The 16 kDa subunit of vacuolar H+-ATPase is a novel sarcoglycan-interacting protein

The sarcoglycan complex in muscle consists of α-, β-, γ- and δ-sarcoglycan and is part of the larger dystrophin–glycoprotein complex (DGC), which is essential for maintaining muscle membrane integrity. Mutations in any of the four sarcoglycans cause limb-girdle muscular dystrophies (LGMD). In this report, we have identified a novel interaction between δ-sarcoglycan and the 16 kDa subunit c (16K) of vacuolar H⁺-ATPase. Co-expression studies in heterologous cell system revealed that 16K interacts specifically with δ-sarcoglycan and the highly related γ-sarcoglycan through the transmembrane domains. In cultured C2C12 myotubes, 16K forms a complex with sarcoglycans at the plasma membrane. Loss of sarcoglycans in the sarcoglycan-deficient BIO14.6 hamster destabilizes the DGC and alters the localization of 16K at the sarcolemma. In addition, the steady state level of β₁-integrin is increased. Recent studies have shown that 16K also interacts directly with β₁-integrin and our data demonstrated that sarcoglycans, 16K and β₁-integrin were immunoprecipitated together in C2C12 myotubes. Since sarcoglycans have been proposed to participate in bi-directional signaling with integrins, our findings suggest that 16K might mediate the communication between sarcoglycans and integrins and play an important role in the pathogenesis of muscular dystrophy.     

Identification of functional domains in sarcoglycans essential for their interaction and plasma membrane targeting

Mutations in sarcoglycans have been reported to cause autosomal-recessive limb-girdle muscular dystrophies. In skeletal and cardiac muscle, sarcoglycans are assembled into a complex on the sarcolemma from four subunits (alpha, beta, gamma, delta). In this report, we present a detailed structural analysis of sarcoglycans using deletion study, limited proteolysis and co-immunoprecipitation. Our results indicate that the extracellular regions of sarcoglycans consist of distinctive functional domains connected by proteinase K-sensitive sites. The N-terminal half domains are required for sarcoglycan interaction. The C-terminal half domains of beta-, gamma- and delta-sarcoglycan consist of a cysteine-rich motif and a previously unrecognized conserved sequence, both of which are essential for plasma membrane localization. Using a heterologous expression system, we demonstrate that missense sarcoglycan mutations affect sarcoglycan complex assembly and/or localization to the cell surface. Our data suggest that the formation of a stable complex is necessary but not sufficient for plasma membrane targeting. Finally, we provide evidence that the beta/delta-sarcoglycan core can associate with the C-terminus of dystrophin. Our results therefore generate important information on the structure of the sarcoglycan complex and the molecular mechanisms underlying the effects of various sarcoglycan mutations in muscular dystrophies.     

Delta-sarcoglycan is required for early zebrafish muscle organization

Mutations in sarcoglycans (alpha-, beta-, gamma-, and delta-) have been linked with limb girdle muscular dystrophy (LGMD) types 2C-F in humans. We have cloned the zebrafish orthologue encoding delta-sarcoglycan and mapped the gene to linkage group 21. The predicted zebrafish delta-sarcoglycan protein is highly homologous with its human orthologue including conservation of two of the three predicted glycosylation sites. Like other members of the dystrophin-associated protein complex (DAPC), delta-sarcoglycan localizes to the sarcolemmal membrane of the myofiber in adult zebrafish, but is more apparent at the myosepta in developing embryos. Zebrafish embryos injected with morpholinos against delta-sarcoglycan were relatively inactive at 5 dpf, their myofibers were disorganized, and swim bladders uninflated. Immunohistochemical and immunoblotting experiments show that delta-, beta-, and gamma-sarcoglycans were all downregulated in the morphants, whereas dystrophin expression was unaffected. Whereas humans lacking delta-sarcoglycan primarily show adult phenotypes, our results suggest that delta-sarcoglycan plays a role in early zebrafish muscle development.     

