Your search keyword '"Nigel F. Clarke"' showing total 3 results

1. Autosomal dominant congenital spinal muscular atrophy: a true form of spinal muscular atrophy caused by early loss of anterior horn cells

Author

Stephen W. Reddel, Luke C. Gandolfo, Nigel F. Clarke, Melanie Bahlo, Michael Rodriguez, Emily C. Oates, Simon Hawke, Kathryn N. North, and Shireen R. Lamandé

Subjects

Male, musculoskeletal diseases, TRPV4, Genetic Linkage, Central nervous system, TRPV Cation Channels, Myosins, Muscular Atrophy, Spinal, Atrophy, Lumbar, Anterior Horn Cell, Anterior Horn Cells, medicine, Humans, Child, Muscle, Skeletal, Aged, Muscle contracture, Family Health, business.industry, Infant, Ultrasonography, Doppler, Anatomy, Spinal muscular atrophy, medicine.disease, Spinal cord, Magnetic Resonance Imaging, Phenotype, medicine.anatomical_structure, Child, Preschool, Female, Autopsy, Neurology (clinical), business

Abstract

Autosomal dominant congenital spinal muscular atrophy is characterized by predominantly lower limb weakness and wasting, and congenital or early-onset contractures of the hip, knee and ankle. Mutations in TRPV4, encoding a cation channel, have recently been identified in one large dominant congenital spinal muscular atrophy kindred, but the genetic basis of dominant congenital spinal muscular atrophy in many families remains unknown. It has been hypothesized that differences in the timing and site of anterior horn cell loss in the central nervous system account for the variations in clinical phenotype between different forms of spinal muscular atrophy, but there has been a lack of neuropathological data to support this concept in dominant congenital spinal muscular atrophy. We report clinical, electrophysiology, muscle magnetic resonance imaging and histopathology findings in a four generation family with typical dominant congenital spinal muscular atrophy features, without mutations in TRPV4, and in whom linkage to other known dominant neuropathy and spinal muscular atrophy genes has been excluded. The autopsy findings in the proband, who died at 14 months of age from an unrelated illness, provided a rare opportunity to study the neuropathological basis of dominant congenital spinal muscular atrophy. There was a reduction in anterior horn cell number in the lumbar and, to a lesser degree, the cervical spinal cord, and atrophy of the ventral nerve roots at these levels, in the absence of additional peripheral nerve pathology or abnormalities elsewhere along the neuraxis. Despite the young age of the child at the time of autopsy, there was no pathological evidence of ongoing loss or degeneration of anterior horn cells suggesting that anterior horn cell loss in dominant congenital spinal muscular atrophy occurs in early life, and is largely complete by the end of infancy. These findings confirm that dominant congenital spinal muscular atrophy is a true form of spinal muscular atrophy caused by a loss of anterior horn cells localized to lumbar and cervical regions early in development.

Published

2012

2. Dysferlin, Annexin A1, and Mitsugumin 53 Are Upregulated in Muscular Dystrophy and Localize to Longitudinal Tubules of the T-System With Stretch

Author

Frances J. Evesson, J. Hawkes, Noah Weisleder, Michael J. Ackerman, Nigel F. Clarke, Frances A. Lemckert, Angela Lek, Neil E. Street, Sandra T. Cooper, Xi F. Zheng, Leigh B. Waddell, Jenny Tran, Jianjie Ma, Kathryn N. North, Andrew P. Landstrom, and Pei-Hui Lin

Subjects

Cytoplasm, Biopsy, Muscle Proteins, Microtubules, Tripartite Motif Proteins, Dysferlin, Sarcolemma, Muscular dystrophy, Child, Annexin A1, Microscopy, Confocal, General Medicine, Middle Aged, Immunohistochemistry, Up-Regulation, Cell biology, Neurology, Child, Preschool, medicine.symptom, ITGA7, Adult, medicine.medical_specialty, Adolescent, Blotting, Western, Biology, Article, Pathology and Forensic Medicine, Young Adult, Cellular and Molecular Neuroscience, Physical Stimulation, Internal medicine, medicine, Humans, Muscle, Skeletal, Myopathy, Aged, Infant, Membrane Proteins, DNA, medicine.disease, Caveolin 3, Endocrinology, Muscular Dystrophies, Limb-Girdle, Membrane protein, biology.protein, Neurology (clinical), Carrier Proteins, Limb-girdle muscular dystrophy

