Talin at myotendinous junctions.

Junctions formed by skeletal muscles where they adhere to tendons, called myotendinous junctions, are sites of tight adhesion and where forces generated by the cell are placed on the substratum. In this regard, myotendinous junctions and focal contacts of fibroblasts in vitro are analogues. Talin is a protein located at focal contacts that may be involved in force transmission from actin filaments to the plasma membrane. This study investigates whether talin is also found at myotendinous junctions. Protein separations on SDS polyacrylamide gels and immunolabeling procedures show that talin is present in skeletal muscle. Immunofluorescence microscopy using anti-talin indicates that talin is found concentrated at myotendinous junctions and in lesser amounts in periodic bands over nonjunctional regions. Electron microscopic immunolabeling shows talin is a component of the digitlike processes of muscle cells that extend into tendons at myotendinous junctions. These findings indicate that there may be similarities in the molecular composition of focal contacts and myotendinous junctions in addition to functional analogies.

PDGF stimulation induces phosphorylation of talin and cytoskeletal reorganization in skeletal muscle.

Modifications in the interactions of the muscle cytoskeleton with the cell membrane occur during cell growth and adaptation, although the mechanisms regulating these interactions are unknown. We have observed that myotendinous junctions (MTJs), which are the primary sites of turnover of the thin filament-membrane associations in skeletal muscle, are greatly enriched in receptors for PDGF. The high concentration of PDGF receptors at MTJs suggested to us that receptor binding may initiate cytoskeletal remodeling in skeletal muscle. We tested this possibility by examining the organization and phosphorylation of cytoskeletal components of L6 myocytes after PDGF stimulation. We have found that 10 min after PDGF stimulation, L6 myoblasts exhibit no stress fibers discernible by phalloidin binding, and that vinculin relocates from focal contacts into a diffuse cytoplasmic distribution. After 60 min of incubation, these changes are largely reversed. Indirect immunofluorescence shows that at 10-min PDGF stimulation, there are no changes in the distribution of talin, the beta 1 subunit of integrin, pp125FAK or desmin. Phosphotyrosine distribution changes upon stimulation from focal contacts to being located both in focal contacts and granules concentrated in perinuclear regions. These granules also immunolabel with anti-PDGF receptor Immunoprecipitations with anti-phosphotyrosine show that polypeptides at 180 and 230 kD show the greatest increase in tyrosine phosphorylation after PDGF stimulation. Immunoblots of anti-phosphotyrosine precipitates show that these polypeptides are the PDGF receptor and talin. We also examined the possibility that the cytoskeletal reorganization observed may result from calpain activation caused by elevated intracellular calcium induced by PDGF stimulation. However, immunoblots of control and stimulated cells show no decrease in the inactive calpain proenzyme or increase in the proteolytic, autolyzed forms of calpain pursuant to stimulation. Furthermore, stimulation produces no increase in the proportion of the 190-kD talin fragment characteristic of calpain-mediated cleavage. The retention of talin and integrin at focal contacts after talin phosphorylation, while vinculin is redistributed, indicate that phosphorylation of talin in PDGF-stimulated cells leads to separation of talin-vinculin associations but not talin-integrin associations. We propose that PDGF binding to PDGF receptors at MTJs may provide one means of regulating myofibril associations with the muscle cell membrane.

A nitric oxide synthase transgene ameliorates muscular dystrophy in mdx mice.

Dystrophin-deficient muscles experience large reductions in expression of nitric oxide synthase (NOS), which suggests that NO deficiency may influence the dystrophic pathology. Because NO can function as an antiinflammatory and cytoprotective molecule, we propose that the loss of NOS from dystrophic muscle exacerbates muscle inflammation and fiber damage by inflammatory cells. Analysis of transgenic mdx mice that were null mutants for dystrophin, but expressed normal levels of NO in muscle, showed that the normalization of NO production caused large reductions in macrophage concentrations in the mdx muscle. Expression of the NOS transgene in mdx muscle also prevented the majority of muscle membrane injury that is detectable in vivo, and resulted in large decreases in serum creatine kinase concentrations. Furthermore, our data show that mdx muscle macrophages are cytolytic at concentrations that occur in dystrophic, NOS-deficient muscle, but are not cytolytic at concentrations that occur in dystrophic mice that express the NOS transgene in muscle. Finally, our data show that antibody depletions of macrophages from mdx mice cause significant reductions in muscle membrane injury. Together, these findings indicate that macrophages promote injury of dystrophin-deficient muscle, and the loss of normal levels of NO production by dystrophic muscle exacerbates inflammation and membrane injury in muscular dystrophy.

