Bayesian analyses of multiple epistatic QTL models for body weight and body composition in mice

NENGJUN YI; DENISE K. ZINNIEL; KYOUNGMI KIM; EUGENE J. EISEN; ALFRED BARTOLUCCI; DAVID B. ALLISON; DANIEL POMP

doi:10.1017/S0016672306007944

Abstract

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To comprehensively investigate the genetic architecture of growth and obesity, we performed Bayesian analyses of multiple epistatic quantitative trait locus (QTL) models for body weights at five ages (12 days, 3, 6, 9 and 12 weeks) and body composition traits (weights of two fat pads and five organs) in mice produced from a cross of the F1 between M16i (selected for rapid growth rate) and CAST/Ei (wild-derived strain of small and lean mice) back to M16i. Bayesian model selection revealed a temporally regulated network of multiple QTL for body weight, involving both strong main effects and epistatic effects. No QTL had strong support for both early and late growth, although overlapping combinations of main and epistatic effects were observed at adjacent ages. Most main effects and epistatic interactions had an opposite effect on early and late growth. The contribution of epistasis was more pronounced for body weights at older ages. Body composition traits were also influenced by an interacting network of multiple QTLs. Several main and epistatic effects were shared by the body composition and body weight traits, suggesting that pleiotropy plays an important role in growth and obesity.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Zhang, Yuan-Ming 2006. Advances on methods for mapping QTL in plant. Chinese Science Bulletin, Vol. 51, Issue. 23, p. 2809.

Yi, Nengjun Shriner, Daniel Banerjee, Samprit Mehta, Tapan Pomp, Daniel and Yandell, Brian S 2007. An Efficient Bayesian Model Selection Approach for Interacting Quantitative Trait Loci Models With Many Effects. Genetics, Vol. 176, Issue. 3, p. 1865.

Shao, Hongguang Reed, Danielle R. and Tordoff, Michael G. 2007. Genetic loci affecting body weight and fatness in a C57BL/6J × PWK/PhJ mouse intercross. Mammalian Genome, Vol. 18, Issue. 12, p. 839.

Ishikawa, Akira Kim, Eun-Hee Bolor, Hasbaira Mollah, Md. Bazlur R. and Namikawa, Takao 2007. A growth QTL (Pbwg1) region of mouse chromosome 2 contains closely linked loci affecting growth and body composition. Mammalian Genome, Vol. 18, Issue. 4, p. 229.

Xu, Shizhong and Jia, Zhenyu 2007. Genomewide Analysis of Epistatic Effects for Quantitative Traits in Barley. Genetics, Vol. 175, Issue. 4, p. 1955.

Davis, Richard C. Jin, Angela Rosales, Melenie Yu, Suzanne Xia, Xiaoyu Ranola, Kathleen Schadt, Eric E. and Lusis, Aldons J. 2007. A genome-wide set of congenic mouse strains derived from CAST/Ei on a C57BL/6 background. Genomics, Vol. 90, Issue. 3, p. 306.

Gordon, Ryan R. Hunter, Kent W. Sørensen, Peter and Pomp, Daniel 2008. Genotype × diet interactions in mice predisposed to mammary cancer. I. Body weight and fat. Mammalian Genome, Vol. 19, Issue. 3, p. 163.

TANG, Zai-xiang and XU, Chen-wu 2008. Advances in the Research of Strategies and Methods for Analyzing Complex Traits. Agricultural Sciences in China, Vol. 7, Issue. 7, p. 775.

Yi, N and Shriner, D 2008. Advances in Bayesian multiple quantitative trait loci mapping in experimental crosses. Heredity, Vol. 100, Issue. 3, p. 240.

Vaughan, Laura K. Divers, Jasmin Padilla, Miguel A. Redden, David T. Tiwari, Hemant K. Pomp, Daniel and Allison, David B. 2009. The use of plasmodes as a supplement to simulations: A simple example evaluating individual admixture estimation methodologies. Computational Statistics & Data Analysis, Vol. 53, Issue. 5, p. 1755.

Yi, Nengjun and Banerjee, Samprit 2009. Hierarchical Generalized Linear Models for Multiple Quantitative Trait Locus Mapping. Genetics, Vol. 181, Issue. 3, p. 1101.

YAMAMOTO, AKIHIKO ANHOLT, ROBERT R. H. and MACKAY, TRUDY F. C. 2009. Epistatic interactions attenuate mutations affecting startle behaviour inDrosophila melanogaster. Genetics Research, Vol. 91, Issue. 6, p. 373.

Flint, Jonathan and Mackay, Trudy F.C. 2009. Genetic architecture of quantitative traits in mice, flies, and humans. Genome Research, Vol. 19, Issue. 5, p. 723.

Ankra-Badu, G A Pomp, D Shriner, D Allison, D B and Yi, N 2009. Genetic influences on growth and body composition in mice: multilocus interactions. International Journal of Obesity, Vol. 33, Issue. 1, p. 89.

Duthie, C. Simm, G. Doeschl-Wilson, A. Kalm, E. Knap, P. W. and Roehe, R. 2010. Epistatic analysis of carcass characteristics in pigs reveals genomic interactions between quantitative trait loci attributable to additive and dominance genetic effects1. Journal of Animal Science, Vol. 88, Issue. 7, p. 2219.

LI, JUN REYNOLDS, RICHARD POMP, DANIEL ALLISON, DAVID B. and YI, NENGJUN 2010. Mapping interacting QTL for count phenotypes using hierarchical Poisson and binomial models: an application to reproductive traits in mice. Genetics Research, Vol. 92, Issue. 1, p. 13.

ISHIKAWA, Akira and LI, Chun 2010. Development and Characterization of a Congenic Strain Carrying Pbwg12, a Growth QTL on Mouse Chromosome 12. Experimental Animals, Vol. 59, Issue. 1, p. 109.

Fawcett, Gloria L. Jarvis, Joseph P. Roseman, Charles C. Wang, Bing Wolf, Jason B. and Cheverud, James M. 2010. Fine‐mapping of Obesity‐related Quantitative Trait Loci in an F9/10 Advanced Intercross Line. Obesity, Vol. 18, Issue. 7, p. 1383.

Ankra-Badu, Georgina A Shriner, Daniel Le Bihan-Duval, Elisabeth Mignon-Grasteau, Sandrine Pitel, Frédérique Beaumont, Catherine Duclos, Michel J Simon, Jean Porter, Tom E Vignal, Alain Cogburn, Larry A Allison, David B Yi, Nengjun and Aggrey, Samuel E 2010. Mapping main, epistatic and sex-specific QTL for body composition in a chicken population divergently selected for low or high growth rate. BMC Genomics, Vol. 11, Issue. 1,

Jarvis, Joseph P and Cheverud, James M 2011. Mapping the Epistatic Network Underlying Murine Reproductive Fatpad Variation. Genetics, Vol. 187, Issue. 2, p. 597.

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Bayesian analyses of multiple epistatic QTL models for body weight and body composition in mice

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