Your search keyword '"Blakely, Emma"' showing total 27 results

1. Pathological mechanisms underlying single large-scale mitochondrial DNA deletions.

Author

Rocha, Mariana C., Rosa, Hannah S., Grady, John P., Blakely, Emma L., He, Langping, Romain, Nadine, Haller, Ronald G., Newman, Jane, McFarland, Robert, Ng, Yi Shiau, Gorman, Grainne S., Schaefer, Andrew M., Tuppen, Helen A., Taylor, Robert W., and Turnbull, Doug M.

Subjects

MITOCHONDRIAL DNA, MITOCHONDRIAL pathology, SKELETAL muscle, BIOLOGICAL assay, IMMUNOFLUORESCENCE, BIOPSY, COMPARATIVE studies, DNA, ENERGY metabolism, ENZYMES, LONGITUDINAL method, RESEARCH methodology, MEDICAL cooperation, GENETIC mutation, PROTEINS, RESEARCH, EVALUATION research, GENOTYPES

Abstract

Objective: Single, large-scale deletions in mitochondrial DNA (mtDNA) are a common cause of mitochondrial disease. This study aimed to investigate the relationship between the genetic defect and molecular phenotype to improve understanding of pathogenic mechanisms associated with single, large-scale mtDNA deletions in skeletal muscle.Methods: We investigated 23 muscle biopsies taken from adult patients (6 males/17 females with a mean age of 43 years) with characterized single, large-scale mtDNA deletions. Mitochondrial respiratory chain deficiency in skeletal muscle biopsies was quantified by immunoreactivity levels for complex I and complex IV proteins. Single muscle fibers with varying degrees of deficiency were selected from 6 patient biopsies for determination of mtDNA deletion level and copy number by quantitative polymerase chain reaction.Results: We have defined 3 "classes" of single, large-scale deletion with distinct patterns of mitochondrial deficiency, determined by the size and location of the deletion. Single fiber analyses showed that fibers with greater respiratory chain deficiency harbored higher levels of mtDNA deletion with an increase in total mtDNA copy number. For the first time, we have demonstrated that threshold levels for complex I and complex IV deficiency differ based on deletion class.Interpretation: Combining genetic and immunofluorescent assays, we conclude that thresholds for complex I and complex IV deficiency are modulated by the deletion of complex-specific protein-encoding genes. Furthermore, removal of mt-tRNA genes impacts specific complexes only at high deletion levels, when complex-specific protein-encoding genes remain. These novel findings provide valuable insight into the pathogenic mechanisms associated with these mutations. Ann Neurol 2018;83:115-130. [ABSTRACT FROM AUTHOR]

Published

2018

2. Pathogenic mitochondrial mt-tRNAAla variants are uniquely associated with isolated myopathy.

Author

Lehmann, Diana, Schubert, Kathrin, Joshi, Pushpa R, Hardy, Steven A, Tuppen, Helen A L, Baty, Karen, Blakely, Emma L, Bamberg, Christian, Zierz, Stephan, Deschauer, Marcus, and Taylor, Robert W

Subjects

MUSCLE diseases, MITOCHONDRIAL DNA abnormalities, HUMAN genetic variation, GENETIC mutation, PHOSPHORYLATION, GENETICS

Abstract

Pathogenic mitochondrial DNA (mtDNA) point mutations are associated with a wide range of clinical phenotypes, often involving multiple organ systems. We report two patients with isolated myopathy owing to novel mt-tRNAAla variants. Muscle biopsy revealed extensive histopathological findings including cytochrome c oxidase (COX)-deficient fibres. Pyrosequencing confirmed mtDNA heteroplasmy for both mutations (m.5631G>A and m.5610G>A) whilst single-muscle fibre segregation studies (revealing statistically significant higher mutation loads in COX-deficient fibres than in COX-positive fibres), hierarchical mutation segregation within patient tissues and decreased steady-state mt-tRNAAla levels all provide compelling evidence of pathogenicity. Interestingly, both patients showed very high-mutation levels in all tissues, inferring that the threshold for impairment of oxidative phosphorylation, as evidenced by COX deficiency, appears to be extremely high for these mt-tRNAAla variants. Previously described mt-tRNAAla mutations are also associated with a pure myopathic phenotype and demonstrate very high mtDNA heteroplasmy thresholds, inferring at least some genotype:phenotype correlation for mutations within this particular mt-tRNA gene. [ABSTRACT FROM AUTHOR]

Published

2015

3. A recessive homozygous p.Asp92Gly SDHD mutation causes prenatal cardiomyopathy and a severe mitochondrial complex II deficiency.

Author

Alston, Charlotte, Ceccatelli Berti, Camilla, Blakely, Emma, Oláhová, Monika, He, Langping, McMahon, Colin, Olpin, Simon, Hargreaves, Iain, Nolli, Cecilia, McFarland, Robert, Goffrini, Paola, O'Sullivan, Maureen, and Taylor, Robert

Subjects

SUCCINATE dehydrogenase, GENETIC mutation, CARDIOMYOPATHIES, MITOCHONDRIAL pathology, HOMOZYGOSITY, DEFICIENCY diseases, GENETICS

Abstract

Succinate dehydrogenase (SDH) is a crucial metabolic enzyme complex that is involved in ATP production, playing roles in both the tricarboxylic cycle and the mitochondrial respiratory chain (complex II). Isolated complex II deficiency is one of the rarest oxidative phosphorylation disorders with mutations described in three structural subunits and one of the assembly factors; just one case is attributed to recessively inherited SDHD mutations. We report the pathological, biochemical, histochemical and molecular genetic investigations of a male neonate who had left ventricular hypertrophy detected on antenatal scan and died on day one of life. Subsequent postmortem examination confirmed hypertrophic cardiomyopathy with left ventricular non-compaction. Biochemical analysis of his skeletal muscle biopsy revealed evidence of a severe isolated complex II deficiency and candidate gene sequencing revealed a novel homozygous c.275A>G, p.(Asp92Gly) SDHD mutation which was shown to be recessively inherited through segregation studies. The affected amino acid has been reported as a Dutch founder mutation p.(Asp92Tyr) in families with hereditary head and neck paraganglioma. By introducing both mutations into Saccharomyces cerevisiae, we were able to confirm that the p.(Asp92Gly) mutation causes a more severe oxidative growth phenotype than the p.(Asp92Tyr) mutant, and provides functional evidence to support the pathogenicity of the patient's SDHD mutation. This is only the second case of mitochondrial complex II deficiency due to inherited SDHD mutations and highlights the importance of sequencing all SDH genes in patients with biochemical and histochemical evidence of isolated mitochondrial complex II deficiency. [ABSTRACT FROM AUTHOR]

Published

2015

4. Novel MTND1 mutations cause isolated exercise intolerance, complex I deficiency and increased assembly factor expression.