Sarcospan-deficient mice maintain normal muscle function

Sarcospan is an integral membrane component of the dystrophin-glycoprotein complex (DGC) found at the sarcolemma of striated and smooth muscle. The DGC plays important roles in muscle function and viability as evidenced by defects in components of the DGC, which cause muscular dystrophy. Sarcospan is unique among the components of the complex in that it contains four transmembrane domains with intracellular N- and C-terminal domains and is a member of the tetraspan superfamily of proteins. Sarcospan is tightly linked to the sarcoglycans, and together these proteins form a subcomplex within the DGC. Stable expression of sarcospan at the sarcolemma is dependent upon expression of the sarcoglycans. Here we describe the generation and analysis of mice carrying a null mutation in the Sspn gene. Surprisingly, the Sspn-deficient muscle maintains expression of other components of the DGC at the sarcolemma, and no gross histological abnormalities of muscle from the mice are observed. The Sspn-deficient muscle maintains sarcolemmal integrity as determined by serum creatine kinase and Evans blue uptake assays, and the Sspn-deficient muscle maintains normal force and power generation capabilities. These data suggest either that sarcospan is not required for normal DGC function or that the Sspn-deficient muscle is compensating for the absence of sarcospan, perhaps by utilizing another protein to carry out its function.     

Isolation and characterization of myogenic satellite cells from the muscular dystrophic hamster

Myogenic satellite cells were isolated from control and dystrophic hamster diaphragms to examine cellular mechanisms involved in the physiology of muscular dystrophy. The Bio 14.6 dystrophic hamster, which possesses a defect in the delta-sarcoglycan gene, develops biochemical and physical symptoms of Duchenne-like and limb girdle muscular dystrophies. Because primary cultures of the control and dystrophic satellite cells became extensively contaminated with non-myogenic cells during proliferation, cell clones were developed to provide pure cultures for study. Cell culture conditions were optimized with the use of Ham's F-12K medium containing 10% fetal bovine serum +5% horse serum + 10 ng/mL basic fibroblast growth factor + 50 microg/mL porcine gelatin. Proliferation rates of the two clonal cultures were similar between the two lines. Satellite cell-derived myotubes from both primary cultures and clones differed between control and dystrophic animals. Dystrophic myotubes tended to be long and narrow, while the control-derived myotubes were broader. Measurement of muscle-specific creatine kinase during differentiation revealed that the dystrophic myotubes possessed higher creatine kinase levels than control myotubes (up to 146-fold at 168 h). The results demonstrate that satellite cells can be isolated from the hamster and may provide a useful tool to study muscular dystrophies associated with defects in the sarcoglycan complex and the involvement of sarcoglycans in normal skeletal muscle growth and development.     

Filamin 2 (FLN2): A muscle-specific sarcoglycan interacting protein

Mutations in genes encoding for the sarcoglycans, a subset of proteins within the dystrophin-glycoprotein complex, produce a limb-girdle muscular dystrophy phenotype; however, the precise role of this group of proteins in the skeletal muscle is not known. To understand the role of the sarcoglycan complex, we looked for sarcoglycan interacting proteins with the hope of finding novel members of the dystrophin-glycoprotein complex. Using the yeast two-hybrid method, we have identified a skeletal muscle-specific form of filamin, which we term filamin 2 (FLN2), as a gamma- and delta-sarcoglycan interacting protein. In addition, we demonstrate that FLN2 protein localization in limb-girdle muscular dystrophy and Duchenne muscular dystrophy patients and mice is altered when compared with unaffected individuals. Previous studies of filamin family members have determined that these proteins are involved in actin reorganization and signal transduction cascades associated with cell migration, adhesion, differentiation, force transduction, and survival. Specifically, filamin proteins have been found essential in maintaining membrane integrity during force application. The finding that FLN2 interacts with the sarcoglycans introduces new implications for the pathogenesis of muscular dystrophy.     

Aquaporin-4 expression is severely reduced in human sarcoglycanopathies and dysferlinopathies

Aquaporin-4 (AQP4) is the major water channel expressed in fast-twitch skeletal muscle fibers. AQP4 is reduced in Duchenne and Becker Muscular Dystrophies, but not in caveolinopathies, thus suggesting an interaction with dystrophin or with members of the dystrophin-glycoprotein complex (DGC) rather than a nonspecific effect due to muscle membrane damage. To establish the role of sarcoglycans in AQP4 decrease occurring in muscular dystrophy, AQP4 expression was analyzed in muscle biopsies from patients affected by Limb Girdle Muscular Dystrophies (LGMDs) 2C-F genetically confirmed. In all the LGMD 2C-F (2α-, 1β-, 2γ-, 1δ-deficiency), AQP4 was severely decreased. This effect was associated to a marked reduction in α1-syntrophin levels. In control muscle AQP4 did not show a direct interaction with any of the four sarcoglycans but, it co-immunoprecipitated with α1-syntrophin, indicating that this modular protein may link AQP4 levels with the DGC complex. To determine whether AQP4 expression could be affected in other LGMDs due to the defect of a membrane protein not associated to the dystrophin complex, we examined AQP4 expression in 6 patients affected by dysferlin deficiency genetically confirmed. All the patients displayed a reduction of the water channel, and AQP4 expression appeared to correlate with the severity of the muscle histopathological lesions. However, differently from what observed in the sarcoglycans, α1-syntrophin expression was normal or just slightly reduced. These results seem to indicate an additional mechanism of regulation of AQP4 levels in muscle cells.In accordance with a specific effect of membrane muscle disorders, AQP4 protein levels were not changed in 3 mitochondrial and 3 metabolic myopathies. In conclusion, AQP4 expression and membrane localization are markedly reduced in LGMD 2B-2F. The role of AQP4 in the degenerative mechanism occurring in these diseases will be the object of our future research.     

