Physical exercise stimulates autophagy in normal skeletal muscles but is detrimental for collagen VI-deficient muscles

Autophagy is a catabolic process that provides the degradation of altered/damaged organelles through the fusion between autophagosomes and lysosomes. Proper regulation of the autophagic flux is fundamental for the homeostasis of skeletal muscles in physiological conditions and in response to stress. Defective as well as excessive autophagy is detrimental for muscle health and has a pathogenic role in several forms of muscle diseases. Recently, we found that defective activation of the autophagic machinery plays a key role in the pathogenesis of muscular dystrophies linked to collagen VI. Impairment of the autophagic flux in collagen VI null (Col6a1–/–) mice causes accumulation of dysfunctional mitochondria and altered sarcoplasmic reticulum, leading to apoptosis and degeneration of muscle fibers. Here we show that physical exercise activates autophagy in skeletal muscles. Notably, physical training exacerbated the dystrophic phenotype of Col6a1–/– mice, where autophagy flux is compromised. Autophagy was not induced in Col6a1–/– muscles after either acute or prolonged exercise, and this led to a marked increase of muscle wasting and apoptosis. These findings indicate that proper activation of autophagy is important for muscle homeostasis during physical activity.     

Reactivation of autophagy by spermidine ameliorates the myopathic defects of collagen VI-null mice

Autophagy is a self-degradative process responsible for the clearance of damaged or unnecessary cellular components. We have previously found that persistence of dysfunctional organelles due to autophagy failure is a key event in the pathogenesis of COL6/collagen VI-related myopathies, and have demonstrated that reactivation of a proper autophagic flux rescues the muscle defects of Col6a1-null (col6a1^−/−) mice. Here we show that treatment with spermidine, a naturally occurring nontoxic autophagy inducer, is beneficial for col6a1^−/− mice. Systemic administration of spermidine in col6a1^−/− mice reactivated autophagy in a dose-dependent manner, leading to a concurrent amelioration of the histological and ultrastructural muscle defects. The beneficial effects of spermidine, together with its being easy to administer and the lack of overt side effects, open the field for the design of novel nutraceutical strategies for the treatment of muscle diseases characterized by autophagy impairment.     

miRNAS in normal and diseased skeletal muscle

The last 20 years have witnessed major advances in the understanding of muscle diseases and significant inroads are being made to treat muscular dystrophy. However, no curative therapy is currently available for any of the muscular dystrophies, despite the immense progress made using several approaches and only palliative and symptomatic treatment is available for patients. The discovery of miRNAs as new and important regulators of gene expression is expected to broaden our biological understanding of the regulatory mechanism in muscle by adding another dimension of regulation to the diversity and complexity of gene-regulatory networks. As important regulators of muscle development, unravelling the regulatory circuits involved may be challenging, given that a single miRNA can regulate the expression of many mRNA targets. Although the identification of the regulatory targets of miRNAs in muscle is a challenge, it will be critical for placing them in genetic pathways and biological contexts. Therefore, combining informatics, biochemical and genetic approaches will not only expected to reveal the elucidation of the miRNA regulatory network in skeletal muscle and to bring a better knowledge on muscle tissue regulation but will also raise new opportunities for therapeutic intervention in muscular dystrophies by identifying candidate miRNAs as potential targets for clinical application.     

rAAV6-microdystrophin rescues aberrant Golgi complex organization in mdx skeletal muscles

Muscular dystrophies are a diverse group of severe degenerative muscle diseases. Recent interest in the role of the Golgi complex (GC) in muscle disease has been piqued by findings that several dystrophies result from mutations in putative Golgi-resident glycosyltransferases. Given this new role of the Golgi in sarcolemmal stability, we hypothesized that abnormal Golgi distribution, regulation and/or function may constitute part of the pathology of other dystrophies, where the primary defect is independent of Golgi function. Thus, we investigated GC organization in the dystrophin-deficient muscles of mdx mice, a mouse model for Duchenne muscular dystrophy. We report aberrant organization of the synaptic and extrasynaptic GC in skeletal muscles of mdx mice. The GC is mislocalized and improperly concentrated at the surface and core of mdx myofibers. Golgi complex localization is disrupted after the onset of necrosis and normal redistribution is impaired during regeneration of mdx muscle fibers. Disruption of the microtubule cytoskeleton may account in part for aberrant GC localization in mdx myofibers. Golgi complex distribution is restored to wild type and microtubule cytoskeleton organization is significantly improved by recombinant adeno-associated virus 6-mediated expression of DeltaR4-R23/DeltaCT microdystrophin showing a novel mode of microdystrophin functionality. In summary, GC distribution abnormalities are a novel component of mdx skeletal muscle pathology rescued by microdystrophin expression.     

