Assessment of long-term trends in genetic mean and variance after the introduction of genomic selection in layers: a simulation study

Pocrnić, Ivan; Obšteter, Jana; Gaynor, R. Chris; Wolc, Anna

doi:10.1101/2023.02.20.529187

Cited by 1 publication

(1 citation statement)

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“…In breeding programs, it is not only important to achieve faster genetic gain while maintaining those increased levels, but to track the loss of diversity as it can be indicative of the potential a breeding program possesses to keep improving genetic gain, especially when GS drives the increasing of inbreeding rates (Meuwissen et al., 2020; Obšteter et al., 2019; Pocrnic et al., 2023). In the long‐term, GS scenarios returned higher gains compared with the phenotypic program, as largely registered in different crops that tracked the long‐term GS impacts (Allier et al., 2020; Lubanga et al., 2022; Powell et al., 2020).…”

Section: Discussionmentioning

confidence: 99%

Simulation‐based decision‐making and implementation of tools in hybrid crop breeding pipelines

Peixoto,

Coelho,

Leach

et al. 2023

Crop Science

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New technologies have been developed over the last few years aiming to support breeding pipeline optimization for long‐term genetic gains. However, the implementation of these new tools and their impact on any breeding program's budget are not well studied. Here, we compare multiple breeding pipeline strategies accounting for genomic selection and high‐throughput phenotyping by means of hybrid gain and cost effectiveness. We simulated a hybrid crop breeding program through coalescent theory. We compared two strategies for parental updates and four breeding pipelines: conventional breeding pipeline; conventional breeding pipeline with high‐throughput phenotyping; conventional breeding pipeline with genomic selection; conventional breeding pipeline with genomic selection and high‐throughput phenotyping. All analyses were implemented under three different levels of genotype‐by‐environment interaction (G×E) and two traits heritabilities (0.3 and 0.7). Overall, the results show that scenarios with early parental selection perform better than the others. In addition, the implementation of high‐throughput phenotyping (HTP) delivered the highest hybrid gain in the long‐term, whereas the implementation of genomic selection seems to be more cost‐effective. We suggest, considering breeding programs with complex trait inheritance and accounting for higher levels of G×E, to invest in breeding pipelines accounting for genomic selection as a strategy to create and maintain long‐term hybrid gain. Moreover, considering an unconstrained budget, the investment in both, genomic selection and HTP, represents the best strategy. Hence, these results provide strategies that may aid breeders in optimizing self‐pollination breeding programs.This article is protected by copyright. All rights reserved

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