UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
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Diabetes resulting from heterozygosity for an inactivating mutation of the homeodomain transcription factor insulin promoter factor 1 (IPF-1) is due to a genetic defect of beta-cell function referred to as maturity-onset diabetes of the young 4. IPF-1 is required for the development of the pancreas and mediates glucose-responsive stimulation of insulin gene transcription. To quantitate islet cell responses in a family harboring a Pro63fsdelC mutation in IPF-1, we performed a five-step (1-h intervals) hyperglycemic clamp on seven heterozygous members (NM) and eight normal genotype members (NN). During the last 30 min of the fifth glucose step, glucagon-like peptide 1 (GLP-1) was also infused (1.5 pmol x kg(-1) x min(-1)). Fasting plasma glucose levels were greater in the NM group than in the NN group (9.2 vs. 5.9 mmol/l, respectively; P < 0.05). Fasting insulin levels were similar in both groups (72 vs. 105 pmol/l for NN vs. NM, respectively). First-phase insulin and C-peptide responses were absent in individuals in the NM group, who had markedly attenuated insulin responses to glucose alone compared with the NN group. At a glucose level of 16.8 mmol/l above fasting level, GLP-1 augmented insulin secretion equivalently (fold increase) in both groups, but the insulin and C-peptide responses to GLP-1 were sevenfold less in the NM subjects than in the NN subjects. In both groups, glucagon levels fell during each glycemic plateau, and a further reduction occurred during the GLP-1 infusion. Sigmoidal dose-response curves of glucose clearance versus insulin levels during the hyperglycemic clamp in the two small groups showed both a left shift and a lower maximal response in the NM group compared with the NN group, which is consistent with an increased insulin sensitivity in the NM subjects. A sharp decline occurred in the dose-response curve for suppression of nonesterified fatty acids versus insulin levels in the NM group. We conclude that the Pro63fsdelC IPF-1 mutation is associated with a severe impairment of beta-cell sensitivity to glucose and an apparent increase in peripheral tissue sensitivity to insulin and is a genetically determined cause of beta-cell dysfunction.
Diabetes 2000 Nov
PMID:Impaired insulin secretion and increased insulin sensitivity in familial maturity-onset diabetes of the young 4 (insulin promoter factor 1 gene). 1107 52

Abundant evidence supports a genetic predisposition to both type 2 diabetes and the traits that precede diabetes (insulin resistance and insulin secretion). Unusual causes of diabetes have been identified, including autosomal dominant, single gene forms due to mutations of glucokinase, the hepatocyte nuclear factors, and insulin promoter factor 1. Mitochondrial mutations also may cause type 2 diabetes, but together these causes explain only a small fraction of type 2 diabetes. In contrast, up to 10% of type 2 diabetes, at least in Caucasian populations, may be autoimmune. Animal models of type 2 diabetes support multiple genetic loci. To identify the loci in the remaining 85% of cases, investigators have tested candidate genes in known pathways formutations with some success. However, no candidate identified to date appears to act as a major susceptibility locus. More recently investigators have used linkage approaches to find genes for type 2 diabetes and the prediabetic traits of insulin resistance and insulin secretion. A locus has now been mapped and potential causative variants identified on chromosome 2q, and many other studies are in progress. New genetic tools and the anticipated completion of the human genome project will likely result in the discovery of yet new genes and pathways that may offer new targets for intervention. Whether a better understanding of the pathophysiology can lead to earlier prediction and detection or prevention will depend on the magnitude of risk conferred by individual genes and particular populations.
Diabetes Technol Ther 2000
PMID:Genetics of type 2 diabetes: an overview for the millennium. 1146 42

Mutations in the human genes encoding hepatocyte nuclear factors (HNF) 1alpha, 1beta, 4alpha, and IPF1(PDX1/IDX1/STF1) result in pancreatic beta cell dysfunction and diabetes mellitus. In hepatocytes, hnf4alpha controls the transcription of hnf1alpha, suggesting that this same interaction may operate in beta cells and thus account for the common diabetic phenotype. We show that, in pancreatic islet and exocrine cells, hnf4alpha expression unexpectedly depends on hnf1alpha. This effect is tissue-specific and mediated through direct occupation by hnf1alpha of an alternate promoter located 45.6 kb from the previously characterized hnf4alpha promoter. Hnf1alpha also exerts direct control of pancreatic-specific expression of hnf4gamma and hnf3gamma. Hnf1alpha dependence of hnf4alpha, hnf4gamma, hnf3gamma, and two previously characterized distal targets (glut2 and pklr) is established only after differentiated cells arise during pancreatic embryonic development. These studies define an unexpected hierarchical regulatory relationship between two genes involved in human monogenic diabetes in the cells, which are relevant to its pathophysiology. Furthermore, they indicate that hnf1alpha is an essential component of a transcription factor circuit whose role may be to maintain differentiated functions of pancreatic cells.
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PMID:A transcription factor regulatory circuit in differentiated pancreatic cells. 1173 36

