Structural basis for diamide modulation of ryanodine receptor

Abstract

Diamide insecticides target insect ryanodine receptors (RYRs) and cause dysregulation of calcium signaling in insect muscles and neurons, generating worldwide sales over 2 billion US dollars annually. Several resistance mutations have been reported to reduce the efficacy of the diamides, but the exact binding sites and mechanism of resistance mutations were not clear. Recently, we solved the cryo-electron microscopy (cryo-EM) structure of RYR in complex with the anthranilic diamide chlorantraniliprole (CHL). CHL binds to the pseudo-voltage-sensor domain (pVSD) of RYR, a site in proximity to the previously identified resistance mutations. Mutagenesis studies in silico, in mutant cell lines, and in transgenic Drosophila strains revealed the key residues involved in diamide coordination and the molecular mechanism under species-selectivity and resistance mutations. We also proposed that CHL may alleviate the loss-of-function effects of some central core disease (CCD) mutations by increasing the opening probability (Po) of RYR1. In addition, we solved the crystal structures of several RYR domains from the diamondback moth and the bee, revealing insect-specific structural features which could be potentially targeted by novel insecticides. Interestingly, we found that the phosphorylation of insect RYR is temperature dependent, facilitated by the low thermal stability and dynamic structure of the insect RYR. Our structures provide a foundation for developing novel pesticides to overcome the resistance crisis.