Alpha7beta1 integrin does not alleviate disease in a mouse model of limb girdle muscular dystrophy type 2F

Transgenic expression of the alpha7beta1 integrin in the dystrophic mdx/utr-/- mouse decreases development of muscular dystrophy and enhances longevity. To explore the possibility that elevating alpha7beta1 integrin expression could also ameliorate different forms of muscular dystrophy, we used transgenic technology to enhance integrin expression in mice lacking delta-sarcoglycan (delta sgc), a mouse model for human limb girdle muscular dystrophy type 2F. Unlike alpha7 transgenic mdx/utr-/- mice, enhanced alpha7beta1 integrin expression in the delta sgc-null mouse did not alleviate muscular dystrophy in these animals. Expression of the transgene in the delta sgc-null did not alleviate dystrophic histopathology, nor did it decrease cardiomyopathy or restore exercise tolerance. One hallmark of integrin-mediated alleviation of muscular dystrophy in the mdx/utr-/- background is the restoration of myotendinous junction integrity. As assessed by atomic force microscopy, myotendinous junctions from normal and delta sgc-null mice were indistinguishable, thus suggesting the important influence of myotendinous junction integrity on the severity of muscular dystrophy and providing a possible explanation for the inability of enhanced integrin expression to alleviate dystrophy in the delta sgc-null mouse. These results suggest that distinct mechanisms underlie the development of the diseases that arise from deficiencies in dystrophin and sarcoglycan.     

Dystrophin and utrophin influence fiber type composition and post-synaptic membrane structure

The X-linked muscle wasting disease Duchenne muscular dystrophy is caused by the lack of dystrophin in muscle. Protein structure predictions, patient mutations, in vitro binding studies and transgenic and knockout mice suggest that dystrophin plays a mechanical role in skeletal muscle, linking the subsarcolemmal cytoskeleton with the extracellular matrix through its direct interaction with the dystrophin-associated protein complex (DAPC). Although a signaling role for dystrophin has been postulated, definitive data have been lacking. To identify potential non-mechanical roles of dystrophin, we tested the ability of various truncated dystrophin transgenes to prevent any of the skeletal muscle abnormalities associated with the double knockout mouse deficient for both dystrophin and the dystrophin-related protein utrophin. We show that restoration of the DAPC with Dp71 does not prevent the structural abnormalities of the post-synaptic membrane or the abnormal oxidative properties of utrophin/dystrophin-deficient muscle. In marked contrast, a dystrophin protein lacking the cysteine-rich domain, which is unable to prevent dystrophy in the mdx mouse, is able to ameliorate these abnormalities in utrophin/dystrophin-deficient mice. These experiments provide the first direct evidence that in addition to a mechanical role and relocalization of the DAPC, dystrophin and utrophin are able to alter both structural and biochemical properties of skeletal muscle. In addition, these mice provide unique insights into skeletal muscle fiber type composition.     

Transgenic overexpression of ADAM12 suppresses muscle regeneration and aggravates dystrophy in aged mdx mice

Muscular dystrophies are characterized by insufficient restoration and gradual replacement of the skeletal muscle by fat and connective tissue. ADAM12 has previously been shown to alleviate the pathology of young dystrophin-deficient mdx mice, a model for Duchenne muscular dystrophy. The observed effect of ADAM12 was suggested to be mediated via a membrane-stabilizing up-regulation of utrophin, alpha7B integrin, and dystroglycans. Ectopic ADAM12 expression in normal mouse skeletal muscle also improved regeneration after freeze injury, presumably by the same mechanism. Hence, it was suggested that ADAM12 could be a candidate for nonreplacement gene therapy of Duchenne muscular dystrophy. We therefore evaluated the long-term effect of ADAM12 overexpression in muscle. Surprisingly, we observed loss of skeletal muscle and accelerated fibrosis and adipogenesis in 1-year-old mdx mice transgenically overexpressing ADAM12 (ADAM12(+)/mdx mice), even though their utrophin levels were mildly elevated compared with age-matched controls. Thus, membrane stabilization was not sufficient to provide protection during prolonged disease. Consequently, we reinvestigated skeletal muscle regeneration in ADAM12 transgenic mice (ADAM12(+)) after a knife cut lesion and observed that the regeneration process was significantly impaired. ADAM12 seemed to inhibit the satellite cell response and delay myoblast differentiation. These results discourage long-term therapeutic use of ADAM12. They also point to impaired regeneration as a possible factor in development of muscular dystrophy.     