Author

Gorman, Grainne S., Blakely, Emma L., Hue Tran Hornig Do, Tuppen, Helen A. L., Greaves, Laura C., Langping He, Baker, Angela, Falkous, Gavin, Newman, Jane, Trenell, Michael I., Lecky, Bryan, Petty, Richard K., Turnbull, Doug M., McFarland, Robert, and Taylor, Robert W.

Subjects

*GENETIC mutation, *EXERCISE, *GENE expression, *OXIDATIVE phosphorylation, *MITOCHONDRIAL DNA, *DEHYDROGENASES

Abstract

Complex I (CI) is the largest of the five multi-subunit complexes constituting the human oxidative phosphorylation (OXPHOS) system. Seven of its catalytic core subunits are encoded by mitochondrial DNA (ND (NADH dehydrogenase)1-6, ND4L (NADH dehydrogenase subunit 4L)), with mutations in all seven having been reported in association with isolated CI deficiency. We investigated two unrelated adult patients presenting with marked exercise intolerance, persistent lactic acidaemia and severe muscle-restricted isolated CI deficiency associated with sub-sarcolemmal mitochondrial accumulation. Screening of the mitochondrial genome detected novel mutations in the MTND1 (NADH dehydrogenase subunit 1) gene, encoding subunit of CI [Patient 1, m.3365T>C predicting p.(Leu20Pro); Patient 2, m.4175G>A predicting p.(Trp290*)] at high levels of mitochondrial DNA heteroplasmy in skeletal muscle. We evaluated the effect of these novel MTND1 mutations on complex assembly showing that CI assembly, although markedly reduced, was viable in the absence of detectable ND1 signal. Real-time PCR and Western blotting showed overexpression of different CI assembly factor transcripts and proteins in patient tissue. Together, our data indicate that the mechanism underlying the expression of the biochemical defect may involve a compensatory response to the novel MTND1 gene mutations, promoting assembly factor up-regulation and stabilization of respiratory chain super-complexes, resulting in partial rescue of the clinical phenotype. [ABSTRACT FROM AUTHOR]

Published

2015

5. Accurate Measurement of Mitochondrial DNA Deletion Level and Copy Number Differences in Human Skeletal Muscle.

Author

Grady, John P., Murphy, Julie L., Blakely, Emma L., Haller, Ronald G., Taylor, Robert W., Turnbull, Doug M., and Tuppen, Helen A. L.

Subjects

MITOCHONDRIAL DNA, DNA copy number variations, SKELETAL muscle physiology, GENETIC mutation, MOLECULAR genetics

Abstract

Accurate and reliable quantification of the abundance of mitochondrial DNA (mtDNA) molecules, both wild-type and those harbouring pathogenic mutations, is important not only for understanding the progression of mtDNA disease but also for evaluating novel therapeutic approaches. A clear understanding of the sensitivity of mtDNA measurement assays under different experimental conditions is therefore critical, however it is routinely lacking for most published mtDNA quantification assays. Here, we comprehensively assess the variability of two quantitative Taqman real-time PCR assays, a widely-applied MT-ND1/MT-ND4 multiplex mtDNA deletion assay and a recently developed MT-ND1/B2M singleplex mtDNA copy number assay, across a range of DNA concentrations and mtDNA deletion/copy number levels. Uniquely, we provide a specific guide detailing necessary numbers of sample and real-time PCR plate replicates for accurately and consistently determining a given difference in mtDNA deletion levels and copy number in homogenate skeletal muscle DNA. [ABSTRACT FROM AUTHOR]

Published

2014

6. Use of Whole-Exome Sequencing to Determine the Genetic Basis of Multiple Mitochondrial Respiratory Chain Complex Deficiencies.

Author

Taylor, Robert W., Pyle, Angela, Griffin, Helen, Blakely, Emma L., Duff, Jennifer, Langping He, Smertenko, Tania, Alston, Charlotte L., Neeve, Vivienne C., Best, Andrew, Yarham, John W., Kirschner, Janbernd, Schara, Ulrike, Talim, Beril, Topaloglu, Haluk, Baric, Ivo, Holinski-Feder, Elke, Abicht, Angela, Czermin, Birgit, and Kleinle, Stephanie

Subjects

MITOCHONDRIAL pathology, RESPIRATORY disease diagnosis, MOLECULAR diagnosis, MITOCHONDRIAL DNA, GENETIC mutation, DIAGNOSIS

Abstract

IMPORTANCE Mitochondrial disorders have emerged as a common cause of inherited disease, but their diagnosis remains challenging. Multiple respiratory chain complex defects are particularly difficult to diagnose at the molecular level because of the massive number of nuclear genes potentially involved in intramitochondrial protein synthesis, with many not yet linked to human disease. OBJECTIVE To determine the molecular basis of multiple respiratory chain complex deficiencies. DESIGN, SETTING, AND PARTICIPANTS We studied 53 patients referred to 2 national centers in the United Kingdom and Germany between 2005 and 2012. All had biochemical evidence of multiple respiratory chain complex defects but no primary pathogenic mitochondrial DNA mutation. Whole-exome sequencing was performed using 62-Mb exome enrichment, followed by variant prioritization using bioinformatic prediction tools, variant validation by Sanger sequencing, and segregation of the variant with the disease phenotype in the family. RESULTS Presumptive causal variants were identified in 28 patients (53%; 95% Cl, 39%-67%) and possible causal variants were identified in 4 (8%; 95% Cl, 2%-18%). Together these accounted for 32 patients (60% 95% Cl, 46%-74%) and involved 18 different genes. These included recurrent mutations in RMND1, AARS2, and MT01, each on a haplotype background consistent with a shared founder allele, and potential novel mutations in 4 possible mitochondrial disease genes (VARS2, GARS, FLAD1, and PTCD1). Distinguishing clinical features included deafness and renal involvement associated with RMND1 and cardiomyopathy with AARS2 and MT01. However, atypical clinical features were present in some patients, including normal liver function and Leigh syndrome (subacute necrotizing encephalomyelopathy) seen in association with TRMU mutations and no cardiomyopathy with founder SC02 mutations. It was not possible to confidently identify the underlying genetic basis in 21 patients (40%; 95% Cl, 26%-54%). CONCLUSIONS AND RELEVANCE Exome sequencing enhances the ability to identify potential nuclear gene mutations in patients with biochemically defined defects affecting multiple mitochondrial respiratory chain complexes. Additional study is required in independent patient populations to determine the utility of this approach in comparison with traditional diagnostic methods. [ABSTRACT FROM AUTHOR]

Published

2014

7. Distal weakness with respiratory insufficiency caused by the m.8344A>G “MERRF” mutation.

Author

Blakely, Emma L., Alston, Charlotte L., Lecky, Bryan, Chakrabarti, Biswajit, Falkous, Gavin, Turnbull, Douglass M., Taylor, Robert W., and Gorman, Grainne S.

