Identification and Dissection of Four Major QTL Affecting Milk Fat Content in the German Holstein-Friesian Population

Xiaolong Wang,Ruedi Fries,Friedrich Reinhardt,Christine Wurmser,Jens Tetens,Georg Thaller,Simone Jung,Hubert Pausch,Vladimir N Uversky

doi:10.1371/journal.pone.0040711

Xiaolong Wang, Ruedi Fries + Show 7 more

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https://doi.org/10.1371/journal.pone.0040711

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Journal: PloS one	Publication Date: Jul 11, 2012
Citations: 108	License type: CC BY 4.0

Affiliation: Technical University of Munich, Kiel University

Abstract

Milk composition traits exhibit a complex genetic architecture with a small number of major quantitative trait loci (QTL) explaining a large fraction of the genetic variation and numerous QTL with minor effects. In order to identify QTL for milk fat percentage (FP) in the German Holstein-Friesian (HF) population, a genome-wide association study (GWAS) was performed. The study population consisted of 2327 progeny-tested bulls. Genotypes were available for 44,280 SNPs. Phenotypes in the form of estimated breeding values (EBVs) for FP were used as highly heritable traits. A variance components-based approach was used to account for population stratification. The GWAS identified four major QTL regions explaining 46.18% of the FP EBV variance. Besides two previously known FP QTL on BTA14 (P = 8.91×10−198) and BTA20 (P = 7.03×10−12) within DGAT1 and GHR, respectively, we uncovered two additional QTL regions on BTA5 (P = 2.00×10−13) and BTA27 (P = 9.83×10−5) encompassing EPS8 and GPAT4, respectively. EPS8 and GPAT4 are involved in lipid metabolism in mammals. Re-sequencing of EPS8 and GPAT4 revealed 50 polymorphisms. Genotypes for five of them were inferred for the entire study population. Two polymorphisms affecting potential transcription factor binding sites of EPS8 (P = 1.40×10−12) and GPAT4 (P = 5.18×10−5), respectively, were highly significantly associated with the FP EBV. Our results provide evidence that alteration of regulatory sites is an important aspect of genetic variation of complex traits in cattle.

Highlights

Improvement of milk yield and composition is a major objective of dairy cattle breeding programs and highly reliable breeding values are estimated to this end
The genome-wide association study based on 44,280 SNPs and 2327 progeny-tested bulls identified four quantitative trait loci (QTL) for fat percentage (FP) on BTA5, BTA14, BTA20 and BTA27 in the German HF population (Figure 1)
The four identified QTL regions account for a large part of the estimated breeding values (EBVs) variance (46.18%)

Summary

Introduction

Improvement of milk yield and composition is a major objective of dairy cattle breeding programs and highly reliable breeding values are estimated to this end. Milk composition traits such as protein and fat content are important production traits and permit insights into the metabolic constitution of lactating cows [1]. Most prominently, a K232A-substitution within the acylCoA:diacylglycerol acyltransferase encoding gene DGAT1 [6,7] and a F279Y-substitution within the growth hormone receptor encoding gene GHR [8,9] have been well characterized These two polymorphisms account for a major fraction of the genetic variation of FP in various cattle breeds These two polymorphisms account for a major fraction of the genetic variation of FP in various cattle breeds (e.g. [10,11,12])

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