Upregulation of store-operated Ca2+ entry in dystrophic mdx mouse muscle

2010 ◽  
Vol 299 (1) ◽  
pp. C42-C50 ◽  
Author(s):  
Joshua N. Edwards ◽  
Oliver Friedrich ◽  
Tanya R. Cully ◽  
Frederic von Wegner ◽  
Robyn M. Murphy ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Fibers ◽  
Mdx Mouse ◽  
Cell Necrosis ◽  
Wild Type ◽  
Dystrophic Muscle ◽  
Adult Skeletal Muscle ◽  
Mouse Muscle ◽  
Threefold Increase ◽  
Tubular System

Store-operated Ca2+ entry (SOCE) is an important mechanism in virtually all cells. In adult skeletal muscle, this mechanism is highly specialized for the rapid delivery of Ca2+ from the transverse tubule into the junctional cleft during periods of depleting Ca2+ release. In dystrophic muscle fibers, SOCE may be a source of Ca2+ overload, leading to cell necrosis. However, this possibility is yet to be examined in an adult fiber during Ca2+ release. To examine this, Ca2+ in the tubular system and cytoplasm were simultaneously imaged during direct release of Ca2+ from sarcoplasmic reticulum (SR) in skeletal muscle fibers from healthy (wild-type, WT) and dystrophic mdx mouse. The mdx fibers were found to have normal activation and deactivation properties of SOCE. However, a depression of the cytoplasmic Ca2+ transient in mdx compared with WT fibers was observed, as was a shift in the SOCE activation and deactivation thresholds to higher SR Ca2+ concentrations ([Ca2+]SR). The shift in SOCE activation and deactivation thresholds was accompanied by an approximately threefold increase in STIM1 and Orai1 proteins in dystrophic muscle. While the mdx fibers can introduce more Ca2+ into the fiber for an equivalent depletion of [Ca2+]SR via SOCE, it remains unclear whether this is deleterious.

scholarly journals Extensive but Coordinated Reorganization of the Membrane Skeleton in Myofibers of Dystrophic (mdx) Mice

1999 ◽  
Vol 144 (6) ◽  
pp. 1259-1270 ◽  
Author(s):  
McRae W. Williams ◽  
Robert J. Bloch
Keyword(s):  
Skeletal Muscle ◽  
Membrane Proteins ◽  
Muscle Fibers ◽  
Membrane Skeleton ◽  
Confocal Imaging ◽  
Mdx Mouse ◽  
Mdx Mice ◽  
Intracellular Membrane ◽  
Dystrophic Muscle ◽  
Dihydropyridine Receptors

We used immunofluorescence techniques and confocal imaging to study the organization of the membrane skeleton of skeletal muscle fibers of mdx mice, which lack dystrophin. β-Spectrin is normally found at the sarcolemma in costameres, a rectilinear array of longitudinal strands and elements overlying Z and M lines. However, in the skeletal muscle of mdx mice, β-spectrin tends to be absent from the sarcolemma over M lines and the longitudinal strands may be disrupted or missing. Other proteins of the membrane and associated cytoskeleton, including syntrophin, β-dystroglycan, vinculin, and Na,K-ATPase are also concentrated in costameres, in control myofibers, and mdx muscle. They also distribute into the same altered sarcolemmal arrays that contain β-spectrin. Utrophin, which is expressed in mdx muscle, also codistributes with β-spectrin at the mutant sarcolemma. By contrast, the distribution of structural and intracellular membrane proteins, including α-actinin, the Ca-ATPase and dihydropyridine receptors, is not affected, even at sites close to the sarcolemma. Our results suggest that in myofibers of the mdx mouse, the membrane- associated cytoskeleton, but not the nearby myoplasm, undergoes widespread coordinated changes in organization. These changes may contribute to the fragility of the sarcolemma of dystrophic muscle.

