Analysis of the UK diagnostic strategy for limb girdle muscular dystrophy 2A.

Diagnosis of limb girdle muscular dystrophy type 2A can be complex due to phenotypic variability, lack of precision of protein analysis in muscle biopsies, and absence of mutational hot spots in the CAPN3 gene. The aim of this study was to review clinical and biopsy data from a group of patients with known CAPN3 genetic status to validate and refine our current diagnostic strategy, which combines clinical information and protein analysis to direct gene testing. We analysed 85 patients in whom CAPN3 gene sequencing had been performed. Forty-two patients had two mutations, 15 a single mutation and in 28 no mutation was found. We identified clinical features that clearly discriminated the LGMD2A patients. These were: presence of scapular winging, contractures and normal respiratory function. In addition, a typical pattern of muscle weakness on manual muscle testing could be confirmed. Interpretation of protein expression obtained by Western blot was complex and involved the analysis of a number of bands detected by two antibodies for calpain 3. Loss of all calpain 3 bands was 100% specific for LGMD2A, but this pattern was found in only 23%. Absence or reduction of the approximately 60 kDa bands was also highly specific for LGMD2A, while increased abundance was highly predictive of no mutations being found even where other bands were reduced, suggesting that this is the most sensitive marker of artefactual protein degradation. Twenty-three percent of the patients with two mutations had normal full-sized calpain 3 protein, consistent with the finding of mutations localized in parts of the gene likely or proven to be involved in autolytic activity. Clinical and biochemical findings in patients with only one mutation were similar to patients with two mutations, indicating that other gene analysis techniques should be used before excluding the diagnosis. Our analysis confirms that our strategy is still valid to prioritize genetic testing in this complex group of patients, provided patients with normal protein but a suggestive clinical phenotype are not excluded from genetic testing.

The respiratory management of patients with duchenne muscular dystrophy: a DMD care considerations working group specialty article.

In 2001, the Muscular Dystrophy Community Assistance, Research and Education Amendments (MD-CARE Act) was enacted, which directed federal agencies to coordinate the development of treatments and cures for muscular dystrophy. As part of the mandate, the Centers for Disease Control and Prevention (CDC) initiated surveillance and educational activities, which included supporting development of care considerations for Duchenne muscular dystrophy (DMD) utilizing the RAND/UCLA Appropriateness Method (RAM). This document represents the consensus recommendations of the project's 10-member Respiratory Panel and includes advice on necessary equipment, procedures and diagnostics; and a structured approach to the assessment and management of the respiratory complications of DMD via assessment of symptoms of hypoventilation and identification of specific thresholds of forced vital capacity, peak cough flow and maximum expiratory pressure. The document includes a set of Figures adaptable as "pocket guides" to aid clinicians. This article is an expansion of the respiratory component of the multi-specialty article originally appearing in Lancet Neurology, comprising respiratory recommendations from the CDC Care Considerations project.

COL6A1 genomic deletions in Bethlem myopathy and Ullrich muscular dystrophy.

We have identified highly similar heterozygous COL6A1 genomic deletions, spanning from intron 8 to exon 13 or intron 13, in two patients with Ullrich congenital muscular dystrophy and the milder Bethlem myopathy. The 5' breakpoints of both deletions are located within a minisatellite in intron 8. The mutations cause in-frame deletions of 66 and 84 amino acids in the amino terminus of the triple-helical domain, leading to intracellular accumulation of mutant polypeptides and reduced extracellular collagen VI microfibrils. Our studies identify a deletion-prone region in COL6A1 and suggest that similar mutations can lead to congenital muscle disorders of different clinical severity.

Hereditary spastic paraparesis: disrupted intracellular transport associated with spastin mutation.

The commonest cause of hereditary spastic paraplegia (HSP) is mutation in the spastin gene. Both the normal function of spastin in the central nervous system and the mechanism by which mutation in spastin causes axonal degeneration are unknown. One hypothesis is that mutant spastin disrupts microtubule dynamics, causing an impairment of organelle transport on the microtubule network, which leads to degeneration in the distal parts of long axons. To study this neuronal and non-neuronal cells were transfected with either wild type or mutant spastin proteins. We demonstrated evidence of a transient interaction of wild-type spastin with microtubules, with resulting disassembly of microtubules, supporting a role for wild-type spastin as a microtubule-severing protein. Mutant spastin demonstrated an abnormal interaction with microtubules, colocalizing with but no longer severing microtubules. The abnormal interaction of mutant spastin with microtubules was demonstrated to be associated with an abnormal perinuclear clustering of mitochondria and peroxisomes, suggestive of an impairment of kinesin-mediated intracellular transport. Our findings indicate that an abnormal interaction of mutant spastin with microtubules, which disrupts organelle transport on the microtubule cytoskeleton, is likely to be the primary disease mechanism in HSP caused by missense mutations in the spastin gene.