Myonuclear apoptosis in dystrophic mdx muscle occurs by perforin-mediated cytotoxicity.

Myonuclear apoptosis is an early event in the pathology of dystrophin-deficient muscular dystrophy in the mdx mouse. However, events that initiate apoptosis in muscular dystrophy are unknown, and whether elimination of apoptosis can ameliorate subsequent muscle wasting remains a major question. We have tested the hypothesis that cytotoxic T-lymphocytes initiate myonuclear apoptosis in dystrophic muscle, and examined whether perforin-mediated cytotoxicity plays a role in the pathophysiology of muscular dystrophy. Mdx mice showed muscle invasion by cytotoxic T cells and helper T cells at the onset of histologically detectable muscle fiber pathology. At this time, perforin-expressing cells were also present at elevated concentration. Mdx mice depleted of CD8(+) cells showed a significant reduction of apoptotic myonuclei concentration and a reduction in necrosis, judged by macrophage invasion of muscle fibers. Double-mutant mice, deficient in dystrophin and perforin, showed nearly complete absence of myonuclear apoptosis, and a significant reduction in the concentration of macrophages in the connective tissue surrounding muscle fibers. However, muscle fiber invasion by macrophages was not reduced significantly in double mutant mice. Thus, cytotoxic T-lymphocytes contribute significantly to apoptosis and necrosis in mdx dystrophy, and perforin-mediated killing is primarily responsible for myonuclear apoptosis.

Identification of a putative collagen-binding protein from chicken skeletal muscle as glycogen phosphorylase.

We have purified and generated antisera to a 95 kDa skeletal muscle protein that constitutes the largest mass fraction of gelatin-agarose binding proteins in skeletal muscle. Preliminary results indicated that this 95 kDa chicken skeletal muscle protein bound strongly to gelatin-agarose and type IV collagen-agarose, suggesting a possible function in muscle cell adhesion to collagen. However, N-terminal sequencing of proteolytic fragments of the 95 kDa protein indicates that it is the chicken skeletal muscle form of glycogen phosphorylase, the binding of which to gelatin-agarose is unlikely to be biologically relevant. Further characterization showed that the skeletal muscle form of glycogen phosphorylase is immunologically distinct from the liver and brain forms in the chicken, and suggests that, unlike mammalian skeletal muscle, chicken skeletal muscle may have two phosphorylase isoforms. Furthermore, immunolocalization data and solubility characteristics of glycogen phosphorylase in muscle extraction experiments suggest the enzyme may interact strongly with an unidentified component of the muscle cytoskeleton. Thus, this study yields a novel purification technique for skeletal muscle glycogen phosphorylase, provides new information on the distribution and isoforms of glycogen phosphorylase, and provides a caveat for using gelatin affinity chromatography as a primary step in purifying collagen-binding proteins from skeletal muscle.

Apoptosis of macrophages during the resulution of muscle inflammation.

We tested the hypothesis that apoptosis contributes to the depletion of macrophages expressing the ED1 or ED2 antigen during the resolution of rat muscle inflammation. Muscle inflammation was induced by subjecting rat soleus muscle to 10 days of unloading followed by periods of muscle reloading. Terminal deoxynucleotidyl transferase- mediated deoxyuridine triphosphate (dUTP) labeling of apoptotic nuclei showed that apoptotic inflammatory cells increase in concentration within necrotic fibers and in the connective tissue at 2 days following muscle injury caused by increased loading. Four days following injury, the apoptotic cells within damaged fibers returned to control levels, and at 7 days following injury apoptotic cells in the connective tissue returned to control concentrations. No preferential, internucleosomal cleavage of DNA from inflamed muscle was observed, although there was greater fragmentation of DNA in inflamed muscle than in controls. Double labeling studies show that cells expressing either ED1 or ED2 antigen can undergo apoptosis in vivo. The time course of apoptosis and concentration of apoptotic cells within damaged muscle fibers indicates that apoptosis contributes to returning ED1+ cells to control concentration during the resolution of inflammation. However, apoptosis of ED2+ cells during the first week following injury is not sufficient to return ED2+ cell concentrations to control values.

