Muscle progenitor cell proliferation during passive stretch of unweighted soleus in dystrophin deficient mice

Dystrophin, subsarcolemmal protein communicating muscle fiber cytoskeleton to extracellular matrix, is believed to be involved in mechanical signal transduction. The experiment was carried out to assess the role of dystrophin in passive stretch-induced preventing unloaded muscle fiber atrophy and possible linkage between this protein and muscle progenitor (satellite cells) proliferation activity. The study was performed on two months old C57 black and mdx (dystrophin-deficient) mice. Passive stretch resulted in attenuating atrophy development in two fiber types of both C57 black and mdx mice. Altered dystrophin synthesis in mdx mice had virtually no effect on passive stretch preventive action. Thus the hypothesis about dystrophin key role in mediating stretch-induced hypertrophy effects didn't find its confirmation concerning gravitational unloading atrophy. Chronic hindlimb unloading downregulated SC proliferative activity in soleus muscle, passive stretch drastically increased proliferation both in C57 and mdx mice. Thus we observed no relationship between altered dystrophin synthesis and satellite cell proliferation activity in soleus muscle under conditions of simulated microgravity and concurrent passive stretch.     

Cellular effects of functional unloading and passive strain of soleus muscle in dystrophin-deficient mice

There is a suggestion that dystrophin, a subsarcolemmal protein communicating fiber cytoskeleton to extracellular matrix, participates in signal transduction reflecting the mechanical state of skeletal muscle (mechanotransduction). Recent works indicate the possible signaling role of this protein in the prevention of the activation of proteolytic processes accompanying development of muscle fiber atrophy and in realization of anabolic effects of muscle passive stretching. To assess the role of dystrophin in these processes, the experiment was carried out on two-month old C57 black and mdx (dystrophin-deficient) mice subjected to hind-limb suspension with stretching and without it. Passive stretching results in the partial prevention of atrophy in two muscle fiber types of both C57 black and mdx mice; at the same time, in mdx mice, the slow-to-fast transformation of the soleus muscle fiber type was not observed. Proliferative activity in soleus muscle decreased as a result of hind-limb suspension, but markedly increased during muscle passive stretching. We have found no correlation between the altered dystrophin synthesis and proliferative activity of satellite cells during hind-limb suspension and hind-limb suspension with stretching. Hence, the disturbed dystrophin synthesis retards the atrophy of slow muscle fibers and practically does not affect the stretching preventive action.     

Dystrophin Involved in the Susceptibility of Slow Muscles to Hindlimb Unloading via Concomitant Activation of TGF-β1/Smad3 Signaling and Ubiquitin–Proteasome Degradation in Mice

While it is well known that the slow-twitch muscles are vulnerable to microgravity conditions, the molecular and cellular mechanisms underlying this phenomenon remain unknown. Dystrophin, which constitutes an important link between the cytoskeleton and the extracellular matrix, is hypothesized to be involved in force generation and mechanical stabilization of the skeletal muscle. Here we have shown that after a 14-day hindlimb unloading (HU) of the C57BL/10 mice, the expression of dystrophin was significantly down-regulated in the fast-twitch myofibers, while in the slow-twitch myofibers, it was up-regulated. In order to investigate the role of dystrophin in HU-induced susceptibility to muscle atrophy, we compared the degradation signaling mechanisms of slow-twitch soleus muscle in dystrophin-deficient (mdx) and the wild-type (WT) mice. We found that mdx mice manifest less reduction of muscle mass and myofiber cross-sectional area than the control animals. Also, the expression of two ubiquitin ligases (MuRF1, Atrogin-1), which plays a crucial role in the ubiquitin–proteasome-mediated muscular degradation, was significantly down-regulated in soleus muscle of the hindlimb-unloaded mdx mice. In comparison, in the soleus muscle of unloaded WT mice, these ligases were significantly up-regulated. Whereas the hindlimb unloading reduced the expression of transforming growth factor β (TGF-β1)/Smad3 in mdx mice, in WT mice, the expression of this growth factor was augmented in response to unloading. Correspondingly, as a result of HU of the mdx mice, the expression of four subtypes of the myosin heavy chain and troponin I was reduced or it exhibited a delayed slow-to-fast transition. In summary, our results suggest that dystrophin exerts an intermediary and positive role in the disuse atrophy of the slow-twitch muscles. This effect is mediated through the activation of TGF-β1/Smad3 signaling and downstream ubiquitin–proteasome pathway.     

