Array comparative genomic hybridisation on first polar bodies suggests that non-disjunction is not the predominant mechanism leading to aneuploidy in humans

IntroductionAneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises pr...

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Published in	Journal of medical genetics Vol. 48; no. 7; pp. 433 - 437
Main Authors	Gabriel, A S, Thornhill, A R, Ottolini, C S, Gordon, A, Brown, A P C, Taylor, J, Bennett, K, Handyside, A, Griffin, D K
Format	Journal Article
Language	English
Published	London BMJ Publishing Group Ltd 01.07.2011 BMJ Publishing Group BMJ Publishing Group LTD
Subjects	aCGH Adult Age Aneuploidy Biological and medical sciences cell biology chromatid Chromosome Aberrations Chromosomes Chromosomes, Human - genetics Comparative Genomic Hybridization counselling Datasets Deoxyribonucleic acid diagnostics DNA Fundamental and applied biological sciences. Psychology Genes genetic screening Genetic testing genetics Genetics of eukaryotes. Biological and molecular evolution Humans Hypotheses Medical genetics Medical sciences meiosis Meiosis - genetics Middle Aged Molecular and cellular biology Nondisjunction, Genetic Oocytes Polar body Quality screening Software Studies Chromosomal aberration Polar body Human Non disjunction Aneuploidy Genetics Comparative study Mechanism
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ISSN	0022-2593 1468-6244 1468-6244
DOI	10.1136/jmg.2010.088070

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Abstract	IntroductionAneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors.Materials and methodsArray comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors.ResultsSingle chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies.DiscussionThe received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered.
AbstractList	Aneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors.INTRODUCTIONAneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors.Array comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors.MATERIALS AND METHODSArray comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors.Single chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies.RESULTSSingle chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies.The received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered.DISCUSSIONThe received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered. Introduction Aneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors. Materials and methods Array comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors. Results Single chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies. Discussion The received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered. Aneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors. Array comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors. Single chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies. The received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered. IntroductionAneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of mechanism by which such errors occur in humans are the subject of some debate. It is generally believed that aneuploidy arises primarily as a result of segregation of a whole chromosome to the same pole as its homologue (non-disjunction). Nonetheless, classical cytogenetic studies suggest that this model does not fully account for the patterns observed in human oocytes. An alternative model (precocious separation of sister chromatids) has thus been proposed, but recurring criticism of this model purports that technical issues may have led to interpretation errors.Materials and methodsArray comparative genomic hybridisation (aCGH) was used on 164 human first polar bodies to distinguish between whole chromosome (non-disjunction) and chromatid (precocious separation) errors.ResultsSingle chromatid errors were over 11 times more common than whole chromosome errors, consistent with prior classical cytogenetic and fluorescence in situ hybridisation (FISH) studies.DiscussionThe received wisdom that non-disjunction is the primary mechanism leading to human aneuploidy should be reconsidered.
Author	Gabriel, A S Gordon, A Handyside, A Brown, A P C Taylor, J Thornhill, A R Bennett, K Ottolini, C S Griffin, D K
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Snippet	IntroductionAneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the... Introduction Aneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but... Aneuploidy (the presence of extra or missing chromosomes) arises primarily through chromosome segregation errors in the oocyte at meiosis I but the details of...
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SubjectTerms	aCGH Adult Age Aneuploidy Biological and medical sciences cell biology chromatid Chromosome Aberrations Chromosomes Chromosomes, Human - genetics Comparative Genomic Hybridization counselling Datasets Deoxyribonucleic acid diagnostics DNA Fundamental and applied biological sciences. Psychology Genes genetic screening Genetic testing genetics Genetics of eukaryotes. Biological and molecular evolution Humans Hypotheses Medical genetics Medical sciences meiosis Meiosis - genetics Middle Aged Molecular and cellular biology Nondisjunction, Genetic Oocytes Polar body Quality screening Software Studies
Title	Array comparative genomic hybridisation on first polar bodies suggests that non-disjunction is not the predominant mechanism leading to aneuploidy in humans
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