Subjects

*ASTHENIA, *RESPIRATORY insufficiency, *MERRF syndrome, *GENETIC mutation, *TRANSFER RNA, *EPILEPSY, *ATAXIA, *MYOCLONUS, *PHENOTYPES

Abstract

Abstract: The m.8344A>G mutation in the mt-tRNALys gene, first described in myoclonic epilepsy and ragged red fibers (MERRF), accounts for approximately 80% of mutations in individuals with MERRF syndrome. Although originally described in families with a classical syndrome of myoclonus, ataxia, epilepsy and ragged red fibers in muscle biopsy, the m.8344A>G mutation is increasingly recognised to exhibit marked phenotypic heterogeneity. This paper describes the clinical, morphological and laboratory features of an unusual phenotype in a patient harboring the m.8344A>G ‘MERRF’ mutation. We present the case of a middle-aged woman with distal weakness since childhood who also had ptosis and facial weakness and who developed mid-life respiratory insufficiency necessitating non-invasive nocturnal ventilator support. Neurophysiological and acetylcholine receptor antibody analyses excluded myasthenia gravis whilst molecular genetic testing excluded myotonic dystrophy, prompting a diagnostic needle muscle biopsy. Mitochondrial histochemical abnormalities including subsarcolemmal mitochondrial accumulation (ragged-red fibers) and in excess of 90% COX-deficient fibers, was seen leading to sequencing of the mitochondrial genome in muscle. This identified the m.8344A>G mutation commonly associated with the MERRF phenotype. This case extends the evolving phenotypic spectrum of the m.8344A>G mutation and emphasizes that it may cause indolent distal weakness with respiratory insufficiency, with marked histochemical defects in muscle. Our findings support consideration of screening of this gene in cases of indolent myopathy resembling distal limb-girdle muscular dystrophy in which screening of the common genes prove negative. [Copyright &y& Elsevier]

Published

2014

8. Defective i6A37 Modification of Mitochondrial and Cytosolic tRNAs Results from Pathogenic Mutations in TRIT1 and Its Substrate tRNA.

Author

Yarham, John W., Lamichhane, Tek N., Pyle, Angela, Mattijssen, Sandy, Baruffini, Enrico, Bruni, Francesco, Donnini, Claudia, Vassilev, Alex, He, Langping, Blakely, Emma L., Griffin, Helen, Santibanez-Koref, Mauro, Bindoff, Laurence A., Ferrero, Ileana, Chinnery, Patrick F., McFarland, Robert, Maraia, Richard J., and Taylor, Robert W.

Subjects

MITOCHONDRIA, GENETIC mutation, TRANSFER RNA, NUCLEIC acids, MITOCHONDRIAL DNA

Abstract

Identifying the genetic basis for mitochondrial diseases is technically challenging given the size of the mitochondrial proteome and the heterogeneity of disease presentations. Using next-generation exome sequencing, we identified in a patient with severe combined mitochondrial respiratory chain defects and corresponding perturbation in mitochondrial protein synthesis, a homozygous p.Arg323Gln mutation in TRIT1. This gene encodes human tRNA isopentenyltransferase, which is responsible for i6A37 modification of the anticodon loops of a small subset of cytosolic and mitochondrial tRNAs. Deficiency of i6A37 was previously shown in yeast to decrease translational efficiency and fidelity in a codon-specific manner. Modelling of the p.Arg323Gln mutation on the co-crystal structure of the homologous yeast isopentenyltransferase bound to a substrate tRNA, indicates that it is one of a series of adjacent basic side chains that interact with the tRNA backbone of the anticodon stem, somewhat removed from the catalytic center. We show that patient cells bearing the p.Arg323Gln TRIT1 mutation are severely deficient in i6A37 in both cytosolic and mitochondrial tRNAs. Complete complementation of the i6A37 deficiency of both cytosolic and mitochondrial tRNAs was achieved by transduction of patient fibroblasts with wild-type TRIT1. Moreover, we show that a previously-reported pathogenic m.7480A>G mt-tRNASer(UCN) mutation in the anticodon loop sequence A36A37A38 recognised by TRIT1 causes a loss of i6A37 modification. These data demonstrate that deficiencies of i6A37 tRNA modification should be considered a potential mechanism of human disease caused by both nuclear gene and mitochondrial DNA mutations while providing insight into the structure and function of TRIT1 in the modification of cytosolic and mitochondrial tRNAs. [ABSTRACT FROM AUTHOR]

Published

2014

9. Mutations in the SPG7 gene cause chronic progressive external ophthalmoplegia through disordered mitochondrial DNA maintenance.

