Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish

Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish

Impaired mitochondrial fatty acid β-oxidation has been correlated with many metabolic syndromes, and the metabolic characteristics of the mammalian models of mitochondrial dysfunction have also been intensively studied. However, the effects of the impaired mitochondrial fatty acid β-oxidation on sys...

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Main Authors: Jia-Min Li, Ling-Yu Li, Xuan Qin, Pascal Degrace, Laurent Demizieux, Samwel M. Limbu, Xin Wang, Mei-Ling Zhang, Dong-Liang Li, Zhen-Yu Du
Format: Article
Language:English
Published: Frontiers Media S.A. 2018-05-01
Series:Frontiers in Physiology
Subjects:
low carnitine zebrafish
mildronate
FA β-oxidation
dyslipidemia
metabolism
Online Access:http://journal.frontiersin.org/article/10.3389/fphys.2018.00509/full
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language English
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author Jia-Min Li
Ling-Yu Li
Xuan Qin
Pascal Degrace
Laurent Demizieux
Samwel M. Limbu
Samwel M. Limbu
Xin Wang
Mei-Ling Zhang
Dong-Liang Li
Zhen-Yu Du
spellingShingle Jia-Min Li
Ling-Yu Li
Xuan Qin
Pascal Degrace
Laurent Demizieux
Samwel M. Limbu
Samwel M. Limbu
Xin Wang
Mei-Ling Zhang
Dong-Liang Li
Zhen-Yu Du
Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
Frontiers in Physiology
low carnitine zebrafish
mildronate
FA β-oxidation
dyslipidemia
metabolism
author_facet Jia-Min Li
Ling-Yu Li
Xuan Qin
Pascal Degrace
Laurent Demizieux
Samwel M. Limbu
Samwel M. Limbu
Xin Wang
Mei-Ling Zhang
Dong-Liang Li
Zhen-Yu Du
author_sort Jia-Min Li
title Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
title_short Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
title_full Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
title_fullStr Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
title_full_unstemmed Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in Zebrafish
title_sort inhibited carnitine synthesis causes systemic alteration of nutrient metabolism in zebrafish
publisher Frontiers Media S.A.
series Frontiers in Physiology
issn 1664-042X
publishDate 2018-05-01
description Impaired mitochondrial fatty acid β-oxidation has been correlated with many metabolic syndromes, and the metabolic characteristics of the mammalian models of mitochondrial dysfunction have also been intensively studied. However, the effects of the impaired mitochondrial fatty acid β-oxidation on systemic metabolism in teleost have never been investigated. In the present study, we established a low-carnitine zebrafish model by feeding fish with mildronate as a specific carnitine synthesis inhibitor [0.05% body weight (BW)/d] for 7 weeks, and the systemically changed nutrient metabolism, including carnitine and triglyceride (TG) concentrations, fatty acid (FA) β-oxidation capability, and other molecular and biochemical assays of lipid, glucose, and protein metabolism, were measured. The results indicated that mildronate markedly decreased hepatic carnitine concentrations while it had no effect in muscle. Liver TG concentrations increased by more than 50% in mildronate-treated fish. Mildronate decreased the efficiency of liver mitochondrial β-oxidation, increased the hepatic mRNA expression of genes related to FA β-oxidation and lipolysis, and decreased the expression of lipogenesis genes. Mildronate decreased whole body glycogen content, increased glucose metabolism rate, and upregulated the expression of glucose uptake and glycolysis genes. Mildronate also increased whole body protein content and hepatic mRNA expression of mechanistic target of rapamycin (mtor), and decreased the expression of a protein catabolism-related gene. Liver, rather than muscle, was the primary organ targeted by mildronate. In short, mildronate-induced hepatic inhibited carnitine synthesis in zebrafish caused decreased mitochondrial FA β-oxidation efficiency, greater lipid accumulation, and altered glucose and protein metabolism. This reveals the key roles of mitochondrial fatty acid β-oxidation in nutrient metabolism in fish, and this low-carnitine zebrafish model could also be used as a novel fish model for future metabolism studies.