Neural regulation of acetylcholinesterase-associated collagen Q in rat skeletal muscles

Acetylcholinesterase-associated collagen Q is expressed also outside of neuromuscular junctions in the slow soleus muscle, but not in fast muscles. We examined the nerve dependence of muscle collagen Q expression and mechanisms responsible for these differences. Denervation decreased extrajunctional collagen Q mRNA levels in the soleus muscles and junctional levels in fast sternomastoid muscles to about one third. Cross-innervation of denervated soleus muscles by a fast muscle nerve, or electrical stimulation by 'fast' impulse pattern, reduced their extrajunctional collagen Q mRNA levels by 70–80%. In contrast, stimulation of fast muscles by 'slow' impulse pattern had no effect on collagen Q expression. Calcineurin inhibitors tacrolimus and cyclosporin A decreased collagen Q mRNA levels in the soleus muscles to about 35%, but did not affect collagen Q expression in denervated soleus muscles or the junctional expression in fast muscles. Therefore, high extrajunctional expression of collagen Q in the soleus muscle is maintained by its tonic nerve-induced activation pattern via the activated Ca²⁺-calcineurin signaling pathway. The extrajunctional collagen Q expression in fast muscles is independent of muscle activation pattern and seems irreversibly suppressed. The junctional expression of collagen Q in fast muscles is partly nerve-dependent, but does not encompass the Ca²⁺-calcineurin signaling pathway.     

Autophagy activation in COL6 myopathic patients by a low-protein-diet pilot trial

A pilot clinical trial based on nutritional modulation was designed to assess the efficacy of a one-year low-protein diet in activating autophagy in skeletal muscle of patients affected by COL6/collagen VI-related myopathies. Ullrich congenital muscular dystrophy and Bethlem myopathy are rare inherited muscle disorders caused by mutations of COL6 genes and for which no cure is yet available. Studies in col6 null mice revealed that myofiber degeneration involves autophagy defects and that forced activation of autophagy results in the amelioration of muscle pathology. Seven adult patients affected by COL6 myopathies underwent a controlled low-protein diet for 12 mo and we evaluated the presence of autophagosomes and the mRNA and protein levels for BECN1/Beclin 1 and MAP1LC3B/LC3B in muscle biopsies and blood leukocytes. Safety measures were assessed, including muscle strength, motor and respiratory function, and metabolic parameters. After one y of low-protein diet, autophagic markers were increased in skeletal muscle and blood leukocytes of patients. The treatment was safe as shown by preservation of lean:fat percentage of body composition, muscle strength and function. Moreover, the decreased incidence of myofiber apoptosis indicated benefits in muscle homeostasis, and the metabolic changes pointed at improved mitochondrial function. These data provide evidence that a low-protein diet is able to activate autophagy and is safe and tolerable in patients with COL6 myopathies, pointing at autophagy activation as a potential target for therapeutic applications. In addition, our findings indicate that blood leukocytes are a promising noninvasive tool for monitoring autophagy activation in patients.     

Stem cells for skeletal muscle repair

Skeletal muscle is a highly specialized tissue composed of non-dividing, multi-nucleated muscle fibres that contract to generate force in a controlled and directed manner. Skeletal muscle is formed during embryogenesis from a subset of muscle precursor cells, which generate both differentiated muscle fibres and specialized muscle-forming stem cells known as satellite cells. Satellite cells remain associated with muscle fibres after birth and are responsible for muscle growth and repair throughout life. Failure in satellite cell function can lead to delayed, impaired or failed recovery after muscle injury, and such failures become increasingly prominent in cases of progressive muscle disease and in old age. Recent progress in the isolation of muscle satellite cells and elucidation of the cellular and molecular mediators controlling their activity indicate that these cells represent promising therapeutic targets. Such satellite cell-based therapies may involve either direct cell replacement or development of drugs that enhance endogenous muscle repair mechanisms. Here, we discuss recent breakthroughs in understanding both the cell intrinsic and extrinsic regulators that determine the formation and function of muscle satellite cells, as well as promising paths forward to realizing their full therapeutic potential.     

