UNIPROT:P01275 - FACTA Search

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Query: UNIPROT:P01275 (glucagon)
26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The expression of the genes encoding the hormones glucagon, insulin, somatostatin, and pancreatic polypeptide in the endocrine islets of the pancreas is regulated in a cell-specific manner, defining four distinct cellular phenotypes (A-, B-, D-, and F-cells, respectively). Binding of nuclear proteins to cognate DNA sequences within cis-acting regulatory elements mediates the transcriptional events that result in the cell-specific activation or repression of gene expression. In a parallel study, we describe the functional properties of the SMS-UE, a pancreatic islet D-cell specific enhancer element that regulates the expression of the somatostatin gene and contains two interdependent domains, A and B. In the studies described herein, we have characterized the nuclear proteins that recognize the SMS-UE. Domain A of the SMS-UE is a DNA enhancer sequence that is identical to that bound by the ubiquitously distributed CCAAT box-binding protein alpha-CBF, a transcription factor that regulates the expression of the human chorionic gonadotrophin alpha-subunit gene. The B-domain, on the other hand, binds an islet cell-specific protein with characteristics similar to those of Isl-1, a transcriptional activator protein that binds to the E2 enhancer of the rat insulin-1 gene. In addition, the SMS-UE binds transcription factor CREB but not CREM, the close homolog of CREB, on a site adjacent to, or overlapping, the 3' end of domain B. We show that the carboxyl-terminal bZIP domain of CREB binds to the cAMP response element of the somatostatin gene but is not sufficient for binding to the SMS-UE, and we present evidence suggesting that CREB.SMS-UE binding requires stabilization by a region of the protein located within the transactivation domain.
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PMID:Somatostatin gene upstream enhancer element activated by a protein complex consisting of CREB, Isl-1-like, and alpha-CBF-like transcription factors. 135 92

Fetal (20-21 day gestation) and neonatal (less than 5-day-old) rat islets were isolated from the glucagon-rich (dorsal) and glucagon-poor (ventral) pancreatic regions. After 1 or 2 wk in culture, groups of islets from each region were transferred to culture dishes containing Krebs-Ringer bicarbonate buffer with low (2.4 mM) and high (16.7 mM) glucose plus aminophylline. After 2 wk in culture, insulin released into medium was higher than after 1 wk, and more so if the islets originated from dorsal tissue (P less than .01). Glucagon release in response to alanine (10 mM) stimulation was also significantly higher in dorsal than in ventral islets (6.38 +/- 1.98 vs. 1.49 +/- 0.89 pg X islet-1 X h-1, respectively; P less than .02). Coincident with higher insulin and glucagon release, islet yield was greater in tissue from the dorsal neonatal pancreas than from that obtained in the fetal and neonatal ventral pancreas [range: dorsal, 131-180 (median, 153), vs. ventral, 53-127 (median, 84), islets obtained on day 5 of culture]. Neonatal islets of dorsal origin were transplanted intrasplenically (500-3000 islets) to streptozocin-induced diabetic inbred Lewis rats. Only rats receiving greater than 2500 islets were cured by transplantation. These experiments show that dorsal fetal islets secrete more insulin than do ventral islets and that islet yield is higher when islets are isolated from dorsal rather than from ventral perinatal pancreatic tissue. Despite their in vitro behavior, more neonatal dorsal islets are required to cure experimental diabetes than are reported with adult islets.
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PMID:Hormone release, islet yield, and transplantation of fetal and neonatal rat dorsal and ventral pancreatic islets. 309 1

As part of an ongoing search for susceptibility loci for NIDDM, we tested 19 genes whose products are implicated in insulin secretion or action for linkage with NIDDM. Loci included the G-protein-coupled inwardly rectifying potassium channels expressed in beta-cells (KCNJ3 and KCNJ7), glucagon (GCG), glucokinase regulatory protein (GCKR), glucagon-like peptide I receptor (GLP1R), LIM/homeodomain islet-1 (ISL1), caudal-type homeodomain 3 (CDX3), proprotein convertase 2 (PCSK2), cholecystokinin B receptor (CCKBR), hexokinase 1 (HK1), hexokinase 2 (HK2), mitochondrial FAD-glycerophosphate dehydrogenase (GPD2), liver and muscle forms of pyruvate kinase (PKL, PKM), fatty acid-binding protein 2 (FABP2), hepatic phosphofructokinase (PFKL), protein serine/threonine phosphatase 1 beta (PPP1CB), and low-density lipoprotein receptor (LDLR). Additionally, we tested the histidine-rich calcium locus (HRC) on chromosome 19q. All regions were tested for linkage with microsatellite markers in 751 individuals from 172 families with at least two patients with overt NIDDM (according to World Health Organization criteria) in the sibship, using nonparametric methods. These 172 families comprise 352 possible affected sib pairs with overt NIDDM or 621 possible affected sib pairs defined as having a fasting plasma glucose value of >6.1 mmol/l or a glucose value of >7.8 mmol/l 2 h after oral glucose load. No evidence for linkage was found with any of the 19 candidate genes and NIDDM in our population by nonparametric methods, suggesting that those genes are not major contributors to the pathogenesis of NIDDM. However, some evidence for suggestive linkage was found between a more severe form of NIDDM, defined as overt NIDDM diagnosed before 45 years of age, and the CCKBR locus (11p15.4; P = 0.004). Analyses of six additional markers spanning 27 cM on chromosome 11p confirmed the suggestive linkage in this region. Whether an NIDDM susceptibility gene lies on chromosome 11p in our population must be determined by further analyses.
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PMID:Genetics of NIDDM in France: studies with 19 candidate genes in affected sib pairs. 916 80

