Project description:Although mutations in the nuclear receptor HNF4A were identified as the cause of Maturity Onset Diabetes of the Young 1 (MODY1) nearly two decades ago, the mechanisms by which HNF4A regulates glucose homeostasis remain unclear. Here we report that loss of Drosophila HNF4 recapitulates hallmark symptoms of MODY1, including adult-onset hyperglycemia, glucose intolerance and impaired glucose-stimulated insulin secretion (GSIS). These defects are linked to an unexpected role for dHNF4 within mitochondria to directly regulate mtDNA transcription, while also promoting the expression of nuclear genes involved in oxidative phosphorylation (OXPHOS) and Hex-C, a homolog of the MODY2 gene Glucokinase. dHNF4 is required in the fat body and insulin-producing cells to maintain glucose homeostasis by supporting a developmental switch toward OXPHOS and GSIS at the transition to adulthood. These findings establish an animal model for MODY1 and define a developmental reprogramming of metabolism to support the energetic needs of the mature animal.

Project description:The aim of this experiment was to use microarray analysis to examine the phenotype of dis-regulated insulin secretion and abnormal beta cell growth in HNF4 alpha null mice. These mice show impaired glucose tolerance and elevated fasting and fed plasma insulin levels. Rana Gupta from Klaus Kaestner's Lab extracted RNA from isolated islets. Three controls and five mutants were provided for the study.

Project description:We find that HNF4G is an intestine-particular HNF4 paralog, and works redundantly with HNF4A for driving intestinal differentiation by controlling chromatin accessibility and regulating thousands of transcripts particular to differentiated cells. Without HNF4s, cells fail to achieve a differentiated state. A positive feedback loop between HNF4 transcriptional regulation and BMP/SMAD signaling stabilizes differentiation, and the two inputs cooperatively activate differentiation gene expression.

Project description:Background and Aims: HNF4a is a nuclear hormone receptor transcription factor that has been shown to be required for hepatocyte differentiation and development of the liver. It has also been implicated in regulating expression of genes that act in the epithelium of the lower gastrointestinal tract. This implied that HNF4a might be required for development of the gut. Methods: We generated mouse embryos in which HNF4a was ablated in the epithelial cells of the fetal colon using Cre-loxP technology. Embryos were examined using a combination of histology, immunohistochemistry, gene array and RT-PCR, and chromatin immunoprecipitation analyses to define the consequence of loss of HNF4a on colon development. Results: Embryos could be generated until E18.5 that lacked HNF4a in their colon. Although, early stages of colonic development occurred, HNF4a null colons failed to form normal crypts. In addition, goblet cell maturation was perturbed and expression of an array of genes that encode proteins with diverse roles in colon function was disrupted. Several genes whose expression in the colon was dependent on HNF4a contained HNF4a–binding sites sequences within putative transcriptional regulatory regions and a subset of these sites were occupied by HNF4a in vivo. Conclusion: HNF4a is a transcription factor that is essential for development of the mammalian colon, regulates goblet cell maturation and is required for expression of genes that control normal colon function and epithelial cell differentiation. Keywords: E18.5 FETAL HNF4 NULL COLONS

Project description:Drosophila HNF4 promotes glucose-stimulated insulin secretion and increased mitochondrial function in adults

Project description:To define changes in gene expression resulting from loss of hnf4 in the small intestine. Keywords: genetic modification

Project description:A strong association of the gain-of-function mutation in the TALK-1 K+ channel (p.L114P) with maturity-onset diabetes of the young (MODY) was recently reported in two distinct families. TALK-1 is a key regulator of β-cell electrical activity and glucose-stimulated insulin secretion (GSIS). KCNK16, the gene that encodes TALK-1, is the most abundant and β-cell–restricted K+ channel transcript and KCNK16 locus is strongly associated to type-2 diabetes. To investigate the impact of TALK-1-L114P on glucose homeostasis and confirm its association with MODY, a mouse model containing the TALK-1-L114P mutation was generated. Heterozygous and homozygous TALK-1-L114P mice exhibit increased neonatal lethality in the C57BL/6J and the CD-1(ICR) genetic background, respectively. Lethality is likely a result of severe hyperglycemia observed in the homozygous TALK-1-L114P neonates due to lack of GSIS and can be reduced with insulin treatment. TALK-1-L114P drastically increases whole-cell β-cell K+ currents resulting in blunted glucose-stimulated Ca2+ entry and a complete loss of glucose-induced Ca2+ oscillations. Thus, adult TALK-1-L114P mice have reduced GSIS and plasma insulin levels, which significantly impairs glucose homeostasis. Taken together, this study shows that the MODY-associated TALK-1-L114P mutation disrupts glucose homeostasis in adult mice resembling a MODY phenotype and causes neonatal lethality by altering islet hormone secretion during development. These data strongly suggest that TALK-1 is an islet-restricted target for the treatment for diabetes

