Megf10 deficiency impairs skeletal muscle stem cell migration and muscle regeneration

Chengcheng Li; Dorianmarie Vargas-Franco; Madhurima Saha; Rachel M. Davis; Kelsey A. Manko; Isabelle Draper; Christina A. Pacak; Peter B. Kang

doi:10.1002/2211-5463.13031

Megf10 deficiency impairs skeletal muscle stem cell migration and muscle regeneration

Chengcheng Li, Dorianmarie Vargas-Franco, Madhurima Saha, Rachel M. Davis, Kelsey A. Manko, Isabelle Draper, Christina A. Pacak, Peter B. Kang

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

Biallelic loss-of-function MEGF10 mutations lead to MEGF10 myopathy, also known as early onset myopathy with areflexia, respiratory distress, and dysphagia (EMARDD). MEGF10 is expressed in muscle satellite cells, but the contribution of satellite cell dysfunction to MEGF10 myopathy is unclear. Myofibers and satellite cells were isolated and examined from Megf10^−/− and wild-type mice. A separate set of mice underwent repeated intramuscular barium chloride injections. Megf10^−/− muscle satellite cells showed reduced proliferation and migration, while Megf10^−/− mouse skeletal muscles showed impaired regeneration. Megf10 deficiency is associated with impaired muscle regeneration, due in part to defects in satellite cell function. Efforts to rescue Megf10 deficiency will have therapeutic implications for MEGF10 myopathy and other inherited muscle diseases involving impaired muscle regeneration.

Original language	English (US)
Pages (from-to)	114-123
Number of pages	10
Journal	FEBS Open Bio
Volume	11
Issue number	1
DOIs	https://doi.org/10.1002/2211-5463.13031
State	Published - Jan 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2020 The Authors. FEBS Open Bio published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.

Keywords

MEGF10 myopathy
satellite cells
skeletal muscle regeneration

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title = "Megf10 deficiency impairs skeletal muscle stem cell migration and muscle regeneration",

abstract = "Biallelic loss-of-function MEGF10 mutations lead to MEGF10 myopathy, also known as early onset myopathy with areflexia, respiratory distress, and dysphagia (EMARDD). MEGF10 is expressed in muscle satellite cells, but the contribution of satellite cell dysfunction to MEGF10 myopathy is unclear. Myofibers and satellite cells were isolated and examined from Megf10−/− and wild-type mice. A separate set of mice underwent repeated intramuscular barium chloride injections. Megf10−/− muscle satellite cells showed reduced proliferation and migration, while Megf10−/− mouse skeletal muscles showed impaired regeneration. Megf10 deficiency is associated with impaired muscle regeneration, due in part to defects in satellite cell function. Efforts to rescue Megf10 deficiency will have therapeutic implications for MEGF10 myopathy and other inherited muscle diseases involving impaired muscle regeneration.",

keywords = "MEGF10 myopathy, satellite cells, skeletal muscle regeneration",

author = "Chengcheng Li and Dorianmarie Vargas-Franco and Madhurima Saha and Davis, {Rachel M.} and Manko, {Kelsey A.} and Isabelle Draper and Pacak, {Christina A.} and Kang, {Peter B.}",

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AU - Li, Chengcheng

AU - Vargas-Franco, Dorianmarie

AU - Saha, Madhurima

AU - Davis, Rachel M.

AU - Manko, Kelsey A.

AU - Draper, Isabelle

AU - Pacak, Christina A.

AU - Kang, Peter B.

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AB - Biallelic loss-of-function MEGF10 mutations lead to MEGF10 myopathy, also known as early onset myopathy with areflexia, respiratory distress, and dysphagia (EMARDD). MEGF10 is expressed in muscle satellite cells, but the contribution of satellite cell dysfunction to MEGF10 myopathy is unclear. Myofibers and satellite cells were isolated and examined from Megf10−/− and wild-type mice. A separate set of mice underwent repeated intramuscular barium chloride injections. Megf10−/− muscle satellite cells showed reduced proliferation and migration, while Megf10−/− mouse skeletal muscles showed impaired regeneration. Megf10 deficiency is associated with impaired muscle regeneration, due in part to defects in satellite cell function. Efforts to rescue Megf10 deficiency will have therapeutic implications for MEGF10 myopathy and other inherited muscle diseases involving impaired muscle regeneration.

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Megf10 deficiency impairs skeletal muscle stem cell migration and muscle regeneration

Abstract

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Keywords

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