Ling Ashley S, Hay El Hamidi
USDA Agricultural Research Service, Fort Keogh Livestock and Range Research Laboratory, Miles City, MT 59301, USA.
Transl Anim Sci. 2024 Feb 29;8:txae024. doi: 10.1093/tas/txae024. eCollection 2024.
Cattle operations in the Northern Great Plains region of the United States face extreme cold weather conditions and require nutritional supplementation over the winter season in order for animals to maintain body condition. In cow-calf operations, body condition scores (BCS) measured at calving and breeding have been shown to be associated with several economically important health and fertility traits, so maintenance of BCS is both an animal welfare and economic concern. A low-to-medium heritability has been found for BCS when measured across various production stages, indicating a large environmental influence but sufficient genetic basis for selection. The present study evaluated BCS measured prior to calving (late winter) and breeding (early summer) under three winter supplementation environments in a multitrait linear mixed model. Traits were discretized by winter supplementation and genetic correlations between environments were considered a reflection of evidence for genotype-by-environment interactions between BCS and diet. Winter supplementation treatments were fed October through April and varied by range access and protein content: 1) feedlot environment with approximately 15% crude protein (CP) corn/silage diet, 2) native rangeland access with 1.8 kg of an 18% CP pellet supplement, and 3) native rangeland access with a self-fed 50% CP and mineral supplement. A total of 2,988 and 2,353 records were collected across multiple parities on 1,010 and 800 individuals for prebreeding and precalving BCS, respectively. Heifers and cows came from a composite beef cattle breed developed and maintained by the USDA Fort Keogh Livestock and Range Research Laboratory near Miles City, Montana. Genetic correlations between treatments 1 and 2, 1 and 3, and 2 and 3 were 0.98, 0.78, and 0.65 and 1.00, 0.98, and 0.99 for precalving and prebreeding BCS, respectively. This provides moderate evidence of genotype-by-environment interactions for precalving BCS under treatment 3 relative to treatments 1 and 2, but no evidence for genotype-by-environment interactions for prebreeding BCS. Treatment 3 differed substantially in CP content relative to treatments 1 and 2, indicating that some animals differ in their ability to maintain BCS up to spring calving across a protein gradient. These results indicate the potential for selection of animals with increased resilience under cold weather conditions and high protein, restricted energy diets to maintain BCS.
美国大平原北部地区的养牛场面临极端寒冷的天气条件,冬季需要进行营养补充,以使动物保持身体状况。在母牛-犊牛养殖场,产犊和配种时测量的身体状况评分(BCS)已被证明与几个经济上重要的健康和繁殖性状相关,因此维持BCS既是动物福利问题,也是经济问题。在不同生产阶段测量时,BCS的遗传力为低到中等,这表明环境影响很大,但有足够的遗传基础可供选择。本研究在多性状线性混合模型中,评估了在三种冬季补充环境下产犊前(冬末)和配种前(初夏)测量的BCS。性状按冬季补充情况进行离散化处理,环境之间的遗传相关性被视为BCS与日粮之间基因型-环境互作证据的反映。冬季补充处理从10月持续到4月,根据牧场准入和蛋白质含量而有所不同:1)饲养场环境,采用约15%粗蛋白(CP)的玉米/青贮饲料日粮;2)可进入原生牧场,补充1.8千克含18%CP的颗粒饲料;3)可进入原生牧场,自由采食50%CP和矿物质补充剂。分别在1,010头和800头个体的多个胎次上收集了2,988条和2,353条记录,用于配种前和产犊前的BCS。小母牛和母牛来自美国农业部位于蒙大拿州迈尔斯城附近的基奥堡牲畜与草原研究实验室培育和维持的一个复合肉牛品种。处理1和2、1和3、2和3之间的遗传相关性,产犊前BCS分别为0.98、0.78和0.65,配种前BCS分别为1.00、0.98和0.99。这为处理3相对于处理1和2的产犊前BCS基因型-环境互作提供了适度证据,但没有为配种前BCS的基因型-环境互作提供证据。处理3的CP含量相对于处理1和2有很大差异,这表明一些动物在跨越蛋白质梯度直至春季产犊时维持BCS的能力不同。这些结果表明,有可能选择在寒冷天气条件下以及高蛋白、能量受限日粮情况下具有更强恢复力以维持BCS的动物。
