Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients

BACKGROUND: Calpain-3 deficiency causes oxidative and nitrosative stress-induced damage in skeletal muscle of LGMD2A patients, but mitochondrial respiratory chain function and anti-oxidant levels have not been systematically assessed in this clinical population previously. METHODS: We identified 14...

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Autores principales: Nilsson, Mats I., Macneil, Lauren G., Kitaoka, Yu, Alqarni, Fatimah, Suri, Rahul, Akhtar, Mahmood, Haikalis, Maria E., Dhaliwal, Pavneet, Saeed, Munim, Tarnopolsky, Mark A.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: Public Library of Science 2014
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Research Article
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4117472/
https://www.ncbi.nlm.nih.gov/pubmed/25079074
http://dx.doi.org/10.1371/journal.pone.0102549
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author Nilsson, Mats I.
Macneil, Lauren G.
Kitaoka, Yu
Alqarni, Fatimah
Suri, Rahul
Akhtar, Mahmood
Haikalis, Maria E.
Dhaliwal, Pavneet
Saeed, Munim
Tarnopolsky, Mark A.
author_facet Nilsson, Mats I.
Macneil, Lauren G.
Kitaoka, Yu
Alqarni, Fatimah
Suri, Rahul
Akhtar, Mahmood
Haikalis, Maria E.
Dhaliwal, Pavneet
Saeed, Munim
Tarnopolsky, Mark A.
author_sort Nilsson, Mats I.
collection PubMed
description BACKGROUND: Calpain-3 deficiency causes oxidative and nitrosative stress-induced damage in skeletal muscle of LGMD2A patients, but mitochondrial respiratory chain function and anti-oxidant levels have not been systematically assessed in this clinical population previously. METHODS: We identified 14 patients with phenotypes consistent with LGMD2A and performed CAPN3 gene sequencing, CAPN3 expression/autolysis measurements, and in silico predictions of pathogenicity. Oxidative damage, anti-oxidant capacity, and mitochondrial enzyme activities were determined in a subset of muscle biopsies. RESULTS: Twenty-one disease-causing variants were detected along the entire CAPN3 gene, five of which were novel (c.338 T>C, c.500 T>C, c.1525-1 G>T, c.2115+4 T>G, c.2366 T>A). Protein- and mRNA-based tests confirmed in silico predictions and the clinical diagnosis in 75% of patients. Reductions in antioxidant defense mechanisms (SOD-1 and NRF-2, but not SOD-2), coupled with increased lipid peroxidation and protein ubiquitination, were observed in calpain-3 deficient muscle, indicating a redox imbalance primarily affecting non-mitochondrial compartments. Although ATP synthase levels were significantly lower in LGMD2A patients, citrate synthase, cytochrome c oxidase, and complex I+III activities were not different from controls. CONCLUSIONS: Despite significant oxidative damage and redox imbalance in cytosolic/myofibrillar compartments, mitochondrial respiratory chain function is largely maintained in skeletal muscle of LGMD2A patients.
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spelling pubmed-41174722014-08-04 Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients Nilsson, Mats I. Macneil, Lauren G. Kitaoka, Yu Alqarni, Fatimah Suri, Rahul Akhtar, Mahmood Haikalis, Maria E. Dhaliwal, Pavneet Saeed, Munim Tarnopolsky, Mark A. PLoS One Research Article BACKGROUND: Calpain-3 deficiency causes oxidative and nitrosative stress-induced damage in skeletal muscle of LGMD2A patients, but mitochondrial respiratory chain function and anti-oxidant levels have not been systematically assessed in this clinical population previously. METHODS: We identified 14 patients with phenotypes consistent with LGMD2A and performed CAPN3 gene sequencing, CAPN3 expression/autolysis measurements, and in silico predictions of pathogenicity. Oxidative damage, anti-oxidant capacity, and mitochondrial enzyme activities were determined in a subset of muscle biopsies. RESULTS: Twenty-one disease-causing variants were detected along the entire CAPN3 gene, five of which were novel (c.338 T>C, c.500 T>C, c.1525-1 G>T, c.2115+4 T>G, c.2366 T>A). Protein- and mRNA-based tests confirmed in silico predictions and the clinical diagnosis in 75% of patients. Reductions in antioxidant defense mechanisms (SOD-1 and NRF-2, but not SOD-2), coupled with increased lipid peroxidation and protein ubiquitination, were observed in calpain-3 deficient muscle, indicating a redox imbalance primarily affecting non-mitochondrial compartments. Although ATP synthase levels were significantly lower in LGMD2A patients, citrate synthase, cytochrome c oxidase, and complex I+III activities were not different from controls. CONCLUSIONS: Despite significant oxidative damage and redox imbalance in cytosolic/myofibrillar compartments, mitochondrial respiratory chain function is largely maintained in skeletal muscle of LGMD2A patients. Public Library of Science 2014-07-31 /pmc/articles/PMC4117472/ /pubmed/25079074 http://dx.doi.org/10.1371/journal.pone.0102549 Text en © 2014 Nilsson et al http://creativecommons.org/licenses/by/4.0/ This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are properly credited.
spellingShingle Research Article
Nilsson, Mats I.
Macneil, Lauren G.
Kitaoka, Yu
Alqarni, Fatimah
Suri, Rahul
Akhtar, Mahmood
Haikalis, Maria E.
Dhaliwal, Pavneet
Saeed, Munim
Tarnopolsky, Mark A.
Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title_full Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title_fullStr Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title_full_unstemmed Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title_short Redox State and Mitochondrial Respiratory Chain Function in Skeletal Muscle of LGMD2A Patients
title_sort redox state and mitochondrial respiratory chain function in skeletal muscle of lgmd2a patients
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4117472/
https://www.ncbi.nlm.nih.gov/pubmed/25079074
http://dx.doi.org/10.1371/journal.pone.0102549
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