Evaluation of linkage disequilibrium measures between multi-allelic markers as predictors of linkage disequilibrium between single nucleotide polymorphisms

H. Zhao; D. Nettleton; J. C. M. Dekkers

doi:10.1017/S0016672307008634

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Effectiveness of marker-assisted selection (MAS) and quantitative trait locus (QTL) mapping using population-wide linkage disequilibrium (LD) between markers and QTLs depends on the extent of LD and how it declines with distance between markers and QTLs in a population. Marker–QTL LD can be predicted from LD between markers. Our previous work evaluated LD measures between multi-allelic markers as predictors of usable LD of multi-allelic markers with QTLs. Since single nucleotide polymorphisms (SNPs) are the current marker of choice for high-density genotyping and LD-mapping of QTLs, the objective of this study was to use LD between multi-allelic markers to predict LD among biallelic SNPs or between SNPs and QTLs. Observable LD between multi-allelic markers was evaluated using nine measures. These included two pooled and standardized measures of LD between pairs of alleles at two markers based on Lewontin's LD measure, two pooled measures of squared correlations between alleles, one standardized measure using Hardy–Weinberg heterozygosities, and four measures based on the chi-square statistic for testing for association between alleles at two loci. The standardized chi-square measure that best predicted usable LD between multi-allelic markers and QTLs, based on our previous work, overestimated usable SNP–SNP or SNP–QTL LD. Instead, three other measures were found to be good predictors of usable SNP–SNP or SNP–QTL LD when LD is generated by drift. Therefore, the LD measure between multi-allelic markers that is best for predicting usable LD in a population depends on the type of markers (i.e. multi-allelic or biallelic) that will eventually be used for QTL mapping or MAS.

Crossref Citations

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Andreescu, Cristina Avendano, Santiago Brown, Stewart R Hassen, Abebe Lamont, Susan J and Dekkers, Jack C M 2007. Linkage Disequilibrium in Related Breeding Lines of Chickens. Genetics, Vol. 177, Issue. 4, p. 2161.

Zaykin, Dmitri V Pudovkin, Alexander and Weir, Bruce S 2008. Correlation-Based Inference for Linkage Disequilibrium With Multiple Alleles. Genetics, Vol. 180, Issue. 1, p. 533.

Slatkin, Montgomery 2008. Linkage disequilibrium — understanding the evolutionary past and mapping the medical future. Nature Reviews Genetics, Vol. 9, Issue. 6, p. 477.

Sargolzaei, M. Schenkel, F.S. Jansen, G.B. and Schaeffer, L.R. 2008. Extent of Linkage Disequilibrium in Holstein Cattle in North America. Journal of Dairy Science, Vol. 91, Issue. 5, p. 2106.

MacLEOD, I. M. MEUWISSEN, T. H. E. HAYES, B. J. and GODDARD, M. E. 2009. A novel predictor of multilocus haplotype homozygosity: comparison with existing predictors. Genetics Research, Vol. 91, Issue. 6, p. 413.

Lipkin, E Straus, K Stein, R Tal Bagnato, A Schiavini, F Fontanesi, L Russo, V Medugorac, I Foerster, M Sölkner, J Dolezal, M Medrano, J F Friedmann, A and Soller, M 2009. Extensive Long-Range and Nonsyntenic Linkage Disequilibrium in Livestock Populations: Deconstruction of a Conundrum. Genetics, Vol. 181, Issue. 2, p. 691.

Banos, G. and Coffey, M.P. 2010. Short communication: Characterization of the genome-wide linkage disequilibrium in 2 divergent selection lines of dairy cows. Journal of Dairy Science, Vol. 93, Issue. 6, p. 2775.

Cahan, Patrick and Graubert, Timothy A 2010. Integrated genomics of susceptibility to alkylator-induced leukemia in mice. BMC Genomics, Vol. 11, Issue. 1,

Marty, Amandine Amigues, Yves Servin, Bertrand Renand, Gilles Levéziel, Hubert and Rocha, Dominique 2010. Genetic Variability and Linkage Disequilibrium Patterns in the Bovine DNAJA1 Gene. Molecular Biotechnology, Vol. 44, Issue. 3, p. 190.

