Departamento de Métodos Cuantitativos y Sistemas de Información, Facultad de Agronomía, Universidad de Buenos Aires, 1417 Ciudad Autónoma de Buenos Aires, Argentina.
Biometrics and Statistics Unit. International Maize and Wheat Improvement Center (CIMMYT), Carretera México -Veracruz, Km 45, Col. El Batán, CP 56237, Texcoco, Edo. de México, México.
Genetics. 2021 Feb 9;217(2). doi: 10.1093/genetics/iyaa048.
Cultivated bread wheat (Triticum aestivum L.) is an allohexaploid species resulting from the natural hybridization and chromosome doubling of allotetraploid durum wheat (T. turgidum) and a diploid goatgrass Aegilops tauschii Coss (Ae. tauschii). Synthetic hexaploid wheat (SHW) was developed through the interspecific hybridization of Ae. tauschii and T. turgidum, and then crossed to T. aestivum to produce synthetic hexaploid wheat derivatives (SHWDs). Owing to this founding variability, one may infer that the genetic variances of native wild populations vs improved wheat may vary due to their differential origin and evolutionary history. In this study, we partitioned the additive variance of SHW and SHWD with respect to their breed origin by fitting a hierarchical Bayesian model with heterogeneous covariance structure for breeding values to estimate variance components for each breed category, and segregation variance. Two data sets were used to test the proposed hierarchical Bayesian model, one from a multi-year multi-location field trial of SHWD and the other comprising the two species of SHW. For the SHWD, the Bayesian estimates of additive variances of grain yield from each breed category were similar for T. turgidum and Ae. tauschii, but smaller for T. aestivum. Segregation variances between Ae. tauschii-T. aestivum and T. turgidum-T. aestivum populations explained a sizable proportion of the phenotypic variance. Bayesian additive variance components and the Best Linear Unbiased Predictors (BLUPs) estimated by two well-known software programs were similar for multi-breed origin and for the sum of the breeding values by origin for both data sets. Our results support the suitability of models with heterogeneous additive genetic variances to predict breeding values in wheat crosses with variable ploidy levels.
栽培小麦(Triticum aestivum L.)是一种异源六倍体物种,由异源四倍体硬粒小麦(T. turgidum)和二倍体山羊草 Aegilops tauschii Coss(Ae. tauschii)自然杂交和染色体加倍形成。合成六倍体小麦(SHW)是通过 Ae. tauschii 和 T. turgidum 的种间杂交产生的,然后与 T. aestivum 杂交产生合成六倍体小麦衍生物(SHWD)。由于这种起源的可变性,可以推断由于其不同的起源和进化历史,原生野生种群与改良小麦的遗传方差可能会有所不同。在这项研究中,我们通过拟合具有异质协方差结构的层次贝叶斯模型来划分 SHW 和 SHWD 的加性方差与其品种起源的关系,以估计每个品种类别的方差分量和分离方差。使用两个数据集来测试所提出的层次贝叶斯模型,一个来自 SHWD 的多年多点田间试验,另一个包含 SHW 的两个物种。对于 SHWD,来自每个品种类别的粒重的加性方差的贝叶斯估计值在 Ae. tauschii 和 T. turgidum 之间相似,但在 T. aestivum 中较小。Ae. tauschii-T. aestivum 和 T. turgidum-T. aestivum 群体之间的分离方差解释了表型方差的相当大一部分。两种知名软件程序估计的贝叶斯加性方差分量和最佳线性无偏预测值(BLUPs)对于多品种起源和两个数据集的起源总和的育种值相似。我们的结果支持具有异质加性遗传方差的模型适合于预测具有不同倍性水平的小麦杂交中的育种值。
