Ascertainment, diagnostic evaluation and gene mapping of South Australian families with possible X-linked mental retardation.

Al Raisi, Zahiya Abdul Hameed

January 2009

Mental retardation is a disorder that affects the lives of many individuals and their families worldwide. The underlying causes are heterogeneous and despite efforts to reveal them, the aetiology remains unknown for 50% of cases. Estimates of the prevalence of MR have varied between one and three percent in different studies, because of differences in definition, classification and approach to ascertainment. Most studies show that MR is about 30% more prevalent in males than females suggesting that XLMR is an important contributor to MR. Previous studies estimated that XLMR has a prevalence of 1.83 males (Herbst et al., 1980). The aim of the thesis was the ascertainment, diagnostic evaluation and gene mapping of South Australian families with possible XLMR. The South Australian Clinical Genetics Service's database (Kintrak) identified 33 families with possible XLMR of unknown cause. The clinical features and diagnostic evaluation of these families were documented. Six of these families were large enough for linkage mapping but only 2 of them agreed to participate in the current study. For one family the gene was localised between markers DXS8067 and DXS1062. Two candidate genes within the linkage interval, PHF6 and GRIA3 were screened for a mutation but no pathological mutation was found. The linkage mapping of the second family is still in progress. One of the 33 families was suspected to have Borjeson-Forssman-Lehmann syndrome and was screened for PHF6 but no mutation was found. Tarpey et al. (2007) identified protein truncating mutations in UPF3B in some patients with Lujan Fryns Syndrome (XLMR with Marfanoid body build). Therefore, the South Australian Clinical Genetics Service's database (Kintrak) was searched for males with a diagnosis of MR and Marfanoid body build and 14 individuals were found. They were screened for mutations in UPF3B gene but no pathological mutation was found. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1364228 / Thesis (M.Clin.Sc.) -- University of Adelaide, School of Paediatrics and Reproductive Health, 2009

genetic medicine; XLMR

Making Medicine Amish

Miller-Fellows, Sarah

23 May 2019

No description available.

Cultural Anthropology

Análise exômica em pacientes portadores de cardiomiopatia hipertrófica / Exomic analysis in patients with cardiomyopathy hypertrophic

Castro, Lara Reinel de

23 September 2015

A cardiomiopatia hipertrófica (CMH) é uma doença geneticamente determinada, caracterizada por hipertrofia ventricular primária, com prevalência estimada de 0.2% na população geral. Qualquer portador tem 50% de chance de transmitir esta doença para seus filhos, o que torna cada vez mais relevante a importância do estudo genético dos indivíduos acometidos e de seus familiares. Já foram descritas diversas mutações genéticas causadoras de CMH, a maioria em genes que codificam proteínas do sarcômero, e algumas mutações mais raras em genes não sarcoméricos. O objetivo desse estudo é sequenciar as regiões exônicas de genes candidatos, incluindo os principais envolvidos na hipertrofia miocárdica, utilizando o sequenciamento de nova geração (Generation Sequencing); testar a aplicabilidade e viabilidade deste sistema para identificar mutações já confirmadas e propor as prováveis novas mutações causadoras de CMH. Métodos e resultados: 66 pacientes não aparentados portadores de CMH foram estudados e submetidos à coleta de sangue para obtenção do DNA para analisar as regiões exômicas de 82 genes candidatos, utilizando a plataforma MiSeq (Illumina). Identificou-se 99 mutações provavelmente patogênicas em 54 pacientes incluídos no estudo (81,8%) relacionadas ou não a CMH, e distribuídas em 42 genes diferentes. Destas mutações 27 já haviam sido publicadas, sendo que 17 delas descritas como causadoras de CMH. Em 28 pacientes (42,4%) identificou-se mutação nos três principais genes sarcoméricos relacionados à CMH (MYH7, MYBPC3, TNNT2). Encontrou-se também um grande número de variantes não sonôminas de efeito clínico incerto e algumas mutações relacionadas a outras enfermidades. Conclusão: a análise da sequencia dos exônos de genes candidatos, demonstrou ser uma técnica promissora para o diagnóstico genético de CMH de forma mais rápida e sensível. A quantidade de dados gerados é o um fator limitante até o momento, principalmente em doenças geneticamente complexas com envolvimento de diversos genes e com sistema de bioinformática limitado. / Hypertrophic Cardiomyopathy (HCM) is a genetically determined disease, estimated prevalence of 0.2% in the general population. Any of its carriers has 50% likelihood to pass it on to their children, and that makes the genetic study of these individuals and their relatives even more relevant. There have been several studies describing genetic mutations that cause HCM - the vast majority in genes responsible for sarcomere protein coding - and other rarer mutations in non-sarcomeric genes. The aim of this research is study exonic areas of specific genes, including the most important ones related to myocardial hypertrophy, identifying the genetic mutations that have already been documented, and possible new pathogenic mutations, using the high throughput DNA sequencing (NGS); testing the pplicability and viability to identify HCM-causing mutations. Methods and results: 66 unrelated patients with CM were studied and subject to blood sample in order to extract their genomic DNA to analyze exomic regions of 82 candidates genes, using the high throughput sequencing technology on MiSeg (Illumina) platform. In this study we identified 99 possible damaging mutations in 54 patients (81.8%) that could be related or not to HCM, and distributed in 42 different genes. 27 of this variants have already been published, and 17 of them have been described as HCM causes. 42,4% of the patients (28 individuals) have genetic mutations in the three main sarcomeric genes related to HCM (MYH7, MYBPC3, TNNT2). We also identified a large number of non-synonymous variants of uncertain clinical significance and some mutations related to other diseases. Conclusion: The exome analysis in candidates genes using NGS has demonstrated to be promising for the genetic diagnosis of HCM, in a short time with sensivity. The amount of data obtained in a short period of time is the main limiting factor, especially for genetically complex diseases that involve multiple genes.

