Expression of the putative Duchenne muscular dystrophy gene in differentiated myogenic cell cultures and in the brain

Cerebellar dysfunction in the mdx mouse model of Duchenne muscular dystrophy: An electrophysiological and behavioural study

Patients with Duchenne muscular dystrophy (DMD) commonly show specific cognitive deficits in addition to a severe muscle impairment caused by the absence of dystrophin expression in skeletal muscle. These cognitive deficits have been related to the absence of dystrophin in specific regions of the central nervous system, notably cerebellar Purkinje cells (PCs). Dystrophin has recently been involved in GABAA receptors clustering at postsynaptic densities, and its absence, by disrupting this clustering, leads to decreased inhibitory input to PC. We performed an in vivo electrophysiological study of the dystrophin-deficient muscular dystrophy X-linked (mdx) mouse model of DMD to compare PC firing and local field potential (LFP) in alert mdx and control C57Bl/10 mice. We found that the absence of dystrophin is associated with altered PC firing and the emergence of fast (~160-200 Hz) LFP oscillations in the cerebellar cortex of alert mdx mice. These abnormalities were not related to the disrupted expression of calcium-binding proteins in cerebellar PC. We also demonstrate that cerebellar long-term depression is altered in alert mdx mice. Finally, mdx mice displayed a force weakness, mild impairment of motor coordination and balance during behavioural tests. These findings demonstrate the existence of cerebellar dysfunction in mdx mice. A similar cerebellar dysfunction may contribute to the cognitive deficits observed in patients with DMD.

Farewell to Professor David Yaffe - A pillar of the myogenesis field

It is with great sadness that we have learned about the passing of Professor David Yaffe (1929-2020, Israel). Yehi Zichro Baruch - May his memory be a blessing. David was a man of family, science and nature. A native of Israel, David grew up in the historic years that preceded the birth of the State of Israel. He was a member of the group that established Kibbutz Revivim in the Negev desert, and in 1948 participated in Israel's War of Independence. David and Ruth eventually joined Kibbutz Givat Brenner by Rehovot, permitting David to be both a kibbutz member and a life-long researcher at the Weizmann Institute of Science, where David received his PhD in 1959. David returned to the Institute after his postdoc at Stanford. Here, after several years of researching a number of tissues as models for studying the process of differentiation, David entered the myogenesis field and stayed with it to his last day. With his dedication to the field of myogenesis and his commitment to furthering the understanding of the People and the Land of Israel throughout the international scientific community, David organized the first ever myogenesis meeting that took place in Shoresh, Israel in 1975. This was followed by the 1980 myogenesis meeting at the same place and many more outstanding meetings, all of which brought together myogenesis, nature and scenery. Herein, through the preparation and publication of this current manuscript, we are meeting once again at a "David Yaffe myogenesis meeting". Some of us have been members of the Yaffe lab, some of us have known David as his national and international colleagues in the myology field. One of our contributors has also known (and communicates here) about David Yaffe's earlier years as a kibbutznick in the Negev. Our collective reflections are a tribute to Professor David Yaffe. We are fortunate that the European Journal of Translational Myology has provided us with tremendous input and a platform for holding this 2020 distance meeting "Farwell to Professor David Yaffe - A Pillar of the Myogenesis Field".

Splicing therapy for neuromuscular disease

Duchenne muscular dystrophy (DMD) and spinal muscular atrophy (SMA) are two of the most common inherited neuromuscular diseases in humans. Both conditions are fatal and no clinically available treatments are able to significantly alter disease course in either case. However, by manipulation of pre-mRNA splicing using antisense oligonucleotides, defective transcripts from the DMD gene and from the SMN2 gene in SMA can be modified to once again produce protein and restore function. A large number of in vitro and in vivo studies have validated the applicability of this approach and an increasing number of preliminary clinical trials have either been completed or are under way. Several different oligonucleotide chemistries can be used for this purpose and various strategies are being developed to facilitate increased delivery efficiency and prolonged therapeutic effect. As these novel therapeutic compounds start to enter the clinical arena, attention must also be drawn to the question of how best to facilitate the clinical development of such personalised genetic therapies and how best to implement their provision.

Distribution of dystrophin- and utrophin-associated protein complexes (DAPC/UAPC) in human hematopoietic stem/progenitor cells

Hematopoietic stem cells (HSC) are defined by their cardinal properties, such as sustained proliferation, multilineage differentiation, and self-renewal, which give rise to a hierarchy of progenitor populations with more restricted potential lineage, ultimately leading to the production of all types of mature blood cells. HSC are anchored by cell adhesion molecules to their specific microenvironment, thus regulating their cell cycle, while cell migration is essentially required for seeding the HSC of the fetal bone marrow (BM) during development as well as in adult BM homeostasis. The dystrophin-associated protein complex (DAPC) is a large group of membrane-associated proteins linking the cytoskeleton to the extracellular matrix and exhibiting scaffolding, adhesion, and signaling roles in muscle and non-muscle cells including mature blood cells. Because adhesion and migration are mechanisms that influence the fate of the HSC, we explored the presence and the feasible role of DAPC. In this study, we characterized the pattern expression by immunoblot technique and, by confocal microscopy analysis, the cellular distribution of dystrophin and utrophin gene products, and the dystrophin-associated proteins (α-, β-dystroglycan, α-syntrophin, α-dystrobrevin) in relation to actin filaments in freshly isolated CD34+ cells from umbilical cord blood. Immunoprecipitation assays demonstrated the presence of Dp71d/Dp71Δ110m ∼DAPC and Up400/Up140∼DAPC. The subcellular distribution of the two DAPC in actin-based structures suggests their dynamic participation in adhesion and cell migration. In addition, the particular protein pattern expression found in hematopoietic stem/progenitor cells might be indicative of their feasible participation during differentiation.

Integration of expressed sequence tag data flanking predicted RNA secondary structures facilitates novel non-coding RNA discovery

Many computational methods have been used to predict novel non-coding RNAs (ncRNAs), but none, to our knowledge, have explicitly investigated the impact of integrating existing cDNA-based Expressed Sequence Tag (EST) data that flank structural RNA predictions. To determine whether flanking EST data can assist in microRNA (miRNA) prediction, we identified genomic sites encoding putative miRNAs by combining functional RNA predictions with flanking ESTs data in a model consistent with miRNAs undergoing cleavage during maturation. In both human and mouse genomes, we observed that the inclusion of flanking ESTs adjacent to and not overlapping predicted miRNAs significantly improved the performance of various methods of miRNA prediction, including direct high-throughput sequencing of small RNA libraries. We analyzed the expression of hundreds of miRNAs predicted to be expressed during myogenic differentiation using a customized microarray and identified several known and predicted myogenic miRNA hairpins. Our results indicate that integrating ESTs flanking structural RNA predictions improves the quality of cleaved miRNA predictions and suggest that this strategy can be used to predict other non-coding RNAs undergoing cleavage during maturation.

