Ortiz Rodomiro, Crossa José, Reslow Fredrik, Perez-Rodriguez Paulino, Cuevas Jaime
Department of Plant Breeding, Swedish University of Agricultural Sciences (SLU), Lomma, Sweden.
International Maize and Wheat Improvement Center (CIMMYT), Texcoco, Mexico.
Front Plant Sci. 2022 Feb 7;13:785196. doi: 10.3389/fpls.2022.785196. eCollection 2022.
Potato breeding must improve its efficiency by increasing the reliability of selection as well as identifying a promising germplasm for crossing. This study shows the prediction accuracy of genomic-estimated breeding values for several potato ( L.) breeding clones and the released cultivars that were evaluated at three locations in northern and southern Sweden for various traits. Three dosages of marker alleles [pseudo-diploid (A), additive tetrasomic polyploidy (B), and additive-non-additive tetrasomic polyploidy (C)] were considered in the genome-based prediction models, for single environments and multiple environments (accounting for the genotype-by-environment interaction or G × E), and for comparing two kernels, the conventional linear, Genomic Best Linear Unbiased Prediction (GBLUP) (GB), and the non-linear Gaussian kernel (GK), when used with the single-kernel genetic matrices of A, B, C, or when employing two-kernel genetic matrices in the model using the kernels from B and C for a single environment (models 1 and 2, respectively), and for multi-environments (models 3 and 4, respectively). Concerning the single site analyses, the trait with the highest prediction accuracy for all sites under A, B, C for model 1, model 2, and for GB and GK methods was tuber starch percentage. Another trait with relatively high prediction accuracy was the total tuber weight. Results show an increase in prediction accuracy of model 2 over model 1. Non-linear Gaussian kernel (GK) did not show any clear advantage over the linear kernel GBLUP (GB). Results from the multi-environments had prediction accuracy estimates (models 3 and 4) higher than those obtained from the single-environment analyses. Model 4 with GB was the best method in combination with the marker structure B for predicting most of the tuber traits. Most of the traits gave relatively high prediction accuracy under this combination of marker structure (A, B, C, and B-C), and methods GB and GK combined with the multi-environment with G × E model.
马铃薯育种必须通过提高选择的可靠性以及鉴定有前景的杂交种质来提高其效率。本研究展示了几个马铃薯(Solanum tuberosum L.)育种无性系和已发布品种的基因组估计育种值的预测准确性,这些无性系和品种在瑞典北部和南部的三个地点针对各种性状进行了评估。基于基因组的预测模型考虑了三种标记等位基因剂量[假二倍体(A)、加性四体多倍体(B)和加性-非加性四体多倍体(C)],用于单环境和多环境(考虑基因型与环境互作或G×E),以及用于比较两种核函数,即传统线性核函数、基因组最佳线性无偏预测(GBLUP)(GB)和非线性高斯核函数(GK),当与A、B、C的单核遗传矩阵一起使用时,或在模型中使用来自B和C的核函数的双核遗传矩阵用于单环境(分别为模型1和2)以及多环境(分别为模型3和4)时。关于单地点分析,在模型1、模型2以及GB和GK方法下,A、B、C所有位点预测准确性最高的性状是块茎淀粉含量。另一个预测准确性相对较高的性状是块茎总重量。结果表明模型2的预测准确性高于模型1。非线性高斯核函数(GK)相对于线性核函数GBLUP(GB)没有显示出任何明显优势。多环境结果的预测准确性估计值(模型3和4)高于单环境分析得到的估计值。结合标记结构B,使用GB的模型4是预测大多数块茎性状的最佳方法。在这种标记结构(A、B、C和B - C)组合以及GB和GK方法与具有G×E模型的多环境相结合的情况下,大多数性状给出了相对较高的预测准确性。
