Molecular consequences of the myopathy-related D286G mutation on actin function

Jun Fan; Chun Chan; Elyshia L. McNamara; Kristen J. Nowak; Hiroyuki Iwamoto; Julien Ochala

doi:10.3389/fphys.2018.01756

Molecular consequences of the myopathy-related D286G mutation on actin function

Jun Fan, Chun Chan, Elyshia L. McNamara, Kristen J. Nowak, Hiroyuki Iwamoto, Julien Ochala^*

^*Corresponding author for this work

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

6 Citations (Scopus)

Abstract

Myopathies are notably associated with mutations in genes encoding proteins known to be essential for the force production of skeletal muscle fibers, such as skeletal alpha-actin. The exact molecular mechanisms by which these specific defects induce myopathic phenotypes remain unclear. Hence, in the present study, to better understand actin dysfunction, we conducted a molecular dynamic simulation together with ex vivo experiments of the specific muscle disease-causing actin mutation, D286G located in the actin-actin interface. Our computational study showed that D286G impairs the flexural rigidity of actin filaments. However, upon activation, D286G did not have any direct consequences on actin filament extension. Hence, D286G may alter the structure of actin filaments but, when expressed together with normal actin molecules, it may only have minor effects on the ex vivo mechanics of actin filaments upon skeletal muscle fiber contraction.

Original language	English
Article number	1756
Journal	Frontiers in Physiology
Volume	9
DOIs	https://doi.org/10.3389/fphys.2018.01756
Publication status	Published - 1 Dec 2018
Externally published	Yes

Keywords

Actin mechanics
Actin mutation
Muscle fiber
Muscle force
Myopathy

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10.3389/fphys.2018.01756

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title = "Molecular consequences of the myopathy-related D286G mutation on actin function",

abstract = "Myopathies are notably associated with mutations in genes encoding proteins known to be essential for the force production of skeletal muscle fibers, such as skeletal alpha-actin. The exact molecular mechanisms by which these specific defects induce myopathic phenotypes remain unclear. Hence, in the present study, to better understand actin dysfunction, we conducted a molecular dynamic simulation together with ex vivo experiments of the specific muscle disease-causing actin mutation, D286G located in the actin-actin interface. Our computational study showed that D286G impairs the flexural rigidity of actin filaments. However, upon activation, D286G did not have any direct consequences on actin filament extension. Hence, D286G may alter the structure of actin filaments but, when expressed together with normal actin molecules, it may only have minor effects on the ex vivo mechanics of actin filaments upon skeletal muscle fiber contraction.",

keywords = "Actin mechanics, Actin mutation, Muscle fiber, Muscle force, Myopathy",

author = "Jun Fan and Chun Chan and McNamara, {Elyshia L.} and Nowak, {Kristen J.} and Hiroyuki Iwamoto and Julien Ochala",

note = "Publisher Copyright: {\textcopyright} 2018 Fan, Chan, McNamara, Nowak, Iwamoto and Ochala.",

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month = dec,

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doi = "10.3389/fphys.2018.01756",

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AU - Fan, Jun

AU - Chan, Chun

AU - McNamara, Elyshia L.

AU - Nowak, Kristen J.

AU - Iwamoto, Hiroyuki

AU - Ochala, Julien

PY - 2018/12/1

Y1 - 2018/12/1

N2 - Myopathies are notably associated with mutations in genes encoding proteins known to be essential for the force production of skeletal muscle fibers, such as skeletal alpha-actin. The exact molecular mechanisms by which these specific defects induce myopathic phenotypes remain unclear. Hence, in the present study, to better understand actin dysfunction, we conducted a molecular dynamic simulation together with ex vivo experiments of the specific muscle disease-causing actin mutation, D286G located in the actin-actin interface. Our computational study showed that D286G impairs the flexural rigidity of actin filaments. However, upon activation, D286G did not have any direct consequences on actin filament extension. Hence, D286G may alter the structure of actin filaments but, when expressed together with normal actin molecules, it may only have minor effects on the ex vivo mechanics of actin filaments upon skeletal muscle fiber contraction.

AB - Myopathies are notably associated with mutations in genes encoding proteins known to be essential for the force production of skeletal muscle fibers, such as skeletal alpha-actin. The exact molecular mechanisms by which these specific defects induce myopathic phenotypes remain unclear. Hence, in the present study, to better understand actin dysfunction, we conducted a molecular dynamic simulation together with ex vivo experiments of the specific muscle disease-causing actin mutation, D286G located in the actin-actin interface. Our computational study showed that D286G impairs the flexural rigidity of actin filaments. However, upon activation, D286G did not have any direct consequences on actin filament extension. Hence, D286G may alter the structure of actin filaments but, when expressed together with normal actin molecules, it may only have minor effects on the ex vivo mechanics of actin filaments upon skeletal muscle fiber contraction.

KW - Actin mechanics

KW - Actin mutation

KW - Muscle fiber

KW - Muscle force

KW - Myopathy

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Molecular consequences of the myopathy-related D286G mutation on actin function

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Keywords

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