Fast-twitch skeletal muscles of dystrophic mouse pups are resistant to injury from acute mechanical stress

2002 ◽  
Vol 283 (4) ◽  
pp. C1090-C1101 ◽  
Author(s):  
Robert W. Grange ◽  
Thomas G. Gainer ◽  
Krista M. Marschner ◽  
Robert J. Talmadge ◽  
James T. Stull
Keyword(s):  
Skeletal Muscles ◽  
Mechanical Injury ◽  
Membrane Injury ◽  
Glycoprotein Complex ◽  
Dystrophin Glycoprotein Complex ◽  
Duchenne's Muscular Dystrophy ◽  
Fast Twitch ◽  
Dystrophin Glycoprotein

Loss of the dystrophin-glycoprotein complex from muscle sarcolemma in Duchenne's muscular dystrophy (DMD) renders the membrane susceptible to mechanical injury, leaky to Ca2+, and disrupts signaling, but the precise mechanism(s) leading to the onset of DMD remain unclear. To assess the role of mechanical injury in the onset of DMD, extensor digitorum longus (EDL) muscles from C57 (control), mdx, and mdx-utrophin-deficient [ mdx:utrn(−/−); dystrophic] pups aged 9–12 days were subjected to an acute stretch-injury or no-stretch protocol in vitro. Before the stretches, isometric stress was attenuated for mdx:utrn(−/−) compared with control muscles at all stimulation frequencies ( P< 0.05). During the stretches, EDL muscles for each genotype demonstrated similar mean stiffness values. After the stretches, isometric stress during a tetanus was decreased significantly for both mdx and mdx:utrn(−/−) muscles compared with control muscles ( P < 0.05). Membrane injury assessed by uptake of procion orange dye was greater for dystrophic compared with control EDL ( P < 0.05), but, within each genotype, the percentage of total cells taking up dye was not different for the no-stretch vs. stretch condition. These data suggest that the sarcolemma of maturing dystrophic EDL muscles are resistant to acute mechanical injury.

scholarly journals Contraction-Induced Loss of Plasmalemmal Electrophysiological Function Is Dependent on the Dystrophin Glycoprotein Complex

2021 ◽  
Vol 12 ◽  
Author(s):  
Cory W. Baumann ◽  
Angus Lindsay ◽  
Sylvia R. Sidky ◽  
James M. Ervasti ◽  
Gordon L. Warren ◽  
...  
Keyword(s):  
M Wave ◽  
Glycoprotein Complex ◽  
Dystrophic Mouse ◽  
Dystrophin Deficiency ◽  
Torque Loss ◽  
Dystrophin Glycoprotein Complex ◽  
The Many ◽  
Dystrophin Glycoprotein ◽  
Mouse Lines

Weakness and atrophy are key features of Duchenne muscular dystrophy (DMD). Dystrophin is one of the many proteins within the dystrophin glycoprotein complex (DGC) that maintains plasmalemmal integrity and cellular homeostasis. The dystrophin-deficient mdx mouse is also predisposed to weakness, particularly when subjected to eccentric (ECC) contractions due to electrophysiological dysfunction of the plasmalemma. Here, we determined if maintenance of plasmalemmal excitability during and after a bout of ECC contractions is dependent on intact and functional DGCs rather than, solely, dystrophin expression. Wild-type (WT) and dystrophic mice (mdx, mL172H and Sgcb−/− mimicking Duchenne, Becker and Limb-girdle Type 2E muscular dystrophies, respectively) with varying levels of dystrophin and DGC functionality performed 50 maximal ECC contractions with simultaneous torque and electromyographic measurements (M-wave root-mean-square, M-wave RMS). ECC contractions caused all mouse lines to lose torque (p&lt;0.001); however, deficits were greater in dystrophic mouse lines compared to WT mice (p&lt;0.001). Loss of ECC torque did not correspond to a reduction in M-wave RMS in WT mice (p=0.080), while deficits in M-wave RMS exceeded 50% in all dystrophic mouse lines (p≤0.007). Moreover, reductions in ECC torque and M-wave RMS were greater in mdx mice compared to mL172H mice (p≤0.042). No differences were observed between mdx and Sgcb−/− mice (p≥0.337). Regression analysis revealed ≥98% of the variance in ECC torque loss could be explained by the variance in M-wave RMS in dystrophic mouse lines (p&lt;0.001) but not within WT mice (R2=0.211; p=0.155). By comparing mouse lines that had varying amounts and functionality of dystrophin and other DGC proteins, we observed that (1) when all DGCs are intact, plasmalemmal action potential generation and conduction is maintained, (2) deficiency of the DGC protein β-sarcoglycan is as disruptive to plasmalemmal excitability as is dystrophin deficiency and, (3) some functionally intact DGCs are better than none. Our results highlight the significant role of the DGC plays in maintaining plasmalemmal excitability and that a collective synergism (via each DGC protein) is required for this complex to function properly during ECC contractions.

scholarly journals Caveolin-3: A Causative Process of Chicken Muscular Dystrophy

Biomolecules ◽  
2020 ◽  
Vol 10 (9) ◽  
pp. 1206
Author(s):  
Tateki Kikuchi
Keyword(s):  
Muscular Dystrophy ◽  
Missense Mutation ◽  
Ubiquitin Ligase ◽  
Core Protein ◽  
Ubiquitin Protein Ligase ◽  
Glycoprotein Complex ◽  
Dystrophin Glycoprotein Complex ◽  
Slow Twitch ◽  
Fast Twitch ◽  
Dystrophin Glycoprotein