Changes in plasma membrane Ca-ATPase and stromal interacting molecule 1 expression levels for Ca2+ signaling in dystrophic mdx mouse muscle

2012 ◽  
Vol 303 (5) ◽  
pp. C567-C576 ◽  
Author(s):  
Tanya R. Cully ◽  
Joshua N. Edwards ◽  
Oliver Friedrich ◽  
D. George Stephenson ◽  
Robyn M. Murphy ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Plasma Membrane ◽  
Mdx Mouse ◽  
Wild Type ◽  
Mouse Muscle ◽  
Muscle Plasma Membrane ◽  
Partner Protein ◽  
Close Relationship ◽  
The Common ◽  
T System

The majority of the skeletal muscle plasma membrane is internalized as part of the tubular (t-) system, forming a standing junction with the sarcoplasmic reticulum (SR) membrane throughout the muscle fiber. This arrangement facilitates not only a rapid and large release of Ca2+ from the SR for contraction upon excitation of the fiber, but has also direct implications for other interdependent cellular regulators of Ca2+. The t-system plasma membrane Ca-ATPase (PMCA) and store-operated Ca2+ entry (SOCE) can also be activated upon release of SR Ca2+. In muscle, the SR Ca2+ sensor responsible for rapidly activated SOCE appears to be the stromal interacting molecule 1L (STIM1L) isoform of STIM1 protein, which directly interacts with the Orai1 Ca2+ channel in the t-system. The common isoform of STIM1 is STIM1S, and it has been shown that STIM1 together with Orai1 in a complex with the partner protein of STIM (POST) reduces the activity of the PMCA. We have previously shown that Orai1 and STIM1 are upregulated in dystrophic mdx mouse muscle, and here we show that STIM1L and PMCA are also upregulated in mdx muscle. Moreover, we show that the ratios of STIM1L to STIM1S in wild-type (WT) and mdx muscle are not different. We also show a greater store-dependent Ca2+ influx in mdx compared with WT muscle for similar levels of SR Ca2+ release while normal activation and deactivation properties were maintained. Interestingly, the fiber-averaged ability of WT and mdx muscle to extrude Ca2+ via PMCA was found to be the same despite differences in PMCA densities. This suggests that there is a close relationship among PMCA, STIM1L, STIM1S, Orai1, and also POST expression in mdx muscle to maintain the same Ca2+ extrusion properties as in the WT muscle.

scholarly journals Involvement of TRPC in the abnormal calcium influx observed in dystrophic (mdx) mouse skeletal muscle fibers

2002 ◽  
Vol 158 (6) ◽  
pp. 1089-1096 ◽  
Author(s):  
Clarisse Vandebrouck ◽  
Dominique Martin ◽  
Monique Colson-Van Schoor ◽  
Huguette Debaix ◽  
Philippe Gailly
Keyword(s):  
Skeletal Muscle ◽  
Transient Receptor Potential ◽  
Calcium Influx ◽  
Surface Membrane ◽  
Muscle Fibers ◽  
Mdx Mouse ◽  
Mdx Mice ◽  
Patch Clamp Technique ◽  
Adult Skeletal Muscle ◽  
Skeletal Muscle Fibers

Duchenne muscular dystrophy results from the lack of dystrophin, a cytoskeletal protein associated with the inner surface membrane, in skeletal muscle. The absence of dystrophin induces an abnormal increase of sarcolemmal calcium influx through cationic channels in adult skeletal muscle fibers from dystrophic (mdx) mice. We observed that the activity of these channels was increased after depletion of the stores of calcium with thapsigargin or caffeine. By analogy with the situation observed in nonexcitable cells, we therefore hypothesized that these store-operated channels could belong to the transient receptor potential channel (TRPC) family. We measured the expression of TRPC isoforms in normal and mdx adult skeletal muscles fibers, and among the seven known isoforms, five were detected (TRPC1, 2, 3, 4, and 6) by RT-PCR. Western blot analysis and immunocytochemistry of normal and mdx muscle fibers demonstrated the localization of TRPC1, 4, and 6 proteins at the plasma membrane. Therefore, an antisense strategy was used to repress these TRPC isoforms. In parallel with the repression of the TRPCs, we observed that the occurrence of calcium leak channels was decreased to one tenth of its control value (patch-clamp technique), showing the involvement of TRPC in the abnormal calcium influx observed in dystrophic fibers.

scholarly journals Muscle-specific microRNA-206 targets multiple components in dystrophic skeletal muscle representing beneficial adaptations

2017 ◽  
Vol 312 (3) ◽  
pp. C209-C221 ◽  
Author(s):  
Adel Amirouche ◽  
Vanessa E. Jahnke ◽  
John A. Lunde ◽  
Nathalie Koulmann ◽  
Damien G. Freyssenet ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Therapeutic Potential ◽  
Neuromuscular Disorders ◽  
Regulatory Function ◽  
Mdx Mouse ◽  
Dystrophic Muscle ◽  
Mouse Muscle ◽  
Multiple Components ◽  
Specific Mrnas ◽  
Pleiotropic Regulator

