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.     

Variations in dystrophin complex in red and white caudal muscles from Torpedo marmorata.

We present an up-to-date study on the nature, at the protein level, of various members of the dystrophin complex at the muscle cell membrane by comparing red and white caudal muscles from Torpedo marmorata. Our investigations involved immunodetection approaches and Western blotting analysis. We determined the presence or absence of different molecules belonging to the dystrophin family complex by analyzing their localization and molecular weight. Specific antibodies directed against dystrophin, i.e., DRP2 alpha-dystrobrevin, beta-dystroglycan, alpha-syntrophin, alpha-, beta-, gamma-, and delta-sarcoglycan, and sarcospan, were used. The immunofluorescence study (confocal microscopy) showed differences in positive immunoreactions at the sarcolemmal membrane in these slow-type and fast-type skeletal muscle fibers. Protein extracts from T. marmorata red and white muscles were analyzed by Western blotting and confirmed the presence of dystrophin and associated proteins at the expected molecular weights. Differences were confirmed by comparative immunoprecipitation analysis of enriched membrane preparations with anti-beta-dystroglycan polyclonal antibody. These experiments revealed clear complex or non-complex formation between members of the dystrophin system, depending on the muscle type analyzed. Differences in the potential function of these various dystrophin complexes in fast or slow muscle fibers are discussed in relation to previous data obtained in corresponding mammalian tissues. (J Histochem Cytochem 49:857-865, 2001)     

Presence of invertebrate dystrophin-like products in obliquely striated muscle of the leech, Pontobdella muricata (Annelida, Hirudinea)

Dystrophin is a 427-kDa cytoskeletal protein, which occurs in scant amounts in vertebrate muscle and nerve cells. No previous references to dystrophin or associated proteins in invertebrates at the protein level have been found, while two recent studies investigated the presence of genes encoding proteins homologous to dystrophin in sea urchin and other invertebrates such as Drosophila melanogaster. In this study, the possible presence and distribution of dystrophin-like proteins were studied in different invertebrate muscle cell types and species through Western blot analysis and light and electron microscope immunohistochemistry using a panel of antibodies whose specificities have been determined in vertebrates. Crude protein extracts of leech Pontobdella muricata were analysed by Western blotting. The revealed protein band, with 140kDa molecular weight, was related to dystrophin, utrophin or dystrophin-related protein-2 (DRP2) according to the specificities of the antibodies used to detect them. The immunofluorescence study showed positive immunoreactions in obliquely striated muscle of this hyrudinean. The immunoelectron microscopy study confirmed specific immunogold labelling beneath the sarcolemma of muscle cells. We thus assume that this protein is an invertebrate dystrophin-like product that is referred to as IDLp140. The potential functions of this invertebrate dystrophin-like protein in invertebrate muscles are discussed relative to previous data in vertebrate tissues.     

Dystroglycan contributes to the formation of multiple dystrophin-like complexes in brain

In muscle, dystrophin anchors a complex of proteins at the cell surface which includes alpha-dystroglycan, beta-dystroglycan, syntrophins and dystrobrevins. Mutations in the dystrophin gene lead to muscular dystrophy and mental retardation. In contrast to muscle, little is known about the localization and the molecular interactions of dystrophin and dystrophin associated proteins (DAPs) in brain. In the present study, we show that alpha-dystroglycan and dystrophin are localized to large neurones in cerebral cortex, hippocampus, cerebellum and spinal cord. Furthermore, we show that dystroglycan is a member of three distinct dystrophin-containing complexes. Two of these complexes contain syntrophin and both dystrophin and syntrophin are enriched in post-synaptic densities. These data suggest that dystrophin and DAPs may have a role in the organization of CNS synapses. Interestingly, the enrichment for syntrophin in post-synaptic densities is not affected in mice mutant for all dystrophin isoforms. Thus in the brain, unlike in muscle, the association of syntrophin with dystrophin is not crucial for the DAP complex which suggests that it may be associated with other proteins.     

Dystrophin-related protein in the fetal and denervated skeletal muscles of normal and mdx mice

The amino acid sequence of the polyclonal antibodies we developed against the carboxyl terminus of the dystrophin-related protein, the putative gene product of B3 cDNA, had no homologous sequence to the dystrophin molecule except for two amino acids located at its ends for immunization. By immunohistochemical examination in C57B1/10ScSn and C57B1/10ScSn-mdx mice we found that the DRP was expressed on the surface membrane of fetal muscle fibers, was assembled at the neuromuscular junctions of the mature muscle fibers, and reappeared on the surface membrane of muscle fibers after denervation. Its localization was similar to that of the acetylcholine receptor, suggesting that DRP is one of the cytoskeletons which organize and stabilize the cytoplasmic domain of the acetylcholine receptor.     