Macrophage invasion does not contribute to muscle membrane injury during inflammation.

Previous observations have shown that neutrophil invasion precedes macrophage invasion during muscle inflammation and that peak muscle injury is observed at the peak of ED1+ macrophage invasion. We tested the hypothesis that neutrophil invasion causes subsequent invasion by ED1+ macrophages and that ED1+ macrophages then contribute significantly to muscle membrane injury during modified muscle use. Rat hindlimbs were unloaded for 10 days followed by reloading by normal ambulation to induce inflammation. Membrane injury was measured by assaying Evans blue-bound serum protein influx through membrane lesions. Muscle neutrophil populations increased significantly during the first 2 h of reloading but ED1+ macrophages did not increase until 24 h. Neutrophil invasion was uncoupled from subsequent macrophage invasion by reloading rat hindlimbs for 2 h to cause neutrophil invasion, followed by resuspension for hours 2-24. This produced similar increases in neutrophil concentration as measured in muscles continuously reloaded for 24 h without causing an increase in macrophages. However, resuspension did not reduce the extent of muscle damage compared with that occurring in muscles that were reloaded continuously for 24 h. Thus, muscle invasion by neutrophils is not sufficient to cause invasion by ED1+ macrophages. In addition, muscle membrane injury that occurs during reloading is independent of invasion by ED1+ macrophages.

Nitric oxide synthase inhibition reduces muscle inflammation and necrosis in modified muscle use.

The objective of this study was to determine the role of nitric oxide in muscle inflammation, fiber necrosis, and apoptosis of inflammatory cells in vivo. The effects of nitric oxide synthase (NOS) inhibition on the concentrations of neutrophils, ED1+ and ED2+ macrophages, apoptotic inflammatory cells, and necrotic muscle fibers in rats subjected to 10 days of hindlimb unloading and 2 days of reloading were determined. Administration of NOS inhibitor N(omega)-nitro-L-arginine methyl ester (L-NAME) significantly reduced the concentrations of neutrophils, ED1+ and ED2+ macrophages, and necrotic fibers in soleus muscle relative to water-treated controls. The concentration of apoptotic inflammatory cells was also significantly lower for L-NAME-treated animals compared with water-treated controls. However, the proportion of the inflammatory cell population that was apoptotic did not differ between L-NAME-treated and control animals, suggesting that L-NAME treatment did not decrease inflammatory cell populations by increasing the frequency of apoptosis. Thus, nitric oxide or one of its intermediates promotes muscle inflammation and fiber necrosis during modified muscle use and plays no more than a minor role in the resolution of muscle inflammation by inducing apoptosis of inflammatory cells.

Identification of an 80 kDa glycoprotein located at sites of close apposition between skeletal muscle cells.

An 80 kDa glycoprotein was isolated from adult frog skeletal muscle by concanavalin (Con A) affinity chromatography and electrophoretic separation by molecular mass. Characteristics of the 80 kDa glycoprotein are that it: 1) binds non-covalently to gelatin-agarose or some other protein(s) bound to gelatin-agarose, 2) does not bind wheat germ agglutinin, 3) appears only at 80 kDa in both reducing and non-reducing electrophoretic separations, 4) is present in skeletal muscle but absent in smooth muscle and cardiac muscle, 5) is not collagenase or hyaluronidase-sensitive, and 6) is antigenically similar to a protein in embryonic chicken skeletal muscle. It was used to generate a polyclonal antiserum which was affinity-purified and used for immunolocalization. Indirect immunofluorescence procedures showed the antigen to be present on the surface of the skeletal muscle cells and concentrated at sites where cells are closely apposed to one another. Preparations in which adult muscle cells were depleted of basement membrane and endomysial proteins did not reduce the amount of 80 kDa protein present in skeletal muscle. These data indicate that this is a cell surface glycoprotein that may mediate attachment of the cell to extracellular proteins at sites where adjacent skeletal muscle cells are apposed.

