Abstract
Modifying plant architecture is often necessary for yield improvement and climate adaptation, but we lack understanding of the genotype-phenotype map for plant morphology in sorghum. Here, we use a nested association mapping (NAM) population that captures global allelic diversity of sorghum to characterize the genetics of leaf erectness, leaf width (at two stages), and stem diameter. Recombinant inbred lines (n=2200) were phenotyped in multiple environments (35,200 observations) and joint linkage mapping was performed with ∼93,000 markers. Fifty-four QTL of small to large effect were identified for trait BLUPs (9-16 per trait) each explaining 0.4-4% of variation across the NAM population. While some of these QTL colocalize with sorghum homologs of grass genes (e.g., those involved in transcriptional regulation of hormone synthesis [rice SPINDLY] and transcriptional regulation of development [rice Ideal plant architecture1]), most QTL did not colocalize with an a priori candidate gene (92%). Genomic prediction accuracy was generally high in five-fold cross-validation (0.65-0.83), and varied from low to high in leave-one-family-out cross-validation (0.04-0.61). The findings provide a foundation to identify the molecular basis of architecture variation in sorghum and establish genomic-enabled breeding for improved plant architecture.
Highlights
Modification of plant architecture during crop improvement has greatly contributed to global agricultural productivity during the last century (Khush, 2001; Duvick, 2005)
Mean Preflag Leaf Width (PLW) ranged from 51 mm in the SC1103 family to 78 mm in the Macia family; mean Vegetative Leaf Width (VLW) ranged from 62 mm in the SC1103 family to 97 mm in the Macia family; mean Leaf Erectness (LFE) ranged from 42 deg in the Ajabsido family to 66 deg in the SC1103 family; and mean Stem Diameter (STD) ranged from 14 mm in the SC1103 family to 24 mm in the SC35 family
The genetic architecture of plant architecture in sorghum This study revealed that a few loci explaining moderate proportion of phenotypic variation vegetative trait are segregating in global sorghum diversity
Summary
Modification of plant architecture during crop improvement has greatly contributed to global agricultural productivity during the last century (Khush, 2001; Duvick, 2005). Ideotype breeding involves the creation of a model plant with characteristics that facilitate efficient photosynthesis, growth, and yield (Donald, 1968; Messina et al, 2009). The Green Revolution ideotypes targeted in maize, rice, and wheat includes reduced height, erect leaves, thick stalks, large and semi-compact inflorescence (ear, panicle, or head) (Khush, 2001). Leaf erectness (the angle between the culm and leaf midrib) is thought to have contributed to increased grain yield in maize through adaptation of hybrids to high planting densities (Duvick, 2005; Hammer et al, 2009). Wide leaves may facilitate efficient solar radiation capture for increased plant productivity (Sarlikioti et al, 2011). Thick stems may increase stalk strength and improve standability (Kashiwagi et al, 2008)
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