Author

Pfeffer, Gerald, Gorman, Gráinne S, Griffin, Helen, Kurzawa-Akanbi, Marzena, Blakely, Emma L., Wilson, Ian, Sitarz, Kamil, Moore, David, Murphy, Julie L., Alston, Charlotte L., Pyle, Angela, Coxhead, Jon, Payne, Brendan, Gorrie, George H., Longman, Cheryl, Hadjivassiliou, Marios, McConville, John, Dick, David, Imam, Ibrahim, and Hilton, David

Subjects

CHRONIC progressive external opthalmoplegia, GENETIC mutation, MITOCHONDRIAL DNA, FAMILIAL spastic paraplegia, PHENOTYPES, FIBROBLASTS

Abstract

Progressive external ophthalmoplegia (PEO) is a canonical feature of mitochondrial disease, but in many patients its genetic basis is unknown. Using exome sequencing, Pfeffer et al. identify mutations in SPG7 as an important cause of PEO associated with spasticity and ataxia, and uncover evidence of disordered mtDNA maintenance in patients.Despite being a canonical presenting feature of mitochondrial disease, the genetic basis of progressive external ophthalmoplegia remains unknown in a large proportion of patients. Here we show that mutations in SPG7 are a novel cause of progressive external ophthalmoplegia associated with multiple mitochondrial DNA deletions. After excluding known causes, whole exome sequencing, targeted Sanger sequencing and multiplex ligation-dependent probe amplification analysis were used to study 68 adult patients with progressive external ophthalmoplegia either with or without multiple mitochondrial DNA deletions in skeletal muscle. Nine patients (eight probands) were found to carry compound heterozygous SPG7 mutations, including three novel mutations: two missense mutations c.2221G>A; p.(Glu741Lys), c.2224G>A; p.(Asp742Asn), a truncating mutation c.861dupT; p.Asn288*, and seven previously reported mutations. We identified a further six patients with single heterozygous mutations in SPG7, including two further novel mutations: c.184-3C>T (predicted to remove a splice site before exon 2) and c.1067C>T; p.(Thr356Met). The clinical phenotype typically developed in mid-adult life with either progressive external ophthalmoplegia/ptosis and spastic ataxia, or a progressive ataxic disorder. Dysphagia and proximal myopathy were common, but urinary symptoms were rare, despite the spasticity. Functional studies included transcript analysis, proteomics, mitochondrial network analysis, single fibre mitochondrial DNA analysis and deep re-sequencing of mitochondrial DNA. SPG7 mutations caused increased mitochondrial biogenesis in patient muscle, and mitochondrial fusion in patient fibroblasts associated with the clonal expansion of mitochondrial DNA mutations. In conclusion, the SPG7 gene should be screened in patients in whom a disorder of mitochondrial DNA maintenance is suspected when spastic ataxia is prominent. The complex neurological phenotype is likely a result of the clonal expansion of secondary mitochondrial DNA mutations modulating the phenotype, driven by compensatory mitochondrial biogenesis. [ABSTRACT FROM PUBLISHER]

Published

2014

10. Adults with RRM2B-related mitochondrial disease have distinct clinical and molecular characteristics.

Author

Pitceathly, Robert D. S., Smith, Conrad, Fratter, Carl, Alston, Charlotte L., He, Langping, Craig, Kate, Blakely, Emma L., Evans, Julie C., Taylor, John, Shabbir, Zarfishan, Deschauer, Marcus, Pohl, Ute, Roberts, Mark E., Jackson, Matthew C., Halfpenny, Christopher A., Turnpenny, Peter D., Lunt, Peter W., Hanna, Michael G., Schaefer, Andrew M., and McFarland, Robert

Subjects

MITOCHONDRIAL DNA, CLINICAL trials, MOLECULAR biology, GENETIC mutation, GENETIC code, LITERATURE reviews

Abstract

Mutations in the nuclear-encoded mitochondrial maintenance gene RRM2B are an important cause of familial mitochondrial disease in both adults and children and represent the third most common cause of multiple mitochondrial DNA deletions in adults, following POLG [polymerase (DNA directed), gamma] and PEO1 (now called C10ORF2, encoding the Twinkle helicase) mutations. However, the clinico-pathological and molecular features of adults with RRM2B-related disease have not been clearly defined. In this multicentre study of 26 adult patients from 22 independent families, including five additional cases published in the literature, we show that extra-ocular neurological complications are common in adults with genetically confirmed RRM2B mutations. We also demonstrate a clear correlation between the clinical phenotype and the underlying genetic defect. Myopathy was a prominent manifestation, followed by bulbar dysfunction and fatigue. Sensorineural hearing loss and gastrointestinal disturbance were also important findings. Severe multisystem neurological disease was associated with recessively inherited compound heterozygous mutations with a mean age of disease onset at 7 years. Dominantly inherited heterozygous mutations were associated with a milder predominantly myopathic phenotype with a later mean age of disease onset at 46 years. Skeletal muscle biopsies revealed subsarcolemmal accumulation of mitochondria and/or cytochrome c oxidase-deficient fibres. Multiple mitochondrial DNA deletions were universally present in patients who underwent a muscle biopsy. We identified 18 different heterozygous RRM2B mutations within our cohort of patients, including five novel mutations that have not previously been reported. Despite marked clinical overlap between the mitochondrial maintenance genes, key clinical features such as bulbar dysfunction, hearing loss and gastrointestinal disturbance should help prioritize genetic testing towards RRM2B analysis, and sequencing of the gene may preclude performance of a muscle biopsy. [ABSTRACT FROM PUBLISHER]

Published

2012

11. Adult-onset spinocerebellar ataxia syndromes due to MTATP6mutations.

Author

Pfeffer, Gerald, Blakely, Emma L., Alston, Charlotte L., Hassani, Adam, Boggild, Mike, Horvath, Rita, Samuels, David C., Taylor, Robert W., and Chinnery, Patrick F.

Subjects

*SPINOCEREBELLAR ataxia, *GENETIC mutation, *PERIPHERAL neuropathy, *GENETIC testing, *MITOCHONDRIAL DNA abnormalities, *CLINICAL pathology

Abstract

BackgroundSpinocerebellar ataxia syndromes presenting in adulthood have a broad range of causes, and despite extensive investigation remain undiagnosed in up to ∼50% cases. Mutations in the mitochondrially encoded MTATP6gene typically cause infantile-onset Leigh syndrome and, occasionally, have onset later in childhood. The authors report two families with onset of ataxia in adulthood (with pyramidal dysfunction and/or peripheral neuropathy variably present), who are clinically indistinguishable from other spinocerebellar ataxia patients.MethodsGenetic screening study of the MTATP6gene in 64 pedigrees with unexplained ataxia, and case series of two families who had MTATP6mutations.ResultsThree pedigrees had mutations in MTATP6, two of which have not been reported previously and are detailed in this report. These families had the m.9185T>C and m.9035T>C mutations, respectively, which have not previously been associated with adult-onset cerebellar syndromes. Other investigations including muscle biopsy and respiratory chain enzyme activity were non-specific or normal.ConclusionsMTATP6sequencing should be considered in the workup of undiagnosed ataxia, even if other investigations do not suggest a mitochondrial DNA disorder. [ABSTRACT FROM AUTHOR]

Published

2012

12. Mutations in the mitochondrial tRNASer(AGY) gene are associated with deafness, retinal degeneration, myopathy and epilepsy.