Calpains and muscular dystrophies.

Calpains are a ubiquitous, well-conserved family of calcium-dependent, cysteine proteases. Their function in muscle has received increased interest because of the discoveries that the activation and concentration of the ubiquitous calpains increase in the mouse model of Duchenne muscular dystrophy (DMD), but null mutations of muscle specific calpain causes limb girdle muscular dystrophy 2A (LGMD2A). These findings indicate that modulation of calpain activity contributes to muscular dystrophies by disrupting normal regulatory mechanisms influenced by calpains, rather than through a general, nonspecific increase in proteolysis. Thus, modulation of calpain activity or expression through pharmacological or molecular genetic approaches may provide therapies for some muscular dystrophies.

Dominant negative myostatin produces hypertrophy without hyperplasia in muscle.

Myostatin, a TGF-beta family member, is a negative regulator of muscle growth. Here, we generated transgenic mice that expressed myostatin mutated at its cleavage site under the control of a muscle specific promoter creating a dominant negative myostatin. These mice exhibited a significant (20-35%) increase in muscle mass that resulted from myofiber hypertrophy and not from myofiber hyperplasia. We also evaluated the role of myostatin in muscle degenerative states, such as muscular dystrophy, and found significant downregulation of myostatin. Thus, further inhibition of myostatin may permit increased muscle growth in muscle degenerative disorders.

Do immune cells promote the pathology of dystrophin-deficient myopathies?

Many features of dystrophin-deficient muscle pathology are not clearly related to the loss of mechanical support of the muscle membrane by dystrophin. In the present review, evidence that supports a role for the immune system in promoting the pathology of dystrophinopathy is presented. The findings summarized here indicate that specific, cellular immune responses by cytotoxic T-lymphocytes and helper T-lymphocytes contribute to muscle pathology in dystrophin-deficient muscle, and that removal of specific lymphoid cell populations can reduce muscle pathology. In addition, innate immune responses may also promote dystrophinopathies by the tremendous infiltration of myeloid cell populations into the dystrophic muscle. Loss of normal redox homeostasis by dystrophin-deficient muscle may increase its sensitivity to free radical-mediated damage by myeloid cells. Collectively, the observations presented here suggest that the contribution of the immune system to dystrophinopathies may be significant, and that therapeutic approaches based upon immune interventions may ameliorate the pathological progression of dystrophin deficiency.

Sparing of mdx extraocular muscles from dystrophic pathology is not attributable to normalized concentration or distribution of neuronal nitric oxide synthase.

Previous findings have led to speculations that decreased concentration of nNOS (neuronal nitric oxide synthase) may underlie some aspects of the pathophysiology of dystrophic muscle. We have tested whether the sparing of extraocular muscles (EOM) in muscular dystrophy is attributable to the presence of normal nNOS concentration and distribution in these muscles. Measurements of total nNOS concentration in control muscle showed that total nNOS comprises approximately 0.05% of total muscle protein, indicating a molar stoichiometry of approximately 60 and 20 to total dystrophin and syntrophin, respectively. Thus, most muscle nNOS is either not associated with the dystrophin complex, or binds to yet unidentified sites in the complex. nNOS concentration was at least two-fold greater in C57 EOM and tibialis anterior (TA) compared with mdx samples. No significant differences in nNOS concentration in EOM versus TA in either mdx or C57 mice were observed, nNOS was concentrated at the sarcolemma of all C57 samples, while mdx nNOS displayed a cytosolic distribution, except in fibers that reverted to express dystrophin. These data show that mdx EOM are spared by a mechanism other than normalized concentration and location of nNOS.

Reduction in myotendinous junction surface area of rats subjected to 4-day spaceflight.