Matrix metalloproteinase-2 ablation in dystrophin-deficient mdx muscles reduces angiogenesis resulting in impaired growth of regenerated muscle fibers

Matrix metalloproteases (MMPs) are a family of endopeptidases classified into subgroups based on substrate preference in normal physiological processes such as embryonic development and tissue remodeling, as well as in various disease processes via degradation of extracellular matrix components. Among the MMPs, MMP-9 and MMP-2 have been reported to be up-regulated in skeletal muscles in the lethal X-linked muscle disorder Duchenne muscular dystrophy (DMD), which is caused by loss of dystrophin. A recent study showed that deletion of the MMP9 gene in mdx, a mouse model for DMD, improved skeletal muscle pathology and function; however, the role of MMP-2 in the dystrophin-deficient muscle is not well known. In this study, we aimed at verifying the role of MMP-2 in the dystrophin-deficient muscle by using mdx mice with genetic ablation of MMP-2 (mdx/MMP-2(-/-)). We found impairment of regenerated muscle fiber growth with reduction of angiogenesis in mdx/MMP-2(-/-) mice at 3 months of age. Expression of vascular endothelial growth factor-A (VEGF-A), an important angiogenesis-related factor, decreased in mdx/MMP-2(-/-) mice at 3 months of age. MMP-2 had not a critical role in the degradation of dystrophin-glycoprotein complex (DGC) components such as β-dystroglycan and β-sarcoglycan in the regeneration process of the dystrophic muscle. Accordingly, MMP-2 may be essential for growth of regenerated muscle fibers through VEGF-associated angiogenesis in the dystrophin-deficient skeletal muscle.     

Suppression of revertant fibers in mdx mice by expression of a functional dystrophin.

Duchenne muscular dystrophy (DMD) is characterized by progressive muscle degeneration that results from the absence of dystrophin. Despite null mutations in the dystrophin gene, many DMD patients display a low percentage of dystrophin-positive fibers. These "revertant fibers" are also present in the dystrophin-deficient mdx mouse and are believed to result from alternative splicing or second mutation events that bypass the mutation and restore an open reading frame. However, it is unclear what role dystrophin and the dystrophic pathology might play in revertant fiber formation and accumulation. We have analyzed the role of dystrophin expression and the dystrophic pathology in this process by monitoring revertant fibers in transgenic mdx mice that express truncated dystrophins. We found that newborn transgenic mice displayed approximately the same number of revertant fibers as newborn mdx mice, indicating that expression of a functional dystrophin does not suppress the initiation of revertant fiber formation. Surprisingly, when the transgene encoded a functional dystrophin, revertant fibers were not detected in adult or old mdx mice. In contrast, adult transgenic mice expressing a non-functional dystrophin accumulated increasing numbers of revertant fibers, similar to mdx mice, suggesting that positive selection is required for the persistence of revertant fibers. Finally, we provide evidence that the loss of revertant dystrophin in transgenic mdx muscle fibers overexpressing a functional dystrophin results from displacement of the revertant protein by the transgene-encoded dystrophin.     