The contribution of muscle progenitor cells to maintaining morphological characteristics of unweighted rat soleus muscle during passive stretch

Skeletal muscle work hypertrophy is usually connected with muscle progenitor SC (satellite cells) activation with subsequent incorporation their nuclei into myofibers. Passive stretch of unloaded muscle was earlier established to prevent atrophic processes and be accompanied by enhanced protein synthesis. We hypothesized that elimination of SC proliferation capacity by gamma-irradiation would partly preavent stretched muscle fiber capability to maintain their size under condition of gravitational unloading. To assess the role of muscle progenitor (satellite) cells in development of passive stretch preventive effect SC proliferation was suppressed by local exposure to ionizing radiation (2500 Rad) and then subsequent hindlimb suspension or hindlimb suspension with concomitant passive stretch were carried out. Reduction of myofiber cross-sectional area and decrease in myo-nuclei number accompanying unloaded muscle atrophy were completely abolished by passive stretch both in irradiated and sham-treated animals. We concluded that satellite cells did not make essential contribution to passive stretch preventive action under condition of simulated weightlessness.     

Protein turnover is elevated in muscle of mdx mice in vivo.

mdx mice lack the protein dystrophin, the absence of which causes Duchenne muscular dystrophy in humans. To examine how mdx mice maintain muscle mass despite dystrophin deficiency, we measured protein turnover rates in muscles of mdx and wild-type (C57BL/10) mice in vivo. At all ages studied, rates of muscle protein synthesis and degradation were higher in mdx than in C57BL/10 mice.     

Influence of hindlimb suspension on calcium-induced contraction characteristics in dystrophin-deficient animals

The direct data concerning effects of unloading on dystrophic muscle were received in study of mdx mice, a model for Duchenne muscular dystrophy, muscles before and after hindlimb suspension. Experiments were performed on softer skinned soleus muscle fibers isolated from wild-type (C57black) as a control and mdx mice aged 2 weeks. Animals of two experimental groups were tail suspended during 21 days. In both groups of hindlimb suspended mice isolated soleus fibers were thinner than in the control groups. But there was a greater 37% significant decrease in fiber diameter in wild-type (CHS) suspended mice vs. 24% in mdx (MHS) suspended group. Values of absolute peak tension in CHS were less than in the control group by 33%, and in MHS mice suspended--by 39%. 21 days of hindlimb suspension resulted in reduction of mean peak specific tension by 28% in MHS and significantly less drop (15%) in CHS groups. We observed a similar rightward shift of the tension pCa curve in both mice strains.     

Susceptibility to sarcomere injury induced by single stretches of maximally activated muscles of mdx mice.

The purpose was to investigate the contribution of mechanical damage to sarcomeres to the greater susceptibility of dystrophic muscle fibers to contraction-induced injury. Single stretches provide an effective method for studying mechanical factors that contribute to the initiation of contraction-induced injury. We hypothesized that, after single stretches, the deficits in isometric force would be greater for muscles of mdx than C57BL/10 mice, whereas membrane damage would be minimal for all muscles. Extensor digitorum longus (EDL) and soleus muscles of mice were removed under anesthesia with Avertin (tribromoethanol). During the plateau of a maximum isometric contraction in vitro, muscles were stretched through single strains of 20-60% fiber length. Isometric force was remeasured 1 min later, and muscles were then incubated in procion orange dye to identify fibers with membrane damage. Force deficits at 1 min were two- to threefold greater for EDL muscles of mdx compared with C57BL/10 mice, whereas no significant differences were observed between soleus muscles of mdx and C57BL/10 mice. For all muscles, membrane damage was minimal and not significantly increased by single stretches for either strain of mice. These data support a critical role of dystrophin maintaining sarcomere stability in EDL muscles, whereas soleus muscles retain abilities, in the absence of dystrophin, not different from control muscles to resist sarcomere damage.     

