Effects of different energy levels in low-protein diet on liver lipid metabolism in the late-phase laying hens through the gut-liver axis.

IF 6.3 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Hong Hu, Ying Huang, Anjian Li, Qianhui Mi, Kunping Wang, Liang Chen, Zelong Zhao, Qiang Zhang, Xi Bai, Hongbin Pan
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引用次数: 0

Abstract

Background: The energy/protein imbalance in a low-protein diet induces lipid metabolism disorders in late-phase laying hens. Reducing energy levels in the low-protein diet to adjust the energy-to-protein ratio may improve fat deposition, but this also decreases the laying performance of hens. This study investigated the mechanism by which different energy levels in the low-protein diet influences liver lipid metabolism in late-phase laying hens through the enterohepatic axis to guide feed optimization and nutrition strategies. A total of 288 laying hens were randomly allocated to the normal-energy and normal-protein diet group (positive control: CK) or 1 of 3 groups: low-energy and low-protein diet (LL), normal-energy and low-protein diet (NL), and high-energy and low-protein diet (HL) groups. The energy-to-protein ratios of the CK, LL, NL, and HL diets were 0.67, 0.74, 0.77, and 0.80, respectively.

Results: Compared with the CK group, egg quality deteriorated with increasing energy intake in late-phase laying hens fed low-protein diet. Hens fed LL, NL, and HL diets had significantly higher triglyceride, total cholesterol, acetyl-CoA carboxylase, and fatty acid synthase levels, but significantly lower hepatic lipase levels compared with the CK group. Liver transcriptome sequencing revealed that genes involved in fatty acid beta-oxidation (ACOX1, HADHA, EHHADH, and ACAA1) were downregulated, whereas genes related to fatty acid synthesis (SCD, FASN, and ACACA) were upregulated in LL group compared with the CK group. Comparison of the cecal microbiome showed that in hens fed an LL diet, Lactobacillus and Desulfovibrio were enriched, whereas riboflavin metabolism was suppressed. Cecal metabolites that were most significantly affected by the LL diet included several vitamins, such as riboflavin (vitamin B2), pantethine (vitamin B5 derivative), pyridoxine (vitamin B6), and 4-pyridoxic acid.

Conclusion: A lipid metabolism disorder due to deficiencies of vitamin B2 and pantethine originating from the metabolism of the cecal microbiome may be the underlying reason for fat accumulation in the liver of late-phase laying hens fed an LL diet. Based on the present study, we propose that targeting vitamin B2 and pantethine (vitamin B5 derivative) might be an effective strategy for improving lipid metabolism in late-phase laying hens fed a low-protein diet.

低蛋白日粮中不同能量水平通过肠肝轴对后期蛋鸡肝脂代谢的影响
背景:低蛋白日粮中的能量/蛋白质失衡会诱发蛋鸡后期的脂质代谢紊乱。降低低蛋白日粮中的能量水平以调整能量与蛋白质的比例可改善脂肪沉积,但这也会降低母鸡的产蛋性能。本研究探讨了低蛋白日粮中不同能量水平通过肠肝轴影响后期蛋鸡肝脂代谢的机制,以指导饲料优化和营养策略。共将 288 只蛋鸡随机分配到正常能量和正常蛋白质日粮组(阳性对照:CK)或低能量和低蛋白质日粮组(LL)、正常能量和低蛋白质日粮组(NL)和高能量和低蛋白质日粮组(HL)中的 3 个组。CK、LL、NL 和 HL 日粮的能量蛋白质比分别为 0.67、0.74、0.77 和 0.80:与 CK 组相比,饲喂低蛋白日粮的后期蛋鸡的鸡蛋质量随着能量摄入量的增加而下降。与CK组相比,饲喂LL、NL和HL日粮的母鸡甘油三酯、总胆固醇、乙酰-CoA羧化酶和脂肪酸合成酶水平显著升高,但肝脂肪酶水平显著降低。肝脏转录组测序显示,与CK组相比,LL组参与脂肪酸β-氧化的基因(ACOX1、HADHA、EHHADH和ACAA1)下调,而与脂肪酸合成相关的基因(SCD、FASN和ACACA)上调。盲肠微生物组的比较表明,在饲喂 LL 日粮的母鸡中,乳酸杆菌和脱硫弧菌富集,而核黄素代谢受到抑制。受 LL 日粮影响最大的盲肠代谢物包括几种维生素,如核黄素(维生素 B2)、泛酸(维生素 B5 衍生物)、吡哆醇(维生素 B6)和 4-吡哆酸:结论:因缺乏维生素 B2 和泛硫氨酸而导致的脂质代谢紊乱源于盲肠微生物群的新陈代谢,这可能是饲喂低脂日粮的后期蛋鸡肝脏脂肪堆积的根本原因。基于本研究,我们认为针对维生素 B2 和泛硫氨酸(维生素 B5 衍生物)可能是改善低蛋白日粮后期蛋鸡脂质代谢的有效策略。
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
CiteScore
10.30
自引率
0.00%
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822
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