophysiological recordings from dosed individuals reveal trains of cercal sensory spikes and sometimes also spike trains from the cercal motor nerves and in the CNS. Low concentrations of these pyrethroids act in vitro to induce repetitive firing in a cercal sensory nerve following a single electrical stimulus. This in vitro measurement, standardized for evaluating structure-activity relationships, shows that only 1 R , insecticidal isomers are highly effective neurotoxins. The most potent compounds on the isolated nerve are [1 R,trans ]- and [1 R,cis ]tetramethrin, each active at 3 × 10 −13 M . The poisoning symptoms of Type I compounds are restlessness, incoordination, hyperactivity, prostration, and paralysis. Type II compounds include [1 R,cis ,α S ]- and [1 R,trans ,α S ]cypermethrin, deltamethrin, and [ S,S ]fenvalerate. These α-cyanophenoxybenzyl pyrethroids do not induce repetitive firing in the cercal sensory nerves either in vivo or in vitro ; moreover, they cause different symptoms, including a pronounced convulsive phase. Two other pyrethroids with an α-cyano substituent, i.e., fenpropathrin and an oxime O -α-cyanophenoxybenzyl ether, are classified as Type I based on their action on a cercal sensory nerve but the symptoms with these compounds resemble Type II. The two classes of pyrethroid action evident with the cockroach are discussed relative to their neurophysiological effects and symptomology in other organisms.

The calcium-ryanodine receptor complex of skeletal and cardiac muscle

[3H]Ryanodine binds with high affinity to saturable and Ca2+-dependent sites in heavy sarcoplasmic reticulum (SR) preparations from rabbit skeletal and cardiac muscle. Ruthenium red, known to interfere with Ca2+-induced Ca2+ release from SR vesicles, inhibits [3H]ryanodine specific binding in both skeletal and cardiac preparations whereas Mg2+, Ba2+, Cd2+ and La3+ selectively inhibit the skeletal preparation. The toxicological relevance of the [3H]ryanodine binding site is established by the correlation of binding inhibition with toxicity for seven ryanoids including two botanical insecticides. These findings provide direct evidence for Ca2+-ryanodine receptor complexes that may play a role in excitation-contraction coupling.

Interaction of 1-Methyl-4-Phenylpyridinium Ion (MPP+) and Its Analogs with the Rotenone/Piericidin Binding Site of NADH Dehydrogenase

Abstract: Nigrostriatal cell death in 1‐methyl‐4‐phenyl‐1,2,3,6‐tetrahydropyridine (MPTP)‐induced Parkinsons disease results from the inhibition of mitochondrial respiration by 1‐methyl‐4‐phenylpyridinium (MPP+). MPP+ blocks electron flow from NADH dehydrogenase to coenzyme Q at or near the same site as do rotenone and piericidin and protects against binding of and loss of activity due to these inhibitors. The 4′‐analogs of MPP+ showed increasing affinity for the site with increasing length of alkyl chain, with the lowest Ki, for 4′‐heptyl‐MPP+, being 6 μM. The 4′‐analogs compete with rotenone for the binding site in a concentration‐dependent manner. They protect the activity of the enzyme from inhibition by piericidin in parallel to preventing its binding, indicating that the analogs and piericidin bind at the same inhibitory site(s). The optimum protection, however, was afforded by 4′‐propyl‐MPP+. The lesser protection by the more lipophilic MPP+ analogs with longer alkyl chains may involve a different orientation in the hydrophobic cleft, allowing rotenone and piericidin to still bind even when the pyridinium cation is in a position to interrupt electron flow from NADH to coenzyme Q.

Interactions of lindane, toxaphene and cyclodienes with brain-specific t-butylbicyclophosphorothionate receptor☆

Three major classes of chlorinated hydrocarbon insecticides, i.e., the lindane/hexachlorocyclohexane, toxaphene and aldrin/dieldrin types, are potent, competitive, and stereospecific inhibitors of t-butylbicyclophosphorothionate (TBPS) binding to brain-specific sites, thereby indicating an action at the gamma-aminobutyric acid (GABA)-regulated chloride channel. The most inhibitory and toxic of four isomers of hexachlorocyclohexane is lindane and of greater than 188 components of toxaphene is 2,2,5-endo, 6-exo,8,9,9,10-octachlorobornane. 12-Ketoendrin (IC50 = 36 nM) is twice as active as the most potent previously known inhibitor of TBPS binding and it is also the most inhibitory and toxic of 22 cyclodienes examined. Within each of these three series of polychlorocycloalkanes the mammalian toxicity is closely related to the potency for inhibition of TBPS binding. A modified receptor assay incorporating liver microsomes and reduced nicotinamide-adenine dinucleotide phosphate compensates in part for oxidative detoxification and bioactivation. Specific TBPS binding is reduced in a dose-dependent manner in dieldrin-poisoned rats. DDT, mirex and kepone are not inhibitors of TBPS binding, even at 10 microM.