Delta-sarcoglycan is necessary for early heart and muscle development in zebrafish

Delta-sarcoglycan, one member of the sarcoglycan complex, is a very conservative muscle-specific protein exclusively expressed in the skeletal and cardiac muscles of vertebrates. Mutations in sarcoglycans are known to be involved in limb-girdle muscular dystrophy (LGMD) and dilated cardiomyopathy (DCM) in humans. To address the role of delta-sarcoglycan gene in zebrafish development, we have studied expression pattern of delta-sarcoglycan in zebrafish embryos and examined the role of delta-sarcoglycan in zebrafish embryonic development by morpholino. Strong expression of delta-sarcoglycan was observed in various muscles including those of the segment, heart, eye, jaw, pectoral fin, branchial arches, and swim bladder in zebrafish embryo. Delta-sarcoglycan was also expressed in midbrain and retina. Knockdown of delta-sarcoglycan resulted in severe abnormality in both the cardiac and skeletal muscles. Some severe ones displayed serious morphological abnormality such as hypoplastic head, linear heart, very weak heartbeats, and runtish trunk, all dead within 5 dpf. Whole-mount in situ hybridization analysis showed that adaxial cells and muscle pioneers were affected in delta-sarcoglycan knockdown embryos. In addition, absence of delta-sarcoglycan protein severely delayed the cardiac development and influenced the differentiation of cardiac muscle, and the cardiac left-right asymmetry was dramatically changed in morpholino-treated embryos. These data together suggest that delta-sarcoglycan plays an important role in early heart and muscle development.     

delta- and gamma-Sarcoglycan localization in the sarcoplasmic reticulum of skeletal muscle.

Sarcoglycans are transmembrane proteins that are members of the dystrophin complex. Sarcoglycans cluster together to form a complex, which is localized in the cell membrane of skeletal, cardiac, and smooth muscle fibers. However, it is still unclear whether or not sarcoglycans are restricted to the sarcolemma. To address this issue, we examined alpha-, beta-, delta-, and gamma-sarcoglycan expression in femoral skeletal muscle from control and dystrophin-deficient mice and rats using confocal microscopy and immunoelectron microscopy. Confocal microscopy of the tissues in cross-section showed that all sarcoglycans were detected under the sarcolemma in rats and control mice. delta- and gamma-sarcoglycan labeling demonstrated striations in the longitudinal section, suggesting that the proteins were expressed in the sarcoplasmic reticulum (SR) or transverse tubules (T-tubules). Moreover, such striations of both sarcoglycans were recognized in the dystrophin-deficient mouse skeletal muscle. Double labeling with phalloidin or alpha-actinin and delta- or gamma-sarcoglycan showed different labeling patterns, indicating that delta-sarcoglycan localization was distinct from that of gamma-sarcoglycan. Immunoelectron microscopy clarified that delta-sarcoglycan was localized in the terminal cisternae of the SR, while gamma-sarcoglycan was found in the terminal cisternae and longitudinal SR over I-bands but not over A-bands. These data demonstrate that delta- and gamma-sarcoglycans are components of the SR in skeletal muscle, suggesting that both sarcoglycans function independent of the dystrophin complex in the SR.     

