Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P01275 (glucagon)
 26,492 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The recent discovery of heretofore unknown, multipotential stem cells within the embryonic and adult islets of Langerhans suggests new therapeutic options for the treatment of diabetes mellitus type 1. These cells are characterised by the expression of the neural stem cell marker nestin and by their ability to differentiate ex vivo into pancreatic endocrine, exocrine and hepatic phenotypes with the expression of insulin, glucagon, amylase, cytokeratin-19 as well as liver specific proteins such as alpha-fetoprotein. The insulinotropic hormone glucagon-like peptide-1 enhances the differentiation of these nestin positive islet derived progenitor (NIP) cells into insulin secreting cells by activation of IDX-1, the key transcription factor for the differentiation into a beta-cell.
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PMID:[Pancreatic stem cells--a new therapeutic option for the treatment of type 1 diabetes mellitus?]. 1249 53

The aim of this study was to clarify the pattern of beta cell neogenesis in the alloxan-perfused, beta cells-depleted segment of glucose intolerant mice induced by selective alloxan perfusion. First, duct cells proliferated in the perfused segment, then cells co-expressing multiple islet hormones and transcription factors such as PDX-1, Nkx2.2, Isl1, and Pax6 were observed in duct cells, and newly formed islet-like cell clusters (ICCs) containing beta cells were recognized. In residual beta cell-depleted islets, glucagon or somatostatin and PDX-1 double-positive immature endocrine cells were recognized. Glucagon or somatostatin, insulin and PDX-1 triple-positive cells then appeared and these cells appeared to undergo terminal differentiation into beta cells. In conclusion, we demonstrated at least two different processes of beta cell neogenesis, i.e., formation of new ICCs from ductal epithelium and redifferentiation of residual non-beta islet cells in this model. In addition, transcription factors that appear in the processes of endocrine cell development may also play essential roles during beta cell neogenesis from duct cells.
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PMID:Beta cell neogenesis from ducts and phenotypic conversion of residual islet cells in the adult pancreas of glucose intolerant mice induced by selective alloxan perfusion. 1250 75

In a transgenic mouse model of the neurodegenerative disorder Huntington's disease (HD), age-dependent neurologic defects are accompanied by progressive alterations in glucose tolerance that culminate in the development of diabetes mellitus and insulin deficiency. Pancreatic islets from HD transgenic mice express reduced levels of the pancreatic islet hormones insulin, somatostatin, and glucagon and exhibit intrinsic defects in insulin production. Intranuclear inclusions accumulate with aging in transgenic pancreatic islets, concomitant with the decline in glucose tolerance. HD transgenic mice develop an age-dependent reduction of insulin mRNA expression and diminished expression of key regulators of insulin gene transcription, including the pancreatic homeoprotein PDX-1, E2A proteins, and the coactivators CBP and p300. Disrupted expression of a subset of transcription factors in pancreatic beta cells by a polyglutamine expansion tract in the huntingtin protein selectively impairs insulin gene expression to result in insulin deficiency and diabetes. Selective dysregulation of gene expression in triplet repeat disorders provides a mechanism for pleiotropic cellular dysfunction that restricts the toxicity of ubiquitously expressed proteins to highly specialized subpopulations of