Prediction of Genomic Breeding Values Using New Computing Strategies for the Implementation of MixP

Overview

Journal Sci Rep

Specialty Science

Date 2017 Dec 10

PMID 29222415

Citations 2

Authors

Linsong Dong

Ming Fang

Zhiyong Wang

Affiliations

Soon will be listed here.

Abstract

MixP is an implementation that uses the Pareto principle to perform genomic prediction. This study was designed to develop two new computing strategies: one strategy for nonMCMC-based MixP (FMixP), and the other one for MCMC-based MixP (MMixP). The difference is that MMixP can estimate variances of SNP effects and the probability that a SNP has a large variance, but FMixP cannot. Simulated data from an international workshop and real data on large yellow croaker were used as the materials for the study. Four Bayesian methods, BayesA, BayesCπ, MMixP and FMixP, were used to compare the predictive results. The results show that BayesCπ, MMixP and FMixP perform better than BayesA for the simulated data, but all methods have very similar predictive abilities for the large yellow croaker. However, FMixP is computationally significantly faster than the MCMC-based methods. Our research may have a potential for the future applications in genomic prediction.

Citing Articles

FMixFN: A Fast Big Data-Oriented Genomic Selection Model Based on an Iterative Conditional Expectation algorithm.

Xu W, Liu X, Liao M, Xiao S, Zheng M, Yao T Front Genet. 2021; 12:721600.

PMID: 34868200 PMC: 8637923. DOI: 10.3389/fgene.2021.721600.

Evaluation of Genomic Selection for Seven Economic Traits in Yellow Drum (Nibea albiflora).

Liu G, Dong L, Gu L, Han Z, Zhang W, Fang M Mar Biotechnol (NY). 2019; 21(6):806-812.

PMID: 31745748 PMC: 6890617. DOI: 10.1007/s10126-019-09925-7.

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