CT-GalNAc transferase overexpression in adult mice is associated with extrasynaptic utrophin in skeletal muscle fibres

Duchenne muscular dystrophy is a genetic muscle disease characterized by the absence of sub-sarcolemmal dystrophin that results in muscle fibre necrosis, progressive muscle wasting and is fatal. Numerous experimental studies with dystrophin-deficient mdx mice, an animal model for the disease, have demonstrated that extrasynaptic upregulation of utrophin, an analogue of dystrophin, can prevent muscle fibre deterioration and reduce or negate the dystrophic phenotype. A different approach for ectopic expression of utrophin relies on augmentation of CT-GalNAc transferase in muscle fibre. We investigated whether CT-GalNAc transferase overexpression in adult mice influence appearance of utrophin in the extrasynaptic sarcolemma. After electrotransfer of plasmid DNA carrying an expression cassette of CT-GalNAc transferase into tibialis anterior muscle of wild type and dystrophic mice, muscle sections were examined by immunofluorescence. CT-GalNAc transgene expression augmented sarcolemmal carbohydrate glycosylation and was accompanied by extrasynaptic utrophin. A 6-week time course study showed that the highest efficiency of utrophin overexpression in a plasmid harboured muscle fibres was 32.2% in CD-1 and 52% in mdx mice, 2 and 4 weeks after CT-GalNAc gene transfer, respectively. The study provides evidence that postnatal CT-GalNAc transferase overexpression stimulates utrophin upregulation that is inherently beneficial for muscle structure and strength restoration. Thus CT-GalNAc may provide an important therapeutic molecule for treatment of dystrophin deficiency in Duchenne muscular dystrophy.     

Integrin alpha 7 beta 1 in muscular dystrophy/myopathy of unknown etiology

To investigate the role of integrin alpha 7 in muscle pathology, we used a "candidate gene" approach in a large cohort of muscular dystrophy/myopathy patients. Antibodies against the intracellular domain of the integrin alpha 7A and alpha 7B were used to stain muscle biopsies from 210 patients with muscular dystrophy/myopathy of unknown etiology. Levels of alpha 7A and alpha 7B integrin were found to be decreased in 35 of 210 patients (approximately 17%). In six of these patients no integrin alpha 7B was detected. Screening for alpha 7B mutation in 30 of 35 patients detected only one integrin alpha 7 missense mutation (the mutation on the second allele was not found) in a patient presenting with a congenital muscular dystrophy-like phenotype. No integrin alpha 7 gene mutations were identified in all of the other patients showing integrin alpha 7 deficiency. In the process of mutation analysis, we identified a novel integrin alpha 7 isoform presenting 72-bp deletion. This isoform results from a partial deletion of exon 21 due to the use of a cryptic splice site generated by a G to A missense mutation at nucleotide position 2644 in integrin alpha 7 cDNA. This spliced isoform is present in about 12% of the chromosomes studied. We conclude that secondary integrin alpha 7 deficiency is rather common in muscular dystrophy/myopathy of unknown etiology, emphasizing the multiple mechanisms that may modulate integrin function and stability.     

Sarcolemmal ion channels in dystrophin-deficient skeletal muscle fibres

Duchenne muscular dystrophy (DMD) is a genetic disease caused by mutations in the dystrophin gene and characterized by progressive skeletal muscle degeneration. A current hypothesis suggests that degeneration of dystrophin-deficient skeletal muscle results from a chronic intracellular Ca²⁺ overload. Ca²⁺ handling in skeletal muscle is tightly controlled by the membrane potential which is set by sarcolemmal ion channels activity. Also, with regard to the subsarcolemmal localization of dystrophin, it is reasonable to enquire if the distribution and function of ion channels might be affected by the absence of dystrophin. This paper briefly summarizes the current knowledge of the properties of sarcolemmal ion channels in fully differentiated dystrophin-deficient skeletal muscle fibres.     

Diagnosis and cell-based therapy for Duchenne muscular dystrophy in humans,mice, and zebrafish

