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)

Northern-blot analysis was used to demonstrate that an increase in extracellular glucose concentration increased the content of preproinsulin mRNA 2.3-fold in the beta-cell line HIT T15. A probe for the constitutively expressed glyceraldehyde-3-phosphate dehydrogenase was used as a control. Mannoheptulose blocked this effect of glucose. A stimulatory effect on preproinsulin mRNA levels was also observed in response to mannose and to 4-methyl-2-oxopentanoate. However, galactose and arginine were ineffective. Glucagon, forskolin and dibutyryl cyclic AMP also elicited an increase in HIT-cell preproinsulin mRNA. The ability of the 5' upstream region of the preproinsulin gene to mediate the effect of glucose and other metabolites on transcription was studied by using a bacterial reporter gene technique. HIT cells were transfected with a plasmid, pOK1, containing the upstream region of the rat insulin-1 gene (-345 to +1) linked to chloramphenicol acetyltransferase (CAT). Co-transfection with a plasmid pRSV beta-gal containing beta-galactosidase driven by the Rous sarcoma virus promoter was used as a control for the efficiency of transfection; expression of CAT activity in transfected HIT cells was normalized by reference to expression of beta-galactosidase. Glucose caused a dose-dependent increase in expression of CAT activity, with a half-maximal effect at 5.5 mM and a maximum response of 4-fold. Mannoheptulose blocked this effect of glucose. Other metabolites (mannose, 4-methyl-2-oxopentanoate and leucine plus glutamine) were also able to increase insulin promoter-driven CAT expression, but galactose and arginine were ineffective. The stimulatory effect of glucose on CAT expression was not blocked by verapamil and was inhibited by increasing extracellular Ca2+ from 0.4 to 5 mM. Both dibutyryl cyclic AMP and forskolin caused an increase in insulin promoter-driven gene expression in the presence of 1 mM-glucose, but neither agent further increased the level of expression occurring in the presence of a maximally stimulating glucose concentration. The phorbol ester phorbol 12-myristate 13-acetate (PMA) also increased insulin promoter-driven CAT expression in the presence of 1 mM-, but not 11 mM-glucose. Staurosporine blocked the stimulatory effect not only of PMA but also of glucose and of dibutyryl cyclic AMP. We conclude that the 5' upstream region of the insulin gene contains sequences responsible for mediating the stimulatory effect of glucose on insulin-gene transcription.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Control of insulin gene expression by glucose. 132 37

Cytokine effects on permanent cell lines of transformed mouse pancreatic alpha- and beta-cells were compared. The beta-tumor cell 1 (beta TC1) line (from an adenoma created in transgenic mice expressing the SV40 large T-antigen oncogene under control of the rat insulin II promoter) produced insulin predominantly, although small quantities of intracellular glucagon (100:1 insulin to glucagon) were detectable by radioimmunoassay. The alpha TC1 line (from an adenoma created in transgenic mice expressing the SV40 large T-antigen oncogene under control of the rat preproglucagon promoter) produced not only glucagon but also considerable quantities of insulin (4:1 glucagon to insulin) and preproinsulin mRNA. We therefore cloned alpha TC1 cells and obtained 12 glucagon-producing clonal cell lines that did not produce levels of insulin detectable by radioimmunoassay. Analysis by Northern blotting of total RNA from two lines, alpha TC1 clones 6 and 9, confirmed the absence of preproinsulin mRNA. No somatostatin or pancreatic polypeptide was detected by immunohistochemical staining in alpha TC1 clones 6 or 9 or beta TC1 cells. Rat recombinant gamma-interferon (IFN-gamma; 5-250 U/ml) or mouse recombinant interleukin 1 (IL-1; 1-25 U/ml) individually inhibited DNA synthesis in beta TC1 cells after 3 days of treatment. The two cytokines in combination acted synergistically to further depress DNA synthesis and increase cytotoxicity. In contrast, alpha TC1 clone 9 cells were not sensitive to inhibition of DNA synthesis by each cytokine individually, although glucagon synthesis was inhibited. The combination of these cytokines caused marked inhibition of DNA and glucagon syntheses in alpha TC1 clone 9 cells. alpha TC1 clone 9 cells were somewhat more resistant to the cytotoxic action of the combined cytokines than were beta TC1 cells. Incubation with 50 U/ml IFN-gamma induced class II MHC molecules (I-Ab, I-Ad, and I-Ed) and enhanced the constitutive expression of class I molecules (H-2Kb and H-2Kd) on the cell surfaces of beta TC1, uncloned alpha TC1, and alpha TC1 clones 6 and 9. Thus, these cell lines are heterozygous for MHC alleles derived from both parental strains used in the construction of the transgenic mice [C57BL/6J (H-2b) and DBA/2J (H-2d)]. Class II gene transcription induced by IFN-gamma was confirmed in beta TC1 and alpha TC1 clone 9 cells by Northern blot analysis with A alpha-, A beta-, E alpha, and E beta-DNA probes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Comparison of cytokine effects on mouse pancreatic alpha-cell and beta-cell lines. Viability, secretory function, and MHC antigen expression. 210 69