Tang, G. Li, X. Plastow, G. Moore, S.S. and Wang, Z. 2011. Developing marker-assisted models for evaluating growth traits in Canadian beef cattle genetic improvement. Livestock Science, Vol. 138, Issue. 1-3, p. 62.

Brito, Fernanda V Neto, José Sargolzaei, Mehdi Cobuci, Jaime A and Schenkel, Flavio S 2011. Accuracy of genomic selection in simulated populations mimicking the extent of linkage disequilibrium in beef cattle. BMC Genetics, Vol. 12, Issue. 1, p. 80.

Huang, Yong-Zhen He, Hua Sun, Jia-Jie Wang, Jing Li, Zhuan-Jian Lan, Xian-Yong Lei, Chu-Zhao Zhang, Chun-Lei Zhang, En-Ping Wang, Ju-Qiang Chen, Hong and Bell, John 2011. Haplotype combination of SREBP-1c gene sequence variants is associated with growth traits in cattle. Genome, Vol. 54, Issue. 6, p. 507.

Li, Z.J. Lan, X.Y. Sun, J.J. Wang, J. Huang, Y.Z. Guo, W.J. Zhang, B. Lei, C.Z. Zhang, C.L. and Chen, H. 2012. Molecular characterization and haplotype combination of PrRP gene polymorphism and its association with production traits in Chinese native goats. Small Ruminant Research, Vol. 105, Issue. 1-3, p. 69.

NI, Gui-Yan ZHANG, Zhe JIANG, Li MA, Pei-Pei ZHANG, Qin and DING, Xing-Dong 2012. Chinese Holstein Cattle effective population size estimated from whole genome linkage disequilibrium. Hereditas (Beijing), Vol. 34, Issue. 1, p. 50.

Huang, Yong-Zhen Zhan, Zhao-Yang Sun, Yu-Jia Wang, Jing Li, Ming-Xun Lan, Xian-Yong Lei, Chu-Zhao Zhang, Chun-Lei Chen, Hong and Bell, J.B. 2013. Comparative analysis of the IGF2 and ZBED6 gene variants and haplotypes reveals significant effect of growth traits in cattle. Genome, Vol. 56, Issue. 6, p. 327.

Wang, J. Wang, C. Gao, Y. Lan, X.-Y. Lei, C.-Z. Wang, J.-Q. and Chen, H. 2013. Impacts of single nucleotide polymorphisms and haplotypes in the bovine Dapper1 gene on body weight. Genetics and Molecular Research, Vol. 12, Issue. 2, p. 1254.

Zhu, M. Zhu, B. Wang, Y. H. Wu, Y. Xu, L. Guo, L. P. Yuan, Z. R. Zhang, L. P. Gao, X. Gao, H. J. Xu, S. Z. and Li, J. Y. 2013. Linkage Disequilibrium Estimation of Chinese Beef Simmental Cattle Using High-density SNP Panels. Asian-Australasian Journal of Animal Sciences, Vol. 26, Issue. 6, p. 772.

Huang, Yong-Zhen Wang, Ke-Yi He, Hua Shen, Qing-Wu Lei, Chu-Zhao Lan, Xian-Yong Zhang, Chun-Lei and Chen, Hong 2013. Haplotype distribution in the GLI3 gene and their associations with growth traits in cattle. Gene, Vol. 513, Issue. 1, p. 141.

Huang, Yong-Zhen He, Hua Zhan, Zhao-Yang Sun, Yu-Jia Li, Ming-Xun Lan, Xian-Yong Lei, Chu-Zhao Zhang, Chun-Lei and Chen, Hong 2013. Relationship of polymorphisms within ZBED6 gene and growth traits in beef cattle. Gene, Vol. 526, Issue. 2, p. 107.

Brinkmeyer‐Langford, C. L. Cai, J. J. Gill, C. A. and Skow, L. C. 2013. Microsatellite variation in the equine MHC. Animal Genetics, Vol. 44, Issue. 3, p. 267.

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Evaluation of linkage disequilibrium measures between multi-allelic markers as predictors of linkage disequilibrium between single nucleotide polymorphisms

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