Literature DB >> 25342132

Acylcarnitines: potential implications for skeletal muscle insulin resistance.

Céline Aguer1, Colin S McCoin2, Trina A Knotts3, A Brianne Thrush1, Kikumi Ono-Moore3, Ruth McPherson4, Robert Dent5, Daniel H Hwang6, Sean H Adams7, Mary-Ellen Harper8.   

Abstract

Insulin resistance may be linked to incomplete fatty acid β-oxidation and the subsequent increase in acylcarnitine species in different tissues including skeletal muscle. It is not known if acylcarnitines participate in muscle insulin resistance or simply reflect dysregulated metabolism. The aims of this study were to determine whether acylcarnitines can elicit muscle insulin resistance and to better understand the link between incomplete muscle fatty acid β-oxidation, oxidative stress, inflammation, and insulin-resistance development. Differentiated C2C12, primary mouse, and human myotubes were treated with acylcarnitines (C4:0, C14:0, C16:0) or with palmitate with or without carnitine acyltransferase inhibition by mildronate. Treatment with C4:0, C14:0, and C16:0 acylcarnitines resulted in 20-30% decrease in insulin response at the level of Akt phosphorylation and/or glucose uptake. Mildronate reversed palmitate-induced insulin resistance concomitant with an ∼25% decrease in short-chain acylcarnitine and acetylcarnitine secretion. Although proinflammatory cytokines were not affected under these conditions, oxidative stress was increased by 2-3 times by short- or long-chain acylcarnitines. Acylcarnitine-induced oxidative stress and insulin resistance were reversed by treatment with antioxidants. Results are consistent with the conclusion that incomplete muscle fatty acid β-oxidation causes acylcarnitine accumulation and associated oxidative stress, raising the possibility that these metabolites play a role in muscle insulin resistance. © FASEB.

Entities:  

Keywords:  fatty acid β-oxidation; inflammation; mitochondria; myotubes; oxidative stress

Mesh:

Substances:

Year:  2014        PMID: 25342132      PMCID: PMC4285541          DOI: 10.1096/fj.14-255901

Source DB:  PubMed          Journal:  FASEB J        ISSN: 0892-6638            Impact factor:   5.191


  44 in total

1.  Mitochondrial overload and incomplete fatty acid oxidation contribute to skeletal muscle insulin resistance.

Authors:  Timothy R Koves; John R Ussher; Robert C Noland; Dorothy Slentz; Merrie Mosedale; Olga Ilkayeva; James Bain; Robert Stevens; Jason R B Dyck; Christopher B Newgard; Gary D Lopaschuk; Deborah M Muoio
Journal:  Cell Metab       Date:  2008-01       Impact factor: 27.287

2.  Dynamic changes in fat oxidation in human primary myocytes mirror metabolic characteristics of the donor.

Authors:  Barbara Ukropcova; Michele McNeil; Olga Sereda; Lilian de Jonge; Hui Xie; George A Bray; Steven R Smith
Journal:  J Clin Invest       Date:  2005-07       Impact factor: 14.808

3.  Increased proton leak and SOD2 expression in myotubes from obese non-diabetic subjects with a family history of type 2 diabetes.

Authors:  Céline Aguer; Melissa Pasqua; A Brianne Thrush; Cynthia Moffat; Michael McBurney; Karen Jardine; Rui Zhang; Brittany Beauchamp; Robert Dent; Ruth McPherson; Mary-Ellen Harper
Journal:  Biochim Biophys Acta       Date:  2013-05-16

4.  Palmitate increases superoxide production through mitochondrial electron transport chain and NADPH oxidase activity in skeletal muscle cells.

Authors:  Rafael Herling Lambertucci; Sandro Massao Hirabara; Leonardo Dos Reis Silveira; Adriana Cristina Levada-Pires; Rui Curi; Tania Cristina Pithon-Curi
Journal:  J Cell Physiol       Date:  2008-09       Impact factor: 6.384

Review 5.  The sites and topology of mitochondrial superoxide production.

Authors:  Martin D Brand
Journal:  Exp Gerontol       Date:  2010-01-11       Impact factor: 4.032

6.  Plasma acylcarnitine profiles suggest incomplete long-chain fatty acid beta-oxidation and altered tricarboxylic acid cycle activity in type 2 diabetic African-American women.

Authors:  Sean H Adams; Charles L Hoppel; Kerry H Lok; Ling Zhao; Scott W Wong; Paul E Minkler; Daniel H Hwang; John W Newman; W Timothy Garvey
Journal:  J Nutr       Date:  2009-04-15       Impact factor: 4.798

7.  Production and release of acylcarnitines by primary myotubes reflect the differences in fasting fat oxidation of the donors.

Authors:  Magnus Wolf; Shili Chen; Xinjie Zhao; Mika Scheler; Martin Irmler; Harald Staiger; Johannes Beckers; Martin Hrabé de Angelis; Andreas Fritsche; Hans-Ulrich Häring; Erwin D Schleicher; Guowang Xu; Rainer Lehmann; Cora Weigert
Journal:  J Clin Endocrinol Metab       Date:  2013-04-30       Impact factor: 5.958

8.  Muscle-specific deletion of carnitine acetyltransferase compromises glucose tolerance and metabolic flexibility.

Authors:  Deborah M Muoio; Robert C Noland; Jean-Paul Kovalik; Sarah E Seiler; Michael N Davies; Karen L DeBalsi; Olga R Ilkayeva; Robert D Stevens; Indu Kheterpal; Jingying Zhang; Jeffrey D Covington; Sudip Bajpeyi; Eric Ravussin; William Kraus; Timothy R Koves; Randall L Mynatt
Journal:  Cell Metab       Date:  2012-05-02       Impact factor: 27.287

9.  Carnitine insufficiency caused by aging and overnutrition compromises mitochondrial performance and metabolic control.