The etiology of chicken muscular dystrophy is the synthesis of aberrant WW domain containing E3 ubiquitin-protein ligase 1 (WWP1) protein made by a missense mutation of WWP1 gene. The β-dystroglycan that confers stability to sarcolemma was identified as a substrate of WWP protein, which induces the next molecular collapse. The aberrant WWP1 increases the ubiquitin ligase-mediated ubiquitination following severe degradation of sarcolemmal and cytoplasmic β-dystroglycan, and an erased β-dystroglycan in dystrophic αW fibers will lead to molecular imperfection of the dystrophin-glycoprotein complex (DGC). The DGC is a core protein of costamere that is an essential part of force transduction and protects the muscle fibers from contraction-induced damage. Caveolin-3 (Cav-3) and dystrophin bind competitively to the same site of β-dystroglycan, and excessive Cav-3 on sarcolemma will block the interaction of dystrophin with β-dystroglycan, which is another reason for the disruption of the DGC. It is known that fast-twitch glycolytic fibers are more sensitive and vulnerable to contraction-induced small tears than slow-twitch oxidative fibers under a variety of diseased conditions. Accordingly, the fast glycolytic αW fibers must be easy with rapid damage of sarcolemma corruption seen in chicken muscular dystrophy, but the slow oxidative fibers are able to escape from these damages.

scholarly journals Caveolin 3, Flotillin 1 and Influenza Virus Hemagglutinin Reside in Distinct Domains on the Sarcolemma of Skeletal Myofibers

2012 ◽  
Vol 2012 ◽  
pp. 1-11 ◽  
Author(s):  
Mika Kaakinen ◽  
Tuula Kaisto ◽  
Paavo Rahkila ◽  
Kalervo Metsikkö
Keyword(s):  
Distribution Patterns ◽  
Cholesterol Depletion ◽  
Similar Distribution ◽  
Glycoprotein Complex ◽  
Influenza Hemagglutinin ◽  
Influenza Virus Hemagglutinin ◽  
Dystrophin Glycoprotein Complex ◽  
Dystrophin Glycoprotein ◽  
Similar Distribution Pattern

We examined the distribution of selected raft proteins on the sarcolemma of skeletal myofibers and the role of cholesterol environment in the distribution. Immunofluorescence staining showed that flotillin-1 and influenza hemagglutinin exhibited rafts that located in the domains deficient of the dystrophin glycoprotein complex, but the distribution patterns of the two proteins were different. Cholesterol depletion from the sarcolemma by means of methyl-β-cyclodextrin resulted in distorted caveolar morphology and redistribution of the caveolin 3 protein. Concomitantly, the water permeability of the sarcolemma increased significantly. However, cholesterol depletion did not reshuffle flotillin 1 or hemagglutinin. Furthermore, a hemagglutinin variant that lacked a raft-targeting signals exhibited a similar distribution pattern as the native raft protein. These findings indicate that each raft protein exhibits a strictly defined distribution in the sarcolemma. Only the distribution of caveolin 3 that binds cholesterol was exclusively dependent on cholesterol environment.

scholarly journals Dystrophin–glycoprotein complex regulates muscle nitric oxide production through mechanoregulation of AMPK signaling

2015 ◽  
Vol 112 (44) ◽  
pp. 13663-13668 ◽  
Author(s):  
Joanne F. Garbincius ◽  
Daniel E. Michele
Keyword(s):  
Nitric Oxide ◽  
Mechanical Activation ◽  
Mechanical Stretch ◽  
Cyclic Stretch ◽  
No Production ◽  
Ampk Signaling ◽  
Glycoprotein Complex ◽  
Dystrophin Glycoprotein Complex ◽  
Dystrophin Glycoprotein

Patients deficient in dystrophin, a protein that links the cytoskeleton to the extracellular matrix via the dystrophin–glycoprotein complex (DGC), exhibit muscular dystrophy, cardiomyopathy, and impaired muscle nitric oxide (NO) production. We used live-cell NO imaging and in vitro cyclic stretch of isolated adult mouse cardiomyocytes as a model system to investigate if and how the DGC directly regulates the mechanical activation of muscle NO signaling. Acute activation of NO synthesis by mechanical stretch was impaired in dystrophin-deficient mdx cardiomyocytes, accompanied by loss of stretch-induced neuronal NO synthase (nNOS) S1412 phosphorylation. Intriguingly, stretch induced the acute activation of AMP-activated protein kinase (AMPK) in normal cardiomyocytes but not in mdx cardiomyocytes, and specific inhibition of AMPK was sufficient to attenuate mechanoactivation of NO production. Therefore, we tested whether direct pharmacologic activation of AMPK could bypass defective mechanical signaling to restore nNOS activity in dystrophin-deficient cardiomyocytes. Indeed, activation of AMPK with 5-aminoimidazole-4-carboxamide riboside or salicylate increased nNOS S1412 phosphorylation and was sufficient to enhance NO production in mdx cardiomyocytes. We conclude that the DGC promotes the mechanical activation of cardiac nNOS by acting as a mechanosensor to regulate AMPK activity, and that pharmacologic AMPK activation may be a suitable therapeutic strategy for restoring nNOS activity in dystrophin-deficient hearts and muscle.

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