To begin to understand pancreas development and the control of endocrine lineage formation in zebrafish, we have examined the expression pattern of several genes shown to act in vertebrate pancreatic development: pdx-1, insulin (W. M. Milewski et al., 1998, Endocrinology 139, 1440-1449), glucagon, somatostatin (F. Argenton et al., 1999, Mech. Dev. 87, 217-221), islet-1 (Korzh et al., 1993, Development 118, 417-425), nkx2.2 (Barth and Wilson, 1995, Development 121, 1755-1768), and pax6.2 (Nornes et al., 1998, Mech. Dev. 77, 185-196). To determine the spatial relationship between the exocrine and the endocrine compartments, we have cloned the zebrafish trypsin gene, a digestive enzyme expressed in differentiated pancreatic exocrine cells. We found expression of all these genes in the developing pancreas throughout organogenesis. Endocrine cells first appear in a scattered fashion in two bilateral rows close to the midline during mid-somitogenesis and converge during late-somitogenesis to form a single islet dorsal to the nascent duodenum. We have examined development of the endocrine lineage in a number of previously described zebrafish mutations. Deletion of chordamesoderm in floating head (Xnot homolog) mutants reduces islet formation to small remnants, but does not delete the pancreas, indicating that notochord is involved in proper pancreas development, but not required for differentiation of pancreatic cell fates. In the absence of knypek gene function, which is involved in convergence movements, the bilateral endocrine primordia do not merge. Presence of trunk paraxial mesoderm also appears to be instrumental for convergence since the bilateral endocrine primordia do not merge in spadetail mutants. We discuss our findings on zebrafish pancreatogenesis in the light of evolution of the pancreas in chordates.
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PMID:Pancreas development in zebrafish: early dispersed appearance of endocrine hormone expressing cells and their convergence to form the definitive islet. 1116 72

The Lim domain homeobox gene (Isl-1) is a positional candidate gene for obesity that maps on chromosome 5q11-q13, a locus linked to BMI and leptin levels in French Caucasians. Isl-1 might be involved in body weight regulation and glucose homeostasis via the activation of proglucagon gene expression, which encodes for glucagon and glucagon-like peptides. By mutation screening of 72 obese subjects, we identified three single-nucleotide polymorphisms (SNPs) in the Isl1 gene. The allele frequencies in the morbidly obese group did not differ from that of the control group. In the obese group, the -47G allele was associated with a decreased risk of type 2 diabetes (odds ratio 0.41, P = 0.019). The AG bearers displayed a higher maximal BMI than the AA bearers in the whole obese group (P = 0.026) as well as in the type 2 diabetic obese subgroup (P = 0.014). In obese families, this allele was not preferentially transmitted from heterozygous parents to their obese siblings, indicating that Isl-1 does not contribute to the linkage with obesity on 5cen-q. However, in French Caucasian morbidly obese subjects, the Isl1-47A-->G SNP may modulate the risk for type 2 diabetes and may increase body weight in diabetic morbidly obese subjects.
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PMID:Positional candidate gene analysis of Lim domain homeobox gene (Isl-1) on chromosome 5q11-q13 in a French morbidly obese population suggests indication for association with type 2 diabetes. 1197 68

A basic-leucine zipper transcription factor, MafA, was recently identified as one of the most important transactivators of insulin gene expression. This protein controls the glucose-regulated and pancreatic beta-cell-specific expression of the insulin gene through a cis-regulatory element called RIPE3b/MARE (Maf-recognition element). Here, we show that MafA expression is restricted to beta-cells of pancreatic islets in vivo and in insulinoma cell lines. We also demonstrate that c-Maf, another member of the Maf family of transcription factors, is expressed in islet alpha-cells and in a glucagonoma cell line (alphaTC1), but not in gamma- and delta-cells. An insulinoma cell line, betaTC6, also expressed c-Maf, albeit at a low level. Chromatin immunoprecipitation assays demonstrated that Maf proteins associate with insulin and glucagon promoters in beta- and alpha-cell lines, respectively. c-Maf protein stimulated glucagon promoter activity in a transient luciferase assay, and activation of the glucagon promoter by c-Maf was more efficient than by the other alpha-cell-enriched transcription factors, Cdx2, Pax6, and Isl-1. Furthermore, inhibition of c-Maf expression in alphaTC1 cells by specific short hairpin RNA resulted in marked reduction of the glucagon promoter activity. Thus, c-Maf and MafA are differentially expressed in alpha- and beta-cells where they regulate glucagon and insulin gene expression, respectively.
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PMID:Differentially expressed Maf family transcription factors, c-Maf and MafA, activate glucagon and insulin gene expression in pancreatic islet alpha- and beta-cells. 1476 89