Human and rat insulin cells show insulin immunoreactivity, and glucagon cells show glucagon immunoreactivity on their membrane surfaces, respectively. The reaction occurs in the form of small dots on the islet cell surface and colocalizes with the chromogranin family of secretory granule markers. Electron microscopy reveals the labeling to occur at sites of exocytotic granule release, involving the surfaces of extruded granule cores. The surfaces of islet cells were labeled both by polyclonal and monoclonal antibodies, excluding that receptor-interacting, anti-idiotypic hormone antibodies were responsible for the staining. Human insulin cells were surface-labeled by monoclonal antibodies recognizing the mature secretory products, insulin and C-peptide but not with monoclonal antibodies specific for proinsulin. Thus, routing of unprocessed preproinsulin to the cell surface may not account for these results. It is concluded that the staining reflects interactions between the appropriate antibodies and exocytotic sites of hormone release.
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PMID:Pancreatic hormones are expressed on the surfaces of human and rat islet cells through exocytotic sites. 266 99

Statistical analyses of DNA sequences of the preproglucagon genes from bovine, human, hamster, and anglerfish suggest that a gene duplication creating two anglerfish genes (AF I and II) occurred about 160 Myr ago, long after the separation of fish and mammals. The analyses further suggest that the internal duplication producing the glucagon and glucagon-like peptide II (GLP-II) regions occurred about 1.2 billion years ago, which would indicate that the GLP-II region was present in the ancestral anglerfish sequence but was silenced or deleted before the gene duplication separating AF I and II. The glucagon-like peptide I (GLP-I) was derived from a duplication of the ancestral glucagon region about 800 Myr ago. The rate of synonymous substitution in these genes is approximately 4.3 x 10(-9) substitutions per year per synonymous site. The rate of nonsynonymous substitution in the signal peptide region is about 1.1 x 10(-9) substitutions per year per nonsynonymous site, a high rate comparable to that in the C-peptide region of preproinsulin. The rate of nonsynonymous substitution in the glicentin-related pancreatic polypeptide (GRPP) region is 0.63 x 10(-9) for the comparisons between mammalian species and 1.8 x 10(-9) for the comparisons between fish and mammals; the moderate rate in mammals suggests a physiological role for GRPP. The glucagon region is extremely conservative; no nonsynonymous substitution is observed in the mammalian genes, and a nonsynonymous rate of 0.18 x 10(-9) was obtained from the comparisons between fish and mammals. In the GLP-I region, the rate of nonsynonymous substitution was estimated to be 0.08 x 10(-9) for the comparisons between mammalian species and 0.30 x 10(-9) for the comparisons between fish and mammals. In the GLP-II region, the rate was estimated to be 0.25 x 10(-9) for the comparisons between mammalian species. Thus, GLP-I and II are also very conservative, which suggests an important physiological role for these peptides.
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PMID:Evolution of glucagon genes. 659 70

The hormone insulin remains the cornerstone of diabetic therapy since it is required for almost all cases of Type 1 and many cases of Type 2 diabetes. Since the discovery of insulin in 1921, much has been learned about its chemistry, structure and action as well as its production in the beta cell. Insulin is formed through a series of precursors, beginning with preproinsulin, the protein encoded in the insulin gene. These precursors direct the prohormone into the secretory pathway and ultimately into the secretory granules where it is converted into insulin and C-peptide. These products are stored and secreted together in a highly regulated manner in response to glucose and other stimuli. This review focuses on the recently discovered prohormone convertases, PC2 and PC3 (PC1), the enzymes responsible for the endoproteolytic processing of proinsulin to insulin and C-peptide in the beta cell as well as for the selective processing of proglucagon to glucagon in the alpha cell or GLP1 in intestinal L-cells. PC2 and PC3 are calcium-dependent serine proteases related to the bacterial enzyme subtilisin. They cleave selectively at Lys-Arg or Arg-Arg sites in precursors, generating products with C-terminal basic residues that are then removed by carboxypeptidase E, an exopeptidase. All 3 enzymes are expressed mainly in secretory granules of neuroendocrine cells throughout the body and in the brain. Inherited defects affecting the prohormone-processing enzymes have recently been found in association with unusual syndromes of obesity and other metabolic disorders.
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PMID:The role of prohormone convertases in insulin biosynthesis: evidence for inherited defects in their action in man and experimental animals. 879 89

