肝脏线粒体能量代谢降低会损害胃预负荷和禁食后的食物摄入调节。

Reduced Liver Mitochondrial Energy Metabolism Impairs Food Intake Regulation Following Gastric Preloads and Fasting.

作者信息

Ponte Michael E, Prom John C, Newcomb Mallory A, Jordan Annabelle B, Comfort Lucas L, Hu Jiayin, Puchalska Patrycja, Geisler Caroline E, Hayes Matthew R, Morris E Matthew

机构信息

Dept. of Cell Biology & Physiology University of Kansas Medical Center, Kansas City, Kansas, USA.

Dept. of Psychiatry University of Pennsylvania, Philadelphia, PA, USA.

出版信息

bioRxiv. 2025 Jan 23:2024.10.24.620086. doi: 10.1101/2024.10.24.620086.

DOI:10.1101/2024.10.24.620086

PMID:39554188

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11565831/

Abstract

OBJECTIVE

The capacity of the liver to serve as a peripheral sensor in the regulation of food intake has been debated for over half a century. The anatomical position and physiological roles of the liver suggest it is a prime candidate to serve as an interoceptive sensor of peripheral tissue and systemic energy state. Importantly, maintenance of liver ATP levels and within-meal food intake inhibition is impaired in human subjects with obesity and obese pre-clinical models. Previously, we have shown decreased hepatic mitochondrial energy metabolism (i.e., oxidative metabolism & ADP-dependent respiration) in male liver-specific, heterozygous PGC1a mice results in increased short-term diet-induced weight gain with increased within meal food intake. Herein, we tested the hypothesis that decreased liver mitochondrial energy metabolism impairs meal termination following nutrient oral pre-loads.

METHODS

Liver mitochondrial respiratory response to changes in ΔG and adenine nucleotide concentration following fasting were examined in male liver-specific, heterozygous PGC1a mice. Further, food intake and feeding behavior during basal conditions, following nutrient oral pre-loads, and following fasting were investigated.

RESULTS

We observed male liver-specific, heterozygous PGC1a mice have reduced mitochondrial response to changes in ΔG and tissue ATP following fasting. These impairments in liver energy state are associated with larger and longer meals during chow feeding, impaired dose-dependent food intake inhibition in response to mixed and individual nutrient oral pre-loads, and greater acute fasting-induced food intake.

CONCLUSION

These data support previous work proposing liver-mediated food intake regulation through modulation of peripheral satiation signals.

摘要

目的

肝脏作为食物摄入调节中的外周传感器的能力已经争论了半个多世纪。肝脏的解剖位置和生理作用表明它是作为外周组织和全身能量状态的内感受传感器的主要候选者。重要的是，肥胖的人类受试者和肥胖的临床前模型中肝脏ATP水平的维持以及餐中食物摄入的抑制受到损害。此前，我们已经表明，雄性肝脏特异性杂合子PGC1a小鼠肝脏线粒体能量代谢降低（即氧化代谢和ADP依赖性呼吸）会导致短期饮食诱导的体重增加，餐中食物摄入量增加。在此，我们测试了以下假设：肝脏线粒体能量代谢降低会损害营养口服预负荷后餐食的终止。

方法

在雄性肝脏特异性杂合子PGC1a小鼠中检查禁食后肝脏线粒体对ΔG和腺嘌呤核苷酸浓度变化的呼吸反应。此外，还研究了基础条件下、营养口服预负荷后以及禁食后的食物摄入量和进食行为。

结果

我们观察到雄性肝脏特异性杂合子PGC1a小鼠在禁食后线粒体对ΔG和组织ATP变化的反应降低。肝脏能量状态的这些损害与正常饮食期间更大、更长时间的餐食、对混合和单一营养口服预负荷的剂量依赖性食物摄入抑制受损以及更大的急性禁食诱导的食物摄入量有关。

结论

这些数据支持先前的研究工作，即通过调节外周饱腹感信号来提出肝脏介导的食物摄入调节。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bc72/11828579/9e328e1cb19a/nihpp-2024.10.24.620086v3-f0001.jpg

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肝脏线粒体能量代谢降低会损害胃预负荷和禁食后的食物摄入调节。

Reduced Liver Mitochondrial Energy Metabolism Impairs Food Intake Regulation Following Gastric Preloads and Fasting.

作者信息

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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