Análise de sequência de DNA

Cardiomiopatia hipertrófica

DNA sequencing analysis

Exoma/genética

Exome/genetics

Genetic medicine

Genética médica

High throughput nucleotide sequencing

Hypertrophic cardiomyopathy

Mutação

Mutation

Next generation sequencing

sequenciamento de nova geração

Análise exômica em pacientes portadores de cardiomiopatia hipertrófica / Exomic analysis in patients with cardiomyopathy hypertrophic

Lara Reinel de Castro

23 September 2015

A cardiomiopatia hipertrófica (CMH) é uma doença geneticamente determinada, caracterizada por hipertrofia ventricular primária, com prevalência estimada de 0.2% na população geral. Qualquer portador tem 50% de chance de transmitir esta doença para seus filhos, o que torna cada vez mais relevante a importância do estudo genético dos indivíduos acometidos e de seus familiares. Já foram descritas diversas mutações genéticas causadoras de CMH, a maioria em genes que codificam proteínas do sarcômero, e algumas mutações mais raras em genes não sarcoméricos. O objetivo desse estudo é sequenciar as regiões exônicas de genes candidatos, incluindo os principais envolvidos na hipertrofia miocárdica, utilizando o sequenciamento de nova geração (Generation Sequencing); testar a aplicabilidade e viabilidade deste sistema para identificar mutações já confirmadas e propor as prováveis novas mutações causadoras de CMH. Métodos e resultados: 66 pacientes não aparentados portadores de CMH foram estudados e submetidos à coleta de sangue para obtenção do DNA para analisar as regiões exômicas de 82 genes candidatos, utilizando a plataforma MiSeq (Illumina). Identificou-se 99 mutações provavelmente patogênicas em 54 pacientes incluídos no estudo (81,8%) relacionadas ou não a CMH, e distribuídas em 42 genes diferentes. Destas mutações 27 já haviam sido publicadas, sendo que 17 delas descritas como causadoras de CMH. Em 28 pacientes (42,4%) identificou-se mutação nos três principais genes sarcoméricos relacionados à CMH (MYH7, MYBPC3, TNNT2). Encontrou-se também um grande número de variantes não sonôminas de efeito clínico incerto e algumas mutações relacionadas a outras enfermidades. Conclusão: a análise da sequencia dos exônos de genes candidatos, demonstrou ser uma técnica promissora para o diagnóstico genético de CMH de forma mais rápida e sensível. A quantidade de dados gerados é o um fator limitante até o momento, principalmente em doenças geneticamente complexas com envolvimento de diversos genes e com sistema de bioinformática limitado. / Hypertrophic Cardiomyopathy (HCM) is a genetically determined disease, estimated prevalence of 0.2% in the general population. Any of its carriers has 50% likelihood to pass it on to their children, and that makes the genetic study of these individuals and their relatives even more relevant. There have been several studies describing genetic mutations that cause HCM - the vast majority in genes responsible for sarcomere protein coding - and other rarer mutations in non-sarcomeric genes. The aim of this research is study exonic areas of specific genes, including the most important ones related to myocardial hypertrophy, identifying the genetic mutations that have already been documented, and possible new pathogenic mutations, using the high throughput DNA sequencing (NGS); testing the pplicability and viability to identify HCM-causing mutations. Methods and results: 66 unrelated patients with CM were studied and subject to blood sample in order to extract their genomic DNA to analyze exomic regions of 82 candidates genes, using the high throughput sequencing technology on MiSeg (Illumina) platform. In this study we identified 99 possible damaging mutations in 54 patients (81.8%) that could be related or not to HCM, and distributed in 42 different genes. 27 of this variants have already been published, and 17 of them have been described as HCM causes. 42,4% of the patients (28 individuals) have genetic mutations in the three main sarcomeric genes related to HCM (MYH7, MYBPC3, TNNT2). We also identified a large number of non-synonymous variants of uncertain clinical significance and some mutations related to other diseases. Conclusion: The exome analysis in candidates genes using NGS has demonstrated to be promising for the genetic diagnosis of HCM, in a short time with sensivity. The amount of data obtained in a short period of time is the main limiting factor, especially for genetically complex diseases that involve multiple genes.

Análise de sequência de DNA

Cardiomiopatia hipertrófica

Exoma/genética

Genética médica

Mutação

sequenciamento de nova geração

DNA sequencing analysis

Exome/genetics

Genetic medicine

High throughput nucleotide sequencing

Hypertrophic cardiomyopathy

Mutation

Next generation sequencing