间歇性禁食与运动对骨骼肌自噬的激活及减脂效果的比较

目的:以运动作为对比,观察不同时长(14 d、28 d)间歇性禁食的体重控制效果,探究其对骨骼肌质量及自噬的影响。方法:选取60只SD大鼠(雄)随机分为3组(n=20):安静对照组(Sed组)、间歇性禁食组(InF组)、有氧运动组(Exe组),设实验周期分别为14 d和28 d。InF组采用间歇性禁食(隔日禁食),Exe组施加跑台运动干预,每周记录体重。DEXA检测体脂并计算体脂指数,天平称量比目鱼肌湿重(双侧)并计算湿重指数,免疫荧光检测细胞外基质蛋白laminin反映肌纤维横截面积、检测LC3标记自噬体,透射电镜观察自噬体数量及形态,Western blot检测自噬相关蛋白ULK1、LC3、p62及调控蛋白AMPKα、p-AMPKα(Thr172)的表达情况。结果:①干预7 d开始,InF、Exe组大鼠体重显著低于Sed组,且InF组体重显著低于Exe组(P<0.01),28 d干预后InF、Exe组体脂指数显著低于Sed组,且InF组体脂指数显著低于Exe组(P<0.05)。②干预28 d时Exe组单根肌纤维面积较Sed、InF组明显增大(P<0.01)。③在各...     

Enhanced autophagy as a potential mechanism for the improved physiological function by simvastatin in muscular dystrophy

Autophagy has recently emerged as an important cellular process for the maintenance of skeletal muscle health and function. Excessive autophagy can trigger muscle catabolism, leading to atrophy. In contrast, reduced autophagic flux is a characteristic of several muscle diseases, including Duchenne muscular dystrophy, the most common and severe inherited muscle disorder. Recent evidence demonstrates that enhanced reactive oxygen species (ROS) production by CYBB/NOX2 impairs autophagy in muscles from the dmd/mdx mouse, a genetic model of Duchenne muscular dystrophy. Statins decrease CYBB/NOX2 expression and activity and stimulate autophagy in skeletal muscle. Therefore, we treated dmd/mdx mice with simvastatin and showed decreased CYBB/NOX2-mediated oxidative stress and enhanced autophagy induction. This was accompanied by reduced muscle damage, inflammation and fibrosis, and increased muscle force production. Our data suggest that increased autophagy may be a potential mechanism by which simvastatin improves skeletal muscle health and function in muscular dystrophy.     

Expression of the gene for large subunit of m-calpain is elevated in skeletal muscle from Duchenne muscular dystrophy patients

Calpain is an intracellular nonlysosomal protease involved in essential regulatory or processing functions of the cell, mediated by physiological concentrations of Ca²⁺. However, in an environment of abnormal intracellular calcium, such as that seen in Duchenne muscular dystrophy (DMD), calpain is suggested to cause degeneration of muscle owing to enhanced activity. To test whether the reported increase in calpain activity in DMD results fromde novo synthesis of the protease, we have assessed the quantitative changes in mRNA specific for m-calpain. mRNA isolated from DMD and control muscle was analysed by dot blot hybridization using a cDNA probe for the large subunit of m-calpain. Compared to control a four-fold increase in specific mRNA was observed in dystrophic muscle. This enhanced expression of the m-calpain gene in dystrophic condition suggests that the reported increase in m-calpain activity results fromde novo synthesis of protease and underlines the important role of m-calpain in DMD.     

Restoration of dystrophin-associated proteins in skeletal muscle of mdx mice transgenic for dystrophin gene

Duchenne muscular dystrophy (DMD) patients and mdx mice are characterized by the absence of dystrophin, a membrane cytoskeletal protein. Dystrophin is associated with a large oligomeric complex of sarcolemmal glycoproteins, including dystroglycan which provides a linkage to the extarcellular matrix component, laminin. The finding that all of the dystrophin-associated proteins (DAPs) are drastically reduced in DMD and mdx skeletal muscle supports the primary function of dystrophin as an anchor of the sarcolemmal glycoprotein complex to the subsarcolemmal cytoskeleton. These findings indicate that the efficacy of dystrophin gene therapy will depend not only on replacing dystrophin but also on restoring all of the DAPs in the sarcolemma. Here we have investigated the status of the DAPs in the skeletal muscle of mdx mice transgenic for the dystrophin gene. Our results demonstrate that transfer of dystrophin gene restores all of the DAPs together with dystrophin, suggesting that dystrophin gene therapy should be effective in restoring the entire dystrophin-glycoprotein complex.     

