Abstract
Spinosyns are allosteric modulators of nicotinic acetylcholine receptors (nAChRs) which in insects specifically target subunit α6. However, their mode of action in mites and compatibility with phytoseiid predators remain unclear. We combined phylogenetics with CRISPR/Cas-based reverse genetics to test whether α6-like subunits mediate spinosyn toxicity in mites and to assess prospects for resistance breeding in phytoseiids. The phylogenetic analysis identified seven α and three β subunits in multiple phytoseiids and in Tetranychus urticae. A single phytoseiid subunit clustered within the insect α6/α7 clade, whereas T. urticae possessed three (Tuα5/α6/α7) without strict one-to-one insect orthology. Using SYNCAS maternal delivery of CRISPR RNPs, we disrupted the putative α6 ortholog in Amblyseius swirskii (Asα6) and each of the three α6/α7-clade genes in T. urticae. In A. swirskii, all survivors of a discriminating spinosad dose carried Asα6 indels, and three independently edited lines exhibited insensitivity to both spinosad and spinetoram (no significant mortality at 10 000 mg a.i./L), whereas the wild type showed LC(50) = 163 mg/L (spinosad) and 54 mg/L (spinetoram). In T. urticae, Tuα6 knockouts conferred high cross-resistance to both compounds, while Tuα5 knockouts slightly increased susceptibility and Tuα7 knockouts produced modest resistance. Our data demonstrate that α6-mediated spinosyn action is conserved in mites, with α6 loss conferring strong cross-resistance in a key phytoseiid predator and in a model tetranychid. These findings enable marker-assisted editing/selection of spinosyn-resistant phytoseiid strains to improve pesticide-biocontrol compatibility and establish α6 as a practical universal marker gene for genome editing in acarine systems.