Abstract
Genomic-assisted breeding has become an important tool in soybean breeding. However, the impact of different genomic selection (GS) approaches on short- and long-term gains is not well understood. Such gains are conditional on the breeding design and may vary with a combination of the prediction model, family size, selection strategies, and selection intensity. To address these open questions, we evaluated various scenarios through a simulated closed soybean breeding program over 200 breeding cycles. Genomic prediction was performed using genomic best linear unbiased prediction (GBLUP), Bayesian methods, and random forest, benchmarked against selection on phenotypic values, true breeding values (TBV), and random selection. Breeding strategies included selections within family (WF), across family (AF), and within pre-selected families (WPSF), with selection intensities of 2.5, 5.0, 7.5, and 10.0%. Selections were performed at the F4 generation, where individuals were phenotyped and genotyped with a 6K single nucleotide polymorphism (SNP) array. Initial genetic parameters for the simulation were estimated from the SoyNAM population. WF selections provided the most significant long-term genetic gains. GBLUP and Bayesian methods outperformed random forest and provided most of the genetic gains within the first 100 generations, being outperformed by phenotypic selection after generation 100. All methods provided similar performances under WPSF selections. A faster decay in genetic variance was observed when individuals were selected AF and WPSF, as 80% of the genetic variance was depleted within 28–58 cycles, whereas WF selections preserved the variance up to cycle 184. Surprisingly, the selection intensity had less impact on long-term gains than did the breeding strategies. The study supports that genetic gains can be optimized in the long term with specific combinations of prediction models, family size, selection strategies, and selection intensity. A combination of strategies may be necessary for balancing the short-, medium-, and long-term genetic gains in breeding programs while preserving the genetic variance.
Highlights
Soybean [Glycine max (L.)] is the most important source of protein for animal feed and an important source of oil for human consumption, biofuel, and other industrial applications
Selection of true breeding values (TBV) represents the upper boundary of each scenario; these are useful to contrast the potential of the different scenarios
The highest long-term population means from selection on TBV occurred within family (WF) with loose selection intensities (7.5–10%)
Summary
Soybean [Glycine max (L.)] is the most important source of protein for animal feed and an important source of oil for human consumption, biofuel, and other industrial applications. The largest producers include Brazil, United States, Argentina, Paraguay, and China (FAO, 2021). Soybeans are bred for several traits, but grain yield is considered as the most important. Genome-wide prediction is a key tool in soybean breeding. It is utilized for faster and more accurate selection of superior individuals (Meuwissen et al, 2001). Other factors that may have contributed to the increasing adoption of genomic selection (GS) in plants include the decreasing cost of genotyping and the availability of software tools and computing power to analyze large datasets
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