Bayesian estimation of genetic parameters for multivariate threshold and continuous phenotypes and molecular genetic data in simulated horse populations using Gibbs sampling.
Abstract: Requirements for successful implementation of multivariate animal threshold models including phenotypic and genotypic information are not known yet. Here simulated horse data were used to investigate the properties of multivariate estimators of genetic parameters for categorical, continuous and molecular genetic data in the context of important radiological health traits using mixed linear-threshold animal models via Gibbs sampling. The simulated pedigree comprised 7 generations and 40000 animals per generation. Additive genetic values, residuals and fixed effects for one continuous trait and liabilities of four binary traits were simulated, resembling situations encountered in the Warmblood horse. Quantitative trait locus (QTL) effects and genetic marker information were simulated for one of the liabilities. Different scenarios with respect to recombination rate between genetic markers and QTL and polymorphism information content of genetic markers were studied. For each scenario ten replicates were sampled from the simulated population, and within each replicate six different datasets differing in number and distribution of animals with trait records and availability of genetic marker information were generated. (Co)Variance components were estimated using a Bayesian mixed linear-threshold animal model via Gibbs sampling. Residual variances were fixed to zero and a proper prior was used for the genetic covariance matrix. Results: Effective sample sizes (ESS) and biases of genetic parameters differed significantly between datasets. Bias of heritability estimates was -6% to +6% for the continuous trait, -6% to +10% for the binary traits of moderate heritability, and -21% to +25% for the binary traits of low heritability. Additive genetic correlations were mostly underestimated between the continuous trait and binary traits of low heritability, under- or overestimated between the continuous trait and binary traits of moderate heritability, and overestimated between two binary traits. Use of trait information on two subsequent generations of animals increased ESS and reduced bias of parameter estimates more than mere increase of the number of informative animals from one generation. Consideration of genotype information as a fixed effect in the model resulted in overestimation of polygenic heritability of the QTL trait, but increased accuracy of estimated additive genetic correlations of the QTL trait. Conclusions: Combined use of phenotype and genotype information on parents and offspring will help to identify agonistic and antagonistic genetic correlations between traits of interests, facilitating design of effective multiple trait selection schemes.
Publication Date: 2007-05-09 PubMed ID: 17490471PubMed Central: PMC1876470DOI: 10.1186/1471-2156-8-19Google Scholar: Lookup
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Summary
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This research investigates the properties of different estimators of genetic parameters for various types of data used in horse breeding, using simulated data based on the Warmblood horse breed. The research examined different scenarios to determine how variations in the information available would affect the accuracy of the genetic estimates.
Research Methodology
- The research was conducted using simulated horse data, modelling several generations with 40000 individuals in each generation.
- The data included different kinds of traits – one continuous trait and four binary traits. A continuous trait may have a range of values, whereas a binary trait has only two different outcomes.
- For one of the binary traits, the researchers simulated both the genetic effects and the genetic marker information. The genetic marker is a section of DNA associated with the trait of interest.
- Different scenarios were set up varying the rate of recombination between the genetic markers and the trait, and the level of polymorphism, or variation, in the genetic markers.
- For each scenario, ten different sets of data were created, each with a different number and distribution of animals with trait records and different levels of genetic marker information.
- The researchers then estimated the (co)variance components using a Bayesian mixed linear-threshold animal model via Gibbs sampling, which is a statistical technique for making inferences about complex probability distributions.
Results
- The accuracy and efficiency (ESS) of genetic parameters varied significantly depending on the dataset.
- The bias in estimates of heritability ranged from -6% to +6% for the continuous trait, -6% to +10% for the binary traits of moderate heritability, and -21% to +25% for binary traits of low heritability.
- The correlation of additive genetic variations were underestimated between the continuous trait and binary traits of low heritability, and overestimated between two binary traits.
- Trait data from two generations of animals improved efficiency and reduced bias more than simply increasing the number of animals included in the data from one generation.
- Inclusion of genotype information as a fixed effect in the model overestimated the heritability of the trait associated with the genetic marker but improved the accuracy of estimated genetic correlations.
Conclusions
- This research suggests that using both phenotype and genotype information from parents and offspring helps to identify genetic correlations between traits. This could help breeders design more effective selection schemes by understanding which traits influence each other and in what ways.
Cite This Article
APA
Stock KF, Distl O, Hoeschele I.
(2007).
Bayesian estimation of genetic parameters for multivariate threshold and continuous phenotypes and molecular genetic data in simulated horse populations using Gibbs sampling.
BMC Genet, 8, 19.
https://doi.org/10.1186/1471-2156-8-19 Publication
Researcher Affiliations
- Institute for Animal Breeding and Genetics, University of Veterinary Medicine Hannover (Foundation), Hannover, Germany. Kathrin-Friederike.Stock@tiho-hannover.de
MeSH Terms
- Animals
- Computer Simulation
- Horses / genetics
- Likelihood Functions
- Linear Models
- Markov Chains
- Monte Carlo Method
- Quantitative Trait Loci
- Sampling Studies
Grant Funding
- R01 GM066103 / NIGMS NIH HHS
- GM66103-01 / NIGMS NIH HHS
References
This article includes 38 references
Citations
This article has been cited 2 times.- Papachristou C, Ober C, Abney M. Genetic variance components estimation for binary traits using multiple related individuals. Genet Epidemiol 2011 Jul;35(5):291-302.
- Jin F, Ashraf AA, Ul Din SM, Farooq U, Zheng K, Shaukat G. Organisational caring ethical climate and its relationship with workplace bullying and post traumatic stress disorder: The role of type A/B behavioural patterns. Front Psychol 2022;13:1042297.
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