Non-proteolytic functions of calpain-3 in sarcoplasmic reticulum in skeletal muscles

Mutations in CAPN3/Capn3, which codes for skeletal muscle-specific calpain-3/p94 protease, are responsible for limb-girdle muscular dystrophy type 2A. Using “knock-in” (referred to as Capn3^CS/CS) mice, in which the endogenous calpain-3 is replaced with a mutant calpain-3:C129S, which is a proteolytically inactive but structurally intact calpain-3, we demonstrated in our previous studies that loss of calpain-3 protease activity causes muscular dystrophy [Ojima, K. et al. (2010) J. Clin. Invest. 120, 2672-2683]. However, compared to Capn3-null (Capn3^−/−) mice, Capn3^CS/CS mice showed less severe dystrophic symptoms. This suggests that calpain-3 also has a non-proteolytic function. This study aimed to elucidate the non-proteolytic functions of calpain-3 through comparison of Capn3^CS/CS mice with Capn3^−/− mice. We found that calpain-3 is a component of the sarcoplasmic reticulum (SR), and that calpain-3 interacts with, but does not proteolyze, typical SR components such as ryanodine receptor and calsequestrin. Furthermore, Capn3^CS/CS mice showed that the nonenzymatic role of calpain-3 is required for proper Ca²⁺ efflux from the SR to cytosol during muscle contraction. These results indicate that calpain-3 functions as a nonenzymatic element for the Ca²⁺ efflux machinery in the SR, rather than as a protease. Thus, defects in the nonenzymatic function of calpain-3 must also be involved in the pathogenesis of limb-girdle muscular dystrophy type 2A.     

High resolution respirometry of permeabilized skeletal muscle fibers in the diagnosis of neuromuscular disorders

High resolution respirometry in combination with the skinned fiber technique offers the possibility to study mitochondrial function routinely in small amounts of human muscle. During a period of 2 years, we investigated mitochondrial function in skeletal muscle tissue of 13 patients (average age = 5.8 years). In all of them, an open muscle biopsy was performed for diagnosis of their neuromuscular disorder. Mitochondrial oxidation rates were measured with a highly sensitive respirometer. Multiple substrate-inhibitor titration was applied for investigation of mitochondrial function. About 50 mg fibers were sufficient to obtain maximal respiratory rates for seven different substrates (pyruvate/malate, glutamate/malate, octanoylcarnitine/malate, palmitoylcarnitine /malate, succinate, durochinol and ascorbate/TMPD). Decreased respiration rates with reference to the wet weight of the permeabilized fiber could immediately be detected during the course of measurements.In 4 patients with mitochondrial encephalomyopathy (MEM) the respiration pattern indicated a specific mitochondrial enzyme defect, which was confirmed in every patient by measurements of the individual enzymes (one patient with PDHC deficiency, one with complex I deficiency and two patients with combined complex I and IV deficiency). In the 6 patients with spinal muscular atrophy (SMA) oxidation rates were found to be decreased to 23 ± 5% of controls. The normalized respiration pattern was comparable to that of the controls indicating a decreased content of mitochondria in SMA muscle with normal functional properties. Also in the 3 patients with Duchenne muscular dystrophy (DMD) decreased oxidation rates (42 ± 5%) were detected. In addition a low RCI (1.2) indicated a loose coupling of oxidative phosphorylation in the mitochondria of these patients.It is concluded that investigation of mitochondrial function in saponin skinned muscle fibers using high resolution respirometry in combination with multiple substrate titration offers a valuable tool for evaluation of mitochondrial alterations in muscle biopsies of children suffering from neuromuscular disorders. (Mol Cell Biochem 174: 71–78, 1997)     

Induction and adaptation of chaperone-assisted selective autophagy CASA in response to resistance exercise in human skeletal muscle

Chaperone-assisted selective autophagy (CASA) is a tension-induced degradation pathway essential for muscle maintenance. Impairment of CASA causes childhood muscle dystrophy and cardiomyopathy. However, the importance of CASA for muscle function in healthy individuals has remained elusive so far. Here we describe the impact of strength training on CASA in a group of healthy and moderately trained men. We show that strenuous resistance exercise causes an acute induction of CASA in affected muscles to degrade mechanically damaged cytoskeleton proteins. Moreover, repeated resistance exercise during 4 wk of training led to an increased expression of CASA components. In human skeletal muscle, CASA apparently acts as a central adaptation mechanism that responds to acute physical exercise and to repeated mechanical stimulation.     