The surface area of myotendinous junctions (MTJs), expressed relative to the cross-sectional area of myofibrils attached to them, was determined using established morphometric techniques in which the digitlike processes of the cell at MTJs are modeled as circular paraboloids. The relative area, called the folding factor, was measured for six rats after a 4-day spaceflight and six control rats maintained in a vivarium under otherwise identical conditions. Spaceflight resulted in a significant reduction in relative MTJ surface area, from 19.7 +/- 2.3 (SD) in control animals to 13.3 +/- 2.5 for animals after spaceflight. Furthermore, space animals displayed increased numbers of fibroblasts enriched in rough endoplasmic reticulum near the MTJ, a greater number of ribosomes and mitochondria within muscle at the MTJ, and increased occurrence of lesions in the connective tissue near the MTJ. The results indicate that spaceflight, possibly through the removal of gravity-associated loading from muscle, causes a modification in MTJ structure and may result in injuries at MTJs after return to normal loading.

Adhesive strength of single muscle cells to basement membrane at myotendinous junctions.

Whole muscles loaded to failure frequently fail at or near myotendinous junctions. The present investigation was directed toward determining the breaking stress and failure site of intact and injured myotendinous junction preparations consisting of muscle cells dissected free from surrounding parallel structures but still attached to tendon collagen fibers. These tests show that the breaking stress for intact myotendinous units is 2.7 x 10(5) N/m2, expressed relative to cell cross-sectional area. Failure occurs immediately external to the junction membrane between the cell membrane and lamina densa of the basement membrane. Site and stress at failure are independent of strain and strain rate over a biologically relevant range. Breaking stress in the plane of the membrane, corrected for membrane folding, is 1.2 X 10(4) N/m2. This value is not significantly greater than stress at maximum isometric tension for these cells at these sarcomere lengths. After compression injury, cells fail within the compression site at significantly lower stress (1.9 X 10(5) N/m2). These findings suggest that, in muscle strain injuries that occur under conditions simulated here, failure occurs at myotendinous junctions unless the muscle has suffered previous compression injury leading to failure within the muscle.

Differential response of macrophage subpopulations to soleus muscle reloading after rat hindlimb suspension.

The hypothesis that distinct populations of macrophages are associated with muscle necrosis and regeneration was examined in Wistar rat soleus muscle after 10 days of hindlimb suspension and 2, 4, and 7 days after the resumption of weight bearing. Necrosis was identified using histological features, such as muscle fiber infiltration, and regeneration was identified using immunohistochemical techniques for developmental myosin heavy chain (dMHC). Light-microscopic observations show that necrotic fibers in 2-day reloaded soleus muscle were invaded by ED1+ and Ia+ macrophages. The number of invaded fibers in muscles reloaded for 2 days increased to 2.8/mm2 compared with 0.2/mm2 in age-matched normal muscle but returned to control values by the 4th day of resumed weight bearing. In the interstitial spaces of 2-day recovery muscle, ED1+ and Ia+ macrophages numbered 369 and 332/mm2, respectively, compared with 12 and 72/mm2, respectively, in control soleus. After 7 days of reloading, the number of ED1+ cells was similar to that of control. Ia+ macrophages decreased to 240/mm2 at 4 days but after 7 days rose above control values to 429/mm2. ED2+ macrophages in 4- and 7-day reloaded soleus increased 70-80% in the interstitial spaces compared with control but were not observed to infiltrate necrotic muscle fibers at any time points. Immunohistochemistry and immunoblots using a monoclonal anti-dMHC antibody demonstrate a greater proportion of myofibers expressing dMHC isoforms after 4 and 7 days of reloading. These findings indicate that macrophage subpopulations are associated with distinct stages during the recovery process from hindlimb suspension: ED1+ macrophages are associated with muscle necrosis, whereas ED2+ cells are associated with muscle regeneration.(ABSTRACT TRUNCATED AT 250 WORDS)

Site and mechanical conditions for failure of skeletal muscle in experimental strain injuries.