The muscular dystrophies are a heterogeneous group of genetically caused muscle degenerative disorders. The Kunkel laboratory has had a longstanding research program into the pathogenesis and treatment of these diseases. Starting with our identification of dystrophin as the defective protein in Duchenne muscular dystrophy (DMD), we have continued our work on normal dystrophin function and how it is altered in muscular dystrophy. Our work has led to the identification of the defective genes in three forms of limb girdle muscular dystrophy (LGMD) and a better understanding of how muscle degenerates in many of the different dystrophies. The identification of mutations causing human forms of dystrophy has lead to improved diagnosis for patients with the disease. We are continuing to improve the molecular diagnosis of the dystrophies and have developed a high-throughput sequencing approach for the low-cost rapid diagnosis of all known forms of dystrophy. In addition, we are continuing to work on therapies using available animal models. Currently, there are a number of mouse models of the human dystrophies, the most notable being the mdx mouse with dystrophin deficiency. These mice are being used to test possible therapies, including stem-cell-based approaches. We have been able to systemically deliver human dystrophin to these mice via the arterial circulation and convert 8% of dystrophin-deficient fibers to fibers expressing human dystrophin. We are now expanding our research to identify new forms of LGMD by analyzing zebrafish models of muscular dystrophy. Currently, we have 14 different zebrafish mutants exhibiting various phenotypes of muscular dystrophy, including muscle weakness and inactivity. One of these mutants carries a stop codon mutation in dystrophin, and we have recently identified another carrying a mutation in titin. We are currently positionally cloning the disease-causative mutation in the remaining 12 mutant strains. We hope that one of these new mutant strains of fish will have a mutation in a gene not previously implicated in human muscular dystrophy. This gene would become a candidate gene to be analyzed in patients which do not carry a mutation in any of the known dystrophy-associated genes. By studying both disease pathology and investigating potential therapies, we hope to make a positive difference in the lives of people living with muscular dystrophy.     

Transgenic expression of {alpha}7{beta}1 integrin maintains muscle integrity, increases regenerative capacity, promotes hypertrophy, and reduces cardiomyopathy in dystrophic mice

We previously reported that enhanced expression of the alpha7beta1 integrin ameliorates the development of muscular dystrophy and extends longevity in alpha7BX2-mdx/utr(-/-) transgenic mice (Burkin DJ, Wallace GQ, Nicol KJ, Kaufman DJ, Kaufman SJ: Enhanced expression of the alpha7beta1 integrin reduces muscular dystrophy and restores viability in dystrophic mice. We now report on the mechanism by which these mice were rescued by the integrin. As a result of increased integrin in alpha7BX2-mdx/utr(-/-) mice the structural integrity of the myotendinous and neuromuscular junctions are maintained. A twofold increase in satellite cells in alpha7BX2-mdx/utr(-/-) skeletal muscle was detected by immunofluorescence using the satellite cell marker c-met. These cells enhanced the regenerative capacity of muscle in the transgenic animals as determined by fusion of BrdUrd-labeled cells into muscle fibers. Increased integrin also leads to hypertrophy. Finally, transgenic expression of alpha7BX2 integrin chain in skeletal muscle secondarily reduces the development of cardiomyopathy, the ultimate cause of death in these animals. We believe this multiplicity of responses to increased alpha7beta1 integrin collectively inhibits the development of muscle disease and increases longevity in these mice.     

Muscle-specific BCL2 expression ameliorates muscle disease in laminin {alpha}2-deficient, but not in dystrophin-deficient, mice

To examine the role of apoptosis in neuromuscular disease progression, we have determined whether pathogenesis in dystrophin-deficient (mdx) and laminin alpha2-deficient (Lama2-null) mice is ameliorated by overexpression of the anti-apoptosis protein BCL2 in diseased muscles. The mdx mice are a model for the human disease, Duchenne muscular dystrophy (DMD), and the Lama2-null mice are a model for human congenital muscular dystrophy type 1A (MDC1A). For these studies, we generated transgenic mice that overexpressed human BCL2 under control of muscle-specific MyoD or MRF4 promoter fragments. We then used cross-breeding to introduce the transgenes into diseased mdx or Lama2-null mice. In mdx mice, we found that overexpression of BCL2 failed to produce any significant differences in muscle pathology. In contrast, in the Lama2-null mice, we found that muscle-specific expression of BCL2 led to a several-fold increase in lifespan and an increased growth rate. Thus, BCL2-mediated apoptosis appears to play a significant role in pathogenesis of laminin alpha2 deficiency, but not of dystrophin deficiency, suggesting that therapies designed to ameliorate disease by inhibition of apoptosis are more likely to succeed in MDC1A than in DMD.     

