Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.
Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.
Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.
Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.
Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.
Project description:The zinc finger factor Insm1 is known to regulate differentiation of pancreatic β cells during development, Here we show that Insm1 is essential for the maintenance of functionally mature pancreatic β cells in mice. We used microarrays to analyse the global gene expression after deletion of insm1 in adult pancreatic β cells and identified functional important genes and immature islets releated genes deregulated in the mutatant islets.
Project description:Recent advances in the understanding of the genetics of type 2 diabetes (T2D) susceptibility have focused attention on the regulation of transcriptional activity within the pancreatic beta-cell. MicroRNAs (miRNAs) represent an important component of regulatory control, and have proven roles in the development of human disease and control of glucose homeostasis. We set out to establish the miRNA profile of human pancreatic islets and of enriched beta-cell populations, and to explore their potential involvement in T2D susceptibility. We used Illumina small RNA sequencing to profile the miRNA fraction in three preparations each of primary human islets and of enriched beta-cells generated by fluorescence-activated cell sorting. In total, 366 miRNAs were found to be expressed (i.e. >100 cumulative reads) in islets and 346 in beta-cells; of the total of 384 unique miRNAs, 328 were shared. A comparison of the islet-cell miRNA profile with those of 15 other human tissues identified 40 miRNAs predominantly expressed (i.e. >50% of all reads seen across the tissues) in islets. Several highly-expressed islet miRNAs, such as miR-375, have established roles in the regulation of islet function, but others (e.g. miR-27b-3p, miR-192-5p) have not previously been described in the context of islet biology. As a first step towards exploring the role of islet-expressed miRNAs and their predicted mRNA targets in T2D pathogenesis, we looked at published T2D association signals across these sites. We found evidence that predicted mRNA targets of islet-expressed miRNAs were globally enriched for signals of T2D association (p-values <0.01, q-values <0.1). At six loci with genome-wide evidence for T2D association (AP3S2, KCNK16, NOTCH2, SCL30A8, VPS26A, and WFS1) predicted mRNA target sites for islet-expressed miRNAs overlapped potentially causal variants. In conclusion, we have described the miRNA profile of human islets and beta-cells and provide evidence linking islet miRNAs to T2D pathogenesis. Examination of the miRNA profiles in 3 preparations of isolated pancreatic islets and 3 preparations of FACS-enriched pancreatic beta-cells