Abstract
SummaryHybrid breeding is the main strategy for improving productivity in many crops, especially in rice and maize. Genomic hybrid breeding is a technology that uses whole‐genome markers to predict future hybrids. Predicted superior hybrids are then field evaluated and released as new hybrid cultivars after their superior performances are confirmed. This will increase the opportunity of selecting true superior hybrids with minimum costs. Here, we used genomic best linear unbiased prediction to perform hybrid performance prediction using an existing rice population of 1495 hybrids. Replicated 10‐fold cross‐validations showed that the prediction abilities on ten agronomic traits ranged from 0.35 to 0.92. Using the 1495 rice hybrids as a training sample, we predicted six agronomic traits of 100 hybrids derived from half diallel crosses involving 21 parents that are different from the parents of the hybrids in the training sample. The prediction abilities were relatively high, varying from 0.54 (yield) to 0.92 (grain length). We concluded that the current population of 1495 hybrids can be used to predict hybrids from seemingly unrelated parents. Eventually, we used this training population to predict all potential hybrids of cytoplasm male sterile lines from 3000 rice varieties from the 3K Rice Genome Project. Using a breeding index combining 10 traits, we identified the top and bottom 200 predicted hybrids. SNP genotypes of the training population and parameters estimated from this training population are available for general uses and further validation in genomic hybrid prediction of all potential hybrids generated from all varieties of rice.
Highlights
Hybrid breeding has been proven to be the most effective strategy to improve yield potential for many crops, especially in cross-pollinated species such as maize, cotton and sorghum (Duvick, 2001; Khan et al, 2009; Stephens and Holland, 1954)
Hybrid breeding takes advantage of heterosis, which describes a phenomenon where F1 hybrids derived from crosses between genetically distinct inbred varieties exhibit superior phenotypic performances over their parents
Hybrid rice is a successful example of hybrid breeding, which has the potential of yielding ~20% more than the inbred varieties grown under the same conditions (Tu et al, 2000)
Summary
Hybrid breeding has been proven to be the most effective strategy to improve yield potential for many crops, especially in cross-pollinated species such as maize, cotton and sorghum (Duvick, 2001; Khan et al, 2009; Stephens and Holland, 1954). The process of developing rice hybrids is not simple, especially in terms of how to select parents for crosses (Xu et al, 2014). MARS is not the best practical method to develop hybrid crops by incorporating a few major genes or pyramiding several genes. In this context, genomic selection (GS) has paved the way to overcome these limitations using whole-genome prediction models. GS is a form of MARS in which markers of the whole genome are used to predict the genomic values of individual lines or hybrids and has become an effective tool for plant breeding (Cooper et al, 2014; Spindel et al, 2015; Zhao et al, 2015b). With the development of the next-generation sequencing technology and the next-generation phenotypic technology (high throughput phenotyping), GS can be a routine practice in plant breeding (Marulanda et al, 2016)
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