Mesenchymal stem cells (MSC) from mouse bone marrow were shown to adopt a pancreatic endocrine phenotype in vitro and to reverse diabetes in an animal model. MSC from human bone marrow and adipose tissue represent very similar cell populations with comparable phenotypes. Adipose tissue is abundant and easily accessible and could thus also harbor cells with the potential to differentiate in insulin producing cells. We isolated human adipose tissue-derived MSC from four healthy donors. During the proliferation period, the cells expressed the stem cell markers nestin, ABCG2, SCF, Thy-1 as well as the pancreatic endocrine transcription factor Isl-1. The cells were induced to differentiate into a pancreatic endocrine phenotype by defined culture conditions within 3 days. Using quantitative PCR a down-regulation of ABCG2 and up-regulation of pancreatic developmental transcription factors Isl-1, Ipf-1, and Ngn3 were observed together with induction of the islet hormones insulin, glucagon, and somatostatin.
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PMID:Human adipose tissue-derived mesenchymal stem cells differentiate into insulin, somatostatin, and glucagon expressing cells. 1646 Jun 77

In order to purify and characterize nestin-positive cells in the developing pancreas a transgenic mouse was generated, in which the enhanced green fluorescent protein (EGFP) was driven by the nestin second intronic enhancer and upstream promoter. In keeping with previous studies on the distribution of nestin, EGFP was expressed in the developing embryo in neurones in the brain, eye, spinal cord, tail bud and glial cells in the small intestine. In the pancreas there was no detectable EGFP at embryonic day 11.5 (E11.5). EGFP expression appeared at E12.5 and increased in intensity through E14.5, E18.5 and post-natal day 1. Flow cytometry was used to quantify and purify the EGFP positive population in the E15.5 pancreas. The purified (96%) EGFP-expressing cells, which represent 20% of the total cell population, were shown by RT/PCR to express exocrine cell markers (amylase and P48) and endocrine cell markers (insulin 1, insulin 2, and Ngn3). They also expressed, at a lower level, PDX-1, Isl-1, and the islet hormones pancreatic polypeptide, glucagon and somatostatin as well as GLUT2, the stem cell marker ABCG2 and PECAM, a marker of endothelial cells. It was further shown by immunocytochemistry of the E15.5 pancreas that EGFP colocalised in separate subpopulations of cells that expressed nestin, insulin and amylase. These results support the conclusion that nestin expressing cells can give rise to both endocrine and exocrine cells. The ability to purify these putative progenitor cells may provide further insights into their properties and function.
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PMID:Presence of endocrine and exocrine markers in EGFP-positive cells from the developing pancreas of a nestin/EGFP mouse. 1669 77

Mesenchymal cells in the developing pancreas express the neural stem cell marker nestin and the transcription factor islet-1 (Isl-1). Using defined culture conditions we isolated on a single cell basis nestin producing cells from human pancreatic islets. These cells were immortalized with lentiviral vectors coding for telomerase and mBmi. They are positive for Isl-1 and nestin and have the potential to adopt a pancreatic endocrine phenotype with expression of critical transcription factors including Ipf-1, Isl-1, Ngn-3, Pax4, Pax6, Nkx2.2, and Nkx6.1 as well as the islet hormones insulin, glucagon, and somatostatin. In addition, they can be differentiated into human albumin producing cells in vivo when grafted into a SCID mouse liver. In accordance with a mesenchymal phenotype, the cells were also able to adopt adipocytic or osteocytic phenotypes in vitro. In conclusion, cultured pancreatic islets contain nestin and Isl-1 positive mesenchymal stem cells with multipotential developmental capacity.
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PMID:Multipotential nestin and Isl-1 positive mesenchymal stem cells isolated from human pancreatic islets. 1671 99

There is growing evidence that the human amnion contains various types of stem cells. As amniotic tissue is readily available, it has the potential to be an important source of material for regenerative medicine. In the present study, we evaluated the potential of human amnion-derived fibroblast-like (HADFIL) cells to differentiate into pancreatic islet cells. Two HADFIL cell populations, derived from two different neonates, were analyzed. The expression of pancreatic cell-specific genes was examined before and after in vitro induction of cellular differentiation. We found that Pdx-1, Isl-1, Pax-4, and Pax-6 showed significantly increased expression following the induction of differentiation. In addition, immunostaining demonstrated that insulin, glucagon, and somatostatin were present in HADFIL cells following the induction of differentiation. These results indicate that HADFIL cell populations have the potential to differentiate into pancreatic islet cells. Although further studies are necessary to determine whether such in vitro-differentiated cells can function in vivo as pancreatic islet cells, these amniotic cell populations might be of value in therapeutic applications that require human pancreatic islet cells.
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PMID:Induced in vitro differentiation of pancreatic-like cells from human amnion-derived fibroblast-like cells. 1962 6

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