The evolution of the insecticidal pyrazoline moiety that was originally discovered in 1972 has led to the discovery of a new crop insecticide, indoxacarb, which is the first commercialized pyrazoline-type sodium-channel blocker. Both monocyclic and fused-tricyclic pyrazolines and pyridazines, as well as structurally related semicarbazones were examined prior to the discovery of analogous tricyclic oxadiazines which had similarly high activity as well as favorable environmental dissipation rates and low toxicity to non-target organisms. The eventual leading candidate, DPX-JW062, was originally obtained as a racemic molecule, but a chiral synthesis was developed which produces material that is 50% ee in the insecticidal (+)-S-enantiomer (DPX-MP062, indoxacarb).
Title: RH 5849, a nonsteroidal ecdysone agonist: effects on a Drosophila cell line Wing KD Ref: Science, 241:467, 1988 : PubMed
The steroid molting hormone 20-hydroxyecdysone is the physiological inducer of molting and metamorphosis in insects. In ecdysone-sensitive Drosophila Kc cells, the insecticide RH 5849 (1,2-dibenzoyl-1-tert-butylhydrazine) mimics the action of 20-hydroxyecdysone by causing the formation of processes, an inhibition of cell proliferation, and induction of acetylcholinesterase. RH 5849 also competes with [3H]ponasterone A for high-affinity ecdysone receptor sites from Kc cell extracts. Resistant cell populations selected by growth in the continued presence of either RH 5849 or 20-hydroxyecdysone are insensitive to both compounds and exhibit a decreased titer of measurable ecdysone receptors. Although it is less potent than 20-hydroxyecdysone in both whole-cell and cell-free receptor assays, RH 5849 is the first nonsteroidal ecdysone agonist.
Title: Profenofos insecticide bioactivation in relation to antidote action and the stereospecificity of acetylcholinesterase inhibition, reactivation, and aging Glickman AH, Wing KD, Casida JE Ref: Toxicology & Applied Pharmacology, 73:16, 1984 : PubMed
Poisoning signs in chicks administered the organophosphorus insecticide profenofos correlated with in vivo inhibition of brain acetylcholinesterase (AChE) activity. Mixtures of atropine with eserine, pyridinium oximes, or the bispyridinium compound SAD-128 increased the LD50 of coadministered profenofos by up to sevenfold in chicks and fourfold in mice. Atropine and the oximes were less effective as profenofos antidotes, indicating that profenofos-inhibited AChE may undergo rapid aging. Brain AChE from chicks poisoned with profenofos was not reactivated by pralidoxime methanesulfonate, although it was from chicks poisoned with the phosphoramidothiolate, methamidophos. Similarly, eel AChE, inhibited in vitro by bioactivated (-)-profenofos, the most toxic isomer, did not reactivate in contrast to that inhibited by methamidophos, nonbioactivated (-)-profenofos, and (+)-profenofos, with or without bioactivation. It appears that the action of eserine and possibly SAD-128 was due to protecting AChE or cholinergic receptors from profenofos or bioactivated profenofos and that oximes may work in the same way rather than as reactivators due to rapid aging of the inhibited AChE.
