Dystrophin is tightly associated with the sarcolemma of mammalian skeletal muscle fibers

Sarcolemmal vesicles with right-side-out configuration were prepared from normal fresh human and rabbit skeletal muscle bundles by incubation in 140 mM KCl solution containing collagenase. The vesicles were used to examine the association of dystrophin, the protein product of the Duchenne muscular dystrophy gene, with the sarcolemma. Western blot analysis, indirect immunofluorescence, and immunoperoxidase staining using specific antibodies raised against the N-terminal and the C-terminal domains show that dystrophin remains associated with the membrane of sarcolemmal vesicles. Indirect immunofluorescence microscopy using permeabilized and unpermeabilized vesicles indicated that both the N-terminus and the C-terminus of dystrophin are localized to the cytoplasmic surface of the sarcolemma. These results suggest that dystrophin has much stronger attachment to the surface membrane than it has to the internal domain of skeletal muscle fibers. Sarcolemmal vesicles thus represent a new system for studying the function of dystrophin and the molecular basis of its association with the sarcolemma.     

A new deletion in 5′-end of dystrophin gene removing M and P promoters and dystrophin muscle enhancers

We describe a 3-year-old boy who, at age of 8 months, during investigations for upper respiratory tract infection was found to have an incidental grossly elevated CK of 20,000 UI/l. Investigations showed only mild calf hypertrophy and absent Gower's sign, normal cognitive function. Electromyography (EMG) showed myopathic features. Electrocardiography and echocardiography were normal. His muscle biopsy revealed myopathic features indicating Duchenne-type dystrophy. Immunohistochemistry for dystrophin N-terminal, C-terminal and mid-rod antibodies analysis showed the complete absence of dystrophin in the muscle fibers. Genetic studies showed a 141.1 Kb deletion removing muscle promoter, muscle exon 1, Purkinje promoter, Purkinje exon 1, dystrophin muscle enhancers similar to one previously reported in a DMD patient who exhibited some residual expression of dystrophin. The difference in dystrophin expression between these two patients might be due to the extension of deletions. The precise delimitation of the macrodeletion here described provides a better understanding of functional organization of the 5′ end of the DMD gene.     

The carboxy-terminal third of dystrophin enhances actin binding activity

Dystrophin is an actin binding protein that is thought to stabilize the cardiac and skeletal muscle cell membranes during contraction. Here, we investigated the contributions of each dystrophin domain to actin binding function. Cosedimentation assays and pyrene-actin fluorescence experiments confirmed that a fragment spanning two-thirds of the dystrophin molecule [from N-terminal actin binding domain (ABD) 1 through ABD2] bound actin filaments with high affinity and protected filaments from forced depolymerization, but was less effective in both assays than full-length dystrophin. While a construct encoding the C-terminal third of dystrophin displayed no specific actin binding activity or competition with full-length dystrophin, our data show that it confers an unexpected regulation of actin binding by the N-terminal two-thirds of dystrophin when present in cis. Time-resolved phosphorescence anisotropy experiments demonstrated that the presence of the C-terminal third of dystrophin in cis also influences actin interaction by restricting actin rotational amplitude. We propose that the C-terminal region of dystrophin allosterically stabilizes an optimal actin binding conformation of dystrophin.     

Dystrophin-related protein is localized to neuromuscular junctions of adult skeletal muscle.

Dystrophin-related protein (DRP) is an autosomal gene product with high homology to dystrophin. We have used highly specific antibodies to the unique C-terminal peptide sequences of DRP and dystrophin to examine the subcellular localization and biochemical properties of DRP in adult skeletal muscle. DRP is enriched in isolated sarcolemma from control and mdx mouse muscle, but is much less abundant than dystrophin. Immunofluorescence microscopy localized DRP almost exclusively to the neuromuscular junction region in rabbit and mouse skeletal muscle, as well as mdx mouse muscle and denervated mouse muscle. DRP is also present in normal size and abundance and localizes to the neuromuscular junction region in muscle from the dystrophic mouse model dy/dy. Thus, DRP is a junction-specific membrane cytoskeletal protein that may play an important role in the organization of the postsynaptic membrane of the neuromuscular junction.     

Use of epitope libraries to identify exon-specific monoclonal antibodies for characterization of altered dystrophins in muscular dystrophy.