Failure in muscle strain injuries has been reported to occur within the muscle belly, at the myotendinous junction, or within muscle near the myotendinous junction. The goal of this investigation was to determine by electron-microscopic examination the site of lesion in whole muscle strained to failure. In addition, site and conditions for failure of stimulated and unstimulated muscle were compared. Frog semitendinosus myotendinous units with intact tendon-bone junctions were strained at physiological strain rates to failure. All failures occurred at or near the proximal myotendinous junction in both stimulated and unstimulated muscle. Stimulated muscle required approximately 30% more force and approximately 110% more energy to reach failure. Electron-microscopic examination of longitudinal sections of small bundles of fibers showed that unstimulated muscle failed within the muscle near the myotendinous junction. Failure occurred in a single transverse plane of each cell within Z disks. Other Z disks near the failure site displayed strains of several hundred percent. Stimulated muscle failed within the lamina lucida at the myotendinous junction in most fibers. No Z-disk strain was observed in those fibers. We conclude that the site of failure in muscle strain injuries varies with the state of activation of the cell at the time of injury. Furthermore, the data show that the breaking strength of the Z disk varied with muscle stimulation and indicate the existence of two load-bearing systems in parallel within Z disks.

Absence of calpain 3 in a form of limb-girdle muscular dystrophy (LGMD2A).

Antibodies that recognise the muscle-specific calpain 3 (CANP3) were used in a 'blind' study to label blots of skeletal muscle from 12 control subjects and from 12 patients with various muscle diseases. Calpain 3 was clearly detected in all control muscle samples analysed, even though some of the muscle had been at room temperature for over an hour before being dissected and snap-frozen. Calpain 3 was also detected in the muscle biopsies from non-LGMD2A patients, but was absent in samples from 3 patients with LGMD2A. These results show that (i) calpain 3 protein can be detected in whole extracts of human muscle, and (ii) that antibodies can be used to differentiate patients with LGMD2A from those with other muscle diseases. This represents an invaluable diagnostic aid since the limb-girdle dystrophies are very difficult to separate on clinical grounds alone. One possible function that was considered for calpain 3 was the post-translational cleavage of the 97 kDa dystroglycan precursor polypeptide into the mature alpha- and beta-dystroglycan proteins. The beta-dystroglycan band was the correct size on blots of LGMD2A muscle, indicating that calpain 3 is probably not involved in the post-translational processing of dystroglycan.

Inflammatory cell response to acute muscle injury.

Nonmuscle cells play central roles in muscle repair and regeneration during the inflammation that follows muscle injury, although many aspects of the mechanisms by which inflammatory cells are attracted to injury sites and activated are unknown. Current evidence indicates that substances released from injured muscle can act as "wound hormones" that initiate inflammation. Most evidence supports the view that mononucleated cells that normally reside in muscle are activated by the injury, and then provide the chemotactic signal to circulating inflammatory cells. Three subsequent stages of inflammation can be identified, according to differences in the populations of inflammatory cells. First, neutrophils rapidly invade the injury site and promote inflammation by releasing cytokines that can attract and activate additional inflammatory cells. In at least some muscle injuries, neutrophils may further damage the injured muscle by releasing oxygen-free radicals that can damage cell membranes. Next, there is an increase in macrophages that invade damaged muscle fibers and phagocytose debris. Finally, there is an increase in a second subpopulation of macrophages that are associated with muscle regeneration. Although many of the potential mediators that underlie the proliferation, invasion, and activation of these inflammatory cell populations are known, few have been demonstrated conclusively to function in injured muscle in vivo.

Force transmission across muscle cell membranes.

Myotendinous junctions (MTJs) display both morphological and molecular specializations for force transmission from contractile, cytoskeletal proteins to extracellular, structural proteins. MTJ membrane folding may be a mechanically important feature in junction structure in that it reduces membrane stress and situates the junction for loading primarily under shear. Force is likely to be transmitted, at least in part, by a chain of proteins including vinculin, talin, integrin, fibronectin and collagen. However, the concentration at MTJs of other structural proteins and of proteins involved in cell adhesion indicate that additional, force transmitting mechanisms also exist. Myonexin and dystrophin, muscle-specific proteins found at MTJs, may also be associated with MTJ force transmission. Periodic structures at non-MTJ membrane, called costameres, have molecular compositions similar to MTJs and may therefore also be involved in force transmission across the muscle cell membrane. Muscle tears occurring during muscle use following periods of disuse occur at or near MTJs. Disuse atrophy is associated with decreased MTJ folding and, therefore, an increase in MTJ stress during loading. This decrease in membrane folding may be the basis of increased tears in atrophied muscle.