Matrix Metalloproteinase-9 Inhibition Improves Proliferation and Engraftment of Myogenic Cells in Dystrophic Muscle of mdx Mice

Duchenne muscular dystrophy (DMD) caused by loss of cytoskeletal protein dystrophin is a devastating disorder of skeletal muscle. Primary deficiency of dystrophin leads to several secondary pathological changes including fiber degeneration and regeneration, extracellular matrix breakdown, inflammation, and fibrosis. Matrix metalloproteinases (MMPs) are a group of extracellular proteases that are involved in tissue remodeling, inflammation, and development of interstitial fibrosis in many disease states. We have recently reported that the inhibition of MMP-9 improves myopathy and augments myofiber regeneration in mdx mice (a mouse model of DMD). However, the mechanisms by which MMP-9 regulates disease progression in mdx mice remain less understood. In this report, we demonstrate that the inhibition of MMP-9 augments the proliferation of satellite cells in dystrophic muscle. MMP-9 inhibition also causes significant reduction in percentage of M1 macrophages with concomitant increase in the proportion of promyogenic M2 macrophages in mdx mice. Moreover, inhibition of MMP-9 increases the expression of Notch ligands and receptors, and Notch target genes in skeletal muscle of mdx mice. Furthermore, our results show that while MMP-9 inhibition augments the expression of components of canonical Wnt signaling, it reduces the expression of genes whose products are involved in activation of non-canonical Wnt signaling in mdx mice. Finally, the inhibition of MMP-9 was found to dramatically improve the engraftment of transplanted myoblasts in skeletal muscle of mdx mice. Collectively, our study suggests that the inhibition of MMP-9 is a promising approach to stimulate myofiber regeneration and improving engraftment of muscle progenitor cells in dystrophic muscle.     

Novel application of flow cytometry: determination of muscle fiber types and protein levels in whole murine skeletal muscles and heart

Conventional methods for measuring proteins within muscle samples such as immunohistochemistry and western blot analysis can be time consuming, labor intensive and subject to sampling errors. We have developed flow cytometry techniques to detect proteins in whole murine heart and skeletal muscle. Flow cytometry and immunohistochemistry were performed on quadriceps and soleus muscles from male C57BL/6J, BALB/c, CBA and mdx mice. Proteins including actins, myosins, tropomyosin and alpha-actinin were detected via single staining flow cytometric analysis. This correlated with immunohistochemistry using the same antibodies. Muscle fiber types could be determined by dual labeled flow cytometry for skeletal muscle actin and different myosins. This showed similar results to immunohistochemistry for I, IIA and IIB myosins. Flow cytometry of heart samples from C57BL/6J and BALB/c mice dual labeled with cardiac and skeletal muscle actin antibodies demonstrated the known increase in skeletal actin protein in BALB/c hearts. The membrane-associated proteins alpha-sarcoglycan and dystrophin could be detected in C57BL/6J mice, but were decreased or absent in mdx mice. With the ability to label whole muscle samples simultaneously with multiple antibodies, flow cytometry may have advantages over conventional methods for certain applications, including assessing the efficacy of potential therapies for muscle diseases.     

Passive stretch inhibits central corelike lesion formation in the soleus muscles of hindlimb-suspended unloaded rats.

Hindlimb suspension unloading (HSU) is a ground-based model simulating the effects of microgravity unloading on the musculoskeletal system. In this model, gravity causes the hind foot of the rat to drop, opening the front of the ankle to 90-105 degrees plantar flexion at rest. As HSU proceeds, the normal weight-bearing angle of 30 degrees dorsiflexion is achieved progressively less, and the contraction range of soleus is abbreviated. Our laboratory reported that 12 days of HSU caused central corelike lesions (CCLs) of myofibril breakdown (Riley DA, Slocum GR, Bain JL, Sedlak FR, Sowa TE, and Mellender JW. J Appl Physiol. 69: 58-66, 1990). The present study investigated whether daily stretch of the calf muscles prevents CCL formation. The soleus muscles of HSU Sprague-Dawley male rats (approximately 287 g) were lengthened by unilateral ankle splinting at 30 degrees. Compared with the nonsplinted side, splinting for 10 or 20 min per day in awake rats significantly decreased CCLs in soleus by 88 and 91%, respectively (P < 0.01). Compared with control muscle wet weight, 20-min splinting reduced atrophy by 33%, whereas 10-min splinting ameliorated atrophy by 17% (P < 0.01). Bilateral soleus electromyograph recording revealed higher levels of contractile activity on the splinted side during splinting. To isolate the effects of stretch from isometric contractile activity, contractions were eliminated by whole animal anesthesia with isoflurane during 10-min daily splinting. The percentage of fibers with CCLs was reduced by 57%, and the average lesion size was 29% smaller in the stretched muscle (P < 0.05). Soleus muscle wet weight and fiber area were unaltered by stretch alone. Loaded contractions during splinting are necessary to prevent muscle fiber atrophy. Passive muscle stretch acts to maintain myofibril structural integrity.     

