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Increased Power To Dissect Adaptive Traits in Global Sorghum Diversity Using a Nested Association Mapping Population

Sophie BouchetDepartment of Agronomy , Kansas State University, Manhattan, Kansas 66506Marcus O. OlatoyeDepartment of Agronomy , Kansas State University, Manhattan, Kansas 66506Sandeep MarlaDepartment of Agronomy , Kansas State University, Manhattan, Kansas 66506Ramasamy PerumalAgricultural Research Center , Kansas State University, Hays, Kansas 67601Tesfaye TessoDepartment of Agronomy , Kansas State University, Manhattan, Kansas 66506Jianming YuDepartment of Agronomy , Iowa State University, Ames, Iowa 50011Mitch TuinstraDepartment of Agronomy , Purdue University, West Lafayette, Indiana 47907Geoffrey P. MorrisDepartment of Agronomy , Kansas State University, Manhattan, Kansas 66506
2017en
ABI

Аннотация

Abstract In crop species, adaptation to different agroclimatic regions creates useful variation but also leads to unwanted genetic correlations. Bouchet....... Adaptation of domesticated species to diverse agroclimatic regions has led to abundant trait diversity. However, the resulting population structure and genetic heterogeneity confounds association mapping of adaptive traits. To address this challenge in sorghum [Sorghum bicolor (L.) Moench]—a widely adapted cereal crop—we developed a nested association mapping (NAM) population using 10 diverse global lines crossed with an elite reference line RTx430. We characterized the population of 2214 recombinant inbred lines at 90,000 SNPs using genotyping-by-sequencing. The population captures ∼70% of known global SNP variation in sorghum, and 57,411 recombination events. Notably, recombination events were four- to fivefold enriched in coding sequences and 5′ untranslated regions of genes. To test the power of the NAM population for trait dissection, we conducted joint linkage mapping for two major adaptive traits, flowering time and plant height. We precisely mapped several known genes for these two traits, and identified several additional QTL. Considering all SNPs simultaneously, genetic variation accounted for 65% of flowering time variance and 75% of plant height variance. Further, we directly compared NAM to genome-wide association mapping (using panels of the same size) and found that flowering time and plant height QTL were more consistently identified with the NAM population. Finally, for simulated QTL under strong selection in diversity panels, the power of QTL detection was up to three times greater for NAM vs. association mapping with a diverse panel. These findings validate the NAM resource for trait mapping in sorghum, and demonstrate the value of NAM for dissection of adaptive traits.

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