Author

Tuppen, Helen AL, Naess, Karin, Kennaway, Nancy G, Al-Dosary, Mazhor, Lesko, Nicole, Yarham, John W, Bruhn, Helene, Wibom, Rolf, Nennesmo, Inger, Weleber, Richard G, Blakely, Emma L, Taylor, Robert W, and McFarland, Robert

Subjects

GENETIC mutation, TRANSFER RNA, MITOCHONDRIAL DNA, GENES, RETINAL degeneration, DEAFNESS, MUSCLE diseases, CAUCASIAN race

Abstract

Although over 200 pathogenic mitochondrial DNA (mtDNA) mutations have been reported to date, determining the genetic aetiology of many cases of mitochondrial disease is still not straightforward. Here, we describe the investigations undertaken to uncover the underlying molecular defect(s) in two unrelated Caucasian patients with suspected mtDNA disease, who presented with similar symptoms of myopathy, deafness, neurodevelopmental delay, epilepsy, marked fatigue and, in one case, retinal degeneration. Histochemical and biochemical evidence of mitochondrial respiratory chain deficiency was observed in the patient muscle biopsies and both patients were discovered to harbour a novel heteroplasmic mitochondrial tRNA (mt-tRNA)Ser(AGY) (MTTS2) mutation (m.12264C>T and m.12261T>C, respectively). Clear segregation of the m.12261T>C mutation with the biochemical defect, as demonstrated by single-fibre radioactive RFLP, confirmed the pathogenicity of this novel variant in patient 2. However, unusually high levels of m.12264C>T mutation within both COX-positive (98.4±1.5%) and COX-deficient (98.2 ±2.1%) fibres in patient 1 necessitated further functional investigations to prove its pathogenicity. Northern blot analysis demonstrated the detrimental effect of the m.12264C>T mutation on mt-tRNASer(AGY) stability, ultimately resulting in decreased steady-state levels of fully assembled complexes I and IV, as shown by blue-native polyacrylamide gel electrophoresis. Our findings expand the spectrum of pathogenic mutations associated with the MTTS2 gene and highlight MTTS2 mutations as an important cause of retinal and syndromic auditory impairment. [ABSTRACT FROM AUTHOR]

Published

2012

13. MPV17 mutation causes neuropathy and leukoencephalopathy with multiple mtDNA deletions in muscle

Author

Blakely, Emma L., Butterworth, Anna, Hadden, Robert D.M., Bodi, Istvan, He, Langping, McFarland, Robert, and Taylor, Robert W.

Subjects

*GENETIC mutation, *NEUROPATHY, *PROGRESSIVE multifocal leukoencephalopathy, *MITOCHONDRIAL DNA, *DELETION mutation, *MITOCHONDRIAL pathology, *CYTOCHROME oxidase

Abstract

Abstract: Disorders of mitochondrial DNA (mtDNA) maintenance are clinically and genetically heterogeneous, embracing recessive mtDNA depletion syndromes affecting children and adult-onset multiple mtDNA deletion disorders. Here we show that mutation of MPV17 – a gene implicated in severe, infantile hepatocerebral mtDNA depletion disorders characterised by a loss of mtDNA copies – can also cause clonally-expanded mtDNA deletion and focal cytochrome c oxidase (COX) deficiency in skeletal muscle associated with an adult presentation of neuropathy and leukoencephalopathy. The mpv17 protein is therefore intimately involved in both the mtDNA replication and repair processes and associated with both quantitative and qualitative mtDNA abnormalities. [Copyright &y& Elsevier]

Published

2012

14. Sensory neuronopathy in patients harbouring recessive polymerase γ mutations.

Author

Lax, Nichola Z., Whittaker, Roger G., Hepplewhite, Philippa D., Reeve, Amy K., Blakely, Emma L., Jaros, Evelyn, Ince, Paul G., Taylor, Robert W., Fawcett, Peter R. W., and Turnbull, Doug M.

Subjects

MITOCHONDRIAL DNA abnormalities, NEUROLOGICAL disorders, THERAPEUTICS, SENSORY neurons, NEURODEGENERATION, GENETIC mutation, DNA replication, ELECTROPHYSIOLOGY

Abstract

Defects in the mitochondrial DNA replication enzyme, polymerase γ, are an important cause of mitochondrial disease with ∼25% of all adult diagnoses attributed to mutations in the POLG gene. Peripheral neuronopathy is often part of the clinical syndrome and can represent the most disabling feature. In spite of this, the molecular mechanisms underlying the neuronopathy remain to be elucidated and treatment strategies are limited. In the present study, we use a combined approach comprising clinical, electrophysiological, neuropathological and molecular genetic investigations to unravel the mechanisms underpinning peripheral neuronopathy in autosomal recessive polymerase γ-related disease. Electrophysiological assessments documented a dorsal root ganglionopathy in all 11 cases. Of the 11 cases, eight also showed changes consistent with motor fibre loss. Detailed neuropathological investigation of two patients confirmed the electrophysiological findings, revealing atrophy of posterior columns and striking neuronal cell loss from the dorsal root ganglia, which was accompanied by severe mitochondrial biochemical abnormalities involving respiratory chain complexes I and IV due to clonally-expanded mitochondrial DNA deletions and a significant reduction in mitochondrial DNA copy number in affected neurons. We propose that the respiratory chain defects, secondary to mitochondrial DNA deletion and depletion, are likely to be responsible for pathology observed in the dorsal root ganglion and the sensory ganglionopathy documented electrophysiologically. [ABSTRACT FROM PUBLISHER]

Published

2012

15. Respiratory chain complex I deficiency caused by mitochondrial DNA mutations.

Author

Swalwell, Helen, Kirby, Denise M., Blakely, Emma L., Mitchell, Anna, Salemi, Renato, Sugiana, Canny, Compton, Alison G., Tucker, Elena J, Ke, Bi-Xia, Lamont, Phillipa J., Turnbull, Douglass M, McFarland, Robert, Taylor, Robert W., and Thorburn, David R.

