Breeding for sustainability: Development of an index to reduce greenhouse gas in dairy cattle.

IF 4 2区农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE

Animal Pub Date : 2025-03-20 DOI:10.1016/j.animal.2025.101491

C Richardson, P Amer, M Post, T Oliveria, K Grant, J Crowley, C Quinton, F Miglior, A Fleming, C F Baes, F Malchiodi

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引用次数: 0

Abstract

Several genetic selection strategies can be incorporated into dairy cattle breeding programmes to target a reduction in greenhouse gas (GHG) emissions and provide a mitigation strategy with only modest additional cost, or labour expense, to the dairy producer. This can be achieved by targeting genetic progress in a specific trait (i.e. methane) or by building selection indexes that balance economic gain and environmental impact for more conventional traits, or both. Various countries have initiated efforts to incorporate emission-related traits into their national selection indexes. The strategies for reducing emissions vary due to system-specific objectives and limitations, ranging from specific methane breeding values to broader sustainability indexes. While methane breeding values may not be commercially available in most cases, Canada has taken the lead as the first country to release a methane breeding value, developed using mid-IR spectral data from milk samples and GreenFeed phenotyped Holstein cows, and develop a GHG index which includes a direct methane trait. The GHG index proposed for commercialisation is expected to reduce emissions per cow per year by 168 kg CO₂e per SD of index, and is composed of Herd Life, Feed Efficiency, Methane Efficiency, and Body Maintenance Requirement traits. The reduction in emissions is largely driven by a genetic gain in Methane Efficiency and Body Maintenance Requirements, with results indicating that omission of a direct methane trait from the index would lead to an unfavourable response in individual cow's own genetic potential to reduce enteric methane output. Other countries are also progressing on this front; Spain has developed a methane estimated breeding value (EBV) and the Netherlands and Denmark are set to publish methane EBV in 2025. Motivation for the use of GHG indexes is strengthening in high-income countries. This motivation could be greatly accelerated if auditable, transparent and scientifically robust ways of recognising emissions changes due to genetic selection were developed. Ideally, these methods would support both national policy setting and supply agreements with milk processors.

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可持续育种：制定减少奶牛温室气体排放的指数。

一些遗传选择策略可以纳入奶牛育种计划，以减少温室气体（GHG）排放为目标，并提供一种缓解策略，对奶牛生产者来说，只需要很少的额外成本或劳动力费用。这可以通过以特定性状（如甲烷）的遗传进展为目标来实现，或者通过建立选择指数来平衡更传统性状的经济收益和环境影响，或者两者兼而有之。各国已经开始努力将与排放有关的特征纳入其国家选择指标。由于系统特定的目标和限制，从特定的甲烷繁殖值到更广泛的可持续性指标，减少排放的战略各不相同。虽然甲烷育种值在大多数情况下可能无法在商业上获得，但加拿大已经率先成为第一个发布甲烷育种值的国家，该值使用牛奶样本和GreenFeed表型荷斯坦奶牛的中红外光谱数据开发，并开发了包括直接甲烷性状的温室气体指数。拟议商业化的温室气体指数预计每SD指数每年可减少每头奶牛168公斤二氧化碳当量的排放量，该指数由牛群寿命、饲料效率、甲烷效率和身体维持需求特征组成。排放量的减少在很大程度上是由甲烷效率和身体维持需求的遗传增益所驱动的，结果表明，在指数中遗漏直接的甲烷性状将导致个体奶牛自身的遗传潜力产生不利的反应，以减少肠道甲烷排放量。其他国家也在这方面取得进展；西班牙已经开发了甲烷估计育种值（EBV），荷兰和丹麦将在2025年发布甲烷EBV。高收入国家使用温室气体指数的动机正在增强。如果开发出可审计的、透明的、科学上可靠的方法来识别基因选择导致的排放变化，这一动机可能会大大加快。理想情况下，这些方法将支持国家政策制定和与牛奶加工商的供应协议。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Animal 农林科学-奶制品与动物科学

CiteScore

7.50

自引率

2.80%

发文量

246

审稿时长

3 months

期刊介绍： Editorial board animal attracts the best research in animal biology and animal systems from across the spectrum of the agricultural, biomedical, and environmental sciences. It is the central element in an exciting collaboration between the British Society of Animal Science (BSAS), Institut National de la Recherche Agronomique (INRA) and the European Federation of Animal Science (EAAP) and represents a merging of three scientific journals: Animal Science; Animal Research; Reproduction, Nutrition, Development. animal publishes original cutting-edge research, ''hot'' topics and horizon-scanning reviews on animal-related aspects of the life sciences at the molecular, cellular, organ, whole animal and production system levels. The main subject areas include: breeding and genetics; nutrition; physiology and functional biology of systems; behaviour, health and welfare; farming systems, environmental impact and climate change; product quality, human health and well-being. Animal models and papers dealing with the integration of research between these topics and their impact on the environment and people are particularly welcome.