Molecular Organization of Sarcoglycan Complex in Mouse Myotubes in Culture

The sarcoglycans are a complex of four transmembrane proteins (α, β, γ, and δ) which are primarily expressed in skeletal muscle and are closely associated with dystrophin and the dystroglycans in the muscle membrane. Mutations in the sarcoglycans are responsible for four autosomal recessive forms of muscular dystrophy. The function and the organization of the sarcoglycan complex are unknown. We have used coimmunoprecipitation and in vivo cross-linking techniques to analyze the sarcoglycan complex in cultured mouse myotubes. We demonstrate that the interaction between β- and δ-sarcoglycan is resistant to high concentrations of SDS and α-sarcoglycan is less tightly associated with other members of the complex. Cross-linking experiments show that β-, γ-, and δ-sarcoglycan are in close proximity to one another and that δ-sarcoglycan can be cross-linked to the dystroglycan complex. In addition, three of the sarcoglycans (β, γ, and δ) are shown to form intramolecular disulfide bonds. These studies further our knowledge of the structure of the sarcoglycan complex. Our proposed model of their interactions helps to explain some of the emerging data on the consequences of mutations in the individual sarcoglycans, their effect on the complex, and potentially the clinical course of muscular dystrophies.     

Syntrophin is an actin-binding protein the cellular localization of which is regulated through cytoskeletal reorganization in skeletal muscle cells

We have characterized the interaction of syntrophin with F-actin. Subcellular fractionation of cardiac and skeletal muscle tissues showed that alpha-, beta1- and beta2-syntrophins were present in the soluble and the membrane fraction. Syntrophins are known to bind to the dystrophin-glycoprotein complex (DGC), but since the DGC is not present in the soluble fraction, it was concluded that some syntrophin did not associate with the DGC. Native syntrophins purified from the soluble fraction and recombinant syntrophins were both able to bind to F-actin, and binding occurred through several sites on syntrophin, including the second pleckstrin homology domain and the unique carboxyl-terminal domain. Syntrophin was also able to inhibit actin-activated myosin ATPase activity and actomyosin super-precipitation. alpha-Syntrophin co-localized with cortical F-actin fibers when expressed in Chinese hamster ovary cells, and deletion of the actin-binding region abolished co-localization. Most of exogenous or endogenous syntrophin also co-localized with stress fibers in endothelial and smooth muscle (A7r5) cells. However, syntrophins were mostly localized in the cytosol of serum-starved C2C12 or primary cultured skeletal muscle myotubes, and translocated to the membrane upon treatment with lysophosphatidic acid or the actin-stabilizing agent jasplakinolide. The actin-depolymerizing agent latrunculin-B abolished this syntrophin translocation. These findings suggest that syntrophin is an actin-binding protein the subcellular localization of which is regulated through cytoskeletal reorganization.     

Sarcoglycan subcomplex in normal and pathological human muscle fibers

Sarcoglycans are a sub-complex of transmembrane proteins which are part of the dystrophin-glycoprotein complex (DGC). They are expressed above all in the skeletal, cardiac and smooth muscle. Although numerous studies have been conducted on the sarcoglycan sub-complex in skeletal and cardiac muscle, the manner of distribution and localization of these proteins along the non-junctional sarcolemma is still not clear. Furthermore, there are unclear data about the actual role of sarcoglycans in human skeletal muscle affected by sarcoglycanopathies. In our studies on human skeletal muscle, normal and pathological, we determined the localization, distribution and interaction of these glycoproteins. Our results, on normal human skeletal muscle, showed that the sarcoglycans can be localized both in the region of the sarcolemma over the I band and over the A band, hypothesizing a correlation between regions of the sarcolemma occupied by costameres and the metabolic type of the fibers (slow and fast). Our data on skeletal muscle affected by sarcoglycanopathy confirmed the hypothesis of a bidirectional signaling between sarcoglycans and integrins and the interaction of filamin2 with both sarcoglycans and integrins. In addition, we have recently demonstrated, in smooth muscle, the presence of alpha-SG, in contrast with data of other Authors. Finally, we analyzed the association between contractile activity and quantitative correlation between alpha- and epsilon-SG, in order to better define the arrangement of sarcoglycan subcomplex.     

Integrins, muscle agrin and sarcoglycans during muscular inactivity conditions: an immunohistochemical study

