Nicholas Fletcher scite author profile

Neuroferritinopathy is a progressive potentially treatable adult-onset movement disorder caused by mutations in the ferritin light chain gene (FTL1). Features overlap with common extrapyramidal disorders: idiopathic torsion dystonia, idiopathic Parkinson's disease and Huntington's disease, but the phenotype and natural history have not been defined. We studied a genetically homogeneous group of 41 subjects with the 460InsA mutation in FTL1, documenting the presentation, clinical course, biochemistry and neuroimaging. The mean age of onset was 39.4 years (SD = 13.3, range 13-63), beginning with chorea in 50%, focal lower limb dystonia in 42.5% and parkinsonism in 7.5%. The majority reported a family history of a movement disorder often misdiagnosed as Huntington's disease. The disease progressed relentlessly, becoming generalized over a 5-10 year period, eventually leading to aphonia, dysphagia and severe motor disability with subcortical/frontal cognitive dysfunction as a late feature. A characteristic action-specific facial dystonia was common (65%), and in 63% there was asymmetry throughout the disease course. Serum ferritin levels were low in the majority of males and post-menopausal females, but within normal limits for pre-menopausal females. MR brain imaging was abnormal on all affected individuals and one presymptomatic carrier. In conclusion, isolated parkinsonism is unusual in neuroferritinopathy, and unlike Huntington's disease, cognitive changes are absent or subtle in the early stages. Depressed serum ferritin is common and provides a useful screening test in routine practice, and gradient echo brain MRI will identify all symptomatic cases.

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Next generation sequencing for molecular diagnosis of neurological disorders using ataxias as a model

Németh

et al. 2013

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Many neurological conditions are caused by immensely heterogeneous gene mutations. The diagnostic process is often long and complex with most patients undergoing multiple invasive and costly investigations without ever reaching a conclusive molecular diagnosis. The advent of massively parallel, next-generation sequencing promises to revolutionize genetic testing and shorten the ‘diagnostic odyssey’ for many of these patients. We performed a pilot study using heterogeneous ataxias as a model neurogenetic disorder to assess the introduction of next-generation sequencing into clinical practice. We captured 58 known human ataxia genes followed by Illumina Next-Generation Sequencing in 50 highly heterogeneous patients with ataxia who had been extensively investigated and were refractory to diagnosis. All cases had been tested for spinocerebellar ataxia 1–3, 6, 7 and Friedrich’s ataxia and had multiple other biochemical, genetic and invasive tests. In those cases where we identified the genetic mutation, we determined the time to diagnosis. Pathogenicity was assessed using a bioinformatics pipeline and novel variants were validated using functional experiments. The overall detection rate in our heterogeneous cohort was 18% and varied from 8.3% in those with an adult onset progressive disorder to 40% in those with a childhood or adolescent onset progressive disorder. The highest detection rate was in those with an adolescent onset and a family history (75%). The majority of cases with detectable mutations had a childhood onset but most are now adults, reflecting the long delay in diagnosis. The delays were primarily related to lack of easily available clinical testing, but other factors included the presence of atypical phenotypes and the use of indirect testing. In the cases where we made an eventual diagnosis, the delay was 3–35 years (mean 18.1 years). Alignment and coverage metrics indicated that the capture and sequencing was highly efficient and the consumable cost was ∼£400 (€460 or US$620). Our pathogenicity interpretation pathway predicted 13 different mutations in eight different genes: PRKCG, TTBK2, SETX, SPTBN2, SACS, MRE11, KCNC3 and DARS2 of which nine were novel including one causing a newly described recessive ataxia syndrome. Genetic testing using targeted capture followed by next-generation sequencing was efficient, cost-effective, and enabled a molecular diagnosis in many refractory cases. A specific challenge of next-generation sequencing data is pathogenicity interpretation, but functional analysis confirmed the pathogenicity of novel variants showing that the pipeline was robust. Our results have broad implications for clinical neurology practice and the approach to diagnostic testing.

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A genetic study of idiopathic focal dystonias

Waddy¹,

Fletcher²,

Harding³

et al. 1991

Annals of Neurology

229

118

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A genetic study of idiopathic focal dystonias was undertaken by examining 153 first-degree relatives of 40 index patients with torticollis (14 patients), other focal cranial dystonias (16 patients), and writer's cramp (10 patients). Nine relatives with dystonia were identified in 6 families; 8 of these had symptoms such as clumsiness or tremor, but none were aware of any dystonia. A further 4 relatives, now decreased, were affected by history. Overall, 25% of index patients had relatives with dystonia. The results of segregation analysis suggested the presence of an autosomal dominant gene or genes with reduced penetrance as a common cause for focal dystonia. Segregation ratios were not significantly different from those ratios observed in generalized or segmental dystonia in the United Kingdom, and it is possible that a single autosomal dominant gene mutation is responsible for inherited dystonia in the majority of patients irrespective of distribution or severity.

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Mutations in SNORD118 cause the cerebral microangiopathy leukoencephalopathy with calcifications and cysts

et al. 2016

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Although ribosomes are ubiquitously expressed and essential for life, recent data indicate that monogenic causes of ribosomal dysfunction can confer a remarkable degree of specificity in terms of human disease phenotype. Box C/D small nucleolar RNAs (snoRNAs) are evolutionarily conserved non-protein encoding RNAs involved in ribosome biogenesis. Here we show that biallelic mutations in the gene SNORD118, encoding the box C/D snoRNA U8, cause the cerebral microangiopathy leukoencephalopathy with calcifications and cysts (LCC), presenting at any age from early childhood to late adulthood. These mutations affect U8 expression, processing and protein binding and thus implicate U8 as essential in cerebral vascular homeostasis.

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The role of DYT1 in primary torsion dystonia in Europe

Valente¹,

Warner²,

Jarman³

et al. 1998

114

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Primary torsion dystonia (PTD) is a clinically and genetically heterogeneous movement disorder. DYT1 on chromosome 9q34 was the first PTD gene to be mapped. A 3-bp (GAG) deletion in this gene was reported to account for almost all early limb-onset generalized PTD. No relationship has been found with DYT1 in patients with prominent craniocervical involvement. To elucidate the DYT1-associated phenotype, we analysed the DYT1 mutation in 150 PTD patients, either sporadic or index cases from small PTD families. Twenty-two patients were positive for the GAG deletion in the DYT1 gene. Fifteen of them presented with the typical DYT1 phenotype (early, limb-onset generalized dystonia without spread to craniocervical muscles), four had limb-onset dystonia with spread to craniocervical muscles, two patients had arm-onset segmental dystonia and one had focal right-arm dystonia. One-hundred and twenty-eight patients were negative for the DYT1 mutation. Forty-six of them had segmental dystonia and 59 had focal dystonia. The other 23 patients presented with generalized dystonia, either with craniocervical involvement (13 patients) or without spread to the craniocervical region (typical DYT1 phenotype-10 patients). These data confirm the importance of the GAG deletion in European cases of PTD, and indicate phenotypic and genotypic heterogeneity.

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