Genotype & phenotypic_image&data_2017_maize

Background : Drought threatens the food supply of the world population. Dissecting the dynamic responses of plants to drought will be beneficial for breeding drought?tolerant crops, as the genetic controls of these responses remain largely unknown. Results : Here we develop a high-throughput multiple optical phenotyping system to non-invasively phenotype 368 maize genotypes with or without drought stress over a course of 98 days, and collected multiple optical images, including color camera scanning, hyperspectral imaging and x-ray computed tomography images. We develop high-throughput analysis pipelines to extract image-based traits (i-traits). Of these i?traits, 10,080 were effective and heritable indicators of maize external and internal drought responses. An i-trait-based genome wide association study reveals 4,322 significant locus-trait associations, representing 1,529 quantitative trait loci (QTLs) and 2,318 candidate genes, many that co-localize with previously reported maize drought responsive QTLs. Expression QTL (eQTL) analysis uncovers many local and distant regulatory variants that control the expression of the candidate genes. We use genetic mutation analysis to validate two new genes, ZmcPGM2 and ZmFAB1A , which regulate i-traits and drought tolerance. Moreover, the value of the candidate genes as drought-tolerant genetic markers is revealed by genome selection analysis, and 15 i?traits are identified as potential markers for maize drought tolerance breeding. Conclusion : Our study demonstrates that combining high-throughput multiple optical phenotyping and GWAS is a novel and effective approach to dissect the genetic architecture of complex traits and clone drought-tolerance associated genes.