Comparable hepatocellular metabolomic signatures under glucose and palmitic acid treatment relative to butyrate in relation to metabolic dysfunction-associated fatty liver disease.

IF 2.5 4区医学 Q3 ENDOCRINOLOGY & METABOLISM

Archives of Physiology and Biochemistry Pub Date : 2025-05-15 DOI:10.1080/13813455.2025.2500651

Priyankar Dey

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引用次数: 0

Abstract

Introduction: Among the dietary factors, glucose, and fatty acids are known to trigger fatty liver disease, while butyrate attenuates steatosis.

Objective: To decipher the hepatocellular altered metabolome under nutrient perturbation relevant to fatty liver disease.

Methods: HepG2 cells were cultured under the influence of sub-lethal doses of glucose, palmitic acid (PA), and butyrate. Following the treatment, intracellular metabolites were extracted and derivatized for GCMS analysis. Chemical class enrichment, metabolic pathway analysis, and metabolomic interactome analysis were undertaken.

Results: Glucose, PA and butyrate caused loss of cell viability at 160 mM, 1600 µM, and 40 mM concentration, respectively. A total of 39, 47, 52, and 51 metabolites were identified in control, glucose, PA, and butyrate, respectively, among which 2-ethylhexanoic acid in control and 2-ethylhexan-1-ol in glucose, PA and butyrate were the most abundant metabolites. Pathways related to the mitochondrial electron transport chain were highly enriched in glucose and PA treatments, leading to increased free radicals. The metabolites identified under glucose and PA treatment were linked to the metabolomic markers of metabolic liver diseases.

Conclusion: Our data showed that the hepatocellular metabolome of HepG2 cells under glucose and PA treatment is closely related, while the metabolome and pathways associated with butyrate treatment are associated with energy metabolism and alleviation of fatty liver.

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葡萄糖和棕榈酸治疗下相对于丁酸治疗与代谢功能障碍相关的脂肪肝疾病的肝细胞代谢组学特征比较

在饮食因素中，葡萄糖和脂肪酸是已知的触发脂肪肝疾病的因素，而丁酸盐可以减轻脂肪变性。目的：探讨与脂肪性肝病相关的营养扰动下肝细胞代谢组改变。方法：采用亚致死剂量葡萄糖、棕榈酸和丁酸对HepG2细胞进行培养。处理后，提取细胞内代谢物并衍生用于GCMS分析。进行了化学类富集、代谢途径分析和代谢组相互作用组分析。结果：葡萄糖、PA和丁酸分别在160 mM、1600µM和40 mM浓度下导致细胞活力丧失。在对照、葡萄糖、PA和丁酸酯中分别鉴定出39、47、52和51种代谢物，其中以对照的2-乙基己酸和葡萄糖、PA和丁酸酯中2-乙基己醇的代谢物含量最多。葡萄糖和PA处理使线粒体电子传递链相关通路高度富集，导致自由基增加。葡萄糖和PA治疗下鉴定的代谢物与代谢性肝病的代谢组学标志物有关。结论：我们的数据显示，葡萄糖和PA处理下HepG2细胞的肝细胞代谢组密切相关，而丁酸处理相关的代谢组和通路与能量代谢和脂肪肝的缓解有关。

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

Archives of Physiology and Biochemistry ENDOCRINOLOGY & METABOLISM-PHYSIOLOGY

CiteScore

6.90

自引率

3.30%

发文量

期刊介绍： Archives of Physiology and Biochemistry: The Journal of Metabolic Diseases is an international peer-reviewed journal which has been relaunched to meet the increasing demand for integrated publication on molecular, biochemical and cellular aspects of metabolic diseases, as well as clinical and therapeutic strategies for their treatment. It publishes full-length original articles, rapid papers, reviews and mini-reviews on selected topics. It is the overall goal of the journal to disseminate novel approaches to an improved understanding of major metabolic disorders. The scope encompasses all topics related to the molecular and cellular pathophysiology of metabolic diseases like obesity, type 2 diabetes and the metabolic syndrome, and their associated complications. Clinical studies are considered as an integral part of the Journal and should be related to one of the following topics: -Dysregulation of hormone receptors and signal transduction -Contribution of gene variants and gene regulatory processes -Impairment of intermediary metabolism at the cellular level -Secretion and metabolism of peptides and other factors that mediate cellular crosstalk -Therapeutic strategies for managing metabolic diseases Special issues dedicated to topics in the field will be published regularly.