Differential transcriptional and posttranslational transcription factor 7-like regulation among nondiabetic individuals and type 2 diabetic patients.

Human genetic studies have revealed that the T minor allele of single nucleotide polymorphism rs7903146 in the transcription factor 7-like 2 (TCF7L2) gene is strongly associated with an increased risk of diabetes by 30%-40%. Molecular and clinical studies are of great importance for understanding how this unique variation in TCF7L2 influences type 2 diabetes (T2D) onset and progression. At the molecular level, some studies have been performed in diabetic mice and pancreatic islets from healthy human donors. Whereas TCF7L2 mRNA levels are up-regulated in islets, protein levels are down-regulated. We performed studies on TCF7L2 splicing, mRNA expression, and protein levels in immortalized human lymphocytes from nondiabetic individuals and T2D patients carrying the C/C or the at-risk T/T genotype. Our results show differential expression of TCF7L2 splice variants between nondiabetic and T2D patients carrying the at-risk genotype, as well as differences in protein levels. Therefore, we investigated the regulation of splice variants, and our results propose that splicing of exon 4 is under control of the serine-arginine-rich factor transformer 2 ß (TRA2B). Finally, we studied the endoplasmic reticulum stress pathways, looking for a posttranslational explanation. We saw a shift in the activation of these pathways between nondiabetic individuals and T2D patients carrying the at-risk genotype. These results suggest that, in human immortalized lymphocytes carrying the at-risk T/T genotype, first the differential expression of TCF7L2 splice variants implies a regulation, at least for exon 4, by TRA2B and second, the differential protein levels between both T/T carriers point to a different activation of endoplasmic reticulum stress pathways.

Coexistence of two different pseudohypoparathyroidism subtypes (Ia and Ib) in the same kindred with independent Gs{alpha} coding mutations and GNAS imprinting defects.

BACKGROUND: Pseudohypoparathyroidism (PHP) defines a rare group of disorders whose common feature is resistance to the parathyroid hormone. Patients with PHP-Ia display additional hormone resistance, Albright hereditary osteodystrophy (AHO) and reduced Gsalpha activity in easily accessible cells. This form of PHP is associated with heterozygous inactivating mutations in Gsalpha-coding exons of GNAS, an imprinted gene locus on chromosome 20q13.3. Patients with PHP-Ib typically have isolated parathyroid hormone resistance, lack AHO features and demonstrate normal erythrocyte Gsalpha activity. Instead of coding Gsalpha mutations, patients with PHP-Ib display imprinting defects of GNAS, caused, at least in some cases, by genetic mutations within or nearby this gene. PATIENTS: Two unrelated PHP families, each of which includes at least one patient with a Gsalpha coding mutation and another with GNAS loss of imprinting, are reported here. RESULTS: One of the patients with GNAS imprinting defects has paternal uniparental isodisomy of chromosome 20q, explaining the observed imprinting abnormalities. The identified Gsalpha coding mutations include a tetranucleotide deletion in exon 7, which is frequently found in PHP-Ia, and a novel single nucleotide change at the acceptor splice junction of intron 11. CONCLUSIONS: These molecular data reveal an interesting mixture, in the same family, of both genetic and epigenetic mutations of the same gene.

Pseudohipoparatiroidismo: diagnóstico genético / No disponible

El pseudohipoparatiroidismo (PHP) está caracterizado por hipocalcemia e hiperfosfatemia debidas a resistencia a la hormona paratiroidea (PTH). Pacientes con PHP-Ia, generalmente, presentan otras resistencias hormonales y muestran un fenotipo característico que se conoce como osteodistrofi a hereditaria de Albright (AHO). Este mismo fenotipo también está presente en pacientes diagnosticados de pseudopseudohipoparatiroidismo (PPHP), que no tienen resistencia hormonal. Por otra parte, los pacientes con PHP-Ib, presentan, preferentemente, resistencia a la PTH y no tienen fenotipo de Albright. Desde el punto de vista genético, el PHP-I está causado por alteraciones en el gen GNAS o en la región 5 de este complejo locus, así, los pacientes con PHP-Ia presentan mutaciones en heterozigosis en cualquiera de los 13 exones codificantes de la proteína Gs, mientras que el PHP-Ib se debe a alteraciones en el patrón de metilación del locus GNAS. En algunos casos, esas pérdidas de metilación se asocian con microdeleciones en regiones situadas 5 al gen GNAS y que son transmitidas por la madre. El locus GNAS está sometido al fenómeno de imprinting y este hecho tiene consecuencias importantes a la hora de establecer un patrón de herencia y un adecuado consejo genético (AU)

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The majority of cases of neonatal diabetes in Spain can be explained by known genetic abnormalities.

BACKGROUND: Neonatal diabetes is a rare disease characterized by hyperglycaemia within the first 3 months of life and requiring insulin treatment; it can either be transient (TNDM) or permanent (PNDM). Alterations at band 6q24 and heterozygous activating mutations in KCNJ11, the gene encoding the pore-forming subunit of the KATP channel, can cause neonatal diabetes. Aims We screened the 6q24 region, KCNJ11, GCK, FOXP3 and IPF1 genes for mutations in families with PNDM or TNDM to establish a phenotype-genotype correlation. METHODS: Twenty-two patients with neonatal diabetes were recruited. Inclusion criteria were insulin-treated diabetes diagnosed within the first 3 months and insulin treatment for at least 15 days. Clinical data were recorded in a questionnaire. RESULTS: We identified 17 genetic alterations in our patients: six alterations at the 6q24 band associated with TNDM and nine mutations in KCNJ11, five of which were novel. The analysis for a phenotype-genotype correlation showed that patients with 6q24 alterations had a lower birth weight and were diagnosed earlier than patients with KCNJ11 mutations. At follow-up of the TNDM patients with genetic alterations, 43% developed diabetes or impaired glucose tolerance in later life (one with 6q24 duplication and two with N48D and E227K mutations at KCNJ11 gene). Furthermore, half the first-degree relatives who carried a genetic alteration but who had not suffered from neonatal diabetes were diagnosed with diabetes or impaired glucose tolerance before the age of 30 years. CONCLUSIONS: KCNJ11 mutations are common in both TNDM and PNDM and are associated with a higher birth weight compared with patients with 6q24 abnormalities. Patients with TNDM should be screened for abnormalities in glucose metabolism in adult life.