Subjects

MITOCHONDRIAL DNA abnormalities, RESPIRATORY diseases, DNA, GENETIC mutation, GENETIC disorders in children, GENOMES, CELL fusion

Abstract

Defects of the mitochondrial respiratory chain are associated with a diverse spectrum of clinical phenotypes, and may be caused by mutations in either the nuclear or the mitochondrial genome (mitochondrial DNA (mtDNA)). Isolated complex I deficiency is the most common enzyme defect in mitochondrial disorders, particularly in children in whom family history is often consistent with sporadic or autosomal recessive inheritance, implicating a nuclear genetic cause. In contrast, although a number of recurrent, pathogenic mtDNA mutations have been described, historically, these have been perceived as rare causes of paediatric complex I deficiency. We reviewed the clinical and genetic findings in a large cohort of 109 paediatric patients with isolated complex I deficiency from 101 families. Pathogenic mtDNA mutations were found in 29 of 101 probands (29%), 21 in MTND subunit genes and 8 in mtDNA tRNA genes. Nuclear gene defects were inferred in 38 of 101 (38%) probands based on cell hybrid studies, mtDNA sequencing or mutation analysis (nuclear gene mutations were identified in 22 probands). Leigh or Leigh-like disease was the most common clinical presentation in both mtDNA and nuclear genetic defects. The median age at onset was higher in mtDNA patients (12 months) than in patients with a nuclear gene defect (3 months). However, considerable overlap existed, with onset varying from 0 to >60 months in both groups. Our findings confirm that pathogenic mtDNA mutations are a significant cause of complex I deficiency in children. In the absence of parental consanguinity, we recommend whole mitochondrial genome sequencing as a key approach to elucidate the underlying molecular genetic abnormality. [ABSTRACT FROM AUTHOR]

Published

2011

16. The p.M292T NDUFS2 mutation causes complex I-deficient Leigh syndrome in multiple families.

Author

Tuppen, Helen A. L., Hogan, Vanessa E., Langping He, Blakely, Emma L., Worgan, Lisa, Al-Dosary, Mazhor, Saretzki, Gabriele, Alston, Charlotte L., Morris, Andrew A., Clarke, Michael, Jones, Simon, Devlin, Anita M., Mansour, Sahar, Chrzanowska-Lightowlers, Zofia M. A., Thorburn, David R., McFarland, Robert, and Taylor, Robert W.

Subjects

PHOSPHORYLATION, MITOCHONDRIAL pathology, GENETIC mutation, PEDIATRICS, JUVENILE diseases

Abstract

Isolated complex I deficiency is the most frequently observed oxidative phosphorylation defect in children with mitochondrial disease, leading to a diverse range of clinical presentations, including Leigh syndrome. For most patients the genetic cause of the biochemical defect remains unknown due to incomplete understanding of the complex I assembly process. Nonetheless, a plethora of pathogenic mutations have been described to date in the seven mitochondrial-encoded subunits of complex I as well as in 12 of the nuclear-encoded subunits and in six assembly factors. Whilst several mitochondrial DNA mutations are recurrent, the majority of these mutations are reported in single families. We have sequenced core structural and functional nuclear-encoded subunits of complex I in a cohort of 34 paediatric patients with isolated complex I deficiency, identifying pathogenic mutations in 6 patients. These included a novel homozygous NDUFS1 mutation in an Asian child with Leigh syndrome, a previously identified NDUFS8 mutation (c.236C>T, p.P79L) in a second Asian child with Leigh-like syndrome and six novel, compound heterozygous NDUFS2 mutations in four white Caucasian patients with Leigh or Leigh-like syndrome. Three of these children harboured an identical NDUFS2 mutation (c.875T>C, p.M292T), which was also identified in conjunction with a novel NDUFS2 splice site mutation (c.866+4A>G) in a fourth Caucasian child who presented to a different diagnostic centre, with microsatellite and single nucleotide polymorphism analyses indicating that this was due to an ancient common founder event. Our results confirm that NDUFS2 is a mutational hotspot in Caucasian children with isolated complex I deficiency and recommend the routine diagnostic investigation of this gene in patients with Leigh or Leigh-like phenotypes. [ABSTRACT FROM PUBLISHER]

Published

2010

17. Mitochondrial DNA mutations and human disease

Author

Tuppen, Helen A.L., Blakely, Emma L., Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*MITOCHONDRIAL DNA, *GENETIC mutation, *MITOCHONDRIAL pathology, *PHENOTYPES, *TWO-dimensional electrophoresis, *MITOCHONDRIAL membranes, *PARKINSON'S disease, *PHOSPHORYLATION

Abstract

Abstract: Mitochondrial disorders are a group of clinically heterogeneous diseases, commonly defined by a lack of cellular energy due to oxidative phosphorylation (OXPHOS) defects. Since the identification of the first human pathological mitochondrial DNA (mtDNA) mutations in 1988, significant efforts have been spent in cataloguing the vast array of causative genetic defects of these disorders. Currently, more than 250 pathogenic mtDNA mutations have been identified. An ever-increasing number of nuclear DNA mutations are also being reported as the majority of proteins involved in mitochondrial metabolism and maintenance are nuclear-encoded. Understanding the phenotypic diversity and elucidating the molecular mechanisms at the basis of these diseases has however proved challenging. Progress has been hampered by the peculiar features of mitochondrial genetics, an inability to manipulate the mitochondrial genome, and difficulties in obtaining suitable models of disease. In this review, we will first outline the unique features of mitochondrial genetics before detailing the diseases and their genetic causes, focusing specifically on primary mtDNA genetic defects. The functional consequences of mtDNA mutations that have been characterised to date will also be discussed, along with current and potential future diagnostic and therapeutic advances. [Copyright &y& Elsevier]

Published

2010

18. A homoplasmic mtDNA variant can influence the phenotype of the pathogenic m.7472Cins MTTS1 mutation: are two mutations better than one?

Author

Swalwell, Helen, Blakely, Emma L., Sutton, Ruth, Tonska, Kasia, Elstner, Matthias, Langping He, Taivassalo, Tanja, Burns, Dennis K., Turnbull, Douglass M., Haller, Ronald G., Davidson, Mercy M., and Taylor, Robert W.