Pancreas duodenum homeobox-1 (PDX-1) (also known as insulin promoter factor-1, islet/duodenum homeobox-1, somatostatin transactivating factor-1, insulin upstream factor-1 and glucose-sensitive factor) is a transcription factor encoded by a Hox-like homeodomain gene. In humans and other animal species, the embryonic development of the pancreas requires PDX-1, as demonstrated by the identification of an individual with pancreatic agenesis resulting from a mutation that impaired the transcription of a functionally active PDX-1 protein. In adult subjects, PDX-1 is essential for normal pancreatic islet function as suggested by its regulatory action on the expression of a number of pancreatic genes, including insulin, somatostatin, islet amyloid polypeptide, the glucose transporter type 2 and glucokinase. Furthermore, heterozygous mutations of PDX-1 have been linked to a type of autosomal dominant form of diabetes mellitus known as maturity onset diabetes of the young type 4. The dual action of PDX-1, as a differentiation factor during embryogenesis and as a regulator of islet cell physiology in mature islet cells, underscores the unique role of PDX-1 in health and disease of the human endocrine pancreas.
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PMID:Pancreas duodenum homeobox-1 regulates pancreas development during embryogenesis and islet cell function in adulthood. 1183 21

Maturity-onset diabetes of the young (MODY) is a genetically and clinically heterogeneous subtype of type 2 diabetes characterised by an early onset, an autosomal dominant inheritance, and a primary defect in insulin secretion. MODY comprises 2-5% of cases of type 2 diabetes. So far, six MODY genes have been identified (MODY1-6): hepatocyte nuclear factor (HNF-4 alpha), glucokinase, HNF-1 alpha, HNF-1 beta, insulin promoter factor 1(IPF-1), and neurogenic differentiation factor 1 (NEUROD1). MODY2 and MODY3 are the most common forms of MODY. Mutations in glucokinase/MODY2 result in a mild form of diabetes. In contrast, MODY3 and some of the other MODY forms are characterised by major insulin secretory defects and severe hyperglycaemia associated with microvascular complications. About 25% of known MODY is caused by mutations in yet unknown genes and present results suggest that other monogenic forms of type 2 diabetes might exist. The diagnosis of MODY has implications for the clinical management of the patient's diabetes. The identification of MODY genes also opens new perspectives in the understanding of the molecular basis of diabetes and may probably contribute to the definition of novel targets for drug development and gene therapy.
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PMID:[Maturity-onset diabetes of the young--MODY. Molecular-genetic, pathophysiological and clinical characteristics]. 1198 98

Maturity-onset diabetes of the young (MODY) is a genetic subgroup of diabetes characterised by an autosomal dominant inheritance and early onset, non-insulin dependent diabetes. This results from a monogenic defect causing beta-cell dysfunction. The defining of five genes in which mutations cause MODY has allowed us to understand the clinical heterogeneity seen in this condition and can guide clinical management. Mutations in the glucokinase gene lead to stable hyperglycaemia, complications are unusual and treatment is rarely needed. Glucokinase patients are often detected during screening in pregnancy. While maternal mutations increase birth weight by increasing maternal glycaemia, fetal mutations reduce birth weight by reducing fetal insulin secretion. Patients with mutation in genes encoding the transcription factors, hepatocyte nuclear factor (HNF)- 1alpha, HNF-4alpha, HNF-1beta and insulin promoter factor 1 (IPF-1) have a common progressive beta-cell failure resulting in increasing hyperglycaemia and treatment requirements. These patients are at risk of developing microvascular complications. They show a pharmacogenetic effect with a specific sensitivity to sulphonylureas. Patients with transcription factor mutations have a range of discrete extra-pancreatic phenotypes including a low renal threshold for glucose with HNF-1alpha mutations, altered lipids and lipoproteins with HNF-4alpha mutations and a variety of cystic renal diseases and uterine and genital developmental disorders with HNF-1beta mutations. Molecular genetic testing is now available in routine clinical practice. This allows confirmation of a diagnosis of MODYand defines the subgroup. Differences in prognosis and treatment strongly support the increased use of molecular genetic testing in diabetes.
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PMID:Different genes, different diabetes: lessons from maturity-onset diabetes of the young. 1217 91

Psammomys obesus, an animal model of type 2 diabetes, shows rapid and marked depletion of pancreatic insulin content as hyperglycemia develops when fed a high-calorie diet. P. obesus islets do not increase proinsulin gene expression when exposed to high glucose, which may be related to absence of the conserved form of the transcription factor insulin promoter factor 1/pancreatic-duodenal homeobox 1. The present study assesses the importance of regulation of proinsulin gene expression by glucose for insulin production. Islets of diabetes-prone P. obesus and diabetes-resistant Wistar rats, cultured at various glucose concentrations for up to 24 h, were analyzed for proinsulin mRNA by quantitative RT-PCR, proinsulin biosynthesis by leucine incorporation into proinsulin, and insulin content and secretion by RIA. No increase in proinsulin mRNA was observed in P. obesus islets during 24-h exposure to increasing concentrations of glucose. In contrast, rat islets exposed to high glucose responded with a 2- to 3-fold stimulation of proinsulin mRNA. The failure of P. obesus islets to increase proinsulin mRNA was accompanied by a reduced proinsulin biosynthetic response: after 24 h, maximal proinsulin biosynthesis was blunted, associated with depletion of islet insulin content. Inhibition of glucose-stimulated proinsulin gene transcription in rat islets by actinomycin D did not affect the early proinsulin biosynthetic response, which, however, was reduced to the level of P. obesus islets after 24 h in culture. We conclude that stimulation of proinsulin gene transcription by glucose is necessary for maintaining proinsulin biosynthesis and hence conserving pancreatic insulin stores, under conditions of sustained secretory drive, but not for short-term regulation of proinsulin biosynthesis Our findings support the hypothesis that inadequate regulation of proinsulin gene expression by glucose contributes to the failure of P. obesus to cope with the increased demand for insulin associated with caloric excess, leading to depletion of insulin stores and diabetes.
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PMID:Glucose-regulated proinsulin gene expression is required for adequate insulin production during chronic glucose exposure. 1219 32

