Department of Agronomy, Horticulture and Plant Science, South Dakota State University, Brookings, South Dakota, USA.
USDA-ARS, CGAHR, Hard Winter Wheat Quality Laboratory, Manhattan, Kansas, USA.
Plant Genome. 2023 Dec;16(4):e20331. doi: 10.1002/tpg2.20331. Epub 2023 May 17.
Improvement of end-use quality remains one of the most important goals in hard winter wheat (HWW) breeding. Nevertheless, the evaluation of end-use quality traits is confined to later development generations owing to resource-intensive phenotyping. Genomic selection (GS) has shown promise in facilitating selection for end-use quality; however, lower prediction accuracy (PA) for complex traits remains a challenge in GS implementation. Multi-trait genomic prediction (MTGP) models can improve PA for complex traits by incorporating information on correlated secondary traits, but these models remain to be optimized in HWW. A set of advanced breeding lines from 2015 to 2021 were genotyped with 8725 single-nucleotide polymorphisms and was used to evaluate MTGP to predict various end-use quality traits that are otherwise difficult to phenotype in earlier generations. The MTGP model outperformed the ST model with up to a twofold increase in PA. For instance, PA was improved from 0.38 to 0.75 for bake absorption and from 0.32 to 0.52 for loaf volume. Further, we compared MTGP models by including different combinations of easy-to-score traits as covariates to predict end-use quality traits. Incorporation of simple traits, such as flour protein (FLRPRO) and sedimentation weight value (FLRSDS), substantially improved the PA of MT models. Thus, the rapid low-cost measurement of traits like FLRPRO and FLRSDS can facilitate the use of GP to predict mixograph and baking traits in earlier generations and provide breeders an opportunity for selection on end-use quality traits by culling inferior lines to increase selection accuracy and genetic gains.
提高食用品质仍然是硬粒春小麦(HWW)育种的最重要目标之一。然而,由于表型鉴定资源密集,食用品质性状的评估仅限于后期的发展世代。基因组选择(GS)在促进食用品质选择方面显示出了前景;然而,复杂性状预测准确性(PA)较低仍然是 GS 实施中的一个挑战。多性状基因组预测(MTGP)模型可以通过纳入相关次要性状的信息来提高复杂性状的 PA,但这些模型在 HWW 中仍有待优化。一组来自 2015 年至 2021 年的先进育种系进行了 8725 个单核苷酸多态性的基因分型,并用于评估 MTGP 以预测各种食用品质性状,否则这些性状在早期世代难以表型鉴定。MTGP 模型的表现优于 ST 模型,PA 最高可提高两倍。例如,烘烤吸水率的 PA 从 0.38 提高到 0.75,面包体积的 PA 从 0.32 提高到 0.52。此外,我们通过包括不同组合的易于评分性状作为协变量来比较 MTGP 模型,以预测食用品质性状。纳入简单性状,如面粉蛋白(FLRPRO)和沉降值(FLRSDS),可显著提高 MT 模型的 PA。因此,像 FLRPRO 和 FLRSDS 这样的性状的快速低成本测量可以促进 GP 在早期世代预测混合特性和烘焙特性的使用,并为育种者提供通过淘汰劣质系来提高选择准确性和遗传增益的机会,以选择食用品质性状。