topic low carnitine zebrafish
mildronate
FA β-oxidation
dyslipidemia
metabolism
url http://journal.frontiersin.org/article/10.3389/fphys.2018.00509/full
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spelling doaj-aa646d59c1c2412282b9ec579bf6f96b2020-11-24T23:04:16ZengFrontiers Media S.A.Frontiers in Physiology1664-042X2018-05-01910.3389/fphys.2018.00509356412Inhibited Carnitine Synthesis Causes Systemic Alteration of Nutrient Metabolism in ZebrafishJia-Min Li0Ling-Yu Li1Xuan Qin2Pascal Degrace3Laurent Demizieux4Samwel M. Limbu5Samwel M. Limbu6Xin Wang7Mei-Ling Zhang8Dong-Liang Li9Zhen-Yu Du10Laboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaLaboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaShanghai Key Laboratory of Regulatory Biology, Institute of Biomedical Sciences and School of Life Sciences, East China Normal University, Shanghai, ChinaTeam Pathophysiology of Dyslipidemia, Faculty of Sciences Gabriel, INSERM UMR1231 “Lipides, Nutrition, Cancer,” Université Bourgogne Franche-Comté, Dijon, FranceTeam Pathophysiology of Dyslipidemia, Faculty of Sciences Gabriel, INSERM UMR1231 “Lipides, Nutrition, Cancer,” Université Bourgogne Franche-Comté, Dijon, FranceLaboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaDepartment of Aquatic Sciences and Fisheries Technology, University of Dar es Salaam, Dar es Salaam, TanzaniaShanghai Key Laboratory of Regulatory Biology, Institute of Biomedical Sciences and School of Life Sciences, East China Normal University, Shanghai, ChinaLaboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaLaboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaLaboratory of Aquaculture Nutrition and Environmental Health, School of Life Sciences, East China Normal University, Shanghai, ChinaImpaired mitochondrial fatty acid β-oxidation has been correlated with many metabolic syndromes, and the metabolic characteristics of the mammalian models of mitochondrial dysfunction have also been intensively studied. However, the effects of the impaired mitochondrial fatty acid β-oxidation on systemic metabolism in teleost have never been investigated. In the present study, we established a low-carnitine zebrafish model by feeding fish with mildronate as a specific carnitine synthesis inhibitor [0.05% body weight (BW)/d] for 7 weeks, and the systemically changed nutrient metabolism, including carnitine and triglyceride (TG) concentrations, fatty acid (FA) β-oxidation capability, and other molecular and biochemical assays of lipid, glucose, and protein metabolism, were measured. The results indicated that mildronate markedly decreased hepatic carnitine concentrations while it had no effect in muscle. Liver TG concentrations increased by more than 50% in mildronate-treated fish. Mildronate decreased the efficiency of liver mitochondrial β-oxidation, increased the hepatic mRNA expression of genes related to FA β-oxidation and lipolysis, and decreased the expression of lipogenesis genes. Mildronate decreased whole body glycogen content, increased glucose metabolism rate, and upregulated the expression of glucose uptake and glycolysis genes. Mildronate also increased whole body protein content and hepatic mRNA expression of mechanistic target of rapamycin (mtor), and decreased the expression of a protein catabolism-related gene. Liver, rather than muscle, was the primary organ targeted by mildronate. In short, mildronate-induced hepatic inhibited carnitine synthesis in zebrafish caused decreased mitochondrial FA β-oxidation efficiency, greater lipid accumulation, and altered glucose and protein metabolism. This reveals the key roles of mitochondrial fatty acid β-oxidation in nutrient metabolism in fish, and this low-carnitine zebrafish model could also be used as a novel fish model for future metabolism studies.http://journal.frontiersin.org/article/10.3389/fphys.2018.00509/fulllow carnitine zebrafishmildronateFA β-oxidationdyslipidemiametabolism

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