Milder course in Duchenne patients with nonsense mutations and no muscle dystrophin

Duchenne muscular dystrophy (DMD), a severe and lethal condition, is caused by the absence of muscle dystrophin. Therapeutic trials aiming at the amelioration of muscle function have been targeting the production of muscle dystrophin in affected Duchenne patients. However, how much dystrophin is required to rescue the DMD phenotype remains an open question. We have previously identified two exceptional golden retriever muscular dystrophy (GRMD) dogs with a milder course despite the total absence of muscle dystrophin. Here we report two unusual patients carrying nonsense mutations in the DMD gene and dystrophin deficiency but with an unexpectedly mild phenotype. Three reported polymorphisms, respectively in genes LTBP4, SPP1 and ACTN3 were excluded as possible DMD genetic modifiers in our patients. Finding the mechanisms that protect some rare patients and dogs from the deleterious effect of absent muscle dystrophin is of utmost importance and may lead to new avenues for treatment. Importantly, these observations indicate that it is possible to have a functional large muscle even without dystrophin.     

Dystrophin in skeletal muscle. II. Immunoreactivity in patients with Xp21 muscular dystrophy

In the preceding paper a sensitive Western blotting analysis system based on the use of a monoclonal antibody to dystrophin was described. Here we report the immunoreactivity on blots and on unfixed frozen sections of muscle from patients with Duchenne (DMD) and Becker (BMD) muscular dystrophy. Muscle from 3 BMD patients showed variation both in the band pattern observed on blots and in the immunocytochemical labelling of dystrophin on frozen sections. In contrast to previous reports, we were able to detect some minor dystrophin bands on blots from 6 of 9 DMD biopsy samples. Tissue sections from 8 of the 9 contained isolated fibres with dystrophin-positive labelling. We conclude that the majority of DMD patients have muscle fibres which can synthesize dystrophin in a limited manner.     

Duchenne and Becker muscular dystrophy: a molecular and immunohistochemical approach

Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are caused by mutations in the dystrophin gene. We studied 106 patients with a diagnosis of probable DMD/BMD by analyzing 20 exons of the dystrophin gene in their blood and, in some of the cases, by immunohistochemical assays for dystrophin in muscle biopsies. In 71.7% of the patients, deletions were found in at least one of the exons; 68% of these deletions were in the hot-spot 3' region. Deletions were found in 81.5% of the DMD cases and in all the BMD cases. The cases without deletions, which included the only woman in the study with DMD, had dystrophin deficiency. The symptomatic female carriers had no deletions but had abnormal dystrophin distribution in the sarcolemma (discontinuous immunostains). The following diagnoses were made for the remaining cases without deletions with the aid of a muscle biopsy: spinal muscular atrophy, congenital myopathy; sarcoglycan deficiency and unclassified limb-girdle muscular dystrophy. Dystrophin analysis by immunohistochemistry continues to be the most specific method for diagnosis of DMD/BMD and should be used when no exon deletions are found in the dystrophin gene in the blood.     

Dystrophin or a “related protein” in Duchenne muscular dystrophy?

Previously we have shown low levels of dystrophin immunoreactivity in muscle from patients with DMD. According to the "frame-shift hypothesis" DMD muscle should not synthesize any dystrophin through to the C-terminus and it has been suggested that the protein detected is not dystrophin, but a related autosomal homologue. We have labelled serial sections of DMD muscle with specific monoclonal antibodies to the amino, rod and C-terminal domains of dystrophin and find labelling on the same individual fibres, allowing us to conclude that the protein detected is Xp21-encoded dystrophin. This has an impact on the interpretation of myoblast transfer experiments. The abundance (on blots) of "C-terminal dystrophin" appears lower than "rod dystrophin" in both BMD and DMD.     

Developmental study of the expression of dystrophin in cultured human muscle aneurally and innervated with fetal rat spinal cord.