Diabetes is caused by an absolute (type 1) or relative (type 2) deficiency of insulin-producing beta cells. The mechanisms governing replication of terminally differentiated beta cells and neogenesis from progenitor cells are unclear. Mice lacking insulin receptor substrate-2 (Irs2) develop beta cell failure, suggesting that insulin signaling is required to maintain an adequate beta cell mass. We report that haploinsufficiency for the forkhead transcription factor Foxo1 reverses beta cell failure in Irs2(-/-) mice through partial restoration of beta cell proliferation and increased expression of the pancreatic transcription factor pancreas/duodenum homeobox gene-1 (Pdx1). Foxo1 and Pdx1 exhibit mutually exclusive patterns of nuclear localization in beta cells, and constitutive nuclear expression of a mutant Foxo1 is associated with lack of Pdx1 expression. We show that Foxo1 acts as a repressor of Foxa2-dependent (Hnf-3beta-dependent) expression from the Pdx1 promoter. We propose that insulin/IGFs regulate beta cell proliferation by relieving Foxo1 inhibition of Pdx1 expression in a subset of cells embedded within pancreatic ducts.
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PMID:The forkhead transcription factor Foxo1 links insulin signaling to Pdx1 regulation of pancreatic beta cell growth. 1248 34

Neonatal diabetes mellitus can be transient or permanent. The severe form of permanent neonatal diabetes mellitus can be associated with pancreas agenesis. Normal pancreas development is controlled by a cascade of transcription factors, where insulin promoter factor 1 (IPF1) plays a crucial role. Here, we describe two novel mutations in the IPF1 gene leading to pancreas agenesis. Direct sequence analysis of exons 1 and 2 of the IPF1 gene revealed two point mutations within the homeobox in exon 2. Genetic analysis of the parents showed that each mutation was inherited from one parent. Mutations localized in helices 1 and 2, respectively, of the homeodomain, decreased the protein half-life significantly, leading to intracellular IPF1 levels of 36% and 27% of wild-type levels. Both mutant forms of IPF1 were normally translocated to the nucleus, and their DNA binding activity on different known target promoters was similar to that of the wild-type protein. However, transcriptional activity of both mutant IPF1 proteins, alone or in combination with HNF3 beta/Foxa2, Pbx1, or the heterodimer E47-beta 2 was reduced, findings accounted for by decreased IPF1 steady state levels and not by impaired protein-protein interactions. We conclude that the IPF1 level is critical for human pancreas formation.
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PMID:Agenesis of human pancreas due to decreased half-life of insulin promoter factor 1. 1297 Mar 16

Pre-B cell leukemia transcription factor 1 (PBX1) encodes a homeodomain containing protein that is essential for pancreatic development and interacts with insulin promoter factor 1 to regulate insulin secretion. PBX1 maps to chromosome 1q22, a region with replicated linkage to type 2 diabetes (T2DM). We screened for sequence variation in nine exons, intronic regions flanking the exons, the 3' untranslated region (3' UTR), as well as 1-kb upstream of exon 1 in 16 Caucasians and 16 African American individuals with T2DM. We evaluated 18 variants including the nonsynonymous substitution G21S in exon 1, one 4 bp insertion/deletion, and one 7 bp insertion/deletion. We typed 10 variants on the basis of frequency and linkage disequilibrium patterns unrelated Caucasian subjects with T2DM and controls, and nine common variants in 129 Caucasian individuals for whom we had detailed assessments of insulin action and insulin secretion. We typed four common variants in African Americans individuals and additional SNPs in pooled DNA samples from both populations. No coding variant was associated with diabetes and no association was found among African American subjects. However, three variants in Caucasians (78287, 91227, and 252050 bp) were associated with T2DM (p<0.05), as were four marker haplotypes that included intron 2 variants. Additionally, three variants including G21S (61 bp) and the diabetes associated SNP at 78287 were significant determinants of insulin sensitivity (S(I)) in interaction with body mass index (p<0.02). Sequence variants in different locations of the PBX1 gene may have modest pleiotropic effects on T2DM susceptibility in Caucasians.
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PMID:Evaluation of sequence variants in the pre-B cell leukemia transcription factor 1 gene: a positional and functional candidate for type 2 diabetes and impaired insulin secretion. 1614 May 54

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