Dietary TH 6040 alters composition and enzyme activity of housefly larval cuticle

Abstract Housefly larvae of 2 days of age were allowed to grow in media containing 0, 0.4, 1.0, or 2.5 ppm TH 6040[1-(4-chlorophenyl)-3-(2,6-difluorobenzoyl)-urea] for 3 days prior to analysis of the cuticle for structural components (chitin and protein) or enzymes important in cuticle formation (chitinase and phenoloxidase). As the TH 6040 concentration is increased, the amount of chitin is progressively reduced such that, at 2.5 ppm TH 6040, the level is only 25% of normal. The amount of cuticle protein is unaffected so the protein: chitin ratio increases from 3.4 in the control larvae to 14.3 in 2.5 ppm-treated larvae, an alteration which probably affects the elasticity and firmness of the endocuticle. Dietary TH 6040 at 1.0 ppm increases the cuticle chitinase activity to about 180% and the cuticle phenoloxidase activity to 155% as compared with control larvae, with a further chitinase activity increase to 240% of normal at 2.5 ppm TH 6040. These enzyme changes are expected to hamper the build-up or maintenance of the cuticle chitin and enhance sclerotization of the exocuticle.

Pest toxicology: the primary mechanisms of pesticide action.

Pesticides are used to control pests before they harm us or our crops. They are selective toxicants in the form and manner used. Pesticides must be effective without human or crop injury. They must also be safe relative to human and environmental toxicology. The study of how the pesticide works on the pest is referred to here as pest toxicology. About 700 pesticides, including insecticides, herbicides, and fungicides, act on perhaps 95 biochemical targets in pest insects, weeds, and destructive fungi. Current insecticides act primarily on four nerve targets, i.e., acetylcholinesterase, the voltage-gated chloride channel, the acetylcholine receptor, and the gamma-aminobutyric acid receptor, systems which are present in animals but not plants. Herbicides act mostly on plant specific pathways by blocking photosynthesis, carotenoid synthesis, or aromatic and branched chain amino acid synthesis essential in plants but not mammals. Many fungicides block ergosterol (the fungal sterol) or tubulin biosynthesis or cytochrome c reductase, while others disrupt basic cellular functions. A major limiting factor in the continuing use of almost all pesticides is the selection of strains not only resistant to the selecting or pressuring compounds but also cross-resistant to other pesticides acting at the same target. One approach to reinstating control is to shift from compounds with the resistant target site or mode of action to another set which have a sensitive target. This type of pesticide management led to the formation of Resistance Action Committees for insecticides, herbicides, and fungicides with very knowledgable experts to define resistance groups, which are in fact listings of primary target sites in pest toxicology. Continued success in pest and pesticide management requires an understanding of comparative biochemistry and molecular toxicology considering pests, people, and crops. Defining and applying the principles of pest toxicology are critical to food production and human health.

Dichloroacetamide antidotes enhance thiocarbamate sulfoxide detoxification by elevating corn root glutathione content and glutathione S-transferase activity

Abstract Glutathione (GSH) content and GSH S -transferase activity are consistently increased in corn roots on 24-hr exposure of corn seedlings to part per million levels of N,N -diallyl-2,2-dichloroacetamide (R-25788) and related antidotes for thiocarbamate herbicide injury in susceptible corn varieties. This combined enhancement of enzyme activity and cofactor level leads to rapid detoxification of thiocarbamate sulfoxides, which are proposed to be the active herbicidal compounds formed on metabolic sulfoxidation. S -( N,N -Dipropylcarbamyl)-GSH is formed by this enzyme-catalyzed detoxification of EPTC sulfoxide. This hypothesis on antidote mode of action is supported by studies on 32 dichloroacetamides and related compounds and on the concentration- and time-dependent relationships of R-25788 action. The liver GSH content is normal in mice injected with high doses of R-25788, but the content is reduced when EPTC or EPTC sulfoxide is administered. EPTC sulfoxide also carbamoylates the thiol group of coenzyme A in neutral aqueous medium.

Pyrethroid toxicology: Mouse intracerebral structure-toxicity relationships☆

Abstract Mouse intracerebral (ic) toxicity studies with 29 pyrethroids confirm earlier mouse intraperitoneal (ip) and rat oral and intravenous findings in three respects: α-cyano-3-phenoxybenzyl esters produce choreoathetosis, convulsions, and salivation, whereas compounds lacking the α-cyano group yield tremors and convulsions; high stereospecificity is involved in inducing both poisoning syndromes; large toxicity differences for (1 R,trans ) vs (1 R,cis ) resmethrin and permethrin do not extend to ethanomethrin and the cyanophenoxybenzyl esters. The ic investigations further establish that: profuse salivation is not unique for pyrethroids with the α-cyano group; the inactivity of (1 R,trans ) resmethrin in the brain is not due to detoxification; pyrethroids acting most rapidly in the brain are those with the highest knockdown activity for insects; the cyanophenoxybenzyl esters, in comparison with the non-cyano pyrethroids, have a high ic toxicity relative to their synergized ip toxicity indicating the importance of the brain in the Type II poisoning syndrome.

Loss of neuropathy target esterase in mice links organophosphate exposure to hyperactivity

Neuropathy target esterase (NTE) is involved in neural development and is the target for neurodegeneration induced by selected organophosphorus pesticides and chemical warfare agents. We generated mice with disruptions in Nte, the gene encoding NTE. Nte−/− mice die after embryonic day 8, and Nte+/− mice have lower activity of Nte in the brain and higher mortality when exposed to the Nte-inhibiting compound ethyl octylphosphonofluoridate (EOPF) than do wild-type mice. Nte+/− and wild-type mice treated with 1 mg per kg of body weight of EOPF have elevated motor activity, showing that even minor reduction of Nte activity leads to hyperactivity. These studies show that genetic or chemical reduction of Nte activity results in a neurological phenotype of hyperactivity in mammals and indicate that EOPF toxicity occurs directly through inhibition of Nte without the requirement for Nte gain of function or aging.