Over the last several years, converging lines of evidence have indicated that miR-206 plays a pivotal role in promoting muscle differentiation and regeneration, thereby potentially impacting positively on the progression of neuromuscular disorders, including Duchenne muscular dystrophy (DMD). Despite several studies showing the regulatory function of miR-206 on target mRNAs in skeletal muscle cells, the effects of overexpression of miR-206 in dystrophic muscles remain to be established. Here, we found that miR-206 overexpression in mdx mouse muscles simultaneously targets multiple mRNAs and proteins implicated in satellite cell differentiation, muscle regeneration, and at the neuromuscular junction. Overexpression of miR-206 also increased the levels of several muscle-specific mRNAs/proteins, while enhancing utrophin A expression at the sarcolemma. Finally, we also observed that the increased expression of miR-206 in dystrophin-deficient mouse muscle decreased the production of proinflammatory cytokines and infiltration of macrophages. Taken together, our results show that miR-206 acts as a pleiotropic regulator that targets multiple key mRNAs and proteins expected to provide beneficial adaptations in dystrophic muscle, thus highlighting its therapeutic potential for DMD.

Branched fibers in dystrophic mdx muscle are associated with a loss of force following lengthening contractions

2007 ◽  
Vol 293 (3) ◽  
pp. C985-C992 ◽  
Author(s):  
S. Chan ◽  
S. I. Head ◽  
J. W. Morley
Keyword(s):  
Skeletal Muscle ◽  
Muscular Dystrophy ◽  
Extensor Digitorum Longus ◽  
Muscle Fibers ◽  
Force Production ◽  
Mdx Mouse ◽  
Mdx Mice ◽  
Dystrophic Muscle ◽  
Lengthening Contractions ◽  
Fast Twitch

We demonstrated that the susceptibility of skeletal muscle to injury from lengthening contractions in the dystrophin-deficient mdx mouse is directly linked with the extent of fiber branching within the muscles and that both parameters increase as the mdx animal ages. We subjected isolated extensor digitorum longus muscles to a lengthening contraction protocol of 15% strain and measured the resulting drop in force production (force deficit). We also examined the morphology of individual muscle fibers. In mdx mice 1–2 mo of age, 17% of muscle fibers were branched, and the force deficit of 7% was not significantly different from that of age-matched littermate controls. In mdx mice 6–7 mo of age, 89% of muscle fibers were branched, and the force deficit of 58% was significantly higher than the 25% force deficit of age-matched littermate controls. These data demonstrated an association between the extent of branching and the greater vulnerability to contraction-induced injury in the older fast-twitch dystrophic muscle. Our findings demonstrate that fiber branching may play a role in the pathogenesis of muscular dystrophy in mdx mice, and this could affect the interpretation of previous studies involving lengthening contractions in this animal.

Enzyme studies of skeletal muscle in mice with hereditary muscular dystrophy

1963 ◽  
Vol 205 (5) ◽  
pp. 897-901 ◽  
Author(s):  
Marilyn W. McCaman
Keyword(s):  
Skeletal Muscle ◽  
Muscular Dystrophy ◽  
Glutathione Reductase ◽  
Enzyme Activities ◽  
Lactic Dehydrogenase ◽  
Normal Muscle ◽  
Dystrophic Muscle ◽  
Nerve Section ◽  
Mouse Muscle ◽  
Dystrophic Mouse

The activities of 20 enzymes in normal, heterozygous, and dystrophic mouse muscle were studied by means of quantitative microchemical methods. Enzyme activities in normal and heterozygous muscle were essentially the same. In dystrophic muscle glucose-6-P dehydrogenase, 6-P-gluconic dehydrogenase, glutathione reductase, peptidase, ß-glucuronidase, and glucokinase activities were significantly higher than in normal muscle, while α-glycero-P dehydrogenase and lactic dehydrogenase activities were significantly lower. The pattern of enzyme activities found in normal gastrocnemius denervated by nerve section was strikingly similar to that in dystrophic muscle.