Project description:To study the role of hepatic nuclear factor alpha (HNF4a in hepatogenesis, we used loxP-Cre technology to eliminate it from developing mouse livers. A comparison of control and experimental livers revealed that hepatocytes lacking HNF4a_failed to fully differentiate. Specifically, HNF4a null liver cells failed to express genes that are markers of mature hepatocytes including Gys2, Pck1, and G6pc. These cells also failed to form normal cellular junctions, which are critical for establishment of the hepatic epithelium [Parviz et al. (2003) Nat.Genet. 34, 292-96]. Because HNF4a functions as a transcription factor, we hypothesized that it regulates liver development by controlling the expression of genes whose products are essential in executing cellular differentiation and morphogenesis. To identify these genes, we compared expression profiles between HNF4a null and wild type E18.5 fetal livers using Affymetrix gene arrays. We identified 564 genes whose expression was decreased by at least 2.5-fold and 34 genes whose expression was increased by at least 2.5-fold when HNF4a was eliminated from hepatocytes. These represent genes involved in diverse molecular pathways, reflecting the pleiotropic phenotype of HNF4a null livers. Our goal was to use the information from the gene arrays to define the mechanisms through which HNF4a controls the generation of the hepatic epithelium. We identified 27 genes from our list of downregulated genes with either defined or predicted roles in cellular junctions and/or adhesion. Most striking was that loss of HNF4a altered the expression of genes encoding proteins involved in virtually all types of cellular junctions including tight junctions (Cldn1, Cldn-2, Cldn-12, Ocln, F11r/Jam1, Cxadr, Crb3), adherens junctions (Cdh1), desmosomes (Dsc2, Pkp2, Krt2-8), and gap junctions (Gjb1, Gjb2). Using immunoblotting and immunohistochemistry, we found that the expression of proteins representing each of these junction types was reduced or absent. Analysis of these genes for the presence of putative HNF4a binding sites revealed that 25 of 27 contain such sites. We have used chromatin immunoprecipitation to confirm that HNF4a occupies several of these sites in vivo, including Cdh1, Cldn1, and F11r/Jam1. From these data, we conclude that HNF4a is a central mediator of the fully differentiated hepatocyte gene expression program and that it orchestrates the expression of cell junction and adhesion proteins required for establishing the hepatic epithelium. Keywords: E18.5 fetal hnf4 null and control mouse livers

Project description:Glucagon and insulin are counter-regulatory pancreatic hormones that precisely control blood glucose homeostasis1. Type 2 diabetes mellitus (T2DM) is characterized by inappropriately elevated blood glucagon2-5 levels as well as insufficient glucose stimulated insulin secretion (GSIS) by pancreatic ß-cells6. Early in the pathogenesis of T2DM, hyperglucagonemia is observable antecedent to ß-cell dysfunction7-9; and in mice, liver-specific activation of glucagon receptor-dependent signaling results in impaired GSIS10. However, the mechanistic relationship between hyperglucagonemia, hepatic glucagon action, and ß-cell dysfunction remains poorly understood. Here we show that glucagon action stimulates hepatic production of the neuropeptide kisspeptin1, which acts in an endocrine manner on ß-cells to suppress GSIS. In vivo glucagon administration acutely stimulates hepatic kisspeptin1 production, and kisspeptin1 is increased in livers from humans with T2DM and from mouse models of diabetes mellitus. Synthetic kisspeptin1 potently suppresses GSIS in vivo and in vitro from normal isolated islets, which express the kisspeptin1 receptor Kiss1R. Administration of a Kiss1R antagonist in diabetic Leprdb/db mice potently augments GSIS and reduces glycemia. Our observations indicate in the pathogenesis of T2DM an endocrine mechanism sequentially linking hyperglucagonemia via hepatic kisspeptin1 production to impaired insulin secretion. In addition, our findings suggest Kiss1R antagonism as a therapeutic avenue to improve ß-cell function in T2DM. Total RNA from L-Δprkar1a KO mice compared to control D-glucose mice

Project description:SHP (small heterodimer partner; NR0B2) belongs to the nuclear hormone receptor superfamily, which regulates numerous developmental and metabolic cellular functions. To study physiological function of SHP, we generated congenic SHP-/- mice on C57Bl/6 background. When the congenic SHP-/- mice were challenged with a western diet (high fat, hgih sucrose, high cholesterol) for 20 weeks, they were resistant to diet induced obesity but severely glucose intolerant compared to wild type control mice. However, their overall peripheral tissue insulin sensitivity was normal when assessed by insulin tolerance test. Next, we examined the glucose stimulated insulin secretion (GSIS) in isolated islets from these animals. Islets from SHP-/- mice showed strongly impaired GSIS especially fed the western diet, which is believed to be a major factor causing the whole body glucose intolerance in SHP-/- mice. Therefore, we explored gene expression in islets using illumina beadchip array to understand mechanisms underneath the impaired GSIS.