Potential of oligonucleotide-mediated exon-skipping therapy for Duchenne muscular dystrophy

Many of the mutations associated with Duchenne muscular dystrophy can potentially be rescued by exon-skipping therapy, targeting selected exons of prespliced mRNA for the dystrophin gene with antisense oligonucleotides, thereby restoring reading frames. The recent development of antisense oligonucleotides with higher stability and lower toxicity, such as morpholinos, has made it possible to restore dystrophin efficiently in dystrophic mice in vivo with no obvious side effects. There seems little doubt that such exon-skipping therapy is destined to proceed to the clinical application stage in patients with Duchenne muscular dystrophy. One of the remaining issues to be addressed is the skipping of multiple exons because such multi-exon skipping therapy could expand the potential patient target population to include 80% of those with duplication mutations and 90% of those with deletion mutations. At present, this multi-exon skipping strategy is being investigated in dystrophic dogs as well as dystrophic mice. There are several challenges that still need to be overcome, including the low uptake of antisense oligonucleotides into the heart and the need to design efficient, nontoxic, cost-effective oligonucleotides. This review summarizes recent progress in exon-skipping therapy and discusses future perspectives with regard to human clinical trials.

Association of Duchenne muscular dystrophy with autism spectrum disorder

We hypothesize that Duchenne muscular dystrophy and autism spectrum disorder/pervasive developmental disorder co-occur with a greater than random frequency. In this study, we set out to reject the hypothesis that Duchenne muscular dystrophy and autism spectrum disorder/pervasive developmental disorder co-occur no more often than expected by chance. Two index cases and six additional boys with concomitant Duchenne muscular dystrophy and autism spectrum disorder were identified in a muscular dystrophy clinic that approximates the total number of Duchenne muscular dystrophy boys (158) in the state of Massachusetts. The rate of prevalence (6 of 158) was compared with the prevalence rate of autism spectrum disorder in boys in the general population (1.6 in 1,000). We rejected the hypothesis that Duchenne muscular dystrophy and autism spectrum disorder co-occurrence was likely to be explained by chance (P = .006). We identify a previously unrecognized association of Duchenne muscular dystrophy with autism spectrum disorder. Further work might elucidate the level of association between these two conditions, either at the genetic or at the protein level, and might clarify, at least partially, the neurobiologic mechanisms associated with autism spectrum disorder.

Dystrophin Dp71 Expression Is Down-regulated during Myogenesis

Dp71 expression is present in myoblasts but declines during myogenesis to avoid interfering with the function of dystrophin, the predominant Duchenne muscular dystrophy gene product in differentiated muscle fibers. To elucidate the transcriptional regulatory mechanisms operating on the developmentally regulated expression of Dp71, we analyzed the Dp71 expression and promoter activity during myogenesis of the C2C12 cells. We demonstrated that the cellular content of Dp71 transcript and protein decrease in myotubes as a consequence of the negative regulation that the differentiation stimulus exerts on the Dp71 promoter. Promoter deletion analysis showed that the 224-bp 5'-flanking region, which contains several Sp-binding sites (Sp-A to Sp-D), is responsible for the Dp71 promoter basal activity in myoblasts as well as for down-regulation of the promoter in differentiated cells. Electrophoretic mobility shift and chromatin immunoprecipitation assays indicated that Sp1 and Sp3 transcription factors specifically bind to the Sp-binding sites in the minimal Dp71 promoter region. Site-directed mutagenesis assay revealed that Sp-A is the most important binding site for the proximal Dp71 promoter activity. Additionally, cotransfection of the promoter construct with Sp1- and Sp3-expressing vectors into Drosophila SL2 cells, which lack endogenous Sp family, confirmed that these proteins activate specifically the minimal Dp71 promoter. Endogenous Sp1 and Sp3 proteins were detected only in myoblasts and not in myotubes, which indicates that the lack of these factors causes down-regulation of the Dp71 promoter activity in differentiated cells. In corroboration, efficient promoter activity was restored in differentiated muscle cells by exogenous expression of Sp1 and Sp3.

Improved antisense oligonucleotide induced exon skipping in the mdx mouse model of muscular dystrophy

BACKGROUND

Duchenne muscular dystrophy (DMD) is a fatal genetic disorder caused by dystrophin gene mutations that preclude synthesis of a functional protein. One potential treatment of the disorder has utilised antisense oligoribonucleotides (AOs) to induce removal of disease-associated exons during pre-mRNA processing. Induced in-frame mRNA transcripts encode a shorter but functional dystrophin. We have investigated and improved the design of AOs capable of removing exon 23, and thus the disease-causing nonsense mutation, from mRNA in the mdx mouse model of DMD.

METHODS

H-2K(b)-tsA58 mdx cultures were transfected with complexes of Lipofectin and AOs. Exon skipping was detected by RT-PCR and subsequent protein production was demonstrated by Western blotting. AOs were delivered at a range of doses in order to compare relative efficiencies.

RESULTS

We describe effective and reproducible exon 23 skipping with several AOs, including one as small as 17 nucleotides. Furthermore, the location of a sensitive exon 23 target site has been refined, whilst minimum effective doses have been estimated in vitro. These doses are significantly lower than previously reported and were associated with the synthesis of dystrophin protein in vitro.

CONCLUSIONS

These results demonstrate the increasing feasibility of an AO-based therapy for treatment of DMD. By refining AO design we have been able to reduce the size and the effective dose of the AOs and have dramatically improved the efficiency of the technique.

The role of utrophin in the potential therapy of Duchenne muscular dystrophy

Duchenne muscular dystrophy is an X-linked recessive muscle wasting disease caused by the absence of the muscle cytoskeletal protein, dystrophin. Dystrophin is a member of the spectrin superfamily of proteins and is closely related in sequence similarity and functional motifs to three proteins that constitute the dystrophin related protein family, including the autosomal homologue, utrophin. An alternative strategy circumventing many problems associated with somatic gene therapies for Duchenne muscular dystrophy has arisen from the demonstration that utrophin can functionally substitute for dystrophin and its over-expression in muscles of dystrophin-null transgenic mice completely prevents the phenotype arising from dystrophin deficiency. One potential approach to increase utrophin levels in muscle for possible therapeutic purpose in humans is to increase expression of the utrophin gene at a transcriptional level via promoter activation. This has lead to an interest in the identification and manipulation of important regulatory regions and/or molecules that increase the expression of utrophin and their delivery to dystrophin-deficient tissue. As pre-existing cellular mechanisms are utilized, this approach would avoid many problems associated with conventional gene therapies.