The majority of mutations in Xp21-linked muscular dystrophy (MD) can be identified by PCR or Southern blotting, as deletions or duplications of groups of exons in the dystrophin gene, but it is not always possible to predict how much altered dystrophin, if any, will be produced. Use of exon-specific monoclonal antibodies (mAbs) on muscle biopsies from MD patients can, in principle, provide information on both the amount of altered dystrophin produced and, when dystrophin is present, the nature of the genetic deletion or point mutation. For this purpose, mAbs which recognize regions of dystrophin encoded by known exons and whose binding is unaffected by the absence of adjacent exons are required. To map mAbs to specific exons, random "libraries" of expressed dystrophin fragments were created by cloning DNAseI digestion fragments of a 4.3-kb dystrophin cDNA into a pTEX expression vector. The libraries were then used to locate the epitopes recognized by 48 mAbs to fragments of 25-60 amino acids within the 1,434-amino-acid dystrophin fragment used to produce the antibodies. This is sufficiently detailed to allow further refinement by using synthetic peptides and, in many cases, to identify the exon in the DMD (Duchenne MD) gene which encodes the epitope. To illustrate their use in dystrophin analysis, a Duchenne patient with a frameshift deletion of exons 42 and 43 makes a truncated dystrophin encoded by exons 1-41, and we now show that this can be detected in the sarcolemma by mAbs up to and including those specific for exon 41 epitopes but not by mAbs specific for exon 43 or later epitopes.     

Absence of utrophin in intercalated discs of human cardiac muscle

Utrophin is the autosomal homologue of dystrophin. In normal skeletal muscle it is localised only to neuromuscular and myotendinous junctions, nerves and vascular tissue. In Xp21 muscular dystrophies, utrophin is also detected on the sarcolemma of skeletal and cardiac muscle, while dystrophin is absent or reduced. In normal cardiac muscle, some reports have demonstrated utrophin at intercalated discs and T-tubules. We have re-examined the distribution of utrophin in normal human cardiac muscle using a panel of eight monoclonal antibodies against different epitopes in N- and C-terminal domains. In contrast to previous studies, utrophin was not detected at the intercalated discs or T-tubules, although labelling of blood vessels was strong. We conclude that the primary location of utrophin in normal heart is in the vascular system. In addition, our results show that the utrophin on cardiac blood vessels is full length, similar to that of skeletal muscle blood vessels.     

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.     

Epitopes in the interacting regions of beta-dystroglycan (PPxY motif) and dystrophin (WW domain).

The dystroglycan gene produces two products from a single mRNA, the extracellular alpha-dystroglycan and the transmembrane beta-dystroglycan. The Duchenne muscular dystrophy protein, dystrophin, associates with the muscle membrane via beta-dystroglycan, the WW domain of dystrophin interacting with a PPxY motif in beta-dystroglycan. A panel of four monoclonal antibodies (MANDAG1-4) was produced using the last 16 amino acids of beta-dystroglycan as immunogen. The mAbs recognized a 43 kDa band on Western blots of all cells and tissues tested and stained the sarcolemma in immunohistochemistry of skeletal muscle over a wide range of animal species. A monoclonal antibody (mAb) against the WW domain of dystrophin, MANHINGE4A, produced using a 16-mer synthetic peptide, recognized dystrophin on Western blots and also stained the sarcolemma. We have identified the precise sequences recognized by the mAbs using a phage-displayed random 15-mer peptide library. A 7-amino-acid consensus sequence SPPPYVP involved in binding all four beta-dystroglycan mAbs was identified by sequencing 17 different peptides selected from the library. PPY were the most important residues for three mAbs, but PxxVP were essential residues for a fourth mAb, MANDAG2. By sequencing five different random peptides from the library, the epitope on dystrophin recognized by mAb MANHINGE4A was identified as PWxRA in the first beta-strand of the WW domain, with the W and R residues invariably present. A recent three-dimensional structure confirms that the two epitopes are adjacent in the dystrophin-dystroglycan complex, highlighting the question of how the two interacting motifs can also be accessible to antibodies during immunolocalization in situ.     

Duchenne muscular dystrophy: deficiency of dystrophin at the muscle cell surface

Dystrophin is the altered gene product in Duchenne muscular dystrophy (DMD). We used polyclonal antibodies against dystrophin to immunohistochemically localize the protein in human muscle. In normal individuals and in patients with myopathies other than DMD, dystrophin was localized to the sarcolemma of the fibers. The protein was absent or markedly deficient in DMD. The sarcolemmal localization of dystrophin is consistent with other evidence that there are structural and functional abnormalities of muscle surface membranes in DMD.     