Alcohol-induced autophagy contributes to loss in skeletal muscle mass

Patients with alcoholic cirrhosis and hepatitis have severe muscle loss. Since ethanol impairs skeletal muscle protein synthesis but does not increase ubiquitin proteasome-mediated proteolysis, we investigated whether alcohol-induced autophagy contributes to muscle loss. Autophagy induction was studied in: A) Human skeletal muscle biopsies from alcoholic cirrhotics and controls, B) Gastrocnemius muscle from ethanol and pair-fed mice, and C) Ethanol-exposed murine C2C12 myotubes, by examining the expression of autophagy markers assessed by immunoblotting and real-time PCR. Expression of autophagy genes and markers were increased in skeletal muscle from humans and ethanol-fed mice, and in myotubes following ethanol exposure. Importantly, pulse-chase experiments showed suppression of myotube proteolysis upon ethanol-treatment with the autophagy inhibitor, 3-methyladenine (3MA) and not by MG132, a proteasome inhibitor. Correspondingly, ethanol-treated C2C12 myotubes stably expressing GFP-LC3B showed increased autophagy flux as measured by accumulation of GFP-LC3B vesicles with confocal microscopy. The ethanol-induced increase in LC3B lipidation was reversed upon knockdown of Atg7, a critical autophagy gene and was associated with reversal of the ethanol-induced decrease in myotube diameter. Consistently, CT image analysis of muscle area in alcoholic cirrhotics was significantly reduced compared with control subjects. In order to determine whether ethanol per se or its metabolic product, acetaldehyde, stimulates autophagy, C2C12 myotubes were treated with ethanol in the presence of the alcohol dehydrogenase inhibitor (4-methylpyrazole) or the acetaldehyde dehydrogenase inhibitor (cyanamide). LC3B lipidation increased with acetaldehyde treatment and increased further with the addition of cyanamide. We conclude that muscle autophagy is increased by ethanol exposure and contributes to sarcopenia.     

Evidence TRPV4 contributes to mechanosensitive ion channels in mouse skeletal muscle fibers

We recorded the activity of single mechanosensitive (MS) ion channels from membrane patches on single muscle fibers isolated from mice. We investigated the actions of various TRP (transient receptor potential) channel blockers on MS channel activity. 2-aminoethoxydiphenyl borate (2-APB) neither inhibited nor facilitated single channel activity at submillimolar concentrations. The absence of an effect of 2-APB indicates MS channels are not composed purely of TRPC or TRPV1, 2 or 3 proteins. Exposing patches to 1-oleolyl-2-acetyl-sn-glycerol (OAG), a potent activator of TRPC channels, also had no effect on MS channel activity. In addition, flufenamic acid and spermidine had no effect on the activity of single MS channels. By contrast, SKF-96365 and ruthenium red blocked single-channel currents at micromolar concentrations. SKF-96365 produced a rapid block of the open channel current. The blocking rate depended linearly on blocker concentration, while the unblocking rate was independent of concentration, consistent with a simple model of open channel block. A fit to the concentration-dependence of block gave k_on = 13 x 10⁶ M^?1s^?1 and k_off = 1609 sec^?1 with K_D = ~124 µM. Block by ruthenium red was complex, involving both reduction of the amplitude of the single-channel current and increased occupancy of subconductance levels. The reduction in current amplitude with increasing concentration of ruthenium red gave a K_D = ~49 µM. The high sensitivity of MS channels to block by ruthenium red suggests MS channels in skeletal muscle contain TRPV subunits. Recordings from skeletal muscle isolated from TRPV4 knockout mice failed to show MS channel activity, consistent with a contribution of TRPV4. In addition, exposure to hypo-osmotic solutions increases opening of MS channels in muscle. Our results provide evidence TRPV4 contributes to MS channels in skeletal muscle.     

Protein 4.1R expression in normal and dystrophic skeletal muscle

4.1R pre-mRNA alternative splicing results in multiple mRNA and protein isoforms that are expressed in virtually all tissues. More specifically, isoforms containing the alternative exon 17a, are exclusively expressed in muscle tissues. In this report, we show that these isoforms are preferentially present in the myoplasm of fast myofibres. 4.1R epitopes are also found at the sarcolemma of both slow and fast myofibres in normal muscle. Interestingly, they are absent from dystrophin-deficient sarcolemma of DMD muscle, and colocalize with partially expressed dystrophin in BMD muscle. We also show that alternative splicing of exons 16 and 17a is regulated during muscle differentiation in an asynchronous fashion, with an early inclusion of exon 16 in forming myotubes, and a late inclusion of exon 17a. Consistently, Western blot analysis led to characterize mainly an approximately 96/98-kDa doublet bearing exons 16-17a-encoding peptide, exclusively occurring in the differentiated muscle.     