Contribution of oxidative stress to pathology in diaphragm and limb muscles with Duchenne muscular dystrophy

Duchenne muscular dystrophy (DMD) is a degenerative skeletal muscle disease that makes walking and breathing difficult. DMD is caused by an X-linked (Xp21) mutation in the dystrophin gene. Dystrophin is a scaffolding protein located in the sarcolemmal cytoskeleton, important in maintaining structural integrity and regulating muscle cell (muscle fiber) growth and repair. Dystrophin deficiency in mouse models (e.g., mdx mouse) destabilizes the interface between muscle fibers and the extracellular matrix, resulting in profound damage, inflammation, and weakness in diaphragm and limb muscles. While the link between dystrophin deficiency with inflammation and pathology is multi-factorial, elevated oxidative stress has been proposed as a central mediator. Unfortunately, the use of non-specific antioxidant scavengers in mouse and human studies has led to inconsistent results, obscuring our understanding of the importance of redox signaling in pathology of muscular dystrophy. However, recent studies with more mechanistic approaches in mdx mice suggest that NAD(P)H oxidase and nuclear factor-kappaB are important in amplifying dystrophin-deficient muscle pathology. Therefore, more targeted antioxidant therapeutics may ameliorate damage and weakness in human population, thus promoting better muscle function and quality of life. This review will focus upon the pathobiology of dystrophin deficiency in diaphragm and limb muscle primarily in mouse models, with a rationale for development of targeted therapeutic antioxidants in DMD patients.     

Deficiency in Cardiac Dystrophin Affects the Abundance of the $\alpha$ -/ $\beta$ -Dystroglycan Complex

Although Duchenne muscular dystrophy is primarilycategorised as a skeletal muscle disease, deficiency in themembrane cytoskeletal protein dystrophin also affects the heart.The central transsarcolemmal linker between the actin membranecytoskeleton and the extracellular matrix is represented by thedystrophin-associated dystroglycans. Chemical cross-linkinganalysis revealed no significant differences in the dimericstatus of the α-/β-dystroglycan subcomplex in thedystrophic mdx heart as compared to normalcardiac tissue. In analogy to skeletal muscle fibres, heartmuscle also exhibited a greatly reduced abundance of bothdystroglycans in dystrophin-deficient cells. Immunoblottingdemonstrated that the degree of reduction inα-dystroglycan is more pronounced in matured mdxskeletal muscle as contrasted to the mdx heart. The factthat the deficiency in dystrophin triggers a similarpathobiochemical response in both types of muscle suggests thatthe cardiomyopathic complications observed inx-linked muscular dystrophy might be initiated bythe loss of the dystrophin-associated surface glycoproteincomplex.     

Expression of a NOS transgene in dystrophin-deficient muscle reduces muscle membrane damage without increasing the expression of membrane-associated cytoskeletal proteins

Muscular dystrophy that is caused by mutation of the membrane-associated, cytoskeletal protein called dystrophin, is accompanied by loss of a dystrophin-associated protein complex (DPC) that includes neuronal nitric oxide synthase (nNOS). Previous work showed that expression of a nNOS transgene in the dystrophin-deficient, mdx mouse greatly reduces muscle membrane damage. In this investigation, we test whether expression of a nNOS transgene in wild-type or mdx muscle increases expression of DPC proteins, or functionally related proteins in the integrin complex that are upregulated in dystrophin-deficiency, or affects expression of the dystrophin homolog, utrophin. Many members of the DPC are enriched in Western blots of cell membranes isolated from NOS transgenic muscle, compared to wild-type. Similarly, alpha7-integrin and the associated cytoskeletal proteins talin and vinculin are increased in NOS transgenic, non-dystrophic muscle. However, utrophin expression is unaffected by elevated NOS expression in healthy muscle. A similar trend in mRNA levels for these proteins was observed by expression profiling. Analysis of membrane preparations from mdx mice and NOS transgenic mdx mice shows that expression of the NOS transgene causes significant reductions in utrophin, talin, and vinculin. Expression profiling of mRNA from mdx and NOS transgenic mdx muscles also shows reduced expression of talin. Immunohistochemistry of mdx and NOS transgenic mdx muscle indicates that reduction in utrophin in NOS transgenic mdx muscle results from a decrease in regenerative fibers that express high levels of utrophin. Together, these findings indicate that the NOS transgene does not reduce dystrophinopathy by increasing the expression of compensatory, structural proteins.     

