Effects of ambient temperature, energy density, and energy source on energy partition and plasma metabolomics profile of finishing pigs.

IF 6.1 1区农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE

Animal Nutrition Pub Date : 2025-03-06 eCollection Date: 2025-06-01 DOI:10.1016/j.aninu.2025.01.005

Dan Jiang, Kai Zhou, Dongsheng Che, Hailong Jiang, Rui Han, Guixin Qin

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引用次数: 0

Abstract

Ambient temperature is an important factor affecting metabolic processes in animals, and its effect on energy metabolism is becoming more evident. Yet, integrative analysis of energy metabolism in finishing pigs at different combinations of ambient temperature, energy density and energy sources, still remain underexplored. In order to determine the special characteristics of energy metabolism of finishing pigs in low-temperature environment, the effects of different combinations of ambient temperature, energy density, and energy source on underlying mechanisms were elucidated by assessing energy metabolism using integrative indirect calorimetry and non-targeted plasma metabolomics analyses. Thirty-two finishing pigs (Duroc × Large White × Landrace) with similar body weight of 85.44 ± 2.04 kg were allotted in a 2 × 2 × 2 factorial arrangement (8 treatment groups, 4 replicates per group, 1 pig per replicate), which included two ambient temperatures (low temperature [10 °C] and normal temperature [20 °C]), two energy densities (normal energy density [NE, 14.02 MJ/kg] and high energe density [HE, 15.14 MJ/kg]), and two energy sources (low-oil source and high-oil source). The experiment period lasted 11 days. Increasing the energy density of the diet by adding oil changed the energy source in a low-temperature environment, improved crude fat digestibility (P < 0.001), and reduced the feed/gain ratio of pigs (P = 0.004), with a tendency for higher average daily gain (P = 0.098), which would increase energy utilization. Adding oil to the diet altered energy sources at low temperature, reducing carbon dioxide emission by 3.10%, increasing energy retention and fat oxidation (P < 0.05). Further, optimizing energy sources by adding oil significantly improved serum glucose (GLU) content (P < 0.001) and reduced urea nitrogen (UN) content at normal temperature (P < 0.001), with the same trend observed at low temperature. The metabolites in the eight groups were mainly enriched in the sphingolipid signaling pathway, insulin resistance, and glycerophospholipid metabolism (P < 0.05). Energy metabolism in finishing pigs was not only affected by ambient temperature and energy density, but also by energy source, leading to variations in metabolic pathways for different energy substances. Increasing the dietary energy density by increasing oil supplementation at low temperature is an effective way to improve the growth performance of finishing pigs while reducing pollutant emissions. The study provides a new solution for optimizing energy nutrition for finishing pigs in low-temperature environment.

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环境温度、能量密度和能量来源对育肥猪能量分配和血浆代谢组学特征的影响

环境温度是影响动物代谢过程的重要因素，其对能量代谢的影响越来越明显。然而，对不同环境温度、能量密度和能量来源组合下育肥猪能量代谢的综合分析仍有待进一步研究。为了确定低温环境下育肥猪能量代谢的特殊性，本研究通过综合间接量热法和非靶向血浆代谢组学分析，探讨了不同环境温度、能量密度和能量来源组合对育肥猪能量代谢的影响机制。试验采用2 × 2 × 2因子设计（8个处理组，每组4个重复，每个重复1头猪），设2个环境温度（低温[10°C]和常温[20°C]）、2个能量密度（正常能量密度[NE， 14.02 MJ/kg]和高能量密度[HE， 15.14 MJ/kg]）、2个能量源（低油源和高油源）。试验期11 d。添加油提高饲粮能量密度改变了低温环境下的能量来源，提高了粗脂肪消化率（P < 0.001），降低了猪的料重比（P = 0.004），并有提高平均日增重的趋势（P = 0.098），提高了能量利用率。饲粮中添加油改变了低温条件下的能量来源，降低了3.10%的二氧化碳排放量，提高了能量潴留和脂肪氧化（P < 0.05）。此外，通过添加油优化能量源，在常温下显著提高了血清葡萄糖（GLU）含量（P < 0.001），显著降低了尿素氮（UN）含量（P < 0.001），在低温下也有相同的趋势。8组代谢产物主要富集于鞘脂信号通路、胰岛素抵抗和甘油磷脂代谢（P < 0.05）。育肥猪的能量代谢不仅受环境温度和能量密度的影响，还受能量来源的影响，导致不同能量物质的代谢途径存在差异。在低温条件下通过增加油脂添加量来提高饲粮能量密度，是提高育肥猪生长性能和减少污染物排放的有效途径。本研究为低温环境下肥育猪能量营养优化提供了新的解决方案。

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来源期刊

Animal Nutrition Agricultural and Biological Sciences-Animal Science and Zoology

CiteScore

7.40

自引率

3.20%

发文量

172

审稿时长

12 weeks

期刊介绍： Animal Nutrition encompasses the full gamut of animal nutritional sciences and reviews including, but not limited to, fundamental aspects of animal nutrition such as nutritional requirements, metabolic studies, body composition, energetics, immunology, neuroscience, microbiology, genetics and molecular and cell biology related to nutrition, and more applied aspects of animal nutrition, such as raw material evaluation, feed additives, nutritive value of novel ingredients and feed safety.