33 resultados para MLPA
Resumo:
Purpose: SCN1A is the most clinically relevant epilepsy gene, most mutations lead to severe myoclonic epilepsy of infancy (SMEI) and generalized epilepsy with febrile seizures plus (GEFS+). We studied 132 patients with epilepsy syndromes with seizures precipitated by fever, and performed phenotype-genotype correlations with SCN1A alterations. Methods: We included patients with SMEI including borderline SMEI (SMEB), GEFS+, febrile seizures (FS), or other seizure types precipitated by fever. We performed a clinical and genetic study focusing on SCN1A, using dHPLC, gene sequencing, and MLPA to detect genomic deletions/duplications on SMEI/SMEB patients. Results: We classified patients as: SMEI/SMEB = 55; GEFS+ = 26; and other phenotypes = 51. SCN1A analysis by dHPLC/sequencing revealed 40 mutations in 37 SMEI/SMEB (67%) and 3 GEFS+ (11.5%) probands. MLPA showed genomic deletions in 2 of 18 SMEI/SMEB. Most mutations were de novo (82%). SMEB patients carrying mutations (8) were more likely to have missense mutations (62.5%), conversely SMEI patients (31) had more truncating, splice site or genomic alterations (64.5%). SMEI/SMEB with truncating, splice site or genomic alterations had a significantly earlier age of onset of FS compared to those with missense mutations and without mutations (p = 0.00007, ANOVA test). None of the remaining patients with seizures precipitated by fever carried SCN1A mutations. Conclusion: We obtained a frequency of 71% SCN1A abnormalities in SMEI/SMEB and of 11.5% in GEFS+ probands. MLPA complements DNA sequencing of SCN1A increasing the mutation detection rate. SMEI/SMEB with truncating, splice site or genomic alterations had a significantly earlier age of onset of FS. This study confirms the high sensitivity of SCN1A for SMEI/SMEB phenotypes. © 2007 International League Against Epilepsy.
Resumo:
Head and Neck Cancers (HNC) are a group of tumours located in the upper aero-digestive tract. Head and Neck Squamous Cell Carcinoma (HNSCC) represent about 90% of all HNC cases. It has been considered the sixth most malignant tumour worldwide and, despite clinical and technological advances, the five-year survival rate has not improved much in the last years. Nowadays, HNSCC is well established as a heterogeneous disease and that its development is due to accumulation of genetic events. Apart from the majority of the patients being diagnosed in an advanced stage, HNSCC is also a disease with poor therapeutic outcome. One of the therapeutic approaches is radiotherapy. However, this approach has different drawbacks like the radioresistance acquired by some tumour cells, leading to a worse prognosis. A major knowledge in radiation biology is imperative to improve this type of treatment and avoid late toxicities, maintaining patient quality of life in the subsequent years after treatment. Then, identification of genetic markers associated to radiotherapy response in patients and possible alterations in cells after radiotherapy are essential steps towards an improved diagnosis, higher survival rate and a better life quality. Not much is known about the radiation effects on cells, so, the principal aim of this study was to contribute to a more extensive knowledge about radiation treatment in HNSCC. For this, two commercial cell lines, HSC-3 and BICR-10, were used and characterized resorting to karyotyping, aCGH and MS-MLPA. These cell lines were submitted to different doses of irradiation and the resulting genetic and methylation alterations were evaluated. Our results showed a great difference in radiation response between the two cell lines, allowing the conclusion that HSC-3 was much more radiosensitive than BICR-10. Bearing this in mind, analysis of cell death, cell cycle and DNA damages was performed to try to elucidate the motifs behind this difference. The characterization of both cell lines allowed the confirmation that HSC-3 was derived from a metastatic tumour and the hypothesis that BICR-10 was derived from a dysplasia. Furthermore, this pilot study enabled the suggestion of some genetic and epigenetic alterations that cells suffer after radiation treatment. Additionally, it also allowed the association of some genetic characteristics that could be related to the differences in radiation response observable in this two cell lines. Taken together all of our results contribute to a better understanding of radiation effects on HNSCC allowing one further step towards the prediction of patients’ outcome, better choice of treatment approaches and ultimately a better quality of life.
Resumo:
Introdução - As anemias hipocrómicas e microcíticas, não sideropénicas, são, na sua maioria, de origem talassémica. As talassémias são hemoglobinopatias caraterizadas pela redução ou ausência da produção de cadeias globínicas, provocadas por mutações nos genes globínicos. A β-talassémia está mais frequentemente associada a mutações pontuais e pequenas deleções ou inserções no gene HBB, enquanto que a α-talassémia normalmente resulta de deleções que eliminam os genes HBA2 e/ou HBA1. Deleções de um só gene, -α3.7 e -α4.2, são frequentes entre africanos, mediterrânicos e asiáticos enquanto que grandes deleções que removem ambos os genes alfa, como a deleção do Sudeste Asiático (--SEA), são comuns nas populações asiáticas. Grandes deleções nos clusters alfa e beta são condições raras, geralmente associadas a fenótipos severos. A identificação destas deleções é realizada através da técnica de MLPA (multiplex ligation-dependent probe amplification). Objetivos - O objetivo principal deste trabalho foi estudar um grupo de indivíduos com hipocromia e microcitose e Hb A2 normal, com suspeita de possuirem deleções nos clusters α ou β. Pretendeu-se, ainda, caraterizar a extensão das deleções encontradas e, quando possível, determinar a localização dos seus breakpoints. Materiais e Métodos - Cinquenta e oito indivíduos (28 homens e 30 mulheres), com hipocromia e microcitose de origem desconhecida, seguidos na Consulta de Hematologia do Hospital Pediátrico e do Hospital Geral do CHC, ou enviados de outros centros, foram testados para a presença de deleções nos clusters α e β. Foram efetuados hemogramas a todas as amostras e os estudos de hemoglobina foram realizados por cromatografia líquida de alta performance (HPLC). Os estudos moleculares incluiram GAP-PCR, MLPA, sequenciação genética e PCR / hibridização reversa. Resultados - Foi possível obter o padrão do rácio das sondas MLPA para as deleções α e β conhecidas ou já caraterizadas. Foram encontradas 6 deleções HBA desconhecidas que removem os genes α ou as regiões reguladoras desse cluster. Detetou-se, também, uma deleção no cluster β, que elimina praticamente todos os seus genes. Conclusões - A identificação de grandes delções nos clusters α e β-globínicos em indivíduos com hipocromia e microcitose, com HbA2 normal, é crucial para o aconselhamento genético. A metodologia de MLPA é uma abordagem simples e fiável, muito útil para o diagnóstico de casos de talassemia, em que não são detetadas mutações α ou β através das técnicas convencionais