In vitro digestion of dystrophin by calcium-dependent proteases, calpains I and II.

Dystrophin is a cytoskeletal protein which is thought to play an important role in membrane physiology since its absence (due to gene deficiency) leads to the symptoms of Duchenne muscular dystrophy (DMD). Some disruption in the regulation of intracellular free Ca2+ levels could lead to DMD-like symptoms. In this study, calpains, which are very active calcium-dependent proteases, were examined for their capacity to hydrolyse dystrophin in vitro. The results show that calpains are able to split dystrophin and produce breakdown products of different sizes (the degree of cleavage being dependent on the incubation time with proteases). The time-course of protease degradation was examined by Western immunoblot using three polyclonal sera which were characterized as being specific to the central (residues 1173-1728) and two distal parts of the molecule ie specific to the N-terminal (residues 43-760) or the C-terminal (residues 3357-3660) extremities of the dystrophin molecule. The cleavage patterns of dystrophin showed an accumulation of some major protease-resistant fragments of high relative molecular mass (250-370 kDa). These observations demonstrate that calpains digest dystrophin very rapidly when the calcium concentration is compatible with their activation. For instance, it is clear that calpains first give rise to large dystrophin products in which the C-terminal region is lacking. These observations suggest that dystrophin antibodies specific to the central domain of the molecule should be used to detect dystrophin for diagnostic purposes and before any conclusion as to the presence or absence of dystrophin can be deduced from results obtained using immunoanalyses of muscle biopsies.     

Localization of the DMDL gene-encoded dystrophin-related protein using a panel of nineteen monoclonal antibodies: presence at neuromuscular junctions, in the sarcolemma of dystrophic skeletal muscle, in vascular and other smooth muscles, and in proliferating brain cell lines

mAbs have been raised against different epitopes on the protein product of the DMDL gene, which is an autosomal homologue of the X-linked DMD gene for dystrophin. These antibodies provide direct evidence that DMDL protein is localized near acetylcholine receptors at neuromuscular junctions in normal and mdx mouse intercostal muscle. The primary location in tissues other than skeletal muscle is smooth muscle, especially in the vascular system, which may account for the wide tissue distribution previously demonstrated by Western blotting. The DMDL protein was undetectable in the nonjunctional sarcolemma of normal human muscle, but was observed in nonjunctional sarcolemma of Duchenne muscular dystrophy patients, where dystrophin itself is absent or greatly reduced. The expression of DMDL protein is not restricted to smooth and skeletal muscle, however, since relatively large amounts are present in transformed brain cell lines of both glial and Schwann cell origin. This contrasts with the low levels of DMDL protein in adult brain tissue.     

Truncation of N-terminal extracellular or C-terminal intracellular domains of human ETA receptor abrogated the binding activity to ET-1.

We have investigated the function of N-terminal and C-terminal domains of the human ETA receptor by expressing truncated mutants in COS-7 cells. Three kinds of ETA receptors truncated in the N-terminal extracellular or C-terminal intracellular domains were produced. Deletion of the entire extracellular N-terminal or intracellular C-terminal domain completely inactivated the ET-1 binding activity. However, the deletion of one half of the N-terminal extracellular domain of the ETA receptor, missing one of two N-linked glycosylation sites, maintained complete binding activity. Specific monoclonal antibodies detected all the truncated ETA receptors in the cell membrane fraction of transfected COS-7 cells. The size of the ETA receptor was heterogeneous due to differential glycosylation and distributed in 48K, 45K and 42K dalton bands in Western blot analysis. These results demonstrated that a part of the N-terminal domain in close proximity to the first transmembrane region is required for the ligand binding activity of the ETA receptor, and the C-terminal domain is perhaps necessary as an anchor for maintenance of the binding site.     

Subcellular localization of dystrophin and vinculin in cardiac muscle fibers and fibers of the conduction system of the chicken ventricle

The subcellular localization of dystrophin and vinculin was investigated in cardiac muscle fibers and fibers of the conduction system of the chicken ventricle by immunofluorescence confocal microscopy. In ventricular cardiac muscle fibers, strong staining with antibody against dystrophin appeared as regularly arranged transverse striations at the sarcolemmal surface, and faint but uniform staining was seen in narrow strips between these striations. In fibers of the ventricular conduction system, the sarcolemma was stained uniformly with this antibody, but strong staining was found as regular striations in many areas and as scattered patches in other areas of the sarcolemma. These intensely stained striations and scattered patches of dystrophin were colocalized with those of vinculin. Because dystrophin striations were located at the level of Z bands of the underlying myofibrils, they were regarded as the concentration of this protein at costameres together with vinculin. In fibers of the conduction system, myofibrils were close to the sarcolemma where dystrophin and vinculin assumed a striated pattern, at some distance from the cell membrane where these proteins exhibited a patchy distribution, and distant from the sarcolemma where dystrophin was uniformly distributed. These data suggest that the distribution patterns of dystrophin reflect the degree of association between the sarcolemma and underlying myofibrils.     