The utrophin gene is transcriptionally up-regulated in regenerating muscle

The utrophin gene codes for a large cytoskeletal protein closely related to dystrophin, the gene mutated in Duchenne's muscular dystrophy. Although utrophin could functionally substitute for dystrophin, in Duchenne's muscular dystrophy patients it did not compensate for the absence of dystrophin because in adult muscle utrophin was poorly expressed and limited to subsynaptic nuclei. However, increased levels of utrophin have been observed in regenerated muscles fibers suggesting that utrophin up-regulation in muscle is feasible. We observed that utrophin mRNA was transiently up-regulated at early time points after muscle injury with a peak already 24 h after muscle damage and utrophin induction in activated satellite cells before fusion into young regenerated fibers. Injection of utrophin lacZ constructs into regenerating muscle demonstrated that the utrophin upstream promoter under the control of its intronic enhancer activated the transcription that leads to the expression of the reporter gene in the newly formed fibers, which was not limited to neuromuscular junctions. Utrophin enhancer activity was dependent on an AP-1 site, and in satellite cells of regenerating muscle the AP-1 factors Fra1, Fra2, and JunD were strongly induced. These results establish that utrophin was induced in adult muscle independently from neuromuscular junctions and suggest that growth factors and cytokines that mediate the muscle repair up-regulate utrophin transcription.

Regulation and functional significance of utrophin expression at the mammalian neuromuscular synapse

Duchenne muscular dystrophy (DMD) is caused by the absence of full-length dystrophin molecules in skeletal muscle fibers. In normal muscle, dystrophin is found along the length of the sarcolemma where it links the intracellular actin cytoskeleton to the extracellular matrix, via the dystrophin-associated protein (DAP) complex. Several years ago, an autosomal homologue to dystrophin, termed utrophin, was identified and shown to be expressed in a variety of tissues, including skeletal muscle. However, in contrast to the localization of dystrophin in extrajunctional regions of muscle fibers, utrophin preferentially accumulates at the postsynaptic membrane of the neuromuscular junction in both normal and DMD adult muscle fibers. Since it has recently been suggested that the upregulation of utrophin might functionally compensate for the lack of dystrophin in DMD, considerable interest is now directed toward the elucidation of the various regulatory mechanisms presiding over expression of utrophin in normal and dystrophic skeletal muscle fibers. In this review, we discuss some of the most recent data relevant to our understanding of the impact of myogenic differentiation and innervation on the expression and localization of utrophin in skeletal muscle fibers.

Expression of the utrophin gene during myogenic differentiation

The process of myogenic differentiation is known to be accompanied by large increases ( approximately 10-fold) in the expression of genes encoding cytoskeletal and membrane proteins including dystrophin and the acetylcholine receptor (AChR) subunits, via the effects of transcription factors belonging to the MyoD family. Since in skeletal muscle (i) utrophin is a synaptic homolog to dystrophin, and (ii) the utrophin promoter contains an E-box, we examined, in the present study, expression of the utrophin gene during myogenic differentiation using the mouse C2 muscle cell line. We observed that in comparison to myoblasts, the levels of utrophin and its transcript were approximately 2-fold higher in differentiated myotubes. In order to address whether a greater rate of transcription contributed to the elevated levels of utrophin transcripts, we performed nuclear run-on assays. In these studies we determined that the rate of transcription of the utrophin gene was approximately 2-fold greater in myotubes as compared to myoblasts. Finally, we examined the stability of utrophin mRNAs in muscle cultures by two separate methods: following transcription blockade with actinomycin D and by pulse-chase experiments. Under these conditions, we determined that the half-life of utrophin mRNAs in myoblasts was approximately 20 h and that it remained largely unaffected during myogenic differentiation. Altogether, these results show that in comparison to other synaptic proteins and to dystrophin, expression of the utrophin gene is only moderately increased during myogenic differentiation.

Impairments in learning and memory accompanied by neurodegeneration in mice transgenic for the carboxyl-terminus of the amyloid precursor protein

In Alzheimer's disease (AD), a progressive decline of cognitive functions is accompanied by neuropathology that includes the degeneration of neurons and the deposition of amyloid in plaques and in the cerebrovasculature. We have proposed that a fragment of the Alzheimer amyloid precursor protein (APP) comprising the carboxyl-terminal 100 amino acids of this molecule (APP-C100) plays a crucial role in the neurodegeneration and subsequent cognitive decline in AD. To test this hypothesis, we performed behavioral analyses on transgenic mice expressing APP-C100 in the brain. The results revealed that homozygous APP-C100 transgenic mice were significantly impaired in cued, spatial and reversal performance of a Morris water maze task, that the degree of the impairment in the spatial learning was age-dependent, and that the homozygous mice displayed significantly more degeneration of neurons in Ammon's horn of the hippocampal formation than did heterozygous or control mice. Among the heterozygotes, females were relatively more impaired in their spatial learning than were males. These findings show that expression of APP-C100 in the brain can cause age-dependent cognitive impairments that are accompanied by hippocampal degeneration.

Dystrophin isoforms DP71 and DP427 have distinct roles in myogenic cells

Duchenne muscular dystrophy is caused by mutations in the dystrophin gene, a complex gene that generates a family of distinct isoforms. In immature muscle cells, two dystrophin isoforms are expressed, Dp427 and Dp71. To characterize the function of Dp71 in myogenesis, we have examined the expression of Dp71 in myogenic cells. The localization of Dp71 in these cells is distinct from the localization of Dp427. Whereas Dp427 localizes to focal adhesions and surface membrane during myogenesis, Dp71 localizes to stress fiberlike structures in myogenic cells. Biochemical fractionation of myogenic cells demonstrates that Dp71 cosediments with the actin bundles thus confirming this interaction. Furthermore, transfection of C2C12 myoblasts with constructs encoding Dp71 fused to green fluorescent protein targeted the protein to the actin microfilament bundles. These results demonstrate involvement of Dp71 with the actin cytoskeleton during myogenesis and suggest a role for Dp71 that is distinct from Dp427.

