Natural genetic variations underlying iron and zinc uptake efficiency in rice under direct-seeded cultivation conditions
摘要
Iron (Fe) and zinc (Zn) deficiencies frequently limit nutrient acquisition and grain micronutrient accumulation in rice grown under direct-seeded rice (DSR) systems due to reduced micronutrient availability in aerobic soils. Understanding the genetic architecture controlling micronutrient uptake and its association with root system architecture (RSA) is critical for developing nutrient-efficient rice varieties. In this study, a diverse panel of 290 rice genotypes was evaluated for RSA, agronomic traits, and grain Fe and Zn concentration under DSR conditions across three years. Genome-wide association analysis using 18,639 high-quality SNP markers identified 118 significant marker–trait associations distributed across the rice genome. Several loci exhibited pleiotropic effects, linking RSA traits with grain micronutrient accumulation and yield-related traits. Notably, multiple genomic regions co-localized with previously reported QTLs and key genes involved in metal homeostasis, including OsIRO2, OsNAS, OsYSL, OsZIP, OsHMA2, and OsVIT1, suggesting conserved regulatory mechanisms controlling Fe and Zn uptake. Expression profiling under Fe and Zn deficiency further revealed differential regulation of transcription factors and metal transporters between nutrient-efficient and inefficient genotypes, indicating genotype-specific adaptive responses to micronutrient stress. These findings provide insights into the genetic basis of micronutrient uptake and identify promising donors, genomic regions and candidate genes for marker-assisted breeding of nutrient-efficient rice varieties adapted to DSR cultivation systems.