The distribution and identity of the various endocrine cell types were examined in the pancreas, stomach, and anterior intestine of the phylogenetically ancient actinopterygian, the gar (Lepisosteus osseus L.), using immunohistochemistry. Antisera used were directed against several insulins (INSs) and somatostatins (SSTs), and members of the pancreatic polypeptide (PP, aPY, NPY) and glucagon (GLUC, GLP) families. In the gar pancreas the most pronounced aggregation of islet tissue is among the exocrine acini near the union of extrahepatic common bile duct with the gastrointestinal junction. Four immunoreactive cell types were identified within well-defined islets (A, B, D, and F cells) but immunoreactive cell types were also seen isolated among the exocrine acini. Centrally located B cells were immunoreactive with mammalian and lamprey INS antisera whereas the widely dispersed D cells immunostained with anti-SST-14, -25, and -34. SST was also localized in the epithelium of the pancreatic ducts. There was a colocalization of immunoreactivity for each member of the PP and GLU families at the periphery of each islet to identify F and A cells, respectively. However, colocalization of peptides from both families is suspected for at least some cells. Although the gastric and intestinal mucosae showed a similar pattern of immunoreactivity to GLP and not GLU, they had contrasting immunoreactivity with the two INS antisera. SST immunoreactivity was restricted to the stomach, whereas three of the four PP-family peptides were only immunoreactive in the intestine. Immunoreactivity to the various antisera used in the study imply that there may be an organ-specific processing of preproinsulin, that the gar SST profile may be more similar to agnathan and bowfin rather than either elasmobranch or teleost SSTs, and that only the GLP portion of the preproglucagon gene is expressed in the gastrointestinal mucosa. Our results are consistent with other recent endocrine studies showing that the gar is a widely distinct actinopterygian.
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PMID:An immunohistochemical study of the endocrine cells within the pancreas, intestine, and stomach of the gar (Lepisosteus osseus L.) 912 60

It has recently been reported that human adult beta-cells proliferate during culture on an extracellular matrix prepared from rat 804G cells and in the presence of hepatocyte growth factor (HGF). The present study compares the mitogenic effect of this condition on human beta-cells and on neighboring non-endocrine duct cells. Islet cell-enriched fractions were prepared from adult human organ donors and cultured in suspension or on 804G matrix, with or without HGF. The combination of 804G matrix and HGF increased the number of 5-bromo-2'-deoxyuridine-positive (BrdU+) cells within 48 h reaching a maximum after 4 days. In sections, virtually all BrdU+ cells were negative for insulin or glucagon and for preproinsulin mRNA but expressed the ductal cell markers cytokeratin 19 and 7, carbonic anhydrase-II, and carbohydrate antigen 19-9. After 4 days of culture, the cytokeratin 19+ ductal cells exhibited a BrdU-labeling index of 30% (P < 0.01 vs. 2% without HGF and matrix), whereas <0.1% of insulin-positive and <1% of glucagon-positive cells were labeled. Formation of bilayers with ductal cells covering the endocrine cells may cause erroneous interpretation on double positivity in unsectioned tissue. It is concluded that culture of human islet cell preparations with HGF and 804G matrix stimulates the proliferation of the duct cells but not of the underlying beta-cells.
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PMID:Culture of adult human islet preparations with hepatocyte growth factor and 804G matrix is mitogenic for duct cells but not for beta-cells. 942 88