So far there have been no developmental studies including the influences of innervation and contractile activity on the expression of dystrophin in cultured human muscle. We performed immunocytochemical studies of the localization of dystrophin on aneurally cultured non-contracting (AMs) and innervated continuously contracting cross-striated human muscle fibers (ICMs) with fetal rat spinal cord from normal and Duchenne muscular dystrophy (DMD) biopsied muscles. In normal AMs, myoblasts and some immature AMs showed negative staining of dystrophin, but many AMs had a patchy (discontinuous) distribution of dystrophin in the subplasmalemmal region and with some granularity near the sarcolemma and in the deeper cytoplasm. In normal ICMs, dystrophin was localized continuously at the inner aspect of the sarcolemmal membrane and some periodic dense patterns were detected in some areas. Both AMs and ICMs from DMD had negative staining of dystrophin. To investigate the muscle contractile activity on the distribution of dystrophin, we paralyzed ICMs with tetrodotoxin (TTX) for two weeks from the first appearance of muscle contractions. In paralyzed innervated muscles (PIMs), dystrophin remained in a patchy (discontinuous) pattern at the inner aspect of the plasmalemma similar to that in AMs. It is strongly suggested that muscle contractile activity plays an important role in the continuous and even distribution of dystrophin at the sarcolemma during development.     

Prediction of dystrophin phenotype by DNA analysis in Duchenne/Becker muscular dystrophy

Allele-specific molecular diagnosis of Duchenne and Becker muscular dystrophies (DMD and BMD) has been largely dependent upon muscle biopsy for dystrophin protein assay. We performed lymphocyte DNA mutation analysis by polymerase chain reaction on 14 boys presenting with a clinical picture compatible with DMD or BMD. DNA analysis revealed that 12 of 14 boys had a deletion of the dystrophin gene, thus establishing the diagnosis of DMD/BMD. Furthermore, genotypes for 9 of 12 deletion patients permitted prediction of the specific allelic disorder (i.e., DMD or BMD). Subsequent dystrophin testing confirmed all of the DNA-based diagnoses. We propose that DNA mutation analysis be included in the initial evaluation of patients suspected of having DMD/BMD, thus potentially eliminating the need for muscle biopsy in the majority of patients.     

Charcot-Marie-Tooth neuropathy type 1A combined with Duchenne muscular dystrophy

We report a 24-year-old male with an unusual combination of two inherited neuromuscular disorders – Charcot-Marie-Tooth (CMT) disease type 1A and Duchenne muscular dystrophy (DMD). A phenotypic presentation of this patient included features of both these disorders. Nerve conduction studies revealed demyelinating peripheral neuropathy. Electromyography showed a profound myogenic pattern. The serum creatine kinase level was highly elevated. Muscle biopsy revealed a dystrophic picture with deficient dystrophin immunostaining. CMT1A duplication on chromosome 17p11.2 was found. The frame-shift mutation c.3609–3612delTAAAinsCTT (p.K1204LfsX11) was detected in the dystrophin gene by analysing mRNA isolated from the muscle tissue. The patient inherited both these mutations from his mother. The combination of CMT1A and DMD has not been reported as yet.     

Duchenne muscular dystrophy caused by a complex rearrangement between intron 43 of the DMD gene and chromosome 4

Deletions/duplications of exons in the DMD gene cause about 70% of all cases of Duchenne muscular dystrophy (DMD). Most remaining mutations are point mutations or small insertion-deletions located mainly in the coding but also in deep intronic regions of the DMD gene. We describe a novel complex rearrangement in a patient affected with DMD that was undetectable using standard molecular diagnostic methods. Analysis of the proband’s mRNA from a muscle biopsy revealed the insertion of an 80 bp cryptic exon from chromosome 4 between exons 43 and 44 of the dystrophin gene. Array comparative genomic hybridization and breakpoint junction sequence analysis indicated this cryptic exon originated from a complex genomic 90 kb insertion of non-coding chromosome 4 into intron 43 of the dystrophin gene. This rearrangement was also detectable in the patient’s mother. The genomic characterization of this novel complex mutation was essential for accurate carrier and genetic counseling of this family and emphasizes the need for comprehensive molecular diagnosis of patients with clinical signs of DMD and clear pathological changes.     

The “rescue” of dystrophin synthesis in boys with Duchenne muscular dystrophy

Over the last few years it has become clear that a proportion of biopsies from patients with Duchenne muscular dystrophy (DMD) contain fibres which show dystrophin-positive immunolabelling. We have collected evidence to demonstrate that low level restoration of the reading frame must have been taking place and that a BMD-like protein was being synthesized in DMD muscle. We have also found a relationship between the abundance of dystrophin (determined by densitometric analysis of blots) and the age at which boys lose the ability to walk independently. Thus, even the low levels of dystrophin in DMD patients may have a functional significance. We now suggest that exon skipping, whereby an existing frame-shifting deletion is modified and extended to an in-frame mutation, may be responsible for the limited rescue of dystrophin synthesis in the muscle from many DMD patients.     

