Portability of Genomic Predictions Trained on Sparse Factorial Designs Across Two Maize Silage Breeding Cycles

Overview

Journal Theor Appl Genet

Publisher Springer

Specialty Genetics

Date 2024 Mar 7

PMID 38453705

Authors

Alizarine Lorenzi

Cyril Bauland

Sophie Pin

Delphine Madur

Valerie Combes

Carine Palaffre

Colin Guillaume

Gaetan Touzy

Tristan Mary-Huard

Alain Charcosset

Laurence Moreau

Affiliations

Soon will be listed here.

Abstract

We validated the efficiency of genomic predictions calibrated on sparse factorial training sets to predict the next generation of hybrids and tested different strategies for updating predictions along generations. Genomic selection offers new prospects for revisiting hybrid breeding schemes by replacing extensive phenotyping of individuals with genomic predictions. Finding the ideal design for training genomic prediction models is still an open question. Previous studies have shown promising predictive abilities using sparse factorial instead of tester-based training sets to predict single-cross hybrids from the same generation. This study aims to further investigate the use of factorials and their optimization to predict line general combining abilities (GCAs) and hybrid values across breeding cycles. It relies on two breeding cycles of a maize reciprocal genomic selection scheme involving multiparental connected reciprocal populations from flint and dent complementary heterotic groups selected for silage performances. Selection based on genomic predictions trained on a factorial design resulted in a significant genetic gain for dry matter yield in the new generation. Results confirmed the efficiency of sparse factorial training sets to predict candidate line GCAs and hybrid values across breeding cycles. Compared to a previous study based on the first generation, the advantage of factorial over tester training sets appeared lower across generations. Updating factorial training sets by adding single-cross hybrids between selected lines from the previous generation or a random subset of hybrids from the new generation both improved predictive abilities. The CDmean criterion helped determine the set of single-crosses to phenotype to update the training set efficiently. Our results validated the efficiency of sparse factorial designs for calibrating hybrid genomic prediction experimentally and showed the benefit of updating it along generations.

Citing Articles

Using phenomic selection to predict hybrid values with NIR spectra measured on the parental lines: proof of concept on maize.

Rincent R, Solin J, Lorenzi A, Nunes L, Griveau Y, Pirus L Theor Appl Genet. 2025; 138(1):28.

PMID: 39797978 PMC: 11724800. DOI: 10.1007/s00122-024-04809-4.

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