Abstract

Mutations in dysferlin cause an inherited muscular dystrophy because of defective membrane repair. Three interacting partners of dysferlin are also implicated in membrane resealing: caveolin-3 (in limb girdle muscular dystrophy type 1C), annexin A1, and the newly identified protein mitsugumin 53 (MG53). Mitsugumin 53 accumulates at sites of membrane damage, and MG53-knockout mice display a progressive muscular dystrophy. This study explored the expression and localization of MG53 in human skeletal muscle, how membrane repair proteins are modulated in various forms of muscular dystrophy, and whether MG53 is a primary cause of human muscle disease. Mitsugumin 53 showed variable sarcolemmal and/or cytoplasmic immunolabeling in control human muscle and elevated levels in dystrophic patients. No pathogenic MG53 mutations were identified in 50 muscular dystrophy patients, suggesting that MG53 is unlikely to be a common cause of muscular dystrophy in Australia. Western blot analysis confirmed upregulation of MG53, as well as of dysferlin, annexin A1, and caveolin-3 to different degrees, in different muscular dystrophies. Importantly, MG53, annexin A1, and dysferlin localize to the t-tubule network and show enriched labeling at longitudinal tubules of the t-system in overstretch. Our results suggest that longitudinal tubules of the t-system may represent sites of physiological membrane damage targeted by this membrane repair complex.

Published

2011

3. Muscle weakness in TPM3-myopathy is due to reduced Ca2+-sensitivity and impaired acto-myosin cross-bridge cycling in slow fibres

Author

Lars Klinge, Sandra T. Cooper, Coen A.C. Ottenheijm, Josine M. de Winter, Nigel F. Clarke, Elyshia McNamara, Steve Marston, Nancy Mokbel, Kristen J. Nowak, Gianina Ravenscroft, Biljana Ilkovski, Alan H. Beggs, Michaela Yuen, John Rendu, Kathryn N. North, Physiology, and ICaR - Heartfailure and pulmonary arterial hypertension

Subjects

Adult, Male, Adolescent, Generalized muscle weakness, Tropomyosin, Myosins, Biology, Filamentous actin, Muscular Diseases, Myosin, Genetics, medicine, Humans, Protein Isoforms, Child, Myopathy, Molecular Biology, Genetics (clinical), Actin, Muscle Weakness, Infant, Muscle weakness, Articles, General Medicine, Anatomy, Middle Aged, Actins, Muscular Atrophy, Muscle Fibers, Slow-Twitch, Child, Preschool, Mutation, Biophysics, Calcium, Female, medicine.symptom, Muscle Contraction, Muscle contraction

Abstract

Dominant mutations in TPM3, encoding α-tropomyosinslow, cause a congenital myopathy characterized by generalized muscle weakness. Here, we used a multidisciplinary approach to investigate the mechanism of muscle dysfunction in 12 TPM3-myopathy patients. We confirm that slow myofibre hypotrophy is a diagnostic hallmark of TPM3-myopathy, and is commonly accompanied by skewing of fibre-type ratios (either slow or fast fibre predominance). Patient muscle contained normal ratios of the three tropomyosin isoforms and normal fibre-type expression of myosins and troponins. Using 2D-PAGE, we demonstrate that mutant α-tropomyosinslow was expressed, suggesting muscle dysfunction is due to a dominant-negative effect of mutant protein on muscle contraction. Molecular modelling suggested mutant α-tropomyosinslow likely impacts actin-tropomyosin interactions and, indeed, co-sedimentation assays showed reduced binding of mutant α-tropomyosinslow (R168C) to filamentous actin. Single fibre contractility studies of patient myofibres revealed marked slow myofibre specific abnormalities. At saturating [Ca(2+)] (pCa 4.5), patient slow fibres produced only 63% of the contractile force produced in control slow fibres and had reduced acto-myosin cross-bridge cycling kinetics. Importantly, due to reduced Ca(2+)-sensitivity, at sub-saturating [Ca(2+)] (pCa 6, levels typically released during in vivo contraction) patient slow fibres produced only 26% of the force generated by control slow fibres. Thus, weakness in TPM3-myopathy patients can be directly attributed to reduced slow fibre force at physiological [Ca(2+)], and impaired acto-myosin cross-bridge cycling kinetics. Fast myofibres are spared; however, they appear to be unable to compensate for slow fibre dysfunction. Abnormal Ca(2+)-sensitivity in TPM3-myopathy patients suggests Ca(2+)-sensitizing drugs may represent a useful treatment for this condition.

Published

2015