Immunoproteasome in animal models of Duchenne muscular dystrophy

Increased proteasome activity has been implicated in the atrophy and deterioration associated with dystrophic muscles of Duchenne muscular dystrophy (DMD). While proteasome inhibitors show promise in the attenuation of muscle degeneration, proteasome inhibition-induced toxicity was a major drawback of this therapeutic strategy. Inhibitors that selectively target the proteasome subtype that is responsible for the loss in muscle mass and quality would reduce side effects and be less toxic. This study examined proteasome activity and subtype populations, along with muscle function, morphology and damage in wild-type (WT) mice and two murine models of DMD, dystrophin-deficient (MDX) and dystrophin- and utrophin-double-knockout (DKO) mice. We found that immunoproteasome content was increased in dystrophic muscles while the total proteasome content was unchanged among the three genotypes of mice. Proteasome proteolytic activity was elevated in dystrophic muscles, especially in DKO mice. These mice also exhibited more severe muscle atrophy than either WT or MDX mice. Muscle damage and regeneration, characterized by the activity of muscle creatine kinase in the blood and the percentage of central nuclei were equally increased in dystrophic mice. Accordingly, the overall muscle function was similarly reduced in both dystrophic mice compared with WT. These data demonstrated that there was transformation of standard proteasomes to immunoproteasomes in dystrophic muscles. In addition, DKO that showed greatest increase in proteasome activities also demonstrated more severe atrophy compared with MDX and WT. These results suggest a putative role for the immunoproteasome in muscle deterioration associated with DMD and provide a potential target for therapeutic intervention.     

Abnormal kainic acid receptor density and reduced seizure susceptibility in dystrophin-deficient mdx mice

Duchenne muscular dystrophy is characterized by a defect in dystrophin, which often causes mental retardation in addition to progressive muscular weakness. As dystrophin is localized in synaptic regions of the CNS, cognitive abnormalities associated with Duchenne muscular dystrophy are attributable to synaptic dysfunction. We report that dystrophin-deficient mdx mice were more resistant to kainic acid-induced seizures but not to GABA antagonist-induced seizures compared with the control mice. The kainic-acid receptor density in the brain was significantly lower in the mdx than in the control, although the density of muscarinic cholinergic receptors, another important neurotransmitter receptor for cognitive function, was normal. Moreover, mdx had significantly lower Timm staining intensity in the mossy fibers, which originate from the dentate granule cells and terminate on the pyramidal cells in the CA3 of the hippocampus. These results suggest that an instability of neurotransmitter receptors, such as kainate-type glutamate receptors, on synaptic membranes due to the disruption of dystrophin complex induces inefficient neurotransmission in Duchenne muscular dystrophy patients.     

Proteomic assessment of the acute phase of dystrophin deficiency in mdx mice

Duchenne muscular dystrophy (DMD) is caused by the absence of a functional dystrophin protein and is modeled by the mdx mouse. The mdx mouse suffers an early necrotic bout in the hind limb muscles lasting from approximately 4 to 7 weeks. The purpose of this investigation was to determine the extent to which dystrophin deficiency changed the proteome very early in the disease process. In order to accomplish this, proteins from gastrocnemius from 6-week-old C57 (n = 6) and mdx (n = 6) mice were labeled with fluorescent dye and subjected to two-dimensional differential in-gel electrophoresis (2D-DIGE). Resulting differentially expressed spots were excised and protein identity determined via MALDI-TOF followed by database searching using MASCOT. Proteins of the immediate energy system and glycolysis were generally down-regulated in mdx mice compared to C57 mice. Conversely, expression of proteins involved in the Kreb’s cycle and electron transport chain were increased in dystrophin-deficient muscle compared to control. Expression of cytoskeletal components, including tubulins, vimentin, and collagen, were increased in mdx mice compared to C57 mice. Importantly, these changes are occurring at only 6 weeks of age and are caused by acute dystrophin deficiency rather than more chronic injury. These data may provide insight regarding early pathologic changes occurring in dystrophin-deficient skeletal muscle.     