Treadmill running causes significant fiber damage in skeletal muscle of KATP channel-deficient mice

2005 ◽  
Vol 22 (2) ◽  
pp. 204-212 ◽  
Author(s):  
M. Thabet ◽  
T. Miki ◽  
S. Seino ◽  
J.-M. Renaud
Keyword(s):  
Skeletal Muscle ◽  
Muscle Fibers ◽  
Treadmill Running ◽  
Wild Type ◽  
Connective Tissues ◽  
Fiber Damage ◽  
Hindlimb Muscles ◽  
Skeletal Muscle Fibers ◽  
And Function ◽  
Deficient Mice

Although it has been suggested that the ATP-sensitive K+ (KATP) channel protects muscle against function impairment, most studies have so far given little evidence for significant perturbation in the integrity and function of skeletal muscle fibers from inactive mice that lack KATP channel activity in their cell membrane. The objective was, therefore, to test the hypothesis that KATP channel-deficient skeletal muscle fibers become damaged when mice are subjected to stress. Wild-type and KATP channel-deficient mice (Kir6.2−/− mice) were subjected to 4–5 wk of treadmill running at either 20 m/min with 0° inclination or at 24 m/min with 20° uphill inclination. Muscles of all wild-type mice and of nonexercised Kir6.2−/− mice had very few fibers with internal nuclei. After 4–5 wk of treadmill running, there was little evidence for connective tissues and mononucleated cells in Kir6.2−/− hindlimb muscles, whereas the number of fibers with internal nuclei, which appear when damaged fibers are regenerated by satellite cells, was significantly higher in Kir6.2−/− than wild-type mice. Between 5% and 25% of the total number of fibers in Kir6.2−/− extensor digitum longus, plantaris, and tibialis muscles had internal nuclei, and most of such fibers were type IIB fibers. Contrary to hindlimb muscles, diaphragms of Kir6.2−/− mice that had run at 24 m/min had few fibers with internal nuclei, but mild to severe fiber damage was observed. In conclusion, the study provides for the first time evidence 1) that the KATP channels of skeletal muscle are essential to prevent fiber damage, and thus muscle dysfunction; and 2) that the extent of fiber damage is greater and the capacity of fiber regeneration is less in Kir6.2−/− diaphragm muscles compared with hindlimb muscles.

Implication of the satellite cell in dystrophic muscle fibrosis: a self-perpetuating mechanism of collagen overproduction

2007 ◽  
Vol 293 (2) ◽  
pp. C661-C669 ◽  
Author(s):  
Catherine Alexakis ◽  
Terence Partridge ◽  
George Bou-Gharios
Keyword(s):  
Skeletal Muscle ◽  
Satellite Cell ◽  
Satellite Cells ◽  
Collagen Type ◽  
Collagen Type I ◽  
C2c12 Cells ◽  
Type I ◽  
Wild Type ◽  
Dystrophic Muscle ◽  
Type Iii

Because of its mechanical function, skeletal muscle is heavily influenced by the composition of its extracellular matrix (ECM). Fibrosis generated by chronic damage, such as occurs in muscular dystrophies, is thus particularly disastrous in this tissue. Here, we examined the interrelationship between the muscle satellite cell and the production of collagen type I, a major component of fibrotic ECM, by using both C2C12, a satellite cell-derived cell line, and primary muscle satellite cells. In C2C12 cells, we found that expression of collagen type I mRNA decreases substantially during skeletal muscle differentiation. On a single-cell level, collagen type I and myogenin became mutually exclusive after 3 days in differentiation medium, whereas addition of collagen markedly suppressed differentiation of C2C12 cells. Primary cultures of satellite cells associated with isolated single fibers of the young (4 wk old) mdx dystrophic mouse and of C57BL/10ScSn wild-type controls expressed collagen type I and type III mRNA and protein. This pattern persisted in wild-type mice at all ages. But, curiously, in older (18-mo-old) mdx mice, although the myogenic cells continued to express type III collagen, type I expression became restricted to nonmyogenic cells. These cells typically constituted part of a cellular sheet surrounding the old mdx fibers. This combination of features strongly suggests that the progression to fibrosis in dystrophic muscle involves changes in the mechanisms controlling matrix production, which generates positive feedback that results in a reprogramming of myoblasts to a profibrotic function.

scholarly journals Normal myogenic cells from newborn mice restore normal histology to degenerating muscles of the mdx mouse.

