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Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth

Postnatal muscle growth is accompanied by increases in fast fiber type compositions and hypertrophy, raising the possibility that a slow to fast transition may be partially requisite for increases in muscle mass. To test this hypothesis, we ablated the Myh4 gene, and thus myosin heavy chain IIB prot...

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Autores principales: Zeng, Caiyun, Shi, Hao, Kirkpatrick, Laila T., Ricome, Aymeric, Park, Sungkwon, Scheffler, Jason M., Hannon, Kevin M., Grant, Alan L., Gerrard, David E.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Frontiers Media S.A. 2022
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8908108/
https://www.ncbi.nlm.nih.gov/pubmed/35283757
http://dx.doi.org/10.3389/fphys.2021.785151
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author Zeng, Caiyun
Shi, Hao
Kirkpatrick, Laila T.
Ricome, Aymeric
Park, Sungkwon
Scheffler, Jason M.
Hannon, Kevin M.
Grant, Alan L.
Gerrard, David E.
author_facet Zeng, Caiyun
Shi, Hao
Kirkpatrick, Laila T.
Ricome, Aymeric
Park, Sungkwon
Scheffler, Jason M.
Hannon, Kevin M.
Grant, Alan L.
Gerrard, David E.
author_sort Zeng, Caiyun
collection PubMed
description Postnatal muscle growth is accompanied by increases in fast fiber type compositions and hypertrophy, raising the possibility that a slow to fast transition may be partially requisite for increases in muscle mass. To test this hypothesis, we ablated the Myh4 gene, and thus myosin heavy chain IIB protein and corresponding fibers in mice, and examined its consequences on postnatal muscle growth. Wild-type and Myh4(–/–) mice had the same number of muscle fibers at 2 weeks postnatal. However, the gastrocnemius muscle lost up to 50% of its fibers between 2 and 4 weeks of age, though stabilizing thereafter. To compensate for the lack of functional IIB fibers, type I, IIA, and IIX(D) fibers increased in prevalence and size. To address whether slowing the slow-to-fast fiber transition process would rescue fiber loss in Myh4(–/–) mice, we stimulated the oxidative program in muscle of Myh4(–/–) mice either by overexpression of PGC-1α, a well-established model for fast-to-slow fiber transition, or by feeding mice AICAR, a potent AMP kinase agonist. Forcing an oxidative metabolism in muscle only partially protected the gastrocnemius muscle from loss of fibers in Myh4(–/–) mice. To explore whether traditional means of stimulating muscle hypertrophy could overcome the muscling deficits in postnatal Myh4(–/–) mice, myostatin null mice were bred with Myh4(–/–) mice, or Myh4(–/–) mice were fed the growth promotant clenbuterol. Interestingly, both genetic and pharmacological stimulations had little impact on mice lacking a functional Myh4 gene suggesting that the existing muscle fibers have maximized its capacity to enlarge to compensate for the lack of its neighboring IIB fibers. Curiously, however, cell signaling events responsible for IIB fiber formation remained intact in the tissue. These findings further show disrupting the slow-to-fast transition of muscle fibers compromises muscle growth postnatally and suggest that type IIB myosin heavy chain expression and its corresponding fiber type may be necessary for fiber maintenance, transition and hypertrophy in mice. The fact that forcing muscle metabolism toward a more oxidative phenotype can partially compensates for the lack of an intact Myh4 gene provides new avenues for attenuating the loss of fast-twitch fibers in aged or diseased muscles.
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spelling pubmed-89081082022-03-11 Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth Zeng, Caiyun Shi, Hao Kirkpatrick, Laila T. Ricome, Aymeric Park, Sungkwon Scheffler, Jason M. Hannon, Kevin M. Grant, Alan L. Gerrard, David E. Front Physiol Physiology Postnatal muscle growth is accompanied by increases in fast fiber type compositions and hypertrophy, raising the possibility that a slow to fast transition may be partially requisite for increases in muscle mass. To test this hypothesis, we ablated the Myh4 gene, and thus myosin heavy chain IIB protein and corresponding fibers in mice, and examined its consequences on postnatal muscle growth. Wild-type and Myh4(–/–) mice had the same number of muscle fibers at 2 weeks postnatal. However, the gastrocnemius muscle lost up to 50% of its fibers between 2 and 4 weeks of age, though stabilizing thereafter. To compensate for the lack of functional IIB fibers, type I, IIA, and IIX(D) fibers increased in prevalence and size. To address whether slowing the slow-to-fast fiber transition process would rescue fiber loss in Myh4(–/–) mice, we stimulated the oxidative program in muscle of Myh4(–/–) mice either by overexpression of PGC-1α, a well-established model for fast-to-slow fiber transition, or by feeding mice AICAR, a potent AMP kinase agonist. Forcing an oxidative metabolism in muscle only partially protected the gastrocnemius muscle from loss of fibers in Myh4(–/–) mice. To explore whether traditional means of stimulating muscle hypertrophy could overcome the muscling deficits in postnatal Myh4(–/–) mice, myostatin null mice were bred with Myh4(–/–) mice, or Myh4(–/–) mice were fed the growth promotant clenbuterol. Interestingly, both genetic and pharmacological stimulations had little impact on mice lacking a functional Myh4 gene suggesting that the existing muscle fibers have maximized its capacity to enlarge to compensate for the lack of its neighboring IIB fibers. Curiously, however, cell signaling events responsible for IIB fiber formation remained intact in the tissue. These findings further show disrupting the slow-to-fast transition of muscle fibers compromises muscle growth postnatally and suggest that type IIB myosin heavy chain expression and its corresponding fiber type may be necessary for fiber maintenance, transition and hypertrophy in mice. The fact that forcing muscle metabolism toward a more oxidative phenotype can partially compensates for the lack of an intact Myh4 gene provides new avenues for attenuating the loss of fast-twitch fibers in aged or diseased muscles. Frontiers Media S.A. 2022-02-24 /pmc/articles/PMC8908108/ /pubmed/35283757 http://dx.doi.org/10.3389/fphys.2021.785151 Text en Copyright © 2022 Zeng, Shi, Kirkpatrick, Ricome, Park, Scheffler, Hannon, Grant and Gerrard. https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
spellingShingle Physiology
Zeng, Caiyun
Shi, Hao
Kirkpatrick, Laila T.
Ricome, Aymeric
Park, Sungkwon
Scheffler, Jason M.
Hannon, Kevin M.
Grant, Alan L.
Gerrard, David E.
Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title_full Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title_fullStr Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title_full_unstemmed Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title_short Driving an Oxidative Phenotype Protects Myh4 Null Mice From Myofiber Loss During Postnatal Growth
title_sort driving an oxidative phenotype protects myh4 null mice from myofiber loss during postnatal growth
topic Physiology
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8908108/
https://www.ncbi.nlm.nih.gov/pubmed/35283757
http://dx.doi.org/10.3389/fphys.2021.785151
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