针吸型肌肉活检联合免疫荧光在假肥大型肌营养不良诊断中的应用

目的 探讨应用针吸型肌肉活检结合免疫荧光染色诊断假肥大型肌营养不良症的应用价值及意义。方法 应用针吸型活检术取533例假肥大型肌营养不良症患者(415例DMD, 118例BMD)的肌组织,采用HE染色观察肌细胞形态,免疫荧光染色技术检测抗肌营养不良蛋白, 以2 例正常人的肌细胞作为对照。结果 正常人肌细胞膜上抗肌萎缩蛋白染色阳性,可见沿肌细胞膜分布完整的荧光条带; DMD 患者肌膜染色阴性,肌细胞膜完全不显色; BM D患者染色弱阳性, 可见沿肌细胞膜分布的间断斑片状荧光带。结论 应用针吸型活检术联合免疫荧光染色可以有效的检测抗肌营养不良蛋白的表达, 有助于DMD 和BMD 的确诊及鉴别诊断。     

Genotype and phenotype characterization in a large dystrophinopathic cohort with extended follow-up

Duchenne and Becker muscular dystrophy (DMD and BMD, respectively) are allelic disorders with different clinical presentations and severity determined by mutations in the gene DMD, which encodes the sarcolemmal protein dystrophin. Diagnosis is based on clinical aspects and muscle protein analysis, followed by molecular confirmation. We revised the main aspects of the natural history of dystrophinopathies to define genotype-phenotype correlations in large patient cohorts with extended follow-up. We also specifically explored subjects carrying nucleotide substitutions in the DMD gene, a comparatively less investigated DMD/BMD subgroup. We studied 320 dystrophinopathic patients (205 DMD and 115 BMD), defining muscular, cardiac, respiratory, and cognitive involvement. We also subdivided patients according to the kind of molecular defect (deletions, duplications, nucleotide substitutions or other microrearrangements) and the mutation sites (proximal/distal to exon 45), studying phenotype-genotype correlations for each group. In DMD, mutation type did not influence clinical evolution; mutations located in distal regions (irrespective of their nature) are more likely to be associated with lower IQ levels (p = 0.005). BMD carrying proximal deletions showed a higher degree of cardiac impairment than BMD with distal deletions (p = 0.0046). In the BMD population, there was a strong correlation between the entity of muscle dystrophin deficiency and clinical course (p = 0.002). An accurate knowledge of natural history may help in the clinical management of patients. Furthermore, several clinical trials are ongoing or are currently planned, some of which aim to target specific DMD mutations: a robust natural history is therefore essential to correctly design these experimental trials.     

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.     

Distribution of dystrophin, nebulin and Ricinus communis I (RCA-I)-binding glycoprotein in tissues of normal and mdx mice

Dystrophin, the protein product of the Duchenne muscular dystrophy (DMD) gene locus, appeared as an immunoreactive triplet of polypeptides in striated muscle tissues from normal mice on Western blot analysis. In smooth muscle tissues, an immunoreactive doublet of corresponding molecular weight was detected. No dystrophin was found in normal mouse brain, not even after enrichment for the Triton X-100 insoluble fraction. Dystrophin was absent from all corresponding tissues from the mdx mutant mouse strain which is known to lack dystrophin. The possibility that these immunoreactive bands represent isoforms is discussed. We have also investigated two other high molecular weight proteins which show secondary abnormalities in DMD muscle, namely nebulin and the 370 kDa Ricinus communis I lectin (RCA I)-binding glycoprotein. Nebulin levels were reduced in skeletal muscle from 6-week-old mdx mice but not in oesophagus from the same animals. By contrast, the RCA I-binding 370 kDa glycoprotein which is greatly reduced in DMD skeletal muscle was present in normal amounts in mdx skeletal muscle. These findings show, for the first time, that mdx myopathy differs from DMD myopathy not only morphologically, but also in its secondary biochemical abnormalities.     

