Flupyrimin: A Novel Insecticide Acting at the Nicotinic Acetylcholine Receptors.

A novel chemotype insecticide flupyrimin (FLP) [N-[(E)-1-(6-chloro-3-pyridinylmethyl)pyridin-2(1H)-ylidene]-2,2,2-trifluoroacetamide], discovered by Meiji Seika Pharma, has unique biological properties, including outstanding potency to imidacloprid (IMI)-resistant rice pests together with superior safety toward pollinators. Intriguingly, FLP acts as a nicotinic antagonist in American cockroach neurons, and [3H]FLP binds to the multiple high-affinity binding components in house fly nicotinic acetylcholine (ACh) receptor (nAChR) preparation. One of the [3H]FLP receptors is identical to the IMI receptor, and the alternative is IMI-insensitive subtype. Furthermore, FLP is favorably safe to rats as predicted by the very low affinity to the rat α4ß2 nAChR. Structure-activity relationships of FLP analogues in terms of receptor potency, featuring the pyridinylidene and trifluoroacetyl pharmacophores, were examined, thereby establishing the FLP molecular recognition at the Aplysia californica ACh-binding protein, a suitable structural surrogate of the insect nAChR. These FLP pharmacophores account for the excellent receptor affinity, accordingly revealing differences in its binding mechanism from IMI.

N-haloacetylimino neonicotinoids: potency and molecular recognition at the insect nicotinic receptor.

This structure-activity relationship study for neonicotinoids with an N-haloacetylimino pharmacophore identifies several candidate compounds showing outstanding insecticidal potency and consequently leads to establishing their molecular recognition at an insect nicotinic receptor structural model, wherein the neonicotinoid halogen atoms (fluorine, chlorine, bromine, and iodine) variously interact with the receptor loops C-D interfacial niche via H-bonding and/or hydrophobic interactions.

Furan-2,5-dimethylene-tethered bis-imidacloprid insecticide conferring high potency.

Bis-imidacloprid (bis-IMI) analogues with suitable alkylene spacers have plant-systemic insecticidal properties. The alkylene-tethered bis-IMI binds in a unique mode to the insect nicotinic acetylcholine receptor (nAChR) wherein the chloropyridine moieties are embraced by two distinct and distant domains. The heptamethylene spacer optimally bridges these two subsites, yet the linker itself binds in a relatively nonspecific manner. This investigation examines the hypothesis that a bis-IMI analogue with a heteroaromatic tether, which undergoes specific interaction(s) with the newly recognized receptor cavity, may enhance the potency relative to those of the alkylene-tethered derivatives. Remarkably, a novel bis-IMI with a furan-2,5-dimethylene fulcrum showed highest receptor potency and insecticidal activity among the analogues with various chemotype spacers. The nAChR structural model, simulating the binding site interactions of the furan-2,5-dimethylene-tethered bis-IMI, reveals that the furan ring is nestled in a hydrophobic pocket, consisting of three aromatic amino acids, and is stabilized via hydrogen bonding.

Structural features of phenoxycarbonylimino neonicotinoids acting at the insect nicotinic receptor.

Substituted-phenoxycarbonylimino neonicotinoid ligands with an electron-donating group showed significantly higher affinity to the insect nicotinic receptor relative to that of the analogue with an electron-withdrawing substituent, thereby establishing in silico binding site interaction model featuring that the phenoxy ring of neonicotinoids and the receptor loop D tryptophan indole plane form a face-to-edge aromatic interaction.

Trifluoroacetyl neonicotinoid insecticides with enhanced hydrophobicity and effectiveness.

Neonicotinoids with nitro- or cyanoimino substituents are extensively utilized as plant-mobile (systemic) insecticides controlling the piercing-sucking insect pests. This investigation considers structural features of neonicotinoids with trifluoroacetyl pharmacophores, which may confer enhanced hydrophobicity and effectiveness. Fifteen trifluoroacetyl neonicotinoid analogues [=NC(O)CF(3) and =CHC(O)CF(3)] are therefore prepared to evaluate the hydrophobicity index, toxicity to houseflies (Musca domestica), and binding affinity to the Musca nicotinic receptor. The =NC(O)CF(3) and =CHC(O)CF(3) compounds showed a higher hydrophobicity than that of nitro- or cyanoimino analogues. The intrinsic insecticidal activities (defined by intrathoracic injection with a synergist pretreatment) of test compounds were well-correlated to their target site potencies. Although nitro or cyano neonicotinoids were not toxic via the topical application route in the absence of a synergist, trifluoroacetyl analogues exhibited excellent insecticidal activity under the same condition. Accordingly, the increased hydrophobicity of trifluoroacetyl neonicotinoids presumably improves the penetrability of compound into insect integument and insecticidal effectiveness.

Crown-capped imidacloprid: a novel design and insecticidal activity.