The subcellular distribution of dystrophin in mouse skeletal, cardiac, and smooth muscle

We use a highly specific and sensitive antibody to further characterize the distribution of dystrophin in skeletal, cardiac, and smooth muscle. No evidence for localization other than at the cell surface is apparent in skeletal muscle and no 427-kD dystrophin labeling was detected in sciatic nerve. An elevated concentration of dystrophin appears at the myotendinous junction and the neuromuscular junction, labeling in the latter being more intense specifically in the troughs of the synaptic folds. In cardiac muscle the distribution of dystrophin is limited to the surface plasma membrane but is notably absent from the membrane that overlays adherens junctions of the intercalated disks. In smooth muscle, the plasma membrane labeling is considerably less abundant than in cardiac or skeletal muscle and is found in areas of membrane underlain by membranous vesicles. As in cardiac muscle, smooth muscle dystrophin seems to be excluded from membrane above densities that mark adherens junctions. Dystrophin appears as a doublet on Western blots of skeletal and cardiac muscle, and as a single band of lower abundance in smooth muscle that corresponds most closely in molecular weight to the upper band of the striated muscle doublet. The lower band of the doublet in striated muscle appears to lack a portion of the carboxyl terminus and may represent a dystrophin isoform. Isoform differences and the presence of dystrophin on different specialized membrane surfaces imply multiple functional roles for the dystrophin protein.     

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.     

Differential expression and developmental regulation of a novel alpha-dystrobrevin isoform in muscle

Alpha-dystrobrevin is a dystrophin-related protein expressed primarily in skeletal muscle, heart, lung and brain. In skeletal muscle, alpha-dystrobrevin is a component of the dystrophin-associated glycoprotein complex and is localized to the sarcolemma, presumably through interactions with dystrophin and utrophin. Alternative splicing of the alpha-dystrobrevin gene generates multiple isoforms which have been grouped into three major classes: alpha-DB1, alpha-DB2, and alpha-DB3. Various isoforms have been shown to interact with a variety of proteins; however, the physiological function of the alpha-dystrobrevins remains unknown. In the present study, we have cloned a novel alpha-dystrobrevin cDNA encoding a protein (referred to as alpha-DB2b) with a unique 11 amino acid C-terminal tail. Using RT PCR with primers specific to the new isoform, we have characterized its expression in skeletal muscle, heart, and brain, and in differentiating C2C12 muscle cells. We show that alpha-DB2b is expressed in skeletal muscle, heart and brain, and that exons 12 and 13 are alternatively spliced in alpha-DB2b to generate at least three splice variants. The major alpha-DB2b splice variant expressed in adult skeletal muscle and heart contains exons 12 and 13, while in adult brain, two alpha-DB2b splice variants are expressed at similar levels. This is consistent with the preferential expression of exons 12 and 13 in other alpha-dystrobrevin isoforms in skeletal muscle and heart. Similarly, in alpha-DB1 the first 21 nucleotides of exon 18 are preferentially expressed in skeletal muscle and heart relative to brain. We also show that the expression of alternatively spliced alpha-DB2b is developmentally regulated in muscle; during differentiation of C2C12 cells, alpha-DB2b expression switches from an isoform lacking exons 12 and 13 to one containing them. We demonstrate similar developmental upregulation of exons 12, 13, and 18 in alpha-DB1 and of exons 12 and 13 in alpha-DB2a. Finally, we show that alpha-DB2b protein is expressed in adult skeletal muscle, suggesting that it has a functional role in adult muscle. Together, these data suggest that alternatively spliced variants of the new alpha-dystrobrevin isoform, alpha-DB2b, are differentially expressed in various tissues and developmentally regulated during muscle cell differentiation in a fashion similar to that previously described for alpha-dystrobrevin isoforms.     

Cognitive flexibility deficits in a mouse model for the absence of full‐length dystrophin

Duchenne muscular dystrophy (DMD) is a progressive muscle‐wasting disorder, caused by mutations in the DMD gene and the resulting lack of dystrophin. The DMD gene has seven promoters, giving rise to multiple full‐length and shorter isoforms. Besides the expression of dystrophin in muscles, the majority of dystrophin isoforms is expressed in brain and dystrophinopathy can lead to cognitive deficits, including intellectual impairments and deficits in executive function. In contrast to the muscle pathology, the impact of the lack of dystrophin on the brain is not very well studied. Here, we study the behavioral consequences of a lack of full‐length dystrophin isoforms in mdx mice, particularly with regard to domains of executive functions and anxiety. We observed a deficit in cognitive flexibility in mdx mice in the absence of motor dysfunction or general learning impairments using two independent behavioral tests. In addition, increased anxiety was observed, but its expression depended on the context. Overall, these results suggest that the absence of full‐length dystrophin in mice has specific behavioral effects that compare well to deficits observed in DMD patients.     

