Estimation of muscle strength from actigraph data in Duchenne muscular dystrophy.

BACKGROUND: The purpose of this study was to evaluate the utility of a wrist actigraph for estimating muscle strength in Duchenne muscular dystrophy patients. METHODS: Twenty-two patients aged 4-19 years wore a wrist actigraph to monitor activities of daily living, and underwent a test of knee extension strength and the 6 min walk test. These measures were made at baseline and at 1 year later. The actigraph data were quantified using the zero crossing mode (ZCM), which indicates the frequency of movement, and the proportional integration mode (PIM), which indicates activity level or vigor of motion. RESULTS: The ZCM and PIM scores of ambulatory patients were higher than those of non-ambulatory patients (P < 0.001). The correlation coefficient between ZCM score and 6 min walk distance, ZCM score and knee extension strength, PIM score and 6 minute walk distance, and PIM score and knee extension strength was -0.44, 0.25, 0.58, and 0.63, respectively. This indicates that the PIM score had a moderate-good association with 6 min walk distance and knee extension strength. CONCLUSION: Muscle strength can be estimated using the PIM score calculated from actigraph data. The PIM score is a good tool for the estimation of muscle strength.

Exon-skipping events in candidates for clinical trials of morpholino.

BACKGROUND: Duchenne muscular dystrophy (DMD) and Becker muscular dystrophy (BMD) are caused by abnormalities in the DMD gene. The majority of DMD patients have out-of-frame deletion(s), which disrupt the reading frame; while some cases of DMD are caused by duplication or nonsense mutation(s). Most patients with BMD have in-frame deletion(s), which preserve the reading frame. The phenotype of BMD is generally milder than that of DMD. Antisense morpholino-mediated exon skipping, which changes out-of-frame deletions to in-frame deletions, is a promising therapeutic approach for DMD. It is necessary, however, to confirm the exon-skipping event in cells of DMD patients before the clinical trial. METHODS: Fibroblasts isolated from four DMD patients were induced to differentiate into the myogenic lineage by infection with Ad.CAGMyoD. The cells were then transfected with two types of morpholino. The exon-skipping event was analyzed on reverse transcription-polymerase chain reaction. RESULTS: Morpholino B30, which is located at the splicing enhancer of exon 51 of the DMD gene, yielded the desired exon 51-skipping event in all deletion patterns of cells tested. Morpholino I25, which is located at the exon donor, induced two different exon-skipping patterns, which are total or partial exon 51-skipping events. According to the sequence analysis, the unexpected unskipped regions were the 95 bp section and the 188 bp section of exon 51, showing that the cryptic splicing donor was newly produced with I25. Unfortunately, these cryptic splicing donors gave rise to out-of-frame patterns. Based on these in vitro results, B30 would presumably be an effective therapy. Interestingly, the cocktail of B30 and I25 appeared to yield a more efficient exon 51-skipping event. CONCLUSION: An in vitro system was developed that could easily screen the effectiveness of antisense sequences and identify good candidates for therapy with morpholino.

A 2-bp deletion in exon 74 of the dystrophin gene does not clearly induce muscle weakness.

Duchenne muscular dystrophy (DMD) is caused by mutation of the dystrophin gene. Cases of dystrophinopathy with a 2-bp deletion in the dystrophin gene commonly result in DMD. We report here a case of dystrophinopathy in a 9-years-old boy with a 2-bp deletion in exon 74 of the dystrophin gene; however, the boy had no clear clinical signs of muscle weakness. Immunohistochemical studies with N-terminal (DYS3) and rod-domain anti-dystrophin (DYS1) antibodies revealed that the dystrophin signals were weaker than in the control sample (non-dystrophinopathy) at the sarcolemma of myofibers, and the studies with C-terminus anti-dystrophin antibody (DYS2) were negative. Our patient's mutation is located between the binding sites of alpha-syntrophin and alpha-dystrobrevin. These results suggest that this mutation does not clearly induce muscle weakness at least through the age of 9 years.

Novel mutation in splicing donor of dystrophin gene first exon in a patient with dilated cardiomyopathy but no clinical signs of skeletal myopathy.

One cause of X-linked dilated cardiomyopathies is mutation of the dystrophin gene. We report the case of a young boy who suffered from dilated cardiomyopathy caused only by dystrophin-deficient cardiac muscle, but who did not present with any clinical signs of skeletal myopathy. Sequence analysis of the patient's dystrophin gene revealed the presence of a novel single point mutation at the first exon-intron boundary, inactivating the 5' splice site consensus sequence of the first intron. The lack of muscle weakness observed clinically can be explained by expression of the brain and Purkinje dystrophin isoforms in skeletal muscle.

Efficient conversion of ES cells into myogenic lineage using the gene-inducible system.

We established genetically engineered ES (ZHTc6-MyoD) cells that harbor a tetracycline-regulated expression vector encoding myogenic transcriptional factor MyoD, for the therapy of muscle diseases, especially Duchenne muscular dystrophy (DMD). Almost all the ZHTc6-MyoD cells were induced into muscle lineage after removal of tetracycline. The undifferentiated ZHTc6-MyoD cells are Sca-1+ and c-kit+, but CD34-, all well-known markers for mouse hematopoietic stem cells. In addition, they are able to maintain themselves in the undifferentiated state, even after one month of culture. Therefore, it is possible to obtain a large quantity of ZHTc6-MyoD cells in the undifferentiated state that maintain the potential to differentiate only into muscle lineage. Additionally, at two weeks post-injection of these cells into muscle of mdx, a model mouse of DMD, clusters of dystrophin-positive myofibers were observed at the injection site. Therefore, ES cells have considerable therapeutic potential for treating muscle diseases.

Smooth muscle-specific dystrophin expression improves aberrant vasoregulation in mdx mice.

Duchenne muscular dystrophy (DMD) is a fatal X-linked muscle-wasting disease caused by mutations of the gene encoding the cytoskeletal protein dystrophin. Therapeutic options for DMD are limited because the pathogenetic mechanism by which dystrophin deficiency produces the clinical phenotype remains obscure. Recent reports of abnormal alpha-adrenergic vasoregulation in the exercising muscles of DMD patients and in the mdx mouse, an animal model of DMD, prompted us to hypothesize that the dystrophin-deficient smooth muscle contributes to the vascular and dystrophic phenotypes of DMD. To test this, we generated transgenic mdx mice that express dystrophin only in smooth muscle (SMTg/mdx). We found that alpha-adrenergic vasoconstriction was markedly attenuated in the contracting hindlimbs of C57BL/10 wild-type mice, an effect that was mediated by nitric oxide (NO) and was severely impaired in the mdx mice. SMTg/mdx mice showed an intermediate phenotype, with partial restoration of the NO-dependent modulation of alpha-adrenergic vasoconstriction in active muscle. In addition, the elevated serum creatine kinase levels observed in mdx mice were significantly reduced in SMTg/mdx mice. This is the first report of a functional role of dystrophin in vascular smooth muscle.