Your search keyword '"Oates, Emily C"' showing total 4 results

1. Loss-of-function mutations in SCN4A cause severe foetal hypokinesia or 'classical' congenital myopathy.

Author

Zaharieva, Irina T., Thor, Michael G., Oates, Emily C., Karnebeek, Clara van, Hendson, Glenda, Blom, Eveline, Witting, Nanna, Rasmussen, Magnhild, Gabbett, Michael T., Ravenscroft, Gianina, Sframeli, Maria, Suetterlin, Karen, Sarkozy, Anna, D'Argenzio, Luigi, Hartley, Louise, Matthews, Emma, Pitt, Matthew, Vissing, John, Ballegaard, Martin, and Krarup, Christian

Subjects

MUSCLE disease treatment, HYPOKINESIA, GENETIC mutation, CONGENITAL disorders, PHENOTYPES, NEONATAL mortality, THERAPEUTICS, DIAGNOSIS of muscle diseases, EPITHELIAL cells, GENEALOGY, GENETIC techniques, MUSCLE diseases, RESEARCH funding, VERTEBRATES, SEVERITY of illness index, MEMBRANE transport proteins, DIAGNOSIS

Abstract

Congenital myopathies are a clinically and genetically heterogeneous group of muscle disorders characterized by congenital or early-onset hypotonia and muscle weakness, and specific pathological features on muscle biopsy. The phenotype ranges from foetal akinesia resulting in in utero or neonatal mortality, to milder disorders that are not life-limiting. Over the past decade, more than 20 new congenital myopathy genes have been identified. Most encode proteins involved in muscle contraction; however, mutations in ion channel-encoding genes are increasingly being recognized as a cause of this group of disorders. SCN4A encodes the α-subunit of the skeletal muscle voltage-gated sodium channel (Nav1.4). This channel is essential for the generation and propagation of the muscle action potential crucial to muscle contraction. Dominant SCN4A gain-of-function mutations are a well-established cause of myotonia and periodic paralysis. Using whole exome sequencing, we identified homozygous or compound heterozygous SCN4A mutations in a cohort of 11 individuals from six unrelated kindreds with congenital myopathy. Affected members developed in utero- or neonatal-onset muscle weakness of variable severity. In seven cases, severe muscle weakness resulted in death during the third trimester or shortly after birth. The remaining four cases had marked congenital or neonatal-onset hypotonia and weakness associated with mild-to-moderate facial and neck weakness, significant neonatal-onset respiratory and swallowing difficulties and childhood-onset spinal deformities. All four surviving cohort members experienced clinical improvement in the first decade of life. Muscle biopsies showed myopathic features including fibre size variability, presence of fibrofatty tissue of varying severity, without specific structural abnormalities. Electrophysiology suggested a myopathic process, without myotonia. In vitro functional assessment in HEK293 cells of the impact of the identified SCN4A mutations showed loss-of-function of the mutant Nav1.4 channels. All, apart from one, of the mutations either caused fully non-functional channels, or resulted in a reduced channel activity. Each of the affected cases carried at least one full loss-of-function mutation. In five out of six families, a second loss-of-function mutation was present on the trans allele. These functional results provide convincing evidence for the pathogenicity of the identified mutations and suggest that different degrees of loss-of-function in mutant Nav1.4 channels are associated with attenuation of the skeletal muscle action potential amplitude to a level insufficient to support normal muscle function. The results demonstrate that recessive loss-of-function SCN4A mutations should be considered in patients with a congenital myopathy. [ABSTRACT FROM AUTHOR]

Published

2016

2. Phenotypic and molecular insights into spinal muscular atrophy due to mutations in BICD2.

Author

Rossor, Alexander M., Oates, Emily C., Salter, Hannah K., Liu, Yang, Murphy, Sinead M., Schule, Rebecca, Gonzalez, Michael A., Scoto, Mariacristina, Phadke, Rahul, Sewry, Caroline A., Houlden, Henry, Jordanova, Albena, Tournev, Iyailo, Chamova, Teodora, Litvinenko, Ivan, Zuchner, Stephan, Herrmann, David N., Blake, Julian, Sowden, Janet E., and Acsadi, Gyuda

Subjects

*PHENOTYPES, *MOLECULAR biology, *SPINAL muscular atrophy, *GENETIC mutation, *COHORT analysis, *DYNEIN, *ADAPTOR proteins, *PATIENTS

