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  • Covalent histone modifications underlie the developmental regulation of insulin gene transcription in pancreatic beta cells.

Covalent histone modifications underlie the developmental regulation of insulin gene transcription in pancreatic beta cells.

The Journal of biological chemistry (2003-04-25)
Swarup K Chakrabarti, Joshua Francis, Suzanne M Ziesmann, James C Garmey, Raghavendra G Mirmira
ABSTRACT

Histone modifying enzymes contribute to the activation or inactivation of transcription by ultimately catalyzing the unfolding or further compaction, respectively, of chromatin structure. Actively transcribed genes are typically hyperacetylated at Lys residues of histones H3 and H4 and hypermethylated at Lys-4 of histone H3 (H3-K4). To determine whether covalent histone modifications play a role in the beta cell-specific expression of the insulin gene, we performed chromatin immunoprecipitation assays using anti-histone antibodies and extracts from beta cell lines, non-beta cell lines, and ES cells, and quantitated specific histone modifications at the insulin promoter by real-time PCR. Our studies reveal that the proximal insulin promoter is hyperacetylated at histone H3 only in beta cells. This hyperacetylation is highly correlated to recruitment of the histone acetyltransferase p300 to the proximal promoter in beta cells, and is consistent with the role of hyperacetylation in promoting euchromatin formation. We also observed that the proximal insulin promoter of beta cells is hypermethylated at H3-K4, and that this modification is correlated to the recruitment of the histone methyltransferase SET7/9 to the promoter. ES cells demonstrate a histone modification pattern intermediate between that of beta cells and non-beta cells, and is consistent with their potential to express the insulin gene. We therefore propose a model in which insulin transcription in the beta cell is facilitated by a unique combination of transcription factors that acts in the setting of an open, euchromatic structure of the insulin gene.

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Sigma-Aldrich
Insulin human, recombinant, expressed in yeast, γ-irradiated, suitable for cell culture