Authors:  Robert C Noland; Timothy R Koves; Sarah E Seiler; Helen Lum; Robert M Lust; Olga Ilkayeva; Robert D Stevens; Fausto G Hegardt; Deborah M Muoio
Journal:  J Biol Chem       Date:  2009-06-24       Impact factor: 5.157

10.  Mechanisms underlying the onset of oral lipid-induced skeletal muscle insulin resistance in humans.

Authors:  Bettina Nowotny; Lejla Zahiragic; Dorothea Krog; Peter J Nowotny; Christian Herder; Maren Carstensen; Toru Yoshimura; Julia Szendroedi; Esther Phielix; Peter Schadewaldt; Nanette C Schloot; Gerald I Shulman; Michael Roden
Journal:  Diabetes       Date:  2013-03-01       Impact factor: 9.461
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  85 in total

1.  Increased palmitate intake: higher acylcarnitine concentrations without impaired progression of β-oxidation.

Authors:  C Lawrence Kien; Dwight E Matthews; Matthew E Poynter; Janice Y Bunn; Naomi K Fukagawa; Karen I Crain; David B Ebenstein; Emily K Tarleton; Robert D Stevens; Timothy R Koves; Deborah M Muoio
Journal:  J Lipid Res       Date:  2015-07-08       Impact factor: 5.922

Review 2.  Metabolic pathways at the crossroads of diabetes and inborn errors.

Authors:  Eric S Goetzman; Zhenwei Gong; Manuel Schiff; Yan Wang; Radhika H Muzumdar
Journal:  J Inherit Metab Dis       Date:  2017-09-26       Impact factor: 4.982

3.  Acylcarnitines as markers of exercise-associated fuel partitioning, xenometabolism, and potential signals to muscle afferent neurons.

Authors:  Jie Zhang; Alan R Light; Charles L Hoppel; Caitlin Campbell; Carol J Chandler; Dustin J Burnett; Elaine C Souza; Gretchen A Casazza; Ronald W Hughen; Nancy L Keim; John W Newman; Gary R Hunter; Jose R Fernandez; W Timothy Garvey; Mary-Ellen Harper; Oliver Fiehn; Sean H Adams
Journal:  Exp Physiol       Date:  2016-12-12       Impact factor: 2.969

Review 4.  The manifold role of the mitochondria in skeletal muscle insulin resistance.

Authors:  William Todd Cade
Journal:  Curr Opin Clin Nutr Metab Care       Date:  2018-07       Impact factor: 4.294

5.  Quantification of muscle triglyceride synthesis rate requires an adjustment for total triglyceride content.

Authors:  Rabia Asghar; Maria Chondronikola; Edgar L Dillon; William J Durham; Craig Porter; Zhanpin Wu; Maria Camacho-Hughes; Clark R Andersen; Heidi Spratt; Elena Volpi; Melinda Sheffield-Moore; Labros Sidossis; Robert R Wolfe; Nicola Abate; Demidmaa R Tuvdendorj
Journal:  J Lipid Res       Date:  2018-08-21       Impact factor: 5.922

Review 6.  Mechanisms of Insulin Action and Insulin Resistance.

Authors:  Max C Petersen; Gerald I Shulman
Journal:  Physiol Rev       Date:  2018-10-01       Impact factor: 37.312

7.  Fine Mapping and Functional Analysis Reveal a Role of SLC22A1 in Acylcarnitine Transport.

Authors:  Hye In Kim; Johannes Raffler; Wenyun Lu; Jung-Jin Lee; Deepti Abbey; Danish Saleheen; Joshua D Rabinowitz; Michael J Bennett; Nicholas J Hand; Christopher Brown; Daniel J Rader
Journal:  Am J Hum Genet       Date:  2017-09-21       Impact factor: 11.025

8.  Long-chain acylcarnitines activate cell stress and myokine release in C2C12 myotubes: calcium-dependent and -independent effects.

Authors:  Colin S McCoin; Trina A Knotts; Kikumi D Ono-Moore; Pieter J Oort; Sean H Adams
Journal:  Am J Physiol Endocrinol Metab       Date:  2015-04-07       Impact factor: 4.310

9.  Novel Molecular Interactions of Acylcarnitines and Fatty Acids with Myoglobin.

Authors:  Sree V Chintapalli; Srinivas Jayanthi; Prema L Mallipeddi; Ravikumar Gundampati; Thallapuranam Krishnaswamy Suresh Kumar; Damian B van Rossum; Andriy Anishkin; Sean H Adams
Journal:  J Biol Chem       Date:  2016-10-07       Impact factor: 5.157

10.  Palmitoyl-carnitine production by blood cells associates with the concentration of circulating acyl-carnitines in healthy overweight women.

Authors:  Maria Chondronikola; Rabia Asghar; Xiaojun Zhang; Edgar L Dillon; William J Durham; Zhanpin Wu; Craig Porter; Maria Camacho-Hughes; Yingxin Zhao; Allan R Brasier; Elena Volpi; Melinda Sheffield-Moore; Nicola Abate; Labros Sidossis; Demidmaa Tuvdendorj
Journal:  Clin Nutr       Date:  2016-09-06       Impact factor: 7.324
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