The dystrophin promoter is negatively regulated by YY1 in undifferentiated muscle cells

The dystrophin gene transcription is up-regulated during muscle cell differentiation. Its expression in muscle cells is induced by the binding of the positive regulators serum response factor and dystrophin promoter bending factor (DPBF) on a regulatory CArG element present on the promoter. Here we show that the dystrophin CArG box is also recognized by the zinc finger nuclear factor YY1. Transient transfection experiments show that YY1 negatively regulates dystrophin transcription in C2C12 muscle cells. On the dystrophin CArG element YY1 competes with the structural factor DPBF. We further show that YY1 and DPBF binding to the CArG element induce opposite DNA bends suggesting that their binding induces alternative promoter structures. Along with C2C12 myotube formation YY1 is reduced and we observed that YY1, but not DPBF, is a substrate of m-calpain, a protease that is up-regulated in muscle cell differentiation. Thus, high levels of YY1 in non-differentiated muscle cells down-regulate the dystrophin promoter, at least in part, by interfering with the spatial organization of the promoter.

Challenges in Duchenne muscular dystrophy

The last seven years has witnessed an explosion in our understanding of the muscular dystrophies. In the early 1980s, prenatal diagnosis of Duchenne muscular dystrophy was developed. The cloning of the gene, in 1996, resulted in a better understanding of the disease process and led to the identification of a novel complex at the membrane. This information led to the cloning of other genes responsible for the autosomally inherited dystrophies. As we approach the millenium, the challenge is shifting to the development of therapy of these diseases. This review, in honour of Professor Alan Emery, explains how these advances have an impact in the clinical management of patients and head the promise the progress holds for the future.

The fate of individual myoblasts after transplantation into muscles of DMD patients

Muscle biopsies from six patients with Duchenne muscular dystrophy (DMD) participating in a myoblast transplantation clinical trial were reexamined using a fluorescence in situ hybridization (FISH)-based method. Donor nuclei were detected in all biopsies analyzed, including nine where no donor myoblasts were previously thought to be present. In three patients, more than 10% of the original number of donor cells were calculated as present 6 months after implantation. Half of the detected donor nuclei were fused into host myofibers, and of these, nearly 50% produced dystrophin. These findings demonstrate that although donor myoblasts have persisted after injection, their microenvironment influences whether they fuse and express dystrophin. Our methodology could be used for developing new approaches to improve myoblast transfer efficacy and for the analysis of future gene- and/or cell-based therapies of numerous genetic disorders.

Increased cerebral choline-compounds in Duchenne muscular dystrophy

We investigated the hypothesis that cell membrane function is abnormal in brains of subjects with Duchenne muscular dystrophy (DMD) using proton-nuclear magnetic resonance (NMR) spectroscopy of human brain extracts. The total amount of choline-containing compounds was significantly higher (about three times) than in normal controls and patients with other myopathies, while N-acetyl-L-aspartic acid and creatine were within the normal range. These findings indicate that abnormal cell membrane function may be correlated with the abnormal dystrophin or lack of dystrophin in the brain of patients with DMD.

Serum response factor and protein-mediated DNA bending contribute to transcription of the dystrophin muscle-specific promoter

The minimal muscle-specific dystrophin promoter contains the consensus sequence CC(A/T)6GG, or the CArG element, which can be found in serum-inducible or muscle-specific promoters. The serum response factor (SRF), which mediates the transcriptional activation of the c-fos gene in response to serum stimulation, can bind to different CArG box elements, suggesting that it could be involved in muscle-constitutive transcription. Here we show that SRF binds to the dystrophin promoter and regulates its muscle-specific transcription. In transient transfections, an altered-binding-specificity SRF mutant restores the muscle-constitutive transcription of a dystrophin promoter with a mutation in its CArG box element. The muscle-constitutive transcription of the dystrophin promoter also requires the sequence GAAACC immediately downstream of the CArG box. This sequence is recognized by a novel DNA bending factor which was named dystrophin promoter-bending factor (DPBF). Mutations of the CArG flanking sequence abolish both DPBF binding and the promoter activity in muscle cells. Its replacement with a p62/ternary complex factor binding site changes the promoter specificity from muscle constitutive to serum responsive. These results show that, on the dystrophin promoter, the transcriptional activation induced by SRF requires the DNA bending induced by DPBF. The bending, next to the CArG box, could promote interactions between SRF and other proteins in the transcriptional complex.

A critical evaluation of resting intracellular free calcium regulation in dystrophic mdx muscle

There are conflicting reports regarding whether resting free calcium levels ([Ca2+]i) are elevated in dystrophic mouse (mdx) myotubes and adult myofibers. We reinvestigated this question and found several lines of evidence supporting the hypothesis that increased calcium influx via leak channels leads to increases in resting [Ca2+]i. 1) Step calibration of fura 2/free acid in myofibers with use of microinjected Ca(2+)-ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid buffers revealed greater [Ca2+]i in dystrophic cells. Careful calibration of fura PE3-AM, a compartmentalization-resistant derivative of fura 2, also showed elevated [Ca2+]i in mdx myotubes. 2) Chronic, but not acute, application of tetrodotoxin reduced resting [Ca2+]i in dystrophic myotubes, suggesting that elevated resting [Ca2+]i is a consequence of previous long-term contractile activity. 3) Rates of manganese quenching of fura 2 fluorescence, an indirect indicator of calcium influx, were significantly higher in mdx myotubes and were increased by nifedipine, a calcium leak channel agonist. 4) Calcium leak channel activity, measured using patch clamping, was greater in the sarcolemma of adult non-enzyme-treated mdx myofibers.

An in vivo and in vitro H-magnetic resonance spectroscopy study of mdx mouse brain: abnormal development or neural necrosis?

Duchenne muscular dystrophy (DMD) is an X-linked genetic disorder primarily affecting young boys, often causing mental retardation in addition to the well-known progressive muscular weakness. Normal dystrophin expression is lacking in skeletal muscle and the central nervous system (CNS) of both DMD children and the mdx mouse model. The underlying biochemical lesion causing mental impairment in DMD is unknown. 1H-magnetic resonance spectroscopy (1H-MRS) detects choline-containing compounds, creatine and N-acetyl aspartate (NAA) in vivo. NAA is commonly used as a chemical marker for neurons, and a decline in NAA is thought to correlate with neuronal loss. Control mice were compared to mdx using a combination of in vivo and in vitro 1H-MRS methods to determine whether neural necrosis or developmental abnormalities occur in dystrophic brain. NAA levels were normal in mdx brain compared to controls suggesting minor, if any, neuronal necrosis in dystrophic brain. In contrast, choline compounds and myo-inositol levels were increased, indicative of gliosis or developmental abnormalities in dystrophic brain.

