Open AccessDeciphering the Genetic Blueprint behind Holstein Milk Proteins and Production
Author(s) -
Hyun Jeong Lee,
Jaemin Kim,
Taeheon Lee,
Jun-Kyu Son,
Hobaek Yoon,
KwangSoo Baek,
Jin Young Jeong,
Yong-Min Cho,
KyungTai Lee,
ByoungChul Yang,
Hyun-Joo Lim,
KwangHyun Cho,
Tae-Hun Kim,
Eung-Gi Kwon,
Jungrye Nam,
Woori Kwak,
Seoae Cho,
Heebal Kim
Publication year - 2014
Publication title -
genome biology and evolution
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.702
H-Index - 74
ISSN - 1759-6653
DOI - 10.1093/gbe/evu102
Subject(s) - biology , holstein cattle , bovine genome , genome , genetics , domestication , selection (genetic algorithm) , inbreeding , inbreeding depression , dairy cattle , gene , population , demography , artificial intelligence , sociology , computer science
Holstein is known to provide higher milk yields than most other cattle breeds, and the dominant position of Holstein today is the result of various selection pressures. Holstein cattle have undergone intensive selection for milk production in recent decades, which has left genome-wide footprints of domestication. To further characterize the bovine genome, we performed whole-genome resequencing analysis of 10 Holstein and 11 Hanwoo cattle to identify regions containing genes as outliers in Holstein, including CSN1S1, CSN2, CSN3, and KIT whose products are likely involved in the yield and proteins of milk and their distinctive black-and-white markings. In addition, genes indicative of positive selection were associated with cardiovascular disease, which is related to simultaneous propagation of genetic defects, also known as inbreeding depression in Holstein.
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