Role of transposons in the specialization of Botrytis cinerea to grapevine: Insights into small RNAs and a new Starship

While transposable elements (TEs) are recognized as major drivers of fungal genome structure, evidence of their direct involvement in the interaction with host plants and the environment is only beginning to emerge. Retrotransposons can generate small RNA (sRNA) that act through cross-kingdom RNA interference, while giant DNA TEs called Starships carry dozens of cargo genes that enrich the accessory gene compartment of fungal genomes. In the polyphagous pathogen Botrytis cinerea, the Vv3 strain and other strains specialized on grapevine display a specific repertoire of TEs, including the retrotransposons BcCopia4, BcGypsy6, and BcGypsy7. This study first explored the putative role of sRNA generated from these retrotransposons in the interaction between the Vv3 strain and its host of origin, grapevine. Putative targets were identified among the host mRNAs, but predicted cleavage sites could not be experimentally validated. Moreover, Dicer mutants unable to produce retrotransposons-derived sRNA remained fully pathogenic on grapevine, indicating that these sRNAs do not act as virulence factors on this host. In parallel, this study provides an updated RNA-seq-based annotation of the accessory genes of the Vv3 strain, which revealed a new 93 kb-Starship harboring 43 cargo genes, some of which are related to arsenic resistance. A formal genetic approach confirmed that this locus confers resistance to this metalloid. This giant TE, named Ariane, was also detected in additional grapevine-specialized strains resistant to arsenic but not in strains isolated from other hosts such as tomato. In conclusion, this study highlights how a Starship giant transposon shaped the accessory genes compartment of the polyphagous fungus B. cinerea and may have contributed to its adaptation to vine cultivation by conferring resistance to arsenic, a compound widely used in vineyards during the last century.