Animal and Dairy Science Department, University of Georgia, Athens 30602-2771.
J Anim Sci. 2012 Jul;90(7):2152-8. doi: 10.2527/jas.2011-4365.
The objectives of this study were to determine if sires perform consistently across altitude and to quantify the genetic relationship between growth and survival at differing altitudes. Data from the American Angus Association included weaning weight (WW) adjusted to 205 (n = 77,771) and yearling weight adjusted to 365 (n = 39,450) d of age from 77,771 purebred Angus cattle born in Colorado between 1972 and 2007. Postweaning gain (PWG) was calculated by subtracting adjusted WW from adjusted yearling weight. Altitude was assigned to each record based upon the zip code of each herd in the database. Records for WW and PWG were each split into 2 traits measured at low and high altitude, with the records from medium altitude removed from the data due to inconsistencies between growth performance and apparent culling rate. A binary trait, survival (SV), was defined to account for censored records at yearling for each altitude. It was assumed that, at high altitude, individuals missing a yearling weight either died or required relocation to a lower altitude predominantly due to brisket disease, a condition common at high altitude. Model 1 considered each WW and PWG measured at 2 altitudes as separate traits. Model 2 treated PWG and SV measured as separate traits due to altitude. Models included the effects of weaning contemporary group, age of dam, animal additive genetic effects, and residual. Maternal genetic and maternal permanent environmental effects were included for WW. Heritability estimates for WW in Model 1 were 0.28 and 0.26 and for PWG were 0.26 and 0.19 with greater values in low altitude. Genetic correlations between growth traits measured at different altitude were moderate in magnitude: 0.74 for WW and 0.76 for PWG and indicate possibility of reranking of sires across altitude. Maternal genetic correlation between WW at varying altitude of 0.75 also indicates these may be different traits. In Model 2, heritabilities were 0.14 and 0.27 for PWG and 0.36 and 0.47 for SV. Genetic correlation between PWG measured at low and high altitude was 0.68. Favorable genetic correlations were estimated between SV and PWG within and between altitudes, suggesting that calves with genetics for increased growth from weaning to yearling also have increased genetic potential for SV. Genetic evaluations of PWG in different altitudes should consider preselection of the data, by using a censoring trait, like survivability to yearling.
本研究的目的是确定父本在不同海拔高度是否表现一致,并量化在不同海拔高度生长和存活的遗传关系。数据来自美国安格斯协会,包括断奶重(WW)调整至 205(n=77771)和 365 日龄体重调整至 365(n=39450),来自 1972 年至 2007 年科罗拉多州出生的 77771 头纯种安格斯牛。断奶后增重(PWG)通过从调整后的 365 日龄体重中减去调整后的 WW 来计算。根据数据库中每个牛群的邮政编码为每个记录分配海拔。WW 和 PWG 的记录分别分为在低海拔和高海拔测量的 2 个性状,由于生长性能和明显淘汰率之间的不一致,从中删除了中海拔的记录。生存(SV)的二元性状定义为每个海拔的记录的年度生存率。假设在高海拔地区,由于牛只患有胸肋病,要么死亡,要么需要转移到较低的海拔,所以缺少 365 日龄体重的个体。该疾病在高海拔地区很常见。模型 1 将在 2 个海拔高度测量的每个 WW 和 PWG 视为单独的性状。模型 2 由于海拔的原因,将 PWG 和 SV 视为单独的性状。模型包括断奶同期组、母畜年龄、动物加性遗传效应和残差的影响。WW 包括母体遗传和母体永久环境效应。模型 1 中 WW 的遗传力估计值为 0.28 和 0.26,PWG 的遗传力估计值为 0.26 和 0.19,低海拔地区的遗传力估计值较高。在不同海拔高度测量的生长性状之间的遗传相关性为中度:WW 为 0.74,PWG 为 0.76,表明在不同海拔高度可能存在对父本的重新排名。在不同海拔 WW 之间的母体遗传相关性为 0.75,也表明这可能是不同的性状。在模型 2 中,PWG 的遗传力估计值为 0.14 和 0.27,SV 的遗传力估计值为 0.36 和 0.47。低海拔和高海拔之间 PWG 的遗传相关性为 0.68。在不同海拔高度,SV 和 PWG 之间和之间估计了有利的遗传相关性,表明从断奶到 1 岁时生长的遗传潜力增加的小牛也具有增加的 SV 遗传潜力。在不同海拔高度进行 PWG 的遗传评估时,应考虑通过使用生存性状(如年度生存率)对数据进行预筛选。
