期刊论文详细信息
Genetics Selection Evolution
Genome-wide prediction of discrete traits using bayesian regressions and machine learning
Research
Selma Forni1  Oscar González-Recio2 
[1] Genus Plc, 100 Bluegrass Commons Blvd. Ste 2200, Hendersonville, TN, USA;INIA, Ctra La Coruña km 7.5, 28040, Madrid, Spain;
关键词: Single Nucleotide Polymorphism;    Loss Function;    Random Forest;    Lasso;    Genomic Selection;   
DOI  :  10.1186/1297-9686-43-7
 received in 2010-05-31, accepted in 2011-02-17,  发布年份 2011
来源: Springer
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【 摘 要 】

BackgroundGenomic selection has gained much attention and the main goal is to increase the predictive accuracy and the genetic gain in livestock using dense marker information. Most methods dealing with the large p (number of covariates) small n (number of observations) problem have dealt only with continuous traits, but there are many important traits in livestock that are recorded in a discrete fashion (e.g. pregnancy outcome, disease resistance). It is necessary to evaluate alternatives to analyze discrete traits in a genome-wide prediction context.MethodsThis study shows two threshold versions of Bayesian regressions (Bayes A and Bayesian LASSO) and two machine learning algorithms (boosting and random forest) to analyze discrete traits in a genome-wide prediction context. These methods were evaluated using simulated and field data to predict yet-to-be observed records. Performances were compared based on the models' predictive ability.ResultsThe simulation showed that machine learning had some advantages over Bayesian regressions when a small number of QTL regulated the trait under pure additivity. However, differences were small and disappeared with a large number of QTL. Bayesian threshold LASSO and boosting achieved the highest accuracies, whereas Random Forest presented the highest classification performance. Random Forest was the most consistent method in detecting resistant and susceptible animals, phi correlation was up to 81% greater than Bayesian regressions. Random Forest outperformed other methods in correctly classifying resistant and susceptible animals in the two pure swine lines evaluated. Boosting and Bayes A were more accurate with crossbred data.ConclusionsThe results of this study suggest that the best method for genome-wide prediction may depend on the genetic basis of the population analyzed. All methods were less accurate at correctly classifying intermediate animals than extreme animals. Among the different alternatives proposed to analyze discrete traits, machine-learning showed some advantages over Bayesian regressions. Boosting with a pseudo Huber loss function showed high accuracy, whereas Random Forest produced more consistent results and an interesting predictive ability. Nonetheless, the best method may be case-dependent and a initial evaluation of different methods is recommended to deal with a particular problem.

【 授权许可】

CC BY   
© González-Recio and Forni; licensee BioMed Central Ltd. 2011

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