Imidacloprid (IMI) derivatives conjugated with benzo-15-crown-5 and benzo-18-crown-6 structures, applied for the first time to explore novel insecticidal molecule, elicited strong excitatory toxic signs to the house flies and stunningly exhibited three to five times higher insecticidal activity than that of the parent IMI, yet the two benzo-crown structures themselves had no effect.

Bis-neonicotinoid insecticides: Observed and predicted binding interactions with the nicotinic receptor.

The bis-pharmacophore approach applied to neonicotinoid insecticides reveals high binding affinity for heptamethylene bis-N(3),N(3')-imidacloprid fitting a nicotinic acetylcholine receptor model wherein the chloropyridine moieties contact loops E and F and the alkylene linker bridges these two distant domains.

Neonicotinoid substituents forming a water bridge at the nicotinic acetylcholine receptor.

Neonicotinoid insecticides are extensively used for crop protection. The chloropyridinyl or chlorothiazolyl nitrogen and tetrahydrofuryl oxygen atoms of neonicotinoids serve as hydrogen acceptors at the target site. This investigation designs and prepares neonicotinoid probes to understand the structure-activity relationships (SARs) at the target site focusing on the water-mediated ligand-protein interactions. 2-Nitroiminoimidazolidine analogues with hydrogen-acceptor N-CH(2)CH(2)CH(2)F and N-CH(2)CH(2)C(O)CH(3) substituents showed higher binding affinities to the Drosophila melanogaster nicotinic receptor than probes with different hydrogen-bonding points in location and capability, suggesting that the appropriately positioned fluorine or carbonyl oxygen plays an important role on hydrogen-bond formation. Their binding site interactions were predicted using a crystal structure of the acetylcholine binding protein. The fluorine or carbonyl oxygen forms a water bridge to Ile-118 (and/or Ile-106) at the binding domain, consistent with that of neonicotinoids with a chloropyridinylmethyl, chlorothiazolylmethyl, or tetrahydrofurylmethyl moiety. Therefore, the present SAR study on binding site interactions helps design potent neonicotinoids with novel substituents.

Molecular features of neonicotinoid pharmacophore variants interacting with the insect nicotinic receptor.

Molecular interactions of neonicotinoid insecticides with the nicotinic acetylcholine receptor have been mapped by chemical and structural neurobiology approaches, thereby encouraging the biorational design of novel nicotinic ligands. This investigation designs, prepares, and evaluates the target site potency of neonicotinoid analogues with various types of electronegative pharmacophores and subsequently predicts their molecular recognition in the ligand-binding pocket. The N-nitroimino (NNO2) neonicotinoid pharmacophore is systematically replaced by N-nitrosoimino (NNO), N-formylimino [NC(O)H], N-alkyl- and N-arylcarbonylimino [NC(O)R], and N-alkoxy- and N-aryloxycarbonylimino [NC(O)OR] variants. The NNO analogues essentially retain the binding affinity of the NNO2 compounds, while the isosteric NC(O)H congeners have diminished potency. The NC(O)R and NC(O)OR analogues, where R is methyl, trifluoromethyl, phenyl, or pyridin-3-yl, have moderate to high affinities. Orientation of the tip oxygen plays a critical role for binding of the NNO and NC(O)H pharmacophores, and the extended NC(O)R and NC(O)OR moieties are embraced by unique binding domains.

Potency and selectivity of trifluoroacetylimino and pyrazinoylimino nicotinic insecticides and their fit at a unique binding site niche.

Neonicotinoid agonists with a nitroimino or cyanoimino pharmacophore are the newest of the four most important classes of insecticides. Our studies on the nicotinic receptor structure in the neonicotinoid-bound state revealed a unique niche of about 6 A depth beyond the nitro oxygen or cyano nitrogen tip. The N-substituted imino pharmacophore was therefore extended to fill the gap. Excellent target site selectivity with high insecticidal activity and low toxicity to mammals were achieved rivaling those of the current neonicotinoid insecticides as illustrated here by 3-(6-chloropyridin-3-ylmethyl)-2-trifluoroacetyliminothiazoline and its pyrazinoylimino analogue.

Proinsecticide candidates N-(5-methyl-2-oxo-1,3-dioxol-4-yl)methyl derivatives of imidacloprid and 1-chlorothiazolylmethyl-2-nitroimino-imidazolidine.

Prodrugs of imidacloprid and the thiazolylmethyl analog masked with oxodioxolylmethyl group on the N3 site were prepared. The prodrugs decomposed in a buffer solution of pH 8.3 and in a physiological salt solution with half-lives of 10-15 h, releasing the parent insecticides. Being consistent with this, an inward current was evoked in dissociated cockroach neurons treated with the masked compound solutions, which were maintained for 24 h after preparation, as measured using patch-clamp electrophysiology, whereas no response was observed in neurons when the solutions were challenged immediately after preparation. The insecticidal test on the American cockroach showed that the minimum lethal dose for each compound at 24 h after injection was 6.4x10(-8) mol, which was similar to that for imidacloprid and the thiazolyl derivative. This result strongly suggested a regeneration of the active ingredients in vivo.