KLHL41 stabilizes skeletal muscle sarcomeres by nonproteolytic ubiquitination

Andres Ramirez-Martinez; Bercin Kutluk Cenik; Svetlana Bezprozvannaya; Beibei Chen; Rhonda Bassel-Duby; Ning Liu; Eric N. Olson

doi:10.7554/eLife.26439

KLHL41 stabilizes skeletal muscle sarcomeres by nonproteolytic ubiquitination

Andres Ramirez-Martinez, Bercin Kutluk Cenik, Svetlana Bezprozvannaya, Beibei Chen, Rhonda Bassel-Duby, Ning Liu^*, Eric N. Olson

^*Corresponding author for this work

Biochemistry and Molecular Genetics

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

42 Scopus citations

Abstract

Maintenance of muscle function requires assembly of contractile proteins into highly organized sarcomeres. Mutations in Kelch-like protein 41 (KLHL41) cause nemaline myopathy, a fatal muscle disorder associated with sarcomere disarray. We generated KLHL41 mutant mice, which display lethal disruption of sarcomeres and aberrant expression of muscle structural and contractile proteins, mimicking the hallmarks of the human disease. We show that KLHL41 is polyubiquitinated and acts, at least in part, by preventing aggregation and degradation of Nebulin, an essential component of the sarcomere. Furthermore, inhibition of KLHL41 poly-ubiquitination prevents its stabilization of nebulin, suggesting a unique role for ubiquitination in protein stabilization. These findings provide new insights into the molecular etiology of nemaline myopathy and reveal a mechanism whereby KLHL41 stabilizes sarcomeres and maintains muscle function by acting as a molecular chaperone. Similar mechanisms for protein stabilization likely contribute to the actions of other Kelch proteins.

Original language	English (US)
Article number	e26439
Journal	eLife
Volume	6
DOIs	https://doi.org/10.7554/eLife.26439
State	Published - Aug 9 2017

Funding

We thank Kate Luby-Phelps for assistance in the UT Southwestern Electron Microscopy Core Facility as well as John Shelton and James Richardson for help with histology. We thank Xiang Chen for technical assistance. We thank Erik Soderblom from Duke University School of Medicine for the use of the Proteomics and Metabolomics Shared Resource, which provided the quantitative proteomics service. We thank Jose Cabrera for assistance with graphics. This work was supported by grants from the NIH (HL130253, HL-077439, DK-099653 and AR-067294), Senator Paul D. Wellstone Muscular Dystrophy Cooperative Research Center grant (U54 HD 087351) and the Robert A Welch Foundation (grant 1–0025 to ENO).

ASJC Scopus subject areas

General Neuroscience
General Immunology and Microbiology
General Biochemistry, Genetics and Molecular Biology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.7554/eLife.26439

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title = "KLHL41 stabilizes skeletal muscle sarcomeres by nonproteolytic ubiquitination",

abstract = "Maintenance of muscle function requires assembly of contractile proteins into highly organized sarcomeres. Mutations in Kelch-like protein 41 (KLHL41) cause nemaline myopathy, a fatal muscle disorder associated with sarcomere disarray. We generated KLHL41 mutant mice, which display lethal disruption of sarcomeres and aberrant expression of muscle structural and contractile proteins, mimicking the hallmarks of the human disease. We show that KLHL41 is polyubiquitinated and acts, at least in part, by preventing aggregation and degradation of Nebulin, an essential component of the sarcomere. Furthermore, inhibition of KLHL41 poly-ubiquitination prevents its stabilization of nebulin, suggesting a unique role for ubiquitination in protein stabilization. These findings provide new insights into the molecular etiology of nemaline myopathy and reveal a mechanism whereby KLHL41 stabilizes sarcomeres and maintains muscle function by acting as a molecular chaperone. Similar mechanisms for protein stabilization likely contribute to the actions of other Kelch proteins.",

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AU - Ramirez-Martinez, Andres

AU - Cenik, Bercin Kutluk

AU - Bezprozvannaya, Svetlana

AU - Chen, Beibei

AU - Bassel-Duby, Rhonda

AU - Liu, Ning

AU - Olson, Eric N.

PY - 2017/8/9

Y1 - 2017/8/9

N2 - Maintenance of muscle function requires assembly of contractile proteins into highly organized sarcomeres. Mutations in Kelch-like protein 41 (KLHL41) cause nemaline myopathy, a fatal muscle disorder associated with sarcomere disarray. We generated KLHL41 mutant mice, which display lethal disruption of sarcomeres and aberrant expression of muscle structural and contractile proteins, mimicking the hallmarks of the human disease. We show that KLHL41 is polyubiquitinated and acts, at least in part, by preventing aggregation and degradation of Nebulin, an essential component of the sarcomere. Furthermore, inhibition of KLHL41 poly-ubiquitination prevents its stabilization of nebulin, suggesting a unique role for ubiquitination in protein stabilization. These findings provide new insights into the molecular etiology of nemaline myopathy and reveal a mechanism whereby KLHL41 stabilizes sarcomeres and maintains muscle function by acting as a molecular chaperone. Similar mechanisms for protein stabilization likely contribute to the actions of other Kelch proteins.

AB - Maintenance of muscle function requires assembly of contractile proteins into highly organized sarcomeres. Mutations in Kelch-like protein 41 (KLHL41) cause nemaline myopathy, a fatal muscle disorder associated with sarcomere disarray. We generated KLHL41 mutant mice, which display lethal disruption of sarcomeres and aberrant expression of muscle structural and contractile proteins, mimicking the hallmarks of the human disease. We show that KLHL41 is polyubiquitinated and acts, at least in part, by preventing aggregation and degradation of Nebulin, an essential component of the sarcomere. Furthermore, inhibition of KLHL41 poly-ubiquitination prevents its stabilization of nebulin, suggesting a unique role for ubiquitination in protein stabilization. These findings provide new insights into the molecular etiology of nemaline myopathy and reveal a mechanism whereby KLHL41 stabilizes sarcomeres and maintains muscle function by acting as a molecular chaperone. Similar mechanisms for protein stabilization likely contribute to the actions of other Kelch proteins.

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KLHL41 stabilizes skeletal muscle sarcomeres by nonproteolytic ubiquitination

Abstract

Funding

ASJC Scopus subject areas

UN SDGs

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