Preservation of muscle force in Mdx3cv mice correlates with low-level expression of a near full-length dystrophin protein

The complete absence of dystrophin causes Duchenne muscular dystrophy. Its restoration by greater than 20% is needed to reduce muscle pathology and improve muscle force. Dystrophin levels lower than 20% are considered therapeutically irrelevant but are associated with a less severe phenotype in certain Becker muscular dystrophy patients. To understand the role of low-level dystrophin expression, we compared muscle force and pathology in mdx3cv and mdx4cv mice. Dystrophin was eliminated in mdx4cv mouse muscle but was expressed in mdx3cv mice as a near full-length protein at approximately 5% of normal levels. Consistent with previous reports, we found dystrophic muscle pathology in both mouse strains. Surprisingly, mdx3cv extensor digitorium longus muscle showed significantly higher tetanic force and was also more resistant to eccentric contraction-induced injury than mdx4cv extensor digitorium longus muscle. Furthermore, mdx3cv mice had stronger forelimb grip strength than mdx4cv mice. Immunostaining revealed utrophin up-regulation in both mouse strains. The dystrophin-associated glycoprotein complex was also restored in the sarcolemma in both strains although at levels lower than those in normal mice. Our results suggest that subtherapeutic expression levels of near full-length, membrane-bound dystrophin, possibly in conjunction with up-regulated utrophin levels, may help maintain minimal muscle force but not arrest muscle degeneration or necrosis. Our findings provide valuable insight toward understanding delayed clinical onset and/or slow disease progression in certain Becker muscular dystrophy patients.     

Distribution of dystrophin and neurofilament protein in muscle spindles of normal and mdx-dystrophic mice: An immunocytochemical study

Dystrophin is a high molecular weight protein localized under the sarcolemma of normal extrafusal muscle fibers but absent in skeletal muscle of Duchenne muscular dystrophy patients and mdx mice. Muscle spindles in the soleus of 32-week-old normal and age-matched mdx mice were examined by immunocytochemical methods to determine the localization of dystrophin in polar and equatorial regions of the intrafusal fibers. Spindles were serially sectioned in transverse and longitudinal planes, and were double-labelled with an antibody to dystrophin and with an antibody to a 200 kD neurofilament protein, which revealed their sensory innervation. By fluorescence microscopy, intrafusal fibers in the soleus of mdx mice were deficient in dystrophin throughout their lengths, whereas their sensory nerve terminals stained intensely with the nerve-specific antibody and appeared unaltered in dystrophy. In the normal soleus, intrafusal fibers displayed a regional variability in the distribution of dystrophin. Polar regions of bag and chain fibers exhibited a peripheral rim of sarcolemmal staining equivalent to that seen in the neighboring extrafusal fibers. Dystrophin labelling in equatorial regions of normal intrafusal fibers, however, showed dystrophin-deficient segments alternating in a spiral fashion with positive-staining domains along the sarcolemma. Double-labelling for dystrophin and neurofilament protein showed that these dystrophin-deficient sites were subjacent to the annulospiral sensory nerve wrappings terminating on the intrafusal fibers. These findings suggest that dystrophin is not an integral part of the subsynaptic sensory membrane in equatorial regions of normal intrafusal fibers and thus is not directly related to sensory signal transduction. The complete absence of this protein in mdx intrafusal fibers indicates that these fibers exhibit the same primary defect in muscular dystrophy as seen in the extrafusal fibers. However, because of their small diameters, capsular investment, and relatively low tension outputs, dystrophic intrafusal fibers may be less prone to the sarcolemmal membrane disruption that is characteristic of extrafusal fibers in this disorder. © 1993 Wiley-Liss, Inc.