Optimization of Multi-Generation Multi-location Genomic Prediction Models for Recurrent Genomic Selection in an Upland Rice Population

Genomic selection is a worthy breeding method to improve genetic gain in recurrent selection breeding schemes. The integration of multi-generation and multi-location information could significantly improve genomic prediction models in the context of shuttle breeding. The Cirad-CIAT upland rice breed...

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Published in:Rice (New York, N.Y.) N.Y.), 2023-09, Vol.16 (1), p.43-43, Article 43
Main Authors: de Verdal, Hugues, Baertschi, Cédric, Frouin, Julien, Quintero, Constanza, Ospina, Yolima, Alvarez, Maria Fernanda, Cao, Tuong-Vi, Bartholomé, Jérôme, Grenier, Cécile
Format: Article
Language:English
Subjects:
Agricultural sciences
Agriculture
Biomedical and Life Sciences
Breeding methods
Calibration
Crop yield
Environment models
Flowering
Genomic selection
Genomics
Genotype & phenotype
Genotype-by-environment interaction
Genotypes
Germplasm
Grain
Life Sciences
Model accuracy
Optimization
Oryza sativa
Phenotyping
Plant breeding
Plant Breeding/Biotechnology
Plant Ecology
Plant Genetics and Genomics
Plant Sciences
Prediction models
Predictions
Rice
Training
Training set optimization
Variance
Zinc
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Summary:Genomic selection is a worthy breeding method to improve genetic gain in recurrent selection breeding schemes. The integration of multi-generation and multi-location information could significantly improve genomic prediction models in the context of shuttle breeding. The Cirad-CIAT upland rice breeding program applies recurrent genomic selection and seeks to optimize the scheme to increase genetic gain while reducing phenotyping efforts. We used a synthetic population (PCT27) of which S 0 plants were all genotyped and advanced by selfing and bulk seed harvest to the S 0:2 , S 0:3 , and S 0:4 generations. The PCT27 was then divided into two sets. The S 0:2 and S 0:3 progenies for PCT27A and the S 0:4 progenies for PCT27B were phenotyped in two locations: Santa Rosa the target selection location, within the upland rice growing area, and Palmira, the surrogate location, far from the upland rice growing area but easier for experimentation. While the calibration used either one of the two sets phenotyped in one or two locations, the validation population was only the PCT27B phenotyped in Santa Rosa. Five scenarios of genomic prediction and 24 models were performed and compared. Training the prediction model with the PCT27B phenotyped in Santa Rosa resulted in predictive abilities ranging from 0.19 for grain zinc concentration to 0.30 for grain yield. Expanding the training set with the inclusion of the PCT27A resulted in greater predictive abilities for all traits but grain yield, with increases from 5% for plant height to 61% for grain zinc concentration. Models with the PCT27B phenotyped in two locations resulted in higher prediction accuracy when the models assumed no genotype-by-environment (G × E) interaction for flowering (0.38) and grain zinc concentration (0.27). For plant height, the model assuming a single G × E variance provided higher accuracy (0.28). The gain in predictive ability for grain yield was the greatest (0.25) when environment-specific variance deviation effect for G × E was considered. While the best scenario was specific to each trait, the results indicated that the gain in predictive ability provided by the multi-location and multi-generation calibration was low. Yet, this approach could lead to increased selection intensity, acceleration of the breeding cycle, and a sizable economic advantage for the program.
ISSN:1939-8425
1939-8433
1934-8037
DOI:10.1186/s12284-023-00661-0