Expression of dystrophin Dp71 during PC12 cell differentiation

The expression of dystrophin-protein 71 (Dp71) was investigated during nerve growth factor (NGF) induced differentiation of PC12 cells. A semi-quantitative reverse transcription-polymerase chain reaction (RT-PCR) assay was designed to measure Dp71 mRNA, whereas the Dp71 protein amount was evaluated by immunoblot analysis using an anti-dystrophin monoclonal antibody. Comparison with control cultures showed that Dp71 mRNA and protein levels increased in parallel with NGF treatment peaking with increments of 60% and 1.4 times, respectively. The upregulation of Dp71 expression during PC12 cells differentiation point at PC12 cells as a suitable model for studying the function of Dp71 in neuronal cells.

Stability of the human dystrophin transcript in muscle

The human dystrophin gene has 79 exons spanning >2300 kb making it the largest known gene. In previous studies we showed that approximately 16 h are required to transcribe the gene in myogenic cultures [Tennyson, C.N., Klamut, H.J. and Worton, R.G. (1995) Nature Genet. 9, 184-190]. To estimate the half-life of the dystrophin mRNA, the decay of the transcript was monitored by quantitative RT-PCR in cultured human fetal myotubes following exposure to actinomycin D. Results from this analysis indicated that the half-life of the dystrophin mRNA is 15.6 +/- 2.8 h in these cultures. Transcript accumulation profiles were predicted using a mathematical model which incorporated the measured half-life. The modeled accumulation profiles were consistent with observed profiles supporting the half-life measured using actinomycin D. The kinetic model was then used to predict the relative amount of nascent and mature dystrophin transcript at steady state. Measurements by quantitative RT-PCR indicated that in adult skeletal muscle tissue the concentration of mature dystrophin mRNA is 5-10 molecules per nucleus, demonstrating, as expected, that it is a low abundance transcript. Furthermore the ratio of nascent to mature dystrophin transcript indicated that dystrophin synthesis may not be at steady state in the adult skeletal muscle we tested. Alternatively, the kinetics of transcript production in skeletal muscle tissue may be different from those observed in cultured fetal myogenic cells.

Early postnatal muscle contractile activity regulates the carbonic anhydrase phenotype of proprioceptive neurons in young and mature mice: evidence for a critical period in development

Carbonic anhydrase activity, a marker of mouse proprioceptive neurons in adult dorsal root ganglia, is first detectable in the perinatal period, increases until postnatal day 60 and remains stable in adulthood. The onset of carbonic anhydrase staining begins after the neurons have made connections with their targets suggesting that neuron-target interactions regulate carbonic anhydrase phenotype development. To examine this possibility, we first analysed carbonic anhydrase expression in mdx mice which are characterized by a massive but reversible degeneration of skeletal muscle concomitant with the carbonic anhydrase ontogenesis. Neuronal carbonic anhydrase expression in mdx mice stopped developing when the period of muscular degeneration-regeneration began. Furthermore this alteration persisted during adulthood. We then analysed carbonic anhydrase expression in fifth lumbar dorsal root ganglion of developing control mice before and after surgical procedures that might interfere with central and peripheral target influences on dorsal root ganglion neurons. Central disconnection (dorsal rhizotomy) did not affect the development of carbonic anhydrase activity. Disrupting neuron-peripheral target interactions by sciatic nerve transection or blocking muscle contraction by tenotomy stopped the development of neuronal carbonic anhydrase content. Finally, recovery was monitored following sciatic nerve crush. In adults, recovery of carbonic anhydrase activity was obtained after functional recuperation; similar manipulations during the first month of life induced irreversible alteration of the carbonic anhydrase phenotype. These results show that the development of carbonic anhydrase activity in proprioceptive neurons is regulated by neuron-muscle interactions (i.e. muscle contraction). They also provide evidence for a critical period in the development of the carbonic anhydrase phenotype. We suggest that these two mechanisms are responsible for the altered carbonic anhydrase phenotype of the dorsal root ganglion neurons in mdx mice, a model of human muscular dystrophy.

Deficiency of brain synaptic dystrophin in human Duchenne muscular dystrophy

Duchenne muscular dystrophy (DMD) is characterized by a defect in dystrophin, a high molecular weight protein that is located predominantly in muscle, but which has been detected in brain. Brain dystrophin has been localized to the synapse, in the postsynaptic density (PSD), and is absent in the mdx mouse, an animal model of human DMD. To define the potential pathogenic role of dystrophin deficiency in cognitive impairment, we examined the protein in human DMD brain. The 427-kd dystrophin was absent in the PSD from DMD brain, but was normally expressed in the brain from an age-matched control subject. Our findings indicate that dystrophin is deficient in human DMD cortical synapses and provide a potential pathogenic mechanism for cognitive impairment.

Rapsyn may function as a link between the acetylcholine receptor and the agrin-binding dystrophin-associated glycoprotein complex

The 43 kDa AChR-associated protein rapsyn is required for the clustering of nicotinic acetylcholine receptors (AChRs) at the developing neuromuscular junction, but the functions of other postsynaptic proteins colocalized with the AChR are less clear. Here we use a fibroblast expression system to investigate the role of the dystrophin-glycoprotein complex (DGC) in AChR clustering. The agrin-binding component of the DGC, dystroglycan, is found evenly distributed across the cell surface when expressed in fibroblasts. However, dystroglycan colocalizes with AChR-rapsyn clusters when these proteins are coexpressed. Furthermore, dystroglycan colocalizes with rapsyn clusters even in the absence of AChR, indicating that rapsyn can cluster dystroglycan and AChR independently. Immunofluorescence staining using a polyclonal antibody to utrophin reveals a lack of staining of clusters, suggesting that the immunoreactive species, like the AChR, does not mediate the observed rapsyndystroglycan interaction. Rapsyn may therefore be a molecular link connecting the AChR to the DGC. At the neuromuscular synapse, rapsyn-mediated linkage of the AChR to the cytoskeleton-anchored DGC may underlie AChR cluster stabilization.