Subjects

*GENETIC mutation, *HETEROGENEITY, *MITOCHONDRIAL DNA, *MUSCLE diseases, *DEAFNESS, *DIABETES

Abstract

Mutations in mitochondrial tRNA (mt-tRNA) genes are well recognized as a common cause of human disease, exhibiting a significant degree of clinical heterogeneity. While these differences are explicable, in part, by differences in the innate pathogenicity of the mutation, its distribution and abundance, other factors, including nuclear genetic background, mitochondrial DNA (mtDNA) haplotype and additional mtDNA mutations may influence the expression of mt-tRNA mutations. We describe the clinical, biochemical and molecular findings in a family with progressive myopathy, deafness and diabetes and striking respiratory chain abnormalities due to a well-characterized heteroplasmic mt-tRNA mutation in the mt-tRNASer(UCN) (MTTS1) gene. In addition to the m.7472Cins mutation, all individuals were homoplasmic for another variant, m.7472A>C, affecting the adjacent nucleotide in the mt-tRNASer(UCN) structure. In addition to available patient tissues, we have analysed transmitochondrial cybrid clones harbouring homoplasmic levels of m.7472A>C and varying levels of the m.7472Cins mutation in an attempt to clarify the precise role of the m.7472A>C transversion in the underlying respiratory chain abnormality. Evidence from both in vivo and in vitro studies demonstrate that the m.7472A>C is able to modify the expression of the m.7472Cins mutation and would suggest that it is not a neutral variant but appears to cause a biochemical defect by itself, confirming that homoplasmic mtDNA variants can modulate the phenotypic expression of pathogenic, heteroplasmic mtDNA mutations.European Journal of Human Genetics (2008) 16, 1265–1274; doi:10.1038/ejhg.2008.65; published online 9 April 2008 [ABSTRACT FROM AUTHOR]

Published

2008

19. Novel mutations in the TK2 gene associated with fatal mitochondrial DNA depletion myopathy

Author

Blakely, Emma, He, Langping, Gardner, Julie L., Hudson, Gavin, Walter, John, Hughes, Imelda, Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*MITOCHONDRIAL DNA, *ENZYMES, *GENES, *MUSCLE diseases, *GENETIC mutation, *NEUROLOGICAL disorders, *JUVENILE diseases, *RESPIRATORY insufficiency

Abstract

Abstract: Mitochondrial DNA depletion syndromes are a heterogeneous group of childhood neurological disorders characterised by a quantitative abnormality of mitochondrial DNA. We describe two siblings who presented at 8 months and 14 months with myopathy, which rapidly progressed and resulted in death by respiratory failure at age 14 and 18 months, respectively. Muscle biopsy revealed marked respiratory chain defects, with real-time PCR confirming a dramatic depletion of mitochondrial DNA. Sequencing of the thymidine kinase 2 (TK2) gene revealed two, novel heterozygous mutations (p.Q87X and p.N100S) with parental DNA analysis confirming the transmission of mutated alleles. [Copyright &y& Elsevier]

Published

2008

20. A mitochondrial cytochrome b mutation causing severe respiratory chain enzyme deficiency in humans and yeast.

Author

Blakely, Emma L., Mitchell, Anna L., Fisher, Nicholas, Meunier, Brigitte, Nijtmans, Leo G., Schaefer, Andrew M., Jackson, Margaret J., Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*CYTOCHROME b, *CYTOCHROMES, *GENETIC mutation, *ENZYMES, *MITOCHONDRIAL DNA, *AMINO acids

Abstract

Whereas the majority of disease-related mitochondrial DNA mutations exhibit significant biochemical and clinical heterogeneity, mutations within the mitochondrially encoded human cytochrome b gene ( MTCYB) are almost exclusively associated with isolated complex III deficiency in muscle and a clinical presentation involving exercise intolerance. Recent studies have shown that a small number of MTCYB mutations are associated with a combined enzyme complex defect involving both complexes I and III, on account of the fact that an absence of assembled complex III results in a dramatic loss of complex I, confirming a structural dependence between these two complexes. We present the biochemical and molecular genetic studies of a patient with both muscle and brain involvement and a severe reduction in the activities of both complexes I and III in skeletal muscle due to a novel mutation in the MTCYB gene that predicts the substitution (Arg318Pro) of a highly conserved amino acid. Consistent with the dramatic biochemical defect, Western blotting and BN-PAGE experiments demonstrated loss of assembled complex I and III subunits. Biochemical studies of the equivalent amino-acid substitution (Lys319Pro) in the yeast enzyme showed a loss of enzyme activity and decrease in the steady-state level of bc1 complex in the mutant confirming pathogenicity. [ABSTRACT FROM AUTHOR]

Published

2005

21. LHON/MELAS overlap syndrome associated with a mitochondrial MTND1 gene mutation.

Author

Blakely, Emma L., de Silva, Rajith, King, Andrew, Schwarzer, Verena, Harrower, Tim, Dawidek, Gervase, Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*MITOCHONDRIAL DNA, *GENETIC mutation, *GENES, *SYNDROMES, *NEUROPATHY, *MITOCHONDRIAL pathology

Abstract

Pathogenic point mutations in the mitochondrial MTND1 gene have previously been described in association with two distinct clinical phenotypes-Leber hereditary optic neuropathy (LHON) and mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS). Here we report the first heteroplasmic mitochondrial DNA (mtDNA) point mutation (3376G>A) in the MTND1 gene associated with an overlap syndrome comprising the clinical features of both LHON and MELAS. Muscle histochemistry revealed subtle mitochondrial abnormalities, while biochemical analysis showed an isolated complex I deficiency. Our findings serve to highlight the growing importance of mutations in mitochondrial complex I structural genes in MELAS and its associated overlap syndromes.European Journal of Human Genetics (2005) 13, 623-627. doi:10.1038/sj.ejhg.5201363 Published online 12 January 2005 [ABSTRACT FROM AUTHOR]

Published

2005

22. Childhood neurological presentation of a novel mitochondrial tRNAVal gene mutation

Author

Blakely, Emma L., Poulton, Joanna, Pike, Michael, Wojnarowska, Fenella, Turnbull, Douglass M., McFarland, Robert, and Taylor, Robert W.

Subjects

*GENETIC mutation, *MITOCHONDRIA, *TRANSFER RNA, *MOVEMENT disorders in children

Abstract

We describe a young girl with a novel 1659T>C mutation in the tRNAVal gene of mitochondrial DNA (mtDNA) who presented with learning difficulties, hemiplegia, and a movement disorder, together with a raised cerebrospinal fluid (CSF) lactate. The mutation, which was present at high levels of heteroplasmy in patient tissues, interrupts a conserved Watson–Crick basepair in the TΨC stem and has not previously been described in controls. This report further confirms the frequent association of mitochondrial tRNA mutation with neurological presentations, even in paediatric cases. [Copyright &y& Elsevier]

Published

2004

23. Noninvasive diagnosis of the 3243A>G mitochondrial DNA mutation using urinary epithelial cells.

Author

Mcdonnell, Martina T., Schaefer, Andrew M., Blakely, Emma L., McFarland, Robert, Chinnery, Patrick F., Turnbull, Douglass M., and Taylor, Robert W.