1990 ◽  
Vol 111 (6) ◽  
pp. 2437-2449 ◽  
Author(s):  
J E Morgan ◽  
E P Hoffman ◽  
T A Partridge
Keyword(s):  
Skeletal Muscle ◽  
Muscle Fibers ◽  
Mdx Mouse ◽  
Newborn Mouse ◽  
Normal Muscle ◽  
Newborn Mice ◽  
X Ray ◽  
Dystrophin Deficiency ◽  
Regenerated Fibers ◽  
Muscle Precursor Cells

Dystrophin deficiency in skeletal muscle of the x-linked dystrophic (mdx) mouse can be partially remedied by implantation of normal muscle precursor cells (mpc) (Partridge, T. A., J. E. Morgan, G. R. Coulton, E. P. Hoffman, and L. M. Kunkel. 1989. Nature (Lond.). 337:176-179). However, it is difficult to determine whether this biochemical "rescue" results in any improvement in the structure or function of the treated muscle, because the vigorous regeneration of mdx muscle more than compensates for the degeneration (Coulton, G. R., N. A. Curtin, J. E. Morgan, and T. A. Partridge. 1988. Neuropathol. Appl. Neurobiol. 14:299-314). By using x-ray irradiation to prevent mpc proliferation, it is possible to study loss of mdx muscle fibers without the complicating effect of simultaneous fiber regeneration. Thus, improvements in fiber survival resulting from any potential therapy can be detected easily (Wakeford, S., D. J. Watt, and T. A. Patridge. 1990. Muscle & Nerve.) Here, we have implanted normal mpc, obtained from newborn mice, into such preirradiated mdx muscles, finding that it is far more extensively permeated and replaced by implanted mpc than is nonirradiated mdx muscle; this is evident both from analysis of glucose-6-phosphate isomerase isoenzyme markers and from immunoblots and immunostaining of dystrophin in the treated muscles. Incorporation of normal mpc markedly reduces the loss of muscle fibers and the deterioration of muscle structure which otherwise occurs in irradiated mdx muscles. Surprisingly, the regenerated fibers are largely peripherally nucleated, whereas regenerated mouse skeletal muscle fibers are normally centrally nucleated. We attribute this regeneration of apparently normal muscle to the tendency of newborn mouse mpc to recapitulate their neonatal ontogeny, even when grafted into 3-wk-old degenerating muscle.

scholarly journals Changes in Gene Expression of the MCU Complex Are Induced by Electrical Stimulation in Adult Skeletal Muscle

2021 ◽  
Vol 11 ◽  
Author(s):  
Esteban R. Quezada ◽  
Alexis Díaz-Vegas ◽  
Enrique Jaimovich ◽  
Mariana Casas
Keyword(s):  
Gene Expression ◽  
Skeletal Muscle ◽  
Electrical Stimulation ◽  
Muscle Fibers ◽  
Low Frequency ◽  
Extracellular Atp ◽  
Mrna Levels ◽  
Dependent Manner ◽  
Adult Skeletal Muscle ◽  
Muscle Plasticity

The slow calcium transient triggered by low-frequency electrical stimulation (ES) in adult muscle fibers and regulated by the extracellular ATP/IP3/IP3R pathway has been related to muscle plasticity. A regulation of muscular tropism associated with the MCU has also been described. However, the role of transient cytosolic calcium signals and signaling pathways related to muscle plasticity over the regulation of gene expression of the MCU complex (MCU, MICU1, MICU2, and EMRE) in adult skeletal muscle is completely unknown. In the present work, we show that 270 0.3-ms-long pulses at 20-Hz ES (and not at 90 Hz) transiently decreased the mRNA levels of the MCU complex in mice flexor digitorum brevis isolated muscle fibers. Importantly, when ATP released after 20-Hz ES is hydrolyzed by the enzyme apyrase, the repressor effect of 20 Hz on mRNA levels of the MCU complex is lost. Accordingly, the exposure of muscle fibers to 30 μM exogenous ATP produces the same effect as 20-Hz ES. Moreover, the use of apyrase in resting conditions (without ES) increased mRNA levels of MCU, pointing out the importance of extracellular ATP concentration over MCU mRNA levels. The use of xestospongin B (inhibitor of IP3 receptors) also prevented the decrease of mRNA levels of MCU, MICU1, MICU2, and EMRE mediated by a low-frequency ES. Our results show that the MCU complex can be regulated by electrical stimuli in a frequency-dependent manner. The changes observed in mRNA levels may be related to changes in the mitochondria, associated with the phenotypic transition from a fast- to a slow-type muscle, according to the described effect of this stimulation frequency on muscle phenotype. The decrease in mRNA levels of the MCU complex by exogenous ATP and the increase in MCU levels when basal ATP is reduced with the enzyme apyrase indicate that extracellular ATP may be a regulator of the MCU complex. Moreover, our results suggest that this regulation is part of the axes linking low-frequency stimulation with ATP/IP3/IP3R.

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