Developmental studies of dystrophin and other cytoskeletal proteins in cultured muscle cells

We studied the developmental changes of localization of dystrophin and other cytoskeletal proteins, especially actin, spectrin and dystrophin related protein (DRP) using immunocytochemistry and quick-freezing and deep-etching (QF-DE) method. In developmental studies of mouse and human muscle cultures, some myoblasts had positive-reactions to spectrin, DRP, and F-actin, but not dystrophin. In aneurally cultured myotubes, dystrophin, DRP, and spectrin were localized diffusely in the cytoplasm and later in discontinuous patterns on the plasma membrane, when myotubes became mature. Spectrin and DRP had more positive reactions in immature myotubes, compared with those of dystrophin. In some areas of myotubes, dystrophin/spectrin and spectrin/actin were localized reciprocally. In innervated cultured human muscle cells, dystrophin and DRP were localized in neuro-muscular junctions, which were co-localized with clusters of acetylcholine receptors. By using the QF-DE method, dystrophin was localized just underneath the plasma membrane, and closely linked to actin-like filaments (8-10 nm in diameter), most of which were decorated with myosin subfragment 1. In actin-poor regions, spectrin was detected as well-organized filamentous structures in highly interconnected networks with various diameters. DRP was distributed irregularly with granular appearance inside the cytoplasm and also under the plasma membrane in immature mouse myotubes. Our present studies show that dystrophin, spectrin, and DRP are localized differently at the developmental stages of myotubes. These results suggest that dystrophin, spectrin, and DRP are organized independently in developing myotubes and these cytoskeletal proteins might play different functions in the preservation of plasma membrane stability in developing myotubes.

Association of aciculin with dystrophin and utrophin

Aciculin is a recently identified 60-kDa cytoskeletal protein, highly homologous to the glycolytic enzyme phosphoglucomutase type 1, (Belkin, A. M., Klimanskaya, I. V., Lukashev, M. E., Lilley, K., Critchley, D., and Koteliansky, V. E. (1994) J. Cell Sci. 107, 159-173). Aciculin expression in skeletal muscle is developmentally regulated, and this protein is particularly enriched at cell-matrix adherens junctions of muscle cells (Belkin, A. M., and Burridge, K. (1994) J. Cell Sci. 107, 1993-2003). The purpose of our study was to identify cytoskeletal protein(s) interacting with aciculin in various cell types. Using immunoprecipitation from cell lysates of metabolically labeled differentiating C2C12 muscle cells with anti-aciculin-specific antibodies, we detected a high molecular weight band (M(r) approximately 400,000), consistently coprecipitating with aciculin. We showed that this 400 kDa band comigrated with dystrophin and immunoblotted with anti-dystrophin antibodies. The association between aciculin and dystrophin in C2C12 cells was shown to resist Triton X-100 extraction and the majority of the complex could be extracted only in the presence of ionic detergents. In the reverse immunoprecipitation experiments, aciculin was detected in the precipitates with different anti-dystrophin antibodies. Immunodepletion experiments with lysates of metabolically labeled C2C12 myotubes showed that aciculin is a major dystrophin-associated protein in cultured skeletal muscle cells. Double immunostaining of differentiating and mature C2C12 myotubes with antibodies against aciculin and dystrophin revealed precise colocalization of these two cytoskeletal proteins throughout the process of myodifferentiation in culture. In skeletal muscle tissue, both proteins are concentrated at the sarcolemma and at myotendinous junctions. In contrast, utrophin, an autosomal homologue of dystrophin, was not codistributed with aciculin in muscle cell cultures and in skeletal muscle tissues. Analytical gel filtration experiments with purified aciculin and dystrophin showed interaction of these proteins in vitro, indicating that their association in skeletal muscle is due to direct binding. Whereas dystrophin was shown to be a major aciculin-associated protein in skeletal muscle, immunoblotting of anti-aciculin immunoprecipitates with antibodies against utrophin showed that aciculin is associated with utrophin in cultured A7r5 smooth muscle cells and REF52 fibroblasts. Immunodepletion experiments performed with lysates of metabolically labeled A7r5 cells demonstrated that aciculin is a major utrophin-binding protein in this cell type. Taken together, our data show that aciculin is a novel dystrophin- and utrophin-binding protein. Association of aciculin with dystrophin (utrophin) in various cell types might provide an additional cytoskeletal-matrix transmembrane link at sites where actin filaments terminate at the plasma membrane.

The effect of glucocorticoids on the accumulation of utrophin by cultured normal and dystrophic human skeletal muscle satellite cells

Human muscle cultures undergo a long-term loss of myotubes and a decline in dystrophin content, which can be prevented by glucocorticoid treatment of the cultures. We confirmed these findings and extended them to show that the utrophin content of control and dexamethasone-treated normal myotube cultures is not significantly different. In contrast to normal cultures, the utrophin content of long-term dexamethasone-treated DMD myotube cultures was significantly greater than that of the corresponding untreated cultures. Utrophin mRNA transcript levels normalized to total poly (A) were unaffected by dexamethasone treatment of either normal or DMD myotube cultures, suggesting the effect of dexamethasone on utrophin accumulation by DMD cultures is mediated post-transcriptionally. A combination of an increase in myotube numbers and lack of competition with dystrophin for membrane-binding sites in DMD myotubes may explain the distinct effects of dexamethasone on utrophin levels in normal and DMD cultures.

The human dystrophin gene requires 16 hours to be transcribed and is cotranscriptionally spliced

The largest known gene is the human dystrophin gene, which has 79 exons spanning at least 2,300 kilobases (kb). Transcript accumulation was monitored from four regions of the gene following induction of expression in muscle cell cultures. Quantitative reverse transcription-polymerase chain reaction (RT-PCR) results indicate that approximately 12 h are required for transcription of 1,770 kb (at an average elongation rate of 2.4 kb min-1), extrapolating to a transcription time of 16 h for the complete gene. Accumulation profiles for spliced and total transcript demonstrated that transcripts are spliced at the 5' end before transcription is complete providing strong evidence for cotranscriptional splicing. The rate of transcript accumulation was reduced at the 3' end of the gene relative to the 5' end, perhaps due to premature termination of transcription complexes.

Mechanosensitive ion channels in skeletal muscle from normal and dystrophic mice

1. We examined the activity of single mechanosensitive ion channels in recordings from cell-attached patches on myoblasts, differentiated myotubes and acutely isolated skeletal muscle fibres from wild-type and mdx and dy mutant mice. The experiments were concerned with the role of these channels in the pathophysiology of muscular dystrophy. 2. The predominant form of channel activity recorded with physiological saline in the patch electrode arose from an approximately 25 pS mechanosensitive ion channel. Channel activity was similar in undifferentiated myoblasts isolated from all three strains of mice. By contrast, channel activity in mdx myotubes was approximately 3-4 times greater than in either wild-type or dy myotubes and arose from a novel mode of mechanosensitive gating. 3. Single mechanosensitive channels in acutely isolated flexor digitorum brevis fibres had properties indistinguishable from those of muscle cells grown in tissue culture. The channel open probability in mdx fibres was approximately 2 times greater than the activity recorded from wild-type fibres. The overall level of activity in fibres, however, was roughly an order of magnitude smaller than in myoblasts or myotubes. 4. Histological examination of the flexor digitorum brevis fibres from mdx mice showed no evidence of myonecrosis or regenerating fibres, suggesting that the elevated channel activity in dystrophin-deficient muscle precedes the onset of fibre degeneration. 5. An early step in the dystrophic process of the mdx mouse, which leads to pathophysiological Ca2+ entry, may be an alteration in the mechanisms that regulate mechanosensitive ion channel activity.