去负荷小鼠比目鱼肌收缩特性和纤维类型转化

目的:探讨去负荷后小鼠比目鱼肌的收缩特性与骨骼肌纤维类型转化之间的关系。方法:采用离体肌肉灌流技术和电刺激方法,在小鼠后肢去负荷28 d引起骨骼肌萎缩后,观察比目鱼肌单收缩、强直收缩能力和肌疲劳指标等收缩特性的改变,同时利用组织免疫荧光染色和实时定量聚合酶链式反应(real-time PCR)等技术检测去负荷后比目鱼肌快慢肌纤维组成和纤维类型转化的变化。结果:去负荷28 d后,小鼠比目鱼肌单收缩力、强直收缩能力和疲劳指数(fatigue index)均有显著性下降,同时伴有快肌纤维亚型的增加和慢肌纤维亚型的减少。结论:去负荷28 d后小鼠比目鱼肌收缩特性的改变和快慢肌纤维类型的转化有关。     

Passive stretch reduces calpain activity through nitric oxide pathway in unloaded soleus muscles

Unloading in spaceflight or long-term bed rest induces to pronounced atrophy of anti-gravity skeletal muscles. Passive stretch partially resists unloading-induced atrophy of skeletal muscle, but the mechanism remains elusive. The aims of this study were to investigate the hypotheses that stretch tension might increase protein level of neuronal nitric oxide synthase (nNOS) in unloaded skeletal muscle, and then nNOS-derived NO alleviated atrophy of skeletal muscle by inhibiting calpain activity. The tail-suspended rats were used to unload rat hindlimbs for 2 weeks, at the same time, left soleus muscle was stretched by applying a plaster cast to fix the ankle at 35° dorsiflexion. Stretch partially resisted atrophy and inhibited the decreased protein level and activity of nNOS in unloaded soleus muscles. Unloading increased frequency of calcium sparks and elevated intracellular resting and caffeine-induced Ca(2+) concentration ([Ca(2+)]i) in unloaded soleus muscle fibers. Stretch reduced frequency of calcium sparks and restored intracellular resting and caffeine-induced Ca(2+) concentration to control levels in unloaded soleus muscle fibers. The increased protein level and activity of calpain as well as the higher degradation of desmin induced by unloading were inhibited by stretch in soleus muscles. In conclusion, these results suggest that stretch can preserve the stability of sarcoplasmic reticulum Ca(2+) release channels which prevents the elevated [Ca(2+)]i by means of keeping nNOS activity, and then the enhanced protein level and activity of calpain return to control levels in unloaded soleus muscles. Therefore, stretch can resist in part atrophy of unloaded soleus muscles.     

Structure of neuromuscular junctions and differentiation of striated muscle fibers in mdx mice after bone-marrow stem cell therapy

Mdx mice are an experimental model of Duchenne muscular dystrophy caused by mutations in the dystrophin gene. Repeated cycles of muscle degeneration-regeneration are common for mdx mice. Disrupted neuromuscular junctions also characterize mdx mice. The structure of mdx mice neuromuscular junctions and the differentiation of striated muscle fibers were investigated 4, 8, 16, and 24 weeks after transplantation of C57BL/6 Lin(−) bone-marrow stem cells. We found that the death of striated muscle fibers decreased 4 weeks after the transplantation of bone-marrow stem cells. Accumulation of muscle fibers without centrally located nuclei began in 8 weeks and dystrophin synthesis increased in 16–24 weeks after the bone-marrow stem cells transplantation. On the longitudinal sections of quadriceps muscle of mdx mice 4 weeks after transplantation, we observed a reduced quantity of acetylcholine receptor clusters and an increase in their area in neuromuscular junctions. Sixteen weeks after the transplantation, the total area of neuromuscular junctions increased due to an enlarged number of acethylcholine receptors and their extended area. The single intramuscular transplantation of C57BL/6 Lin(−) bone-marrow stem cells induces the differentiation of mdx mice striated muscle fibers and improves the structure of neuromuscular junctions.     

