Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism

Lipopolysaccharides (LPS) are prevalent pathogenic molecules that are found within tissues and blood. Elevated circulating LPS is a feature of obesity and sepsis, both of which are associated with mitochondrial abnormalities that are key pathological features of LPS excess. However, the mechanism of...

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Autores principales: Hansen, Melissa E., Simmons, Kurtis J., Tippetts, Trevor S., Thatcher, Mikayla O., Saito, Rex R., Hubbard, Sheryl T., Trumbull, Annie M., Parker, Brian A., Taylor, Oliver J., Bikman, Benjamin T.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Lippincott Williams & Wilkins 2015
Materias:
Basic Science Aspects
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4851226/
https://www.ncbi.nlm.nih.gov/pubmed/26529656
http://dx.doi.org/10.1097/SHK.0000000000000468
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author Hansen, Melissa E.
Simmons, Kurtis J.
Tippetts, Trevor S.
Thatcher, Mikayla O.
Saito, Rex R.
Hubbard, Sheryl T.
Trumbull, Annie M.
Parker, Brian A.
Taylor, Oliver J.
Bikman, Benjamin T.
author_facet Hansen, Melissa E.
Simmons, Kurtis J.
Tippetts, Trevor S.
Thatcher, Mikayla O.
Saito, Rex R.
Hubbard, Sheryl T.
Trumbull, Annie M.
Parker, Brian A.
Taylor, Oliver J.
Bikman, Benjamin T.
author_sort Hansen, Melissa E.
collection PubMed
description Lipopolysaccharides (LPS) are prevalent pathogenic molecules that are found within tissues and blood. Elevated circulating LPS is a feature of obesity and sepsis, both of which are associated with mitochondrial abnormalities that are key pathological features of LPS excess. However, the mechanism of LPS-induced mitochondrial alterations remains poorly understood. Herein we demonstrate the necessity of sphingolipid accrual in mediating altered mitochondrial physiology in skeletal muscle following LPS exposure. In particular, we found LPS elicited disparate effects on the sphingolipids dihydroceramides (DhCer) and ceramides (Cer) in both cultured myotubes and in muscle of LPS-injected mice. Although LPS-treated myotubes had reduced DhCer and increased Cer as well as increased mitochondrial respiration, muscle from LPS-injected mice manifested a reverse trend, namely elevated DhCer, but reduced Cer as well as reduced mitochondrial respiration. In addition, we found that LPS treatment caused mitochondrial fission, likely via dynamin-related protein 1, and increased oxidative stress. However, inhibition of de novo sphingolipid biosynthesis via myriocin protected normal mitochondrial function in spite of LPS, but inhibition of DhCer desaturase 1, which increases DhCer, but not Cer, exacerbated mitochondrial respiration with LPS. In an attempt to reconcile the incongruent effects of LPS in isolated muscle cells and whole muscle tissue, we incubated myotubes with conditioned medium from treated macrophages. In contrast to direct myotube LPS treatment, conditioned medium from LPS-treated macrophages reduced myotube respiration, but this was again mitigated with sphingolipid inhibition. Thus, macrophage sphingolipid production appears to be necessary for LPS-induced mitochondrial alterations in skeletal muscle tissue.
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spelling pubmed-48512262016-05-23 Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism Hansen, Melissa E. Simmons, Kurtis J. Tippetts, Trevor S. Thatcher, Mikayla O. Saito, Rex R. Hubbard, Sheryl T. Trumbull, Annie M. Parker, Brian A. Taylor, Oliver J. Bikman, Benjamin T. Shock Basic Science Aspects Lipopolysaccharides (LPS) are prevalent pathogenic molecules that are found within tissues and blood. Elevated circulating LPS is a feature of obesity and sepsis, both of which are associated with mitochondrial abnormalities that are key pathological features of LPS excess. However, the mechanism of LPS-induced mitochondrial alterations remains poorly understood. Herein we demonstrate the necessity of sphingolipid accrual in mediating altered mitochondrial physiology in skeletal muscle following LPS exposure. In particular, we found LPS elicited disparate effects on the sphingolipids dihydroceramides (DhCer) and ceramides (Cer) in both cultured myotubes and in muscle of LPS-injected mice. Although LPS-treated myotubes had reduced DhCer and increased Cer as well as increased mitochondrial respiration, muscle from LPS-injected mice manifested a reverse trend, namely elevated DhCer, but reduced Cer as well as reduced mitochondrial respiration. In addition, we found that LPS treatment caused mitochondrial fission, likely via dynamin-related protein 1, and increased oxidative stress. However, inhibition of de novo sphingolipid biosynthesis via myriocin protected normal mitochondrial function in spite of LPS, but inhibition of DhCer desaturase 1, which increases DhCer, but not Cer, exacerbated mitochondrial respiration with LPS. In an attempt to reconcile the incongruent effects of LPS in isolated muscle cells and whole muscle tissue, we incubated myotubes with conditioned medium from treated macrophages. In contrast to direct myotube LPS treatment, conditioned medium from LPS-treated macrophages reduced myotube respiration, but this was again mitigated with sphingolipid inhibition. Thus, macrophage sphingolipid production appears to be necessary for LPS-induced mitochondrial alterations in skeletal muscle tissue. Lippincott Williams & Wilkins 2015-12 2015-11-15 /pmc/articles/PMC4851226/ /pubmed/26529656 http://dx.doi.org/10.1097/SHK.0000000000000468 Text en Copyright © 2015 by the Shock Society http://creativecommons.org/licenses/by-nc-nd/4.0 This is an open-access article distributed under the terms of the Creative Commons Attribution-Non Commercial-No Derivatives License 4.0 (CCBY-NC-ND), where it is permissible to download and share the work provided it is properly cited. The work cannot be changed in any way or used commercially. http://creativecommons.org/licenses/by-nc-nd/4.0
spellingShingle Basic Science Aspects
Hansen, Melissa E.
Simmons, Kurtis J.
Tippetts, Trevor S.
Thatcher, Mikayla O.
Saito, Rex R.
Hubbard, Sheryl T.
Trumbull, Annie M.
Parker, Brian A.
Taylor, Oliver J.
Bikman, Benjamin T.
Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title_full Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title_fullStr Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title_full_unstemmed Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title_short Lipopolysaccharide Disrupts Mitochondrial Physiology in Skeletal Muscle via Disparate Effects on Sphingolipid Metabolism
title_sort lipopolysaccharide disrupts mitochondrial physiology in skeletal muscle via disparate effects on sphingolipid metabolism
topic Basic Science Aspects
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4851226/
https://www.ncbi.nlm.nih.gov/pubmed/26529656
http://dx.doi.org/10.1097/SHK.0000000000000468
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