Association of the Mr 58,000 postsynaptic protein of electric tissue with Torpedo dystrophin and the Mr 87,000 postsynaptic protein.

Dystrophin was purified by immunoaffinity chromatography from detergent-solubilized Torpedo electric organ postsynaptic membranes using monoclonal antibodies. A major doublet of proteins at Mr 58,000 and minor proteins at Mr 87,000, Mr 45,000, and Mr 30,000 reproducibly copurified with dystrophin. The Mr 58,000 and Mr 87,000 proteins were identical to previously described peripheral membrane proteins (Mr 58,000 protein and 87,000 protein) whose muscle homologs are associated with the sarcolemma (Froehner, S. C., Murnane, A. A., Tobler, M., Peng, H. B., and Sealock, R. (1987) J. Cell Biol. 104, 1633-1646; Carr, C., Fischbach, G. D., and Cohen, J. B. (1989) J. Cell Biol. 109, 1753-1764). The copurification of dystrophin and Mr 58,000 protein was shown to be specific, since dystrophin was also captured with a monoclonal antibody against the Mr 58,000 protein but not by several control antibodies. The Mr 87,000 protein was a major component (along with the Mr 58,000 protein) in material purified on anti-58,000 columns, suggesting that the Mr 58,000 protein forms a distinct complex with the Mr 87,000 protein, as well as with dystrophin. Immunofluorescence staining of skeletal and cardiac muscle from the dystrophin-minus mdx mouse with the anti-58,000 antibody was confined to the sarcolemma as in normal muscle but was much reduced in intensity, even though immunoblotting demonstrated that the contents of Mr 58,000 protein in normal and mdx muscle were comparable. Thus, the Mr 58,000 protein appears to associate inefficiently with the sarcolemmal membrane in the absence of dystrophin. This deficiency may contribute to the membrane abnormalities that lead to muscle necrosis in dystrophic muscle.     

Dystrophin-glycoprotein complex is highly enriched in isolated skeletal muscle sarcolemma

mAbs specific for protein components of the surface membrane of rabbit skeletal muscle have been used as markers in the isolation and characterization of skeletal muscle sarcolemma membranes. Highly purified sarcolemma membranes from rabbit skeletal muscle were isolated from a crude surface membrane preparation by wheat germ agglutination. Immunoblot analysis of subcellular fractions from skeletal muscle revealed that dystrophin and its associated glycoproteins of 156 and 50 kD are greatly enriched in purified sarcolemma vesicles. The purified sarcolemma was also enriched in novel sarcolemma markers (SL45, SL/TS230) and Na+/K(+)-ATPase, whereas t-tubule markers (alpha 1 and alpha 2 subunits of dihydropyridine receptor, TS28) and sarcoplasmic reticulum markers (Ca2(+)-ATPase, ryanodine receptor) were greatly diminished in this preparation. Analysis of isolated sarcolemma by SDS-PAGE and densitometric scanning demonstrated that dystrophin made up 2% of the total protein in the rabbit sarcolemma preparation. Therefore, our results demonstrate that although dystrophin is a minor muscle protein it is a major constituent of the sarcolemma membrane in skeletal muscle. Thus the absence of dystrophin in Duchenne muscular dystrophy may result in a major disruption of the cytoskeletal network underlying the sarcolemma in dystrophic muscle.     

Patterns of dystrophin expression in developing, adult and regenerating tail skeletal muscle of Amphibian urodeles.