Abstract

Rossor et al. report the clinical characteristics of the largest cohort to date of individuals with spinal muscular atrophy caused by mutations in the gene encoding the dynein adaptor protein BICD2. Individuals develop characteristic early-onset lower limb wasting that allows for targeted genetic testing and interpretation of next-generation sequencing data.Spinal muscular atrophy is a disorder of lower motor neurons, most commonly caused by recessive mutations in SMN1 on chromosome 5q. Cases without SMN1 mutations are subclassified according to phenotype. Spinal muscular atrophy, lower extremity-predominant, is characterized by lower limb muscle weakness and wasting, associated with reduced numbers of lumbar motor neurons and is caused by mutations in DYNC1H1, which encodes a microtubule motor protein in the dynein-dynactin complex and one of its cargo adaptors, BICD2. We have now identified 32 patients with BICD2 mutations from nine different families, providing detailed insights into the clinical phenotype and natural history of BICD2 disease. BICD2 spinal muscular atrophy, lower extremity predominant most commonly presents with delayed motor milestones and ankle contractures. Additional features at presentation include arthrogryposis and congenital dislocation of the hips. In all affected individuals, weakness and wasting is lower-limb predominant, and typically involves both proximal and distal muscle groups. There is no evidence of sensory nerve involvement. Upper motor neuron signs are a prominent feature in a subset of individuals, including one family with exclusively adult-onset upper motor neuron features, consistent with a diagnosis of hereditary spastic paraplegia. In all cohort members, lower motor neuron features were static or only slowly progressive, and the majority remained ambulant throughout life. Muscle MRI in six individuals showed a common pattern of muscle involvement with fat deposition in most thigh muscles, but sparing of the adductors and semitendinosus. Muscle pathology findings were highly variable and included pseudomyopathic features, neuropathic features, and minimal change. The six causative mutations, including one not previously reported, result in amino acid changes within all three coiled-coil domains of the BICD2 protein, and include a possible ‘hot spot’ mutation, p.Ser107Leu present in four families. We used the recently solved crystal structure of a highly conserved region of the Drosophila orthologue of BICD2 to further-explore how the p.Glu774Gly substitution inhibits the binding of BICD2 to Rab6. Overall, the features of BICD2 spinal muscular atrophy, lower extremity predominant are consistent with a pathological process that preferentially affects lumbar lower motor neurons, with or without additional upper motor neuron involvement. Defining the phenotypic features in this, the largest BICD2 disease cohort reported to date, will facilitate focused genetic testing and filtering of next generation sequencing-derived variants in cases with similar features. [ABSTRACT FROM AUTHOR]

Published

2015

3. Mutations in BICD2 Cause Dominant Congenital Spinal Muscular Atrophy and Hereditary Spastic Paraplegia.

Author

Oates, Emily?C., Rossor, Alexander?M., Hafezparast, Majid, Gonzalez, Michael, Speziani, Fiorella, MacArthur, Daniel?G., Lek, Monkol, Cottenie, Ellen, Scoto, Mariacristina, Foley, A.?Reghan, Hurles, Matthew, Houlden, Henry, Greensmith, Linda, Auer-Grumbach, Michaela, Pieber, Thomas?R., Strom, Tim?M., Schule, Rebecca, Herrmann, David?N., Sowden, Janet?E., and Acsadi, Gyula

Subjects

*GENETIC mutation, *HUMAN genes, *SPINAL muscular atrophy, *MOTOR neurons, *DYNEIN, *DYNACTIN, *DROSOPHILA

Abstract

Dominant congenital spinal muscular atrophy (DCSMA) is a disorder of developing anterior horn cells and shows lower-limb predominance and clinical overlap with hereditary spastic paraplegia (HSP), a lower-limb-predominant disorder of corticospinal motor neurons. We have identified four mutations in bicaudal D homolog 2 (Drosophila) (BICD2) in six kindreds affected by DCSMA, DCSMA with upper motor neuron features, or HSP. BICD2 encodes BICD2, a key adaptor protein that interacts with the dynein-dynactin motor complex, which facilitates trafficking of cellular cargos that are critical to motor neuron development and maintenance. We demonstrate that mutations resulting in amino acid substitutions in two binding regions of BICD2 increase its binding affinity for the cytoplasmic dynein-dynactin complex, which might result in the perturbation of BICD2-dynein-dynactin-mediated trafficking, and impair neurite outgrowth. These findings provide insight into the mechanism underlying both the static and the slowly progressive clinical features and the motor neuron pathology that characterize BICD2-associated diseases, and underscore the importance of the dynein-dynactin transport pathway in the development and survival of both lower and upper motor neurons. [Copyright &y& Elsevier]

Published

2013

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

Author

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

Subjects

*GENETIC disorders, *TREATMENT of spinal muscular atrophy, *GENETIC mutation, *MAGNETIC resonance imaging, *ELECTROPHYSIOLOGY, *AUTOPSY, DIAGNOSIS of central nervous system diseases

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. [ABSTRACT FROM PUBLISHER]

Published

2012