A novel approach to identify Duchenne muscular dystrophy patients for aminoglycoside antibiotics therapy

Aminoglycoside antibiotics have been found to suppress nonsense mutations located in the defective dystophin gene in mdx mice, suggesting a possible treatment for Duchenne muscular dystrophy (DMD). However, it is very difficult to find patients that are applicable for this therapy, because: (1) only 5-13% of DMD patients have nonsense mutations in the dystrophin gene, (2) it is challenging to find nonsense mutations in the gene because dystrophin cDNA is very long (14 kb), and (3) the efficiency of aminoglycoside-induced read-through is dependent on the kind of nonsense mutation. In order to develop a system for identifying candidates that qualify for aminoglycoside therapy, fibroblasts from nine DMD patients with nonsense mutation of dystrophin gene were isolated, induced to differentiate to myogenic lineage by AdMyoD, and exposed with gentamicin. The dystrophin expression in gentamicin-exposed myotubes was monitored by in vitro dystrophin staining and western blotting analysis. The results showed that gentamicin was able to induce dystrophin expression in the differentiated myotubes by the read-through of the nonsense mutation TGA in the gene; a read-through of the nonsense mutations TAA and TAG did not occur and consequently did not lead to dystrophin expression. Therefore, it is speculated that the aminoglycoside treatment is far more effective for DMD patients that have nonsense mutation TGA than for patients that have nonsense mutation TAA and TAG. In this study, we introduce an easy system to identify patients for this therapy and report for the first time, that dystrophin expression was detected in myotubes of DMD patients using gentamicin.     

Potential oxyradical damage and energy status in individual muscle fibres from degenerating muscle diseases.

Inherited degenerating muscle diseases result in disintegration of muscle fibres, which is initiated by a lack of or alteration to a muscle protein. In Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) the protein is known to be dystrophin. The cellular function of dystrophin is not known in any detail but its absence appears to lead to a weakening of the sarcolemma. It has been proposed by Murphy and Kehrer that this leads ultimately to increased oxyradical production which may accelerate the degeneration. Studies have been carried out on individual muscle fibres derived from biopsy samples from patients with a number of degenerative muscle diseases. The glutathione cycling components, in particular glutathione and glutathione peroxidase, are significantly elevated in DMD, BMD and other diseases. Glutathione reductase is also elevated in some of these diseases. Energy producing systems are also affected particularly in intact fibres of muscle derived from muscle at an advanced stage of the disease. These results suggest that oxyradical damage may occur as a secondary consequence of muscle degenerating disease, leading to a breakdown in the glycogenolytic energy producing system.     

Dystrophin and mutations: one gene, several proteins, multiple phenotypes

A large and complex gene on the X chromosome encodes dystrophin. Many mutations have been described in this gene, most of which affect the expression of the muscle isoform, the best-known protein product of this locus. These mutations result in the Duchenne and Becker muscular dystrophies (DMD and BMD). However, there are several other tissue specific isoforms of dystrophin, some exclusively or predominantly expressed in the brain or the retina. Mutations affecting the correct expression of these tissue-specific isoforms have been associated with the CNS involvement common in DMD. Rare mutations also account for the allelic disorder X-linked dilated cardiomyopathy, in which dystrophin expression or function is affected mostly or exclusively in the heart. Genotype definition of the dystrophin gene in patients with dystrophinopathies has taught us much about functionally important domains of the protein itself and has provided insights into several regulatory mechanisms governing the gene expression profile. Here, we focus on current understanding of the genotype-phenotype relation for mutations in the dystrophin gene and their implications for gene functions.     

The discovery of the DNA methylation episignature for Duchenne muscular dystrophy

Duchenne Muscular Dystrophy (DMD) is an X-linked recessive neuromuscular disorder characterized by progressive muscle weakness due to loss of function mutations in the dystrophin gene. Variation in clinical presentation, the rate of disease progression, and treatment responsiveness have been observed amongst DMD patients, suggesting that factors beyond the loss of dystrophin may contribute to DMD pathophysiology. Epigenetic mechanisms are becoming recognized as important factors implicated in the etiology and progression of various diseases. A growing number of genetic syndromes have been associated with unique genomic DNA methylation patterns (called “episignatures”) that can be used for diagnostic testing and as disease biomarkers. To further investigate DMD pathophysiology, we assessed the genome-wide DNA methylation profiles of peripheral blood from 36 patients with DMD using the combination of Illumina Infinium Methylation EPIC bead chip array and EpiSign technology. We identified a unique episignature for DMD that whose specificity was confirmed in relation other neurodevelopmental disorders with known episignatures. By modeling the DMD episignature, we developed a new DMD episignature biomarker and provided novel insights into the molecular pathogenesis of this disorder, which have the potential to advance more effective, personalized approaches to DMD care.