%0 Journal Article %1 bernardo2014genomewide %A Bernardo, Rex %D 2014 %J Crop Science %K breeding genomic_prediction relatedness %N 1 %P 68-75 %R https://doi.org/10.2135/cropsci2013.05.0315 %T Genomewide Selection when Major Genes Are Known %U https://acsess.onlinelibrary.wiley.com/doi/abs/10.2135/cropsci2013.05.0315 %V 54 %X Current methods for genomewide selection do not distinguish between known major genes and random genomewide markers. My objectives were to determine if explicitly modeling the effects of known major genes affects the response to genomewide selection, and to identify situations in which considering major genes as having fixed effects is helpful. Simulation experiments showed that having a fixed effect for a major gene became more advantageous as the percentage of genetic variance (VG) explained by a major gene (R2) increased and as the heritability on an entry-mean basis (h2) increased. With R2 = 50% and h2 = 0.80, the relative efficiency (based on selection gains in Cycle 4) with a major gene having a fixed versus random effect was 112–121%. Specifying a fixed effect for a single major gene was never disadvantageous except with R2 < 10%. With h2 ≥ 0.50, specifying a fixed versus random effect for a single major gene had little effect on prediction accuracy in Cycle 0. However, prediction accuracy in later cycles declined more rapidly when a major gene had a random effect instead of a fixed effect. The results with L = 2 or 3 major genes were similar to those with one major gene. In contrast, the usefulness of gene information was low with L = 10 major genes. Overall, major genes should be fitted as having fixed effects in genomewide selection when only a few major genes are present and each major gene accounts for ≥10% of VG.

@article{bernardo2014genomewide, abstract = { Current methods for genomewide selection do not distinguish between known major genes and random genomewide markers. My objectives were to determine if explicitly modeling the effects of known major genes affects the response to genomewide selection, and to identify situations in which considering major genes as having fixed effects is helpful. Simulation experiments showed that having a fixed effect for a major gene became more advantageous as the percentage of genetic variance (VG) explained by a major gene (R2) increased and as the heritability on an entry-mean basis (h2) increased. With R2 = 50% and h2 = 0.80, the relative efficiency (based on selection gains in Cycle 4) with a major gene having a fixed versus random effect was 112–121%. Specifying a fixed effect for a single major gene was never disadvantageous except with R2 < 10%. With h2 ≥ 0.50, specifying a fixed versus random effect for a single major gene had little effect on prediction accuracy in Cycle 0. However, prediction accuracy in later cycles declined more rapidly when a major gene had a random effect instead of a fixed effect. The results with L = 2 or 3 major genes were similar to those with one major gene. In contrast, the usefulness of gene information was low with L = 10 major genes. Overall, major genes should be fitted as having fixed effects in genomewide selection when only a few major genes are present and each major gene accounts for ≥10% of VG. }, added-at = {2023-07-05T22:28:49.000+0200}, author = {Bernardo, Rex}, biburl = {https://www.bibsonomy.org/bibtex/2d435a23256cfcff29e5a4e6768f0f9f1/peter.ralph}, doi = {https://doi.org/10.2135/cropsci2013.05.0315}, eprint = {https://acsess.onlinelibrary.wiley.com/doi/pdf/10.2135/cropsci2013.05.0315}, interhash = {8b1c0a3252c658bea87b2993b2dd0279}, intrahash = {d435a23256cfcff29e5a4e6768f0f9f1}, journal = {Crop Science}, keywords = {breeding genomic_prediction relatedness}, number = 1, pages = {68-75}, timestamp = {2023-07-05T22:28:49.000+0200}, title = {Genomewide Selection when Major Genes Are Known}, url = {https://acsess.onlinelibrary.wiley.com/doi/abs/10.2135/cropsci2013.05.0315}, volume = 54, year = 2014 }