Embryonic expression patterns of the Drosophila dystrophin-associated glycoprotein complex orthologs

Mutations in genes encoding proteins of the human dystrophin-associated glycoprotein complex (DGC) cause the Duchenne, Becker and limb-girdle muscular dystrophies. Subsets of the DGC proteins form tissue-specific complexes which are thought to play structural and signaling roles in the muscle and at the neuromuscular junction. Furthermore, mutations in the dystrophin gene that lead to Duchenne muscular dystrophy are frequently associated with cognitive and behavioral deficits, suggesting a role for dystrophin in the nervous system. Despite significant progress over the past decade, many fundamental questions about the roles played by dystrophin and the other DGC proteins in the muscle and peripheral and central nervous systems remain to be answered. Mammalian models of DGC gene function are complicated by the existence of fully or partially redundant genes whose functions can mask effects of the inactivation of a given DGC gene. The genome of the fruitfly Drosophila melanogaster encodes a single ortholog of the majority of the mammalian DGC protein subclasses, thus potentially simplifying their functional analysis. We report here the embryonic mRNA expression patterns of the individual DGC orthologs. We find that they are predominantly expressed in the nervous system and in muscle. Dystrophin, dystrobrevin-like, dystroglycan-like, syntrophin-like 1, and all three sarcoglycan orthologs are found in the brain and the ventral nerve cord, while dystrophin, dystrobrevin-like, dystroglycan-like, syntrophin-like 2, sarcoglycan alpha and sarcoglycan delta are expressed in distinct and sometimes overlapping domains of mesoderm-derived tissues, i.e. muscles of the body wall and around the gut.     

gamma-Syntrophin scaffolding is spatially and functionally distinct from that of the alpha/beta syntrophins

The syntrophins are a family of scaffolding proteins with multiple protein interaction domains that link signaling proteins to dystrophin family members. Each of the three most characterized syntrophins (alpha, beta1, beta2) contains a PDZ domain that binds a unique set of signaling proteins including kinases, ion and water channels, and neuronal nitric oxide synthase (nNOS). The PDZ domains of the gamma-syntrophins do not bind nNOS. In vitro pull-down assays show that the gamma-syntrophins can bind dystrophin but have unique preferences for the syntrophin binding sites of dystrophin family members. Despite their ability to bind dystrophin in vitro, neither gamma-syntrophin isoform co-localizes with dystrophin in skeletal muscle. Furthermore, gamma-syntrophins do not co-purify with dystrophin isolated from mouse tissue. These data suggest that the interaction of gamma-syntrophin with dystrophin is transient and potentially subject to regulatory mechanisms. gamma1-Syntrophin is highly expressed in brain and is specifically localized in hippocampal pyramidal neurons, Purkinje neurons in cerebellum, and cortical neurons. gamma2-Syntrophin is expressed in many tissues including skeletal muscle where it is found only in the subsynaptic space beneath the neuromuscular junction. In both neurons and muscle, gamma-syntrophin isoforms localize to the endoplasmic reticulum where they may form a scaffold for signaling and trafficking.     

Absence of nitric oxide synthase I despite the presence of the dystrophin complex in human striated muscle

Summary Recently, it has been shown that in human striated muscle the signalling enzyme, brain-type nitric oxide synthase I (NOS I), is associated with the sarcolemma and complexes with dystrophin and/or members of the dystrophin complex. In order to find out whether there exists a regular association between NOS I and the complex, muscle biopsies from patients with various muscle disorders were analysed by enzyme histochemistry and immunohistochemistry. In patients suffering from Duchenne muscular dystrophy, and to a lesser extent in those with Becker-type dystrophy, NOS I and dystrophin complex components were absent or drastically reduced in the sarcolemma region. In other dystrophies, as well as in metabolic and inflammatory myopathies, NOS I and dystrophin complex constituents were expressed normally, while in the case of neurogenic diseases leading to denervation atrophy and especially congenital idiopathic clubfoot, the immunohistochemical patterns of the distribution of the dystrophin complex constituents were normal, but NOS I activity and protein were deficient or dramatically diminished. The results can be interpreted as indicating that, in general, NOS I targeting to the sarcolemma is dependent on particular members of the dystrophin complex, such as ·-1 syntrophin, yet the expression and/or positioning of NOS I may be under the control of further factors, probably of neurogenic origin. NOS I-associated diaphorase may thus be a useful complementary tool in the diagnosis of muscle disorders. This revised version was published online in November 2006 with corrections to the Cover Date.