Subjects

MITOCHONDRIAL DNA, DNA, GENETIC mutation, EPITHELIAL cells, URINARY organs, NONINVASIVE diagnostic tests, GENETICS, HUMAN genetics

Abstract

The 3243A>G mutation is one of the most frequently observed mutations of mitochondrial DNA (mtDNA), and is associated with numerous clinical presentations including mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes (MELAS), progressive external ophthalmoplegia (PEO) and diabetes and deafness. The routine diagnosis of the 3243A>G mutation in blood is difficult as mutation levels are known to decrease in this tissue over time, while in some patients it may be absent. We have directly compared the levels of the 3243A>G mutation in skeletal muscle, blood and urinary epithelial cells in 18 patients and observed a striking correlation between the mutation load in postmitotic muscle and urinary epithelium, a mitotic tissue. These data strongly support the use of urinary epithelial cells as the tissue of choice in the noninvasive diagnosis of the 3243A>G mutation.European Journal of Human Genetics (2004) 12, 778-781. doi:10.1038/sj.ejhg.5201216 Published online 16 June 2004 [ABSTRACT FROM AUTHOR]

Published

2004

24. A p.R369G POLG2 mutation associated with adPEO and multiple mtDNA deletions causes decreased affinity between polymerase γ subunits

Author

Craig, Kate, Young, Matthew J., Blakely, Emma L., Longley, Matthew J., Turnbull, Douglass M., Copeland, William C., and Taylor, Robert W.

Subjects

*GENETIC mutation, *MITOCHONDRIAL DNA, *DELETION mutation, *DNA polymerases, *DNA replication, *GENETIC code, *ENZYME inhibitors

Abstract

Abstract: Human mitochondrial DNA (mtDNA) polymerase γ (pol γ) is the sole enzyme required to replicate and maintain the integrity of the mitochondrial genome. It comprises two subunits, a catalytic p140 subunit and a smaller p55 accessory subunit encoded by the POLG2 gene. We describe the molecular characterization of a potential dominant POLG2 mutation (p.R369G) in a patient with adPEO and multiple mtDNA deletions. Biochemical studies of the recombinant mutant p55 protein showed a reduced affinity to the pol γ p140 subunit, leading to impaired processivity of the holoenzyme complex but did not show sensitivity to N-ethylmalaimide (NEM) inhibition, inferring a novel disease mechanism. [Copyright &y& Elsevier]

Published

2012

25. The investigation and diagnosis of pathogenic mitochondrial DNA mutations in human urothelial cells

Author

Blackwood, John K., Whittaker, Roger G., Blakely, Emma L., Alston, Charlotte L., Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*GENETIC mutation, *MITOCHONDRIAL DNA abnormalities, *URINARY organ diseases, *EPITHELIUM, *PHENOTYPES, *TRANSFER RNA, *PHYSIOLOGY

Abstract

Abstract: Patients with mitochondrial DNA disease are amongst the most challenging to diagnose and manage given the striking phenotypic and genetic heterogeneity, which characterise these conditions. Recently, we and others have demonstrated the m.3243A>G mutation, one of the most common mitochondrial DNA pathogenic mutations, is present at clinically relevant levels in urinary epithelium, thus providing a practical, non-invasive test for diagnosis and mutation screening. In this study we further evaluate the use of these cells in detecting the m.3243A>G mutation, other mtDNA tRNA gene point mutations including the m.8344A>G mutation and single large-scale mtDNA deletions. We observe a robust relationship between m.3243A>G levels in urothelial cells and clinically affected tissues that does not change with time. Conversely, single large-scale mtDNA deletions can be detected in urothelial cells, with higher levels present in younger patients with more severe disease, but generally mtDNA deletion levels are not representative of those seen in a clinically affected tissue. Our results have implications for the diagnosis, management and counselling of families with mtDNA disease. [Copyright &y& Elsevier]

Published

2010

26. A novel Twinkle gene mutation in autosomal dominant progressive external ophthalmoplegia

Author

Deschauer, Marcus, Kiefer, Reinhard, Blakely, Emma L., He, Langping, Zierz, Stephan, Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*CONJUNCTIVA diseases, *GENETIC mutation, *MITOCHONDRIAL DNA

Abstract

Autosomal dominant progressive external ophthalmoplegia is a common neurological presentation of mitochondrial disease and is characterised by multiple deletions of mitochondrial DNA in muscle. We describe a family with autosomal dominant progressive external ophthalmoplegia caused by a novel heterozygous A to C transversion at nucleotide 956 of the Twinkle gene. The deltoid muscle biopsy of the index case revealed sparse respiratory deficient cells. Multiple mitochondrial DNA deletions were clearly evident in the index case by both long-range and real-time polymerase chain reaction assays but not by Southern blotting, highlighting the diagnostic difficulties associated with characterising patients with multiple mitochondrial DNA deletions. [Copyright &y& Elsevier]

Published

2003

27. Long-term survival of neonatal mitochondrial complex III deficiency associated with a novel BCS1L gene mutation

Author

Tuppen, Helen A.L., Fehmi, Janev, Czermin, Birgit, Goffrini, Paola, Meloni, Francesca, Ferrero, Iliana, He, Langping, Blakely, Emma L., McFarland, Robert, Horvath, Rita, Turnbull, Douglass M., and Taylor, Robert W.

Subjects

*MITOCHONDRIAL pathology, *GENETIC mutation, *DIAGNOSIS of diseases in women, *YEAST, *COMPLEMENTATION (Genetics), *BIOPSY

Abstract

Abstract: Mutations of the BCS1L gene are a recognised cause of isolated respiratory chain complex III deficiency and underlie several fatal, neonatal mitochondrial diseases. Here we describe a 20-year-old Kenyan woman who initially presented as a floppy infant but whose condition progressed during childhood and adolescence with increasing muscle weakness, focal motor seizures and optic atrophy. Muscle biopsy demonstrated complex III deficiency and the pathogenicity of a novel, homozygous BCS1L mutation was confirmed by yeast complementation studies. Our data indicate that BCS1L mutations can cause a variable, neurological course which is not always fatal in childhood. [ABSTRACT FROM AUTHOR]

Published

2010