Identification of a novel resistance gene which provides insight into Vip3Aa mode of action in Helicoverpa armigera

The global reliance on Bacillus thuringiensis (Bt) proteins for controlling lepidopteran pests in cotton, corn, and soybean crops underscores the critical need to understand resistance mechanisms. Vip3Aa, one of the most widely deployed and currently effective Bt proteins in genetically modified crops, plays a pivotal role in pest management. This study identifies the molecular basis of Vip3Aa resistance in Australian Helicoverpa armigera through genetic crosses, and integrated genomic and transcriptomic analyses. We identified a previously uncharacterized gene, LOC110373801 (designated HaVipR1), as a crucial determinant of Vip3Aa resistance in two field-derived resistant lines. Functional validation using CRISPR-Cas9 knockout in susceptible lines confirmed the gene's role in conferring resistance. Despite extensive laboratory selection of Vip3Aa-resistant colonies in Lepidoptera, the biochemical mechanisms underlying resistance have remained elusive. Our research demonstrates that HaVipR1-mediated resistance operates independently of known resistance genes, including midgut-specific chitin synthase and the transcription factor SfMyb. The identification of HaVipR1 offers further insights into the Vip3Aa mechanism of action. This discovery is vital for devising strategies to counteract resistance and sustain the efficacy of Bt crops. Future research should focus on elucidating the biochemical pathways involving HaVipR1 and investigating its interactions with other resistance mechanisms. Our findings underscore the utility of analysing field-derived resistant lines in providing biologically relevant insights and stress the necessity for comprehensive management strategies to maintain agricultural productivity.