Sarcoglycans are transmembrane proteins that seem to be functionally and pathologically as important as dystrophin. Sarcoglycans cluster together to form a complex, which is localized in the cell membrane of skeletal, cardiac, and smooth muscle. It has been proposed that the dystrophin-glycoprotein complex (DGC) links the actin cytoskeleton with the extracellular matrix and the proper maintenance of this connection is thought to be crucial to the mechanical stability of the sarcolemma. The integrins are a family of heterodimeric cell surface receptors which play a crucial role in cell adhesion including cell-matrix and intracellular interactions and therefore are involved in various biological phenomena, including cell migration, and differentiation tissue repair. Sarcoglycans and integrins play a mechanical and signaling role stabilizing the systems during cycles of contraction and relaxation. Several studies suggested the possibility that integrins might play a role in muscle agrin signalling. On these basis, we performed an immunohistochemical analyzing sarcoglycans, integrins and agrin, on human skeletal muscle affected by sensitive-motor polyneuropathy, in order to better define the correlation between these proteins and neurogenic atrophy due to peripheral neuropathy. Our results showed the existence of a cascade mechanism which provoke a loss of regulatory effects of muscle activity on costameres, due to loss of muscle and neural agrin. This cascade mechanism could determine a quantitative modification of transmembrane receptors and loss of alpha7B could be replaced and reinforced by enhanced expression of the alpha7A integrin to restore muscle fiber viability. Second, it is possible that the reduced cycles of contraction and relaxation of muscle fibers, during muscular atrophy, provoke a loss of mechanical stresses transmitted over cell surface receptors that physically couple the cytoskeleton to extracellular matrix. Consequently, these mechanical changes could determine modifications of chemical signals through variations of pathway structural integrins, and alpha7A could replace alpha7B.     

Removal of dystroglycan causes severe muscular dystrophy in zebrafish embryos

Muscular dystrophy is frequently caused by disruption of the dystrophin-glycoprotein complex (DGC), which links muscle cells to the extracellular matrix. Dystroglycan, a central component of the DGC, serves as a laminin receptor via its extracellular alpha subunit, and interacts with dystrophin (and thus the actin cytoskeleton) through its integral membrane beta subunit. We have removed the function of dystroglycan in zebrafish embryos. In contrast to mouse, where dystroglycan mutations lead to peri-implantation lethality, dystroglycan is dispensable for basement membrane formation during early zebrafish development. At later stages, however, loss of dystroglycan leads to a disruption of the DGC, concurrent with loss of muscle integrity and necrosis. In addition, we find that loss of the DGC leads to loss of sarcomere and sarcoplasmic reticulum organisation. The DGC is required for long-term survival of muscle cells in zebrafish, but is dispensable for muscle formation. Dystroglycan or the DGC is also required for normal sarcomere and sarcoplasmic reticulum organisation. Because zebrafish embryos lacking dystroglycan share several characteristics with human muscular dystrophy, they should serve as a useful model for the disease. In addition, knowing the dystroglycan null phenotype in zebrafish will facilitate the isolation of other molecules involved in muscular dystrophy pathogenesis.     

Ultrastructure of diaphragm from dystrophic alpha-sarcoglycan-null mice

alpha-Sarcoglycan is a 50 kDa single-pass transmembrane glycoprotein exclusively expressed in striated muscle that, together with beta-, gamma-, and delta-sarcoglycan, forms a sub-complex at the muscle fibre cell membrane. The sarcoglycans are components of the dystrophin-associated glycoprotein (DAG) complex which forms a mechanical link between the intracellular cytoskeleton and extracellular matrix. The DAG complex function is to protect the muscle membrane from the stress of contractile activity and as a structure for the docking of signalling proteins. Genetic defects of DAG components cause muscular dystrophies. A lack or defects of alpha-sarcoglycan causes the severe type 2D limb girdle muscular dystrophy. alpha-Sarcoglycan-null (Sgca-null) mice develop progressive muscular dystrophy similar to the human disorder. This animal model was used in the present work for an ultrastructural study of diaphragm muscle. Diaphragm from Sgca-null mouse presents a clear dystrophic phenotype, with necrosis, regeneration, fibre hypertrophy and splitting, excess of collagen and fatty infiltration. Some abnormalities were also observed, such as centrally located nuclei of abnormal shape, fibres containing inclusion bodies within the contractile structure, and fibres with electron-dense material dispersed over almost the entire cell. Additionally, unusual interstitial cells of uncertain identity were detected within muscle fibres. The abnormal ultrastructure of the diaphragm from Sgca-null mice is discussed.     

