Identical large scale rearrangement of mitochondrial DNA causes Kearns-Sayre syndrome in a mother and her son

All these complexes, except complex II, which is entirely nucleus encoded, contain both nucleus and mitochondrion encoded subunits, and their biosynthesis also requires co-operation between the nuclear and mitochondrial genomes. Because of this dual genetic control, oxidative phosphorylation disease...

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Bibliographic Details
Published in:	Journal of medical genetics Vol. 40; no. 11; pp. 858 - 863
Main Authors:	Puoti, G, Carrara, F, Sampaolo, S, De Caro, M, Vincitorio, C M, Invernizzi, F, Zeviani, M
Format:	Journal Article
Language:	English
Published:	London BMJ Publishing Group Ltd 01-11-2003 BMJ BMJ Publishing Group LTD BMJ Group
Subjects:	Abnormalities adenosine triphosphate Adult Age Analysis Ataxia ATP Biological and medical sciences Biopsy Care and treatment Case studies COX creatine kinase cytochrome c oxidase Deoxyribonucleic acid DNA DNA, Mitochondrial - genetics Female Gene mutations General aspects. Genetic counseling Genetic aspects Genetic research Genetic testing Health aspects Hearing loss Humans Kearns-Sayre syndrome Kearns-Sayre Syndrome - genetics Kinases KSS large scale rearrangement Letter to JMG Male Medical genetics Medical sciences Middle Aged mitochondrial disease Mitochondrial diseases Mitochondrial DNA Morphology mtDNA mtDNA deletion Mutation Nuclear Family Patients Pedigree PEO Phenotype Phosphorylation Physiological aspects progressive external ophthalmoplegia RCS Recombination, Genetic - genetics revised Cambridge sequence Italy Human Eye disease Mother Cardiovascular disease Metabolic diseases Genetics Mitochondrial DNA Kearns Sayre syndrome Enzymopathy
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Summary:	All these complexes, except complex II, which is entirely nucleus encoded, contain both nucleus and mitochondrion encoded subunits, and their biosynthesis also requires co-operation between the nuclear and mitochondrial genomes. Because of this dual genetic control, oxidative phosphorylation diseases can be due to mutations either in mitochondrial DNA (mtDNA) or nuclear DNA genes. [...]this attribution is completely arbitrary, because of the technical limitations of both methods. [...]in spite of the enormous number of observations and studies on mtDNA deletions that have been carried out by many research teams in the last 15 years, the frequency of partial deletions, partial duplications (or triplications 15 ), or of a combination of the two is virtually unknown in patients affected by mitochondrial disease.
Bibliography:	ark:/67375/NVC-JWT8LBMF-S istex:E17AFE94A32454C64D09AAC41A55A0F51E4E1481 PMID:14627683 href:jmedgenet-40-858.pdf Correspondence to:  Dr M Zeviani  Division of Molecular Neurogenetics, National Neurological Institute Carlo Besta, via Temolo 4, 20126 Milan, Italy; zeviani@tin.it local:0400858 ObjectType-Case Study-2 SourceType-Scholarly Journals-1 ObjectType-Feature-4 content type line 23 ObjectType-Report-1 ObjectType-Article-3
ISSN:	0022-2593 1468-6244 1468-6244
DOI:	10.1136/jmg.40.11.858