Electrostimulation during hindlimb unloading modulates PI3K-AKT downstream targets without preventing soleus atrophy and restores slow phenotype through ERK

Our aim was to analyze the role of phosphatidylinositol 3-kinase (PI3K)-AKT and MAPK signaling pathways in the regulation of muscle mass and slow-to-fast phenotype transition during hindlimb unloading (HU). For that purpose, we studied, in rat slow soleus and fast extensor digitorum longus muscles, the time course of anabolic PI3K-AKT-mammalian target of rapamycin, catabolic PI3K-AKT-forkhead box O (FOXO), and MAPK signaling pathway activation after 7, 14, and 28 days of HU. Moreover, we performed chronic low-frequency soleus electrostimulation during HU to maintain exclusively contractile phenotype and so to determine more precisely the role of these signaling pathways in the modulation of muscle mass. HU induced a downregulation of the anabolic AKT, mammalian target of rapamycin, 70-kDa ribosomal protein S6 kinase, 4E-binding protein 1, and glycogen synthase kinase-3β targets, and an upregulation of the catabolic FOXO1 and muscle-specific RING finger protein-1 targets correlated with soleus muscle atrophy. Unexpectedly, soleus electrostimulation maintained 70-kDa ribosomal protein S6 kinase, 4E-binding protein 1, FOXO1, and muscle-specific RING finger protein-1 to control levels, but failed to reduce muscle atrophy. HU decreased ERK phosphorylation, while electrostimulation enabled the maintenance of ERK phosphorylation similar to control level. Moreover, slow-to-fast myosin heavy chain phenotype transition and upregulated glycolytic metabolism were prevented by soleus electrostimulation during HU. Taken together, our data demonstrated that the processes responsible for gradual disuse muscle plasticity in HU conditions involved both PI3-AKT and MAPK pathways. Moreover, electrostimulation during HU restored PI3K-AKT activation without counteracting soleus atrophy, suggesting the involvement of other signaling pathways. Finally, electrostimulation maintained initial contractile and metabolism properties in parallel to ERK activation, reinforcing the idea of a predominant role of ERK in the regulation of muscle slow phenotype.     

Dystrophin-associated proteins are greatly reduced in skeletal muscle from mdx mice

Dystrophin, the protein product of the human Duchenne muscular dystrophy gene, exists in skeletal muscle as a large oligomeric complex that contains four glycoproteins of 156, 50, 43, and 35 kD and a protein of 59 kD. Here, we investigated the relative abundance of each of the components of the dystrophin-glycoprotein complex in skeletal muscle from normal and mdx mice, which are missing dystrophin. Immunoblot analysis using total muscle membranes from control and mdx mice of ages 1 d to 30 wk found that all of the dystrophin-associated proteins were greatly reduced (80-90%) in mdx mouse skeletal muscle. The specificity of the loss of the dystrophin-associated glycoproteins was demonstrated by the finding that the major glycoprotein composition of skeletal muscle membranes from normal and mdx mice was identical. Furthermore, skeletal muscle membranes from the dystrophic dy/dy mouse exhibited a normal density of dystrophin and dystrophin-associated proteins. Immunofluorescence microscopy confirmed the results from the immunoblot analysis and showed a drastically reduced density of dystrophin-associated proteins in mdx muscle cryosections compared with normal and dy/dy mouse muscle. Therefore, our results demonstrate that all of the dystrophin-associated proteins are significantly reduced in mdx skeletal muscle and suggest that the loss of dystrophin-associated proteins is due to the absence of dystrophin and not due to secondary effects of muscle fiber degradation.     