Evidence TRPV4 contributes to mechanosensitive ion channels in mouse skeletal muscle fibers

We recorded the activity of single mechanosensitive (MS) ion channels from membrane patches on single muscle fibers isolated from mice. We investigated the actions of various TRP (transient receptor potential) channel blockers on MS channel activity. 2-aminoethoxydiphenyl borate (2-APB) neither inhibited nor facilitated single channel activity at submillimolar concentrations. The absence of an effect of 2-APB indicates MS channels are not composed purely of TRPC or TRPV1, 2 or 3 proteins. Exposing patches to 1-oleolyl-2-acetyl-sn-glycerol (OAG), a potent activator of TRPC channels, also had no effect on MS channel activity. In addition, flufenamic acid and spermidine had no effect on the activity of single MS channels. By contrast, SKF-96365 and ruthenium red blocked single-channel currents at micromolar concentrations. SKF-96365 produced a rapid block of the open channel current. The blocking rate depended linearly on blocker concentration, while the unblocking rate was independent of concentration, consistent with a simple model of open channel block. A fit to the concentration-dependence of block gave k_on = 13 x 10⁶ M⁻¹s⁻¹ and k_off = 1609 sec⁻¹ with K_D = ~124 µM. Block by ruthenium red was complex, involving both reduction of the amplitude of the single-channel current and increased occupancy of subconductance levels. The reduction in current amplitude with increasing concentration of ruthenium red gave a K_D = ~49 µM. The high sensitivity of MS channels to block by ruthenium red suggests MS channels in skeletal muscle contain TRPV subunits. Recordings from skeletal muscle isolated from TRPV4 knockout mice failed to show MS channel activity, consistent with a contribution of TRPV4. In addition, exposure to hypo-osmotic solutions increases opening of MS channels in muscle. Our results provide evidence TRPV4 contributes to MS channels in skeletal muscle.     

Maintenance of highly contractile tissue-cultured avian skeletal myotubes in collagen gel

Summary Highly contractile skeletal myotubes differentiated in tissue culture are normally difficult to maintain on collagen-coated tissue culture dishes for extended periods because of their propensity to detach as a sheet of cells from their substratum. This detachment results in the release of mechanical tension in the growing cell “sheet” and, consequently, loss of cellular protein. We developed a simple method of culturing high density contractile primary avian myotubes embedded in a collagen gel matrix (collagel) attached to either a stainless steel mesh or nylon support structure. With this system the cells are maintained in a highly contractile state for extended periods in vitro under tension. Structural integrity of the myotubes can be maintained for up to 10 d in basal medium without serum or embryo extract. Total cellular protein and myosin heavy chain accumulation in the cells can be maintained for weeks at levels which are two to three times those found in timematched controls that are under little tension. Morphologically, the myotubes are well differentiated with structural characteristics of neonatal myofibers. This new collagel culture system should prove useful in the analysis of in vitro gene expression during myotube to myofiber differentiation and its regulation by various environmental factors such as medium growth factors, innervation, and mechanical activity. This work was supported by grant AM 36266 from the National Institutes of Health, Bethesda, MD, and grant NAG2-414 from the National Aeronautics and Space Administration, Washington, D.C. Parts of this work have appeared in abstract form, In Vitro 23:24a; 1987.     

Utrophin suppresses low frequency oscillations and coupled gating of mechanosensitive ion channels in dystrophic skeletal muscle

An absence of utrophin in muscle from mdx mice prolongs the open time of single mechanosensitive channels. On a time scale much longer than the duration of individual channel activations, genetic depletion of utrophin produces low frequency oscillations of channel open probability. Oscillatory channel opening occurred in the dystrophin/utrophin mutants, but was absent in wild-type and mdx fibers. By contrast, small conductance channels showed random gating behavior when present in the same patch. Applying a negative pressure to a patch on a DKO fiber produced a burst of mode II activity, but channels subsequently closed and remained silent for tens of seconds during the maintained pressure stimulus. In addition, simultaneous opening of multiple MS channels could be frequently observed in recordings from patches on DKO fibers, but only rarely in wild-type and mdx muscle. A model which accounts for the single-channel data is proposed in which utrophin acts as gating spring which maintains the mechanical stability a caveolar-like compartment. The state of this compartment is suggested to be dynamic; its continuity with the extracellular surface varying over seconds to minutes. Loss of the mechanical stability of this compartment contributes to pathogenic Ca²⁺ entry through MS channels in Duchenne dystrophy.