Sarcoglycan isoforms in skeletal muscle

The heterotetrameric sarcoglycan complex, composed of alpha-, beta-, gamma-, and delta-sarcoglycans, is an important component of the dystrophin-associated glycoprotein assembly in striated muscle. Mutations in any of the four genes encoding sarcoglycans cause a deficiency in all sarcoglycans in the sarcolemma and produce one of four types of limb-girdle muscular dystrophy. A fifth widely expressed sarcoglycan, epsilon-sarcoglycan, has been recently described. epsilon-Sarcoglycan is homologous to alpha-sarcoglycan, but whether it associates with the other sarcoglycans in muscle is not known. In this study, we use wild type and alpha-sarcoglycan-deficient mice to analyze the localization and association of sarcoglycans in skeletal muscle in vivo. The amounts of beta-, gamma-, and delta-sarcoglycans are reduced in alpha-sarcoglycan mutants, whereas the amount of epsilon-sarcoglycan is unchanged. We show here that epsilon-sarcoglycan is complexed with beta-, gamma-, and delta-sarcoglycans in both wild type and alpha-sarcoglycan mutant mice. We also use C2C12 myocytes to study the temporal expression and organization of sarcoglycan complexes during muscle cell differentiation in vitro. In C2C12 cells, alpha- and epsilon-sarcoglycans form separate complexes with beta-, gamma-, and delta-sarcoglycans. Both types of complexes are expressed at the cell surface and presumed to be functional. These results suggest that epsilon-sarcoglycan serves a function similar to that of alpha-sarcoglycan and that residual beta-, gamma-, and delta-sarcoglycan seen in mutant mice and alpha-sarcoglycan-deficient patients is due to its association with epsilon-sarcoglycan.     

Identification of the beta1-integrin binding site on alpha-actinin by cryoelectron microscopy

Cell-matrix adhesions in migrating cells are usually mediated by integrins, alpha-beta heterodimeric transmembrane proteins that link extracellular matrix molecules such as fibronectin to the cytoskeleton. We have synthesized the cytoplasmic domain of the beta1-integrin (residues H738-K778) with a histidine tag at its N-terminus. The binding of this peptide to a lipid monolayer containing a chelated-nickel group (dimyristoylphosphatidyl choline-suberimide-nitriloacetic acid:nickel salt) mimics the native environment at the cytoplasmic leaflet of the plasma membrane. A Nanogold particle was covalently linked to cysteines introduced at the C-terminus and after residue T757 on the integrin peptide, and co-crystallized with chicken smooth muscle alpha-actinin. The 2-D arrays of the beta1-integrin-alpha-actinin complex were examined by cryoelectron microscopy, with and without the gold label. Averaged projections were calculated for each specimen along with a difference map to determine the relative position of the gold-labeled beta1-integrin peptide. The difference maps indicate that the beta1-integrin cytoplasmic domain binds alpha-actinin between the first and second, 3-helix motifs in the central rod domain.     

Neuronal nitric oxide synthase localizes through multiple structural motifs to the sarcolemma in mouse myotubes

In skeletal muscle, neuronal nitric oxide synthase is localized at the sarcolemma in association with the dystrophin glycoprotein complex (DGC). The nNOS N-terminal 231 amino acids comprise a PDZ domain (residues 1-100) and a beta-hairpin finger loop (residues 101-130) which binds alpha-syntrophin located in the DGC. Endogenous nNOS and GFP-tagged nNOS localize to the sarcolemma in mouse C2C12 myotubes. Expression of GFP-tagged nNOS domains in C2C12 myotubes reveals that the PDZ domain and the beta-hairpin finger loop of nNOS are independently capable of localizing to the sarcolemma of C2C12 myotubes. Binding studies indicate that alpha-syntrophin binds only to the beta-hairpin finger loop and not the PDZ domain of nNOS. nNOS may bind to proteins in addition to alpha-syntrophin at muscle sarcolemma.     

Sarcoglycan and integrin localization in normal human skeletal muscle: a confocal laser scanning microscope study

Many studies have been performed on the sarcoglycan sub-complex and a7B and b1D integrins, but their distribution and localization patterns along the non-junctional sarcolemma are still not clear. We have carried out an indirect immunofluorescence study on surgical biopsies of normal human skeletal muscle, performing double localization reactions with antibodies to sarcoglycans, integrins and sarcomeric actin. Our results indicate that the tested proteins colocalize with each other. In a few cases, a-sarcoglycan does not colocalize with the other sarcoglycans and integrins. We also demonstrated, by employing antibodies to all the tested proteins, that these proteins can be localized to regions of the sarcolemma corresponding either to the I-band or A-band. Our results seem to confirm the hypothesis of a correlation between the region of the sarcolemma occupied by costameric proteins and the metabolic type (fast or slow) of muscle fibers. On this basis, we suggest that slow fibers are characterized by localization of costameric proteins to I-bands, while fast fibers are characterized by localization of costameric proteins to A-bands. The results open a new line of research in understanding interactions between the components of the DGC and vinculin-talin-integrin complexes in the context of different fiber types. Moreover, the same results may be extended to skeletal muscle fibers affected by neuromuscular diseases to detect possible structural alterations.