Ex vivo stretch reveals altered mechanical properties of isolated dystrophin-deficient hearts

Duchenne muscular dystrophy (DMD) is a progressive and fatal disease of muscle wasting caused by loss of the cytoskeletal protein dystrophin. In the heart, DMD results in progressive cardiomyopathy and dilation of the left ventricle through mechanisms that are not fully understood. Previous reports have shown that loss of dystrophin causes sarcolemmal instability and reduced mechanical compliance of isolated cardiac myocytes. To expand upon these findings, here we have subjected the left ventricles of dystrophin-deficient mdx hearts to mechanical stretch. Unexpectedly, isolated mdx hearts showed increased left ventricular (LV) compliance compared to controls during stretch as LV volume was increased above normal end diastolic volume. During LV chamber distention, sarcomere lengths increased similarly in mdx and WT hearts despite greater excursions in volume of mdx hearts. This suggests that the mechanical properties of the intact heart cannot be modeled as a simple extrapolation of findings in single cardiac myocytes. To explain these findings, a model is proposed in which disruption of the dystrophin-glycoprotein complex perturbs cell-extracellular matrix contacts and promotes the apparent slippage of myocytes past each other during LV distension. In comparison, similar increases in LV compliance were obtained in isolated hearts from β-sarcoglycan-null and laminin-α(2) mutant mice, but not in dysferlin-null mice, suggesting that increased whole-organ compliance in mdx mice is a specific effect of disrupted cell-extracellular matrix contacts and not a general consequence of cardiomyopathy via membrane defect processes. Collectively, these findings suggest a novel and cell-death independent mechanism for the progressive pathological LV dilation that occurs in DMD.     

Taurine deficiency,synthesis and transport in the mdx mouse model for Duchenne Muscular Dystrophy

The amino acid taurine is essential for the function of skeletal muscle and administration is proposed as a treatment for Duchenne Muscular Dystrophy (DMD). Taurine homeostasis is dependent on multiple processes including absorption of taurine from food, endogenous synthesis from cysteine and reabsorption in the kidney. This study investigates the cause of reported taurine deficiency in the dystrophic mdx mouse model of DMD. Levels of metabolites (taurine, cysteine, cysteine sulfinate and hypotaurine) and proteins (taurine transporter [TauT], cysteine deoxygenase and cysteine sulfinate dehydrogenase) were quantified in juvenile control C57 and dystrophic mdx mice aged 18 days, 4 and 6 weeks. In C57 mice, taurine content was much higher in both liver and plasma at 18 days, and both cysteine and cysteine deoxygenase were increased. As taurine levels decreased in maturing C57 mice, there was increased transport (reabsorption) of taurine in the kidney and muscle. In mdx mice, taurine and cysteine levels were much lower in liver and plasma at 18 days, and in muscle cysteine was low at 18 days, whereas taurine was lower at 4: these changes were associated with perturbations in taurine transport in liver, kidney and muscle and altered metabolism in liver and kidney. These data suggest that the maintenance of adequate body taurine relies on sufficient dietary intake of taurine and cysteine availability and metabolism, as well as retention of taurine by the kidney. This research indicates dystrophin deficiency not only perturbs taurine metabolism in the muscle but also affects taurine metabolism in the liver and kidney, and supports targeting cysteine and taurine deficiency as a potential therapy for DMD.     

Altered allosteric properties of cytoskeleton-bound phosphofructokinase in muscle from mice with X chromosome-linked muscular dystrophy (mdx).

Intracellular distribution of cytoskeleton-bound and soluble phosphofructokinase (PFK) (the rate-limiting enzyme in glycolysis) in mdx dystrophic muscle was the same as in control nondystrophic muscle. However, the allosteric activity of both bound and soluble PFK was reduced in mdx muscle, accompanied by a decrease in ATP level. In contrast to normal muscle, the cytoskeleton-bound PFK in mdx muscle was sensitive to allosteric regulation, like the soluble enzyme. This change in the properties of cytoskeletal PFK in mdx mice may result from the absence of dystrophin, believed to reside in the cytoskeleton. The findings that cytoskeletal PFK in mdx muscle, although altered, remains bound to cytoskeleton may play a role in muscle structure and function and the mild clinical symptoms in mdx mice.