早期代乳品喂养可介导由结肠微生物群和胆汁酸谱引起的脂质代谢紊乱,从而降低山羊模型的体重。

IF 6.3 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Ke Zhang, Ting Zhang, Mengmeng Guo, Awang Cuoji, Yangbin Xu, Yitong Zhao, Yuxin Yang, Daniel Brugger, Xiaolong Wang, Langda Suo, Yujiang Wu, Yulin Chen
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引用次数: 0

摘要

背景:幼年反刍动物脂质代谢失调及其对生长性能的影响引起了人们的关注,尤其是在替代饲喂策略的背景下。本研究旨在阐明与母乳(BM)饲喂相比,代乳品(MR)饲喂对山羊幼崽生长、脂质代谢、结肠上皮基因表达、结肠微生物群组成和全身代谢的影响,从而填补生命早期营养方面的一个重要知识空白:方法:10 只雌性山羊分为两组:母乳喂养组(BM 组)和代乳品喂养组(MR 组)。在 28 天的时间里,对体重进行监测,并采集血液和组织样本进行生化、转录组学和代谢组学分析。利用 16S rRNA 基因测序对菌落微生物群进行了分析。为了验证因果关系,还在厌食小鼠体内进行了肠道微生物群移植(IMT)实验:结果:MR喂养的幼鼠日增重减少,原因是脂质代谢受损,表现为血清和肝脏总胆固醇(TC)和非酯化脂肪酸(NEFA)浓度降低。结肠上皮细胞的转录组分析显示,参与脂质代谢负调控的基因上调,同时微生物群发生变化,表现为固醇菌减少,放线菌增加。具体来说,双歧杆菌属和普雷沃特菌属在 MR 组中富集,而梭状芽孢杆菌属和粪杆菌属则减少。代谢组学分析证实了胆汁酸和脂肪酸代谢途径的改变。小鼠的 IMT 实验重现了在 MR 饲喂的山羊身上观察到的代谢表型,证实了微生物群在调节宿主脂质代谢中的作用:结论:用代乳粉饲喂山羊幼崽会破坏脂质代谢和肠道微生物群动态,导致生长速度降低和代谢改变。这些发现强调了早期营养干预对代谢程序的重要性,并表明肠道微生物群的调节可能是改善反刍动物生长和代谢健康的一个目标。这项研究有助于人们了解家畜的营养管理策略及其对动物健康和生产率的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Early-life milk replacer feeding mediates lipid metabolism disorders induced by colonic microbiota and bile acid profiles to reduce body weight in goat model.

Background: Dysregulation of lipid metabolism and its consequences on growth performance in young ruminants have attracted attention, especially in the context of alternative feeding strategies. This study aims to elucidate the effects of milk replacer (MR) feeding on growth, lipid metabolism, colonic epithelial gene expression, colonic microbiota composition and systemic metabolism in goat kids compared to breast milk (BM) feeding, addressing a critical knowledge gap in early life nutrition.

Methods: Ten female goat kids were divided into 2 groups: those fed breast milk (BM group) and those fed a milk replacer (MR group). Over a period of 28 d, body weight was monitored and blood and tissue samples were collected for biochemical, transcriptomic and metabolomic analyses. Profiling of the colonial microbiota was performed using 16S rRNA gene sequencing. Intestinal microbiota transplantation (IMT) experiments in gnotobiotic mice were performed to validate causality.

Results: MR-fed pups exhibited reduced daily body-weight gain due to impaired lipid metabolism as evidenced by lower serum and liver total cholesterol (TC) and non-esterified fatty acid (NEFA) concentrations. Transcriptomic analysis of the colonic epithelium revealed upregulated genes involved in negative regulation of lipid metabolism, concomitant with microbiota shifts characterized by a decrease in Firmicutes and an increase in Actinobacteria. Specifically, genera such as Bifidobacterium and Prevotella were enriched in the MR group, while Clostridium and Faecalibacterium were depleted. Metabolomics analyses confirmed alterations in bile acid and fatty acid metabolic pathways. IMT experiments in mice recapitulated the metabolic phenotype observed in MR-fed goats, confirming the role of the microbiota in modulating host lipid metabolism.

Conclusions: Milk replacer feeding in goat kids disrupts lipid metabolism and gut microbiota dynamics, resulting in reduced growth rates and metabolic alterations. These findings highlight the importance of early nutritional intervention on metabolic programming and suggest that modulation of the gut microbiota may be a target for improving growth and metabolic health in ruminants. This study contributes to the understanding of nutritional management strategies in livestock and their impact on animal health and productivity.

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