Misztal I
J Anim Sci. 2017 Apr;95(4):1780-1787. doi: 10.2527/jas.2016.0953.
Production environments are expected to change, mostly to a hotter climate but also possibly more extreme and drier. Can the current generation of farm animals cope with the changes or should it be specifically selected for changing conditions? In general, genetic selection produces animals with a smaller environmental footprint but also with smaller environmental flexibility. Some answers are coming from heat-stress research across species, with heat tolerance partly understood as a greater environmental flexibility. Specific studies in various species show the complexities of defining and selecting for heat tolerance. In Holsteins, the genetic component for effect of heat stress on production approximately doubles in second and quadruples in third parity. Cows with elevated body temperature have the greatest production under heat stress but probably are at risk for increased mortality. In hot but less intensive environments, the effect of heat stress on production is minimal, although the negative effect on fertility remains. Mortality peaks under heat stress and increases with parity. In Angus, the effect of heat stress is stronger only in selected regions, probably because of adaptation of calving seasons to local conditions and crossbreeding. Genetically, the direct effect shows variability because of heat stress, but the maternal effect does not, probably because dams shield calves from environmental challenges. In pigs, the effect of heat stress is strong for commercial farms but almost nothing for nucleus farms, which have lower pig density and better heat abatement. Under intensive management, heat stress is less evident in drier environments because of more efficient cooling. A genetic component of heat stress exists, but it is partly masked by improving management and selection based on data from elite farms. Genetic selection may provide superior identification of heat-tolerant animals, but a few cycles may be needed for clear results. Also, simple traits exist that are strongly related to heat stress (e.g., slick hair in dairy cattle and shedding intensity in Angus). Defining resilience may be difficult, especially when masked by improving environment. Under climate change, the current selection strategies may be adequate if they 1) are accompanied by constantly improving management, 2) use commercial data, and 3) include traits important under climate change (e.g., mortality).
预计生产环境将会发生变化,主要是气候变得更炎热,也可能更加极端和干燥。当代的农场动物能否应对这些变化,还是应该针对变化的条件进行专门选育?一般来说,基因选择培育出的动物对环境的影响较小,但环境适应能力也较弱。跨物种的热应激研究给出了一些答案,耐热性在一定程度上被理解为具有更强的环境适应能力。对各种物种的具体研究表明,定义和选择耐热性存在复杂性。在荷斯坦奶牛中,热应激对生产影响的遗传成分在第二胎时大约翻倍,在第三胎时则增至四倍。体温升高的奶牛在热应激下产量最高,但可能面临死亡率上升的风险。在炎热但集约化程度较低的环境中,热应激对生产的影响最小,不过对繁殖力的负面影响依然存在。热应激下死亡率会达到峰值,并随着胎次增加。在安格斯牛中,热应激的影响仅在特定地区较为强烈,这可能是由于产犊季节适应了当地条件以及杂交的缘故。从基因角度来看,热应激的直接影响表现出变异性,但母体效应则没有,这可能是因为母畜能保护幼崽免受环境挑战。在猪身上,热应激对商业养殖场影响很大,但对核心种猪场几乎没有影响,因为核心种猪场猪的密度较低且有更好的降温措施。在集约化管理下,由于冷却效率更高,热应激在干燥环境中不太明显。热应激存在遗传成分,但通过基于精英养殖场数据改进管理和选育,这种成分在一定程度上被掩盖了。基因选择可能有助于更好地识别耐热动物,但可能需要几个周期才能得到明确结果。此外,还存在一些与热应激密切相关的简单性状(如奶牛的光滑毛发和安格斯牛的脱毛强度)。定义恢复力可能很困难,尤其是当它被改善的环境所掩盖时。在气候变化的情况下,如果当前的选择策略满足以下条件,可能就足够了:1)伴随着持续改进的管理;2)使用商业数据;3)包括在气候变化下重要的性状(如死亡率)。