Absence of dystrophin and spectrin in regenerating muscle fibers from Becker dystrophy patients

We studied muscle biopsies from 36 Becker muscular dystrophy patients, and correlated dystrophin negative fibers with regenerating and degenerating myofibers. Dystrophin immunohistochemistry was used to identify dystrophin-negative and dystrophin-positive fibers. Immunohistochemical staining for fetal myosin and acid ATPase identified regenerating fibers, and calcium glioxalate and beta-spectrin staining identified necrotic fibers. All Becker biopsies contained detectable dystrophin in the majority of muscle fibers. 13 cases (36%) showed no dystrophin negative fibers, 9 cases (25%) showed a generalized, markedly decreased immunostaining pattern, and 14 cases (39%) showed a subset of dystrophin negative fibers (0.3-8% of total). Most dystrophin-negative fibers in Becker muscle were judged to be in the process of regeneration, and not in degeneration. No correlation was observed between the age of the patients and number of dystrophin negative fibers. We conclude that the absence of dystrophin and spectrin labeling in some BMD myofibers is associated with regeneration, probably due to incomplete expression of dystrophin secondary to myofibers immaturity. Our results might be explained by a developmental delayed expression of these two proteins, or by abnormal assembling in membrane's components during regeneration in dystrophy. Furthermore, our results rationalize the recently reported finding of some dystrophin-negative fibers in polymyositis.

Characterization of the ocular phenotype of Duchenne and Becker muscular dystrophy

PURPOSE

Dystrophin, the Duchenne muscular dystrophy gene product, has been localized to the outer plexiform layer of normal human retina. The purpose of this study is to define completely the ocular phenotype associated with mutations at Xp21, the Duchenne muscular dystrophy gene locus.

METHODS

Twenty-one patients with a diagnosis of Duchenne muscular dystrophy and five patients with Becker muscular dystrophy had ophthalmologic examinations, including electroretinograms (ERGs). Electroretinogram results were correlated with respect to patient DNA analysis.

RESULTS

Twenty-three (88%) patients had reduced scotopic b-wave amplitudes to bright-white flash stimulus, including nine with negative-shaped ERGs. Rod-isolated responses were reduced or not recordable above noise in 14 (67%) patients. Most isolated cone responses (92%) were normal. Flicker amplitudes were reduced in seven patients. Two of these patients with proximal (5' end) deletions had normal scotopic b-waves to dim blue and bright-white flash stimulus. Patients with deletions toward the middle of the gene had greater reductions in their scotopic b-wave amplitudes than patients with deletions located toward the 5' end. Most patients had normal color vision, extraocular muscle function, and Snellen visual acuity. Increased macular pigmentation was seen in 16 patients with Duchenne muscular dystrophy.

CONCLUSION

Most patients with Duchenne or Becker muscular dystrophy have evidence of abnormal scotopic ERGs. Patients with deletions in the central region of the gene had the most severe ERG changes. This study supports previous suggestions that dystrophin may play a role in retinal neurotransmission. The presence of increased macular pigmentation and normal photopic ERGs distinguishes patients with Duchenne muscular dystrophy mutations from other X-linked retinal disorders with negative-shaped ERGs.

Dystrophin-related protein is found in the central nervous system of mice at various developmental stages, especially at the postsynaptic membrane

Dystrophin deficiency is known to be the cause of X-linked Duchenne muscular dystrophy (DMD). A recently cloned B3-cDNA shares 80% homology with the C-terminus and actin-binding portion of dystrophin. This autosome-derived gene product is called dystrophin-related protein (DRP). DRP is known to exist in fetal muscles even in mdx mice, an animal model for X-linked DMD, but not in mature mouse muscles. We raised a polyclonal antibody against a B3-unique amino acid sequence (Ab-LDP) and investigated the existence and distribution of DRP in the central nervous system (CNS) tissues of mdx and normal control B10 mice at various stages of development using immunoblotting and immunohistochemical methods. The former shows that DRP exists in the CNS of both B10 and mdx mice, regardless of the developmental stage, with the exception that the 420 kDa DRP band of the 15-day fetus is faint. In immunohistochemical studies, the choroid plexus, some neurons, glial cels, pia mater, and blood vessels were stained with Ab-LDP. Staining intensity did not differ between B10 and mdx mice or between developmental stages except that the 15-day fetus stained only faintly. This is in contrast to the results obtained for muscles in which DRP localized to muscle membrane in embryo decreases and is assembled at the neuromuscular junction in adults. In addition, an electron microscopic study on the cerebral cortex from adult B10 mice was also performed and revealed Ab-LDP staining of the postsynaptic membrane of dendrite and the rough endoplasmic reticulum of neurons.(ABSTRACT TRUNCATED AT 250 WORDS)

Detection of Duchenne muscular dystrophy gene products in amniotic fluid and chorionic villus sampling cells

We have examined the expression of several Duchenne muscular dystrophy (DMD) gene products in amniotic fluid (AF) and chorionic villus sampling (CVS) cells. Variable amounts of dystrophin could be detected in most CVS and AF samples by immunoprecipitation followed by Western blot analysis. PCR analysis demonstrated the presence of the muscle type dystrophin mRNA in all AF cell cultures. The brain type dystrophin mRNA was also detected in some of these cultures. These DMD gene transcripts are of fetal origin and are produced by most or all clonable AF cells. The results may facilitate the development of a method for prenatal diagnosis of DMD, based on the expression of the gene in AF and CVS cells.

