Expression genome-wide association study and differential methylome profiling reveal upstream regulators of drought memory genes in Arabidopsis thaliana

Plants adapt to recurrent drought through transcriptional memory, yet the upstream regulators remain largely unknown. This study integrated expression genome-wide association study (eGWAS) across 115 Arabidopsis thaliana ecotypes with differential methylome profiling to identify these regulators. Focusing on the memory genes LKR, HIS1-3, and DREB1A, eGWAS identified signaling and epigenetic loci involved in ABA/JA responses and DNA methylation. Methylome profiling by whole-genome bisulfite sequencing of ecotypes contrasting in drought tolerance, as well as in superinduction of memory genes, revealed significantly greater methylation variation during the second drought (D2) than during the first (D1), highlighting the role of epigenetic reprogramming in memory maintenance. Functional validation using T-DNA mutants demonstrated specific modulation of the D2/D1 induction ratio without affecting initial drought responses. Mutants of LKR eGWAS-delineated genes AT1G56660, AT2G19120, AT4G16490, and DEG3, those of HIS1-3 eGWAS genes AT1G14220, AT2G24960, AT3G10845, AT3G19340, CNGC10, EMB2770, GRF7, and RPP2A, and DREB1A eGWAS genes AT1G67000, AT3G61610, AT5G62110, HK2, JMJ12, and LUP5 abolished respective memory gene induction. The eGWAS and methylome approaches converged on DNA repair, chromatin modification, vesicular transport, and proteostasis as core memory hubs. These findings reveal a genetic-epigenetic interplay that coordinates transcriptional memory, priming plants for rapid reactivation of stress pathways during recurrent drought.