The patterns of expression of dystrophin were investigated by indirect immunofluorescence and by immunoblotting in developing, adult and regenerating tail skeletal muscle of newts Pleurodeles waltl and Notophthalmus viridescens. In this study, a monoclonal antibody H-5A3 directed against the C-terminal region (residues 3357-3660) and a polyclonal antibody raised to the central domain (residues 1173-1738) of the chicken skeletal muscle dystrophin were used. Western blot analysis showed that these antibodies recognized a 400 kDa band of dystrophin (and may be of dystrophin-related protein) in the adult muscle tissues and in newt tail regenerates. During skeletal muscle differentiation or epimorphic regeneration (blastema), anti-dystrophin immunoreactivity gradually accumulated over the periphery of the myofibers. Dystrophin and laminin were first and concomitantly observed at the ends of the newly formed myotubes where they were anchored on connective tissue septa or bone processes by dystrophin-rich myotendinous structures. It is noteworthy that neuromuscular junctions, which most probably also contain dystrophin, are established in urodeles near the ends of the myofibers as shown by histochemical localization of AChE activity or fluorescent bungarotoxin detection of AChRs. In the stump transition zone close to the tail amputation level where tissue regeneration of injured muscle fibers took place, dystrophin staining located on the cytoplasmic surface of myofibers progressively disappeared during the dedifferentiation process which seemed to occur during muscle regeneration as suggested by electron microscopy. Furthermore, double labeling experiments using anti-dystrophin and anti-laminin antibodies showed a good correlation between the remodeling processes of the muscle fiber basal lamina and the loss of dystrophin along the sarcolemma of damaged and presumably dedifferentiating muscle cells.     

The crystal structures of dystrophin and utrophin spectrin repeats: implications for domain boundaries

Dystrophin and utrophin link the F-actin cytoskeleton to the cell membrane via an associated glycoprotein complex. This functionality results from their domain organization having an N-terminal actin-binding domain followed by multiple spectrin-repeat domains and then C-terminal protein-binding motifs. Therapeutic strategies to replace defective dystrophin with utrophin in patients with Duchenne muscular dystrophy require full-characterization of both these proteins to assess their degree of structural and functional equivalence. Here the high resolution structures of the first spectrin repeats (N-terminal repeat 1) from both dystrophin and utrophin have been determined by x-ray crystallography. The repeat structures both display a three-helix bundle fold very similar to one another and to homologous domains from spectrin, α-actinin and plectin. The utrophin and dystrophin repeat structures reveal the relationship between the structural domain and the canonical spectrin repeat domain sequence motif, showing the compact structural domain of spectrin repeat one to be extended at the C-terminus relative to its previously defined sequence repeat. These structures explain previous in vitro biochemical studies in which extending dystrophin spectrin repeat domain length leads to increased protein stability. Furthermore we show that the first dystrophin and utrophin spectrin repeats have no affinity for F-actin in the absence of other domains.     

Identification of dystrophin in cardiac sarcolemmal vesicles

We have identified dystrophin in highly purified sarcolemmal vesicles isolated from canine and bovine hearts using specific antibodies against the COOH-terminal region of the protein. Bovine cardiac sarcolemma contained a single immunoreactive protein band (Mr. approximately 400,000) whereas the canine cardiac membrane contained a doublet (Mr. approximately 420,000 and approximately 380,000). The higher molecular weight form of canine cardiac dystrophin was more abundant than the lower molecular weight form. These highly purified preparations of the sarcolemmal vesicles should provide a useful tool for structural and functional analysis of the interaction of dystrophin with the plasma membrane.     

Direct visualization of the dystrophin network on skeletal muscle fiber membrane

Dystrophin, the protein product of the Duchenne muscular dystrophy (DMD) gene locus, is expressed on the muscle fiber surface. One key to further understanding of the cellular function of dystrophin would be extended knowledge about its subcellular organization. We have shown that dystrophin molecules are not uniformly distributed over the humen, rat, and mouse skeletal muscle fiber surface using three independent methods. Incubation of single-teased muscle fibers with antibodies to dystrophin revealed a network of denser transversal rings (costameres) and finer longitudinal interconnections. Double staining of longitudinal semithin cryosections for dystrophin and alpha-actinin showed spatial juxtaposition of the costameres to the Z bands. Where peripheral myonuclei precluded direct contact of dystrophin to the Z bands the organization of dystrophin was altered into lacunae harboring the myonucleus. These lacunae were surrounded by a dystrophin ring and covered by a more uniform dystrophin veil. Mechanical skinning of single-teased fibers revealed tighter mechanical connection of dystrophin to the plasma membrane than to the underlying internal domain of the muscle fiber. The entire dystrophin network remained preserved in its structure on isolated muscle sarcolemma and identical in appearance to the pattern observed on teased fibers. Therefore, connection of defined areas of plasma membrane or its constituents such as ion channels to single sarcomeres might be a potential function exerted by dystrophin alone or in conjunction with other submembrane cytoskeletal proteins.