Expression of the dystrophin-related protein (utrophin) gene during mouse embryogenesis

The utrophin (UTRN) locus is the autosomal homologue of the DMD (Duchenne muscular dystrophy) gene and encodes a protein, utrophin which is thought to be upregulated in the absence of dystrophin. In this study the spatial and temporal expression of the UTRN gene has been examined during mouse embryogenesis and compared with that of the DMD gene. The patterns of expression of these two genes are very different. Whilst DMD is expressed largely in mesodermal derivatives such as cardiac and striated muscle, UTRN shows a more widespread distribution and is expressed in neural tube, tissues which originate from neural crest and a variety of other sites of non-neural origin. In early embryos UTRN transcripts initially accumulate in the mid-neural plate and thereafter in the caudal neural tube. UTRN mRNA then becomes abundant in a subset of neural crest cell derived tissues, in particular the spinal and facial ganglia and ossifying facial cartilages. UTRN is also expressed in a variety of other sites and organs such as the tendon primordia in the digits, the pituitary, thyroid and adrenal glands, cardiac muscle, kidney and lung, follicles of the vibrissae and the outflow tract of the heart. Several patterns of UTRN expression are apparent and we discuss the possibility that these can be ascribed to a family of mRNAs transcribed from the UTRN gene using alternative promoters.

Dp71, the nonmuscle product of the Duchenne muscular dystrophy gene is associated with the cell membrane

The 70.8 kDa protein, Dp71, is the major Duchenne muscular dystrophy (DMD) gene product in many nonmuscle tissues including the brain. Dp71 shares most of the C-terminal and cysteine-rich domains with the dystrophins but lacks the entire large rod shaped domain of spectrin-like repeats, and the N-terminal actin-binding domain. The function of Dp71 is unknown. Using subcellular fractionation and immunostaining we show that Dp71 is associated with the plasma membrane. Dp71 is also associated with the plasma membrane in mdx myogenic cells transfected with a vector expressing Dp71.

Dystrophin and related proteins

During the past year significant progress has been made in understanding how dystrophin deficiency leads to muscle cell necrosis in Duchenne muscular dystrophy and Becker muscular dystrophy. Dystrophin interacts with a glycoprotein complex spanning the muscle sarcolemma, effectively linking the actin cytoskeleton to the extracellular matrix. The carboxyl terminus of dystrophin is required for glycoprotein binding. Interestingly, at least three mRNAs transcribed from the distal end of the DMD gene in tissues other than muscle have been shown to encode this domain. Deficiency of a second component of the dystrophin-associated glycoprotein complex has been shown to occur in another muscle-wasting disorder, severe childhood autosomal recessive muscular dystrophy. Sequence analysis of the entire cDNA for the autosomal dystrophin-related protein utrophin has shown that dystrophin and utrophin are closely related. Furthermore, both of these proteins have been shown to bind to the same or a similar glycoprotein complex in muscle.

The distribution of dystrophin in the murine central nervous system: an immunocytochemical study

A mild non-progressive cognitive defect is a feature of the fatal X-linked disease, Duchenne muscular dystrophy. Recent studies have identified the genetic defect and the resulting loss of the protein dystrophin, and shown that dystrophin messenger RNA and protein are present in normal brain tissue. We have performed western immunoblotting and fluorescence immunocytochemistry using a sensitive antibody made against a large fragment of the dystrophin molecule to study the regional, cellular and subcellular distribution of dystrophin in the mammalian brain. The brains of B10 (control) and mdx (dystrophin deficient null mutant) mouse brain were compared on a point-by-point basis to verify that only dystrophin and not autosomal dystrophin related protein or cross-reacting proteins were being identified. In addition three murine neurologic mutants, nervous, lurcher, and weaver, were studied to refine the localization of dystrophin. In western immunoblots, dystrophin is present in all regions of the brain and in greatest abundance in the cerebellum. Dystrophin, as demonstrated in immunofluorescence, is present in neurons, but not in glia or myelin, and forms punctate foci associated with the plasma membrane of perikarya and dendrites, but not axons. While dystrophin is abundant in cerebral cortical neurons and cerebellar Purkinje cells, it is absent from most subcortical neurons, the granule cells of fascia dentata, and cerebellar neurons other than Purkinje cells. The absence of dystrophin in the cerebellum of the Purkinje cell deficient mutants nervous and lurcher, and its presence in the granule cell deficient mutant weaver indicate that dystrophin is a component of Purkinje cells rather than closely apposed afferents to those cells. The distribution and localization of dystrophin suggests a role in organizing the plasma membrane, possibly as an anchor of the postsynaptic apparatus, a possible basis for the cognitive defect in Duchenne dystrophy.

The structural and functional diversity of dystrophin

Duchenne and Becker muscular dystrophies are caused by defects of the dystrophin gene. Expression of this large X-linked gene is under elaborate transcriptional and splicing control. At least five independent promoters specify the transcription of their respective alternative first exons in a cell-specific and developmentally controlled manner. Three promoters express full-length dystrophin, while two promoters near the C terminus express the last domains in a mutually exclusive manner. Six exons of the C terminus are alternatively spliced, giving rise to several alternative forms. Genetic, biochemical and anatomical studies of dystrophin suggest that a number of distinct functions are subserved by its great structural diversity. Extensive studies of dystrophin may lead to an understanding of the cause and perhaps a rational treatment for muscular dystrophy.

Dystrophin isoforms expressed in the mouse retina

The dystrophin gene is expressed in various tissues of the mouse. Previous immunohistochemical studies suggested the existence of dystrophin protein in the outer plexiform layer of the retina. We analyzed mRNAs from the retina and other tissues of mice and detected the dystrophin transcripts (DT) with the use of the reverse transcription and polymerase chain reaction (RT-PCR) method. The 5' sequences, corresponding to the first exon, of DT in the retina was mainly the brain type, whereas in the 3' region of DT that corresponds to the C-terminal domain of dystrophin, some additional RT-PCR products were detected. Base sequences in three of them showed homology to those for previously reported human dystrophin isoforms. The DT variations in mice were identical between the retina and the brain. It was thus concluded that dystrophin really expresses in the mouse retina and most of the retinal dystrophin proteins belong to the brain type isoform.

Dystrophin and dystrophin-related proteins: a review of protein and RNA studies

The analysis of dystrophin gene expression has led to the identification of multiple transcripts and varying isoforms. The data indicate that transcription of the dystrophin gene occurs from several promoters, which involves developmental and tissue-dependent regulation. These discoveries have complicated the interpretation of immunolocalization studies, although there is a strong correlation between the amount and size of dystrophin and the severity of the clinical phenotype. The importance of using protein-specific antibodies for dystrophin analysis has been underscored by the identification of a protein, designated utrophin, which exhibits significant sequence homology with dystrophin. This review addresses the recent studies of dystrophin and utrophin expression in an attempt to illustrate the transcriptional diversity of these large genes and the localization of their protein products within various tissues.