Leptin controls feeding behavior and insulin secretion from pancreatic beta-cells. Insulin stimulates the production of leptin, thereby establishing an adipoinsular axis. Earlier we identified leptin receptors on pancreatic beta-cells and showed leptin-mediated inhibition of insulin secretion by activation of ATP-sensitive potassium channels. Here we examine transcriptional effects of leptin on the promoter of the rat insulin I gene in rodent beta-cells. A fall in levels of preproinsulin mRNA is detected in vivo in islets of ob/ob mice 24 h after a single injection of leptin, in isolated ob/ob islets treated with leptin in vitro and in the beta-cell line INS-1 on leptin exposure when preproinsulin mRNA expression is stimulated by 25 mM glucose or 10 nM glucagon-like peptide 1. Under these conditions, transcriptional activity of -410 bp of the rat insulin I promoter is inhibited by leptin, whereas transactivation of a 5'-deleted promoter (-307 bp) is not. The -307 sequence contains the known glucose-responsive control elements (E2:A3/4). Constitutive activation of ATP-sensitive potassium channels by diazoxide does not alter leptin inhibition of preproinsulin mRNA levels. Distinct protein-DNA complexes appear on the rat insulin I promoter sequences located between -307 and -410 with nuclear extracts from ob/ob islets in response to leptin, including a signal transducer and activator of transcription (STAT)5b binding site. These results indicate that leptin inhibits transcription of the preproinsulin gene by altering transcription factor binding to sequences upstream from the elements (307 bp) that confer glucose responsivity to the rat insulin I gene promoter. Thus leptin exerts inhibitory effects on both insulin secretion and insulin gene expression in pancreatic beta-cells, but by different cellular mechanisms.
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PMID:Leptin inhibits insulin gene transcription and reverses hyperinsulinemia in leptin-deficient ob/ob mice. 989 92

Glucagon and other pancreatic peptides are made in the gut, but there is little evidence for the formation of insulin. The demonstration of insulin receptors on the mucosa of gut epithelium suggests that there may be an autocrine or paracrine role for insulin made in the gut. Such insulin may control cell division, the secretion of other peptides from the same or neighboring cells, or motility and absorption. To search for the ability of the gut to make insulin, sections of freshly excised segments of rat gut were treated with an antiserum against porcine insulin. Intracellular immunoreactivity appeared in glandular cells in the stomach and colon but not in the small intestine. Preproinsulin mRNA was detected in similar cells in the stomach and colon by in situ hybridization, using specific oligonucleotide probes. Rat preproinsulin 1 and 2 mRNAs were transcribed by reverse transcriptase to the corresponding cDNAs, which were then amplified by polymerase chain reaction, utilizing specific oligonucleotide primers. Restriction analysis confirmed the identity of rat preproinsulin 1 and 2 mRNA in the colon and rat preproinsulin 1 mRNA in the stomach. Neither was found in the small intestine. Base sequences of the cDNAs were identical to the coding regions of pancreatic rat preproinsulin 1 and 2 messages. These observations are strong evidence for the synthesis of preproinsulin in the gut of the rat.
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PMID:Evidence for biosynthesis of preproinsulin in gut of rat. 1121 48

Prohormone convertase 2 (PC2) plays an essential role in the processing of proglucagon to mature active glucagon in pancreatic alpha-cells (J Biol Chem 276:27197-27202, 2001). Mice lacking PC2 demonstrate multiple defects, including chronic mild hypoglycemia and dramatic hyperplasia of the pancreatic alpha-cells. To define the contribution of mature glucagon deficiency to the hypoglycemia and alpha-cell hyperplasia, we have attempted to correct the defects by delivery of exogenous glucagon by micro-osmotic pumps. Intraperitoneal delivery of 0.5 microg glucagon/h in PC2(-/-) mice resulted in the normalization of blood glucose concentrations. Islet remodeling through the loss of hyperplastic alpha-cells was evident by day 11 after pump implantation; by 25 days postimplantation, PC2(-/-) islets were indistinguishable from wild-type islets. These rapid changes were brought about by induction of apoptosis in the alpha-cell population. Morphological normalization of islets was also accompanied by marked downregulation of endogenous preproglucagon gene expression, but with little or no change in the level of preproinsulin gene expression. Exogenous glucagon delivery also normalized hepatic expression of the gluconeogenic enzyme PEPCK. These results demonstrate that the lack of mature glucagon in PC2(-/-) mice is responsible for the aberrant blood glucose levels, islet morphology, and gene expression, and they confirm the role of glucagon as a tonic insulin antagonist in regulating glycemia.
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PMID:Glucagon replacement via micro-osmotic pump corrects hypoglycemia and alpha-cell hyperplasia in prohormone convertase 2 knockout mice. 1181 47

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