Time-restricted feeding mediated modulation of microbiota leads to changes in muscle physiology in Drosophila obesity models.

IF 8 1区医学 Q1 CELL BIOLOGY

Aging Cell Pub Date : 2024-10-24 DOI:10.1111/acel.14382

Christopher Livelo, Yiming Guo, Jagathnarayan Madhanagopal, Casey Morrow, Girish C Melkani

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Abstract

Recent research has highlighted the essential role of the microbiome in maintaining skeletal muscle physiology. The microbiota influences muscle health by regulating lipid metabolism, protein synthesis, and insulin sensitivity. However, metabolic disturbances such as obesity can lead to dysbiosis, impairing muscle function. Time-restricted feeding (TRF) has been shown to mitigate obesity-related muscle dysfunction, but its effects on restoring healthy microbiomes remain poorly understood. This study utilizes 16S microbiome analysis and bacterial supplementation to investigate the bacterial communities influenced by TRF that may benefit skeletal muscle physiology. In wild-type and obese Drosophila models (axenic models devoid of natural microbial communities), the absence of microbiota influence muscle performance and metabolism differently. Specifically, axenic wild-type Drosophila exhibited reduced muscle performance, higher glucose levels, insulin resistance, ectopic lipid accumulation, and decreased ATP levels. Interestingly, in obese Drosophila (induced by a high-fat diet or predisposed obesity mutant Sk2), the absence of microbiota improved muscle performance, lowered glucose levels, reduced insulin resistance, and increased ATP levels. TRF was found to modulate microbiota composition, notably increasing Acetobacter pasteurianus (AP) and decreasing Staphylococcus aureus (SA) in both obesity models. Supplementation with AP improved muscle performance and reduced glucose and insulin resistance, while SA supplementation had the opposite effect. This study provides novel insights into the complex interactions between TRF, microbiota, and skeletal muscle physiology in different Drosophila models.

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限时喂养介导的微生物群调节导致果蝇肥胖模型中肌肉生理学的变化。

最近的研究强调了微生物群在维持骨骼肌生理机能方面的重要作用。微生物群通过调节脂质代谢、蛋白质合成和胰岛素敏感性来影响肌肉健康。然而，代谢紊乱（如肥胖）会导致菌群失调，损害肌肉功能。限时喂养（TRF）已被证明可减轻与肥胖相关的肌肉功能障碍，但其对恢复健康微生物群的影响仍鲜为人知。本研究利用 16S 微生物组分析和细菌补充剂来研究受 TRF 影响的细菌群落，这些细菌群落可能有益于骨骼肌生理学。在野生型果蝇和肥胖果蝇模型（没有天然微生物群落的轴生模型）中，微生物群的缺失对肌肉性能和新陈代谢的影响各不相同。具体来说，轴突野生型果蝇表现出肌肉性能下降、葡萄糖水平升高、胰岛素抵抗、异位脂质积累和 ATP 水平降低。有趣的是，在肥胖果蝇（由高脂肪饮食或易患肥胖症的突变体 Sk2 诱导）中，缺少微生物群会改善肌肉性能、降低葡萄糖水平、减少胰岛素抵抗和增加 ATP 水平。研究发现，在两种肥胖模型中，TRF 都能调节微生物群的组成，特别是增加巴氏醋酸杆菌（AP），减少金黄色葡萄球菌（SA）。补充 AP 可改善肌肉性能，降低葡萄糖和胰岛素抵抗，而补充 SA 则效果相反。这项研究为不同果蝇模型中TRF、微生物群和骨骼肌生理学之间复杂的相互作用提供了新的见解。

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

Aging Cell Biochemistry, Genetics and Molecular Biology-Cell Biology

自引率

2.60%

发文量

212

期刊介绍： Aging Cell is an Open Access journal that focuses on the core aspects of the biology of aging, encompassing the entire spectrum of geroscience. The journal's content is dedicated to publishing research that uncovers the mechanisms behind the aging process and explores the connections between aging and various age-related diseases. This journal aims to provide a comprehensive understanding of the biological underpinnings of aging and its implications for human health. The journal is widely recognized and its content is abstracted and indexed by numerous databases and services, which facilitates its accessibility and impact in the scientific community. These include: Academic Search (EBSCO Publishing) Academic Search Alumni Edition (EBSCO Publishing) Academic Search Premier (EBSCO Publishing) Biological Science Database (ProQuest) CAS: Chemical Abstracts Service (ACS) Embase (Elsevier) InfoTrac (GALE Cengage) Ingenta Select ISI Alerting Services Journal Citation Reports/Science Edition (Clarivate Analytics) MEDLINE/PubMed (NLM) Natural Science Collection (ProQuest) PubMed Dietary Supplement Subset (NLM) Science Citation Index Expanded (Clarivate Analytics) SciTech Premium Collection (ProQuest) Web of Science (Clarivate Analytics) Being indexed in these databases ensures that the research published in Aging Cell is discoverable by researchers, clinicians, and other professionals interested in the field of aging and its associated health issues. This broad coverage helps to disseminate the journal's findings and contributes to the advancement of knowledge in geroscience.