02093naa a2200241 a 450000100080000000500110000800800410001902400390006010000170009924501560011626000090027252013290028165300060161070000200161670000250163670000200166170000190168170000170170070000190171770000190173670000250175577300710178020935412018-07-25       2018    bl uuuu     u00u1 u    #d7 a10.1080/09712119.2017.14159032DOI1 aSILVA, F. F.  aBayesian model combining linkage and linkage disequilibrium analysis for low density-based genomic selection in animal breeding.h[electronic resource]  c2018  aWe combined linkage (LA) and linkage disequilibrium (LDA) analyses (emerging the term ?LALDA?) for genomic selection (GS) purposes. The models were fitted to a simulated dataset and to a real data of feed conversion ratio in pigs. Firstly, the significant QTLs (quantitative trait locus) were identified through LA-based mixed models considering the QTL-genotypes as random effects by means of genotypic identity by descent matrix. This matrix was calculated at the positions of significant QTLs (based on LA) allowing to include the QTL-genotype effects additionally to SNP (single nucleotide polymorphism) markers (based on LDA) and additive polygenic effects in several GS models (Bayesian Ridge Regression ? BRR; Bayes A ? BA; Bayes B ? BB; Bayes C ? BC and Bayesian LASSO ? BL). These models combing all mentioned effects were denominated LALDA. Goodness-of-fit and predictive ability analyses were performed to evaluate the efficiency of these models. For the real data, although slightly, the superiority of the LALDA models was verified in comparison to traditional LDA models for GS. For the simulated dataset, the models presented similar results. For both LDA and LALDA frameworks, BA showed the best fitting through Deviance Information Criterion and higher predictive ability in the simulated and real datasets.  ax1 aJEREZ, E. A. Z.1 aRESENDE, M. D. V. de1 aVIANA, J. M. S.1 aAZEVEDO, C. F.1 aLOPES, P. S.1 aNASCIMENTO, M.1 aLIMA, R. O. de1 aGUIMARÃES, S. E. F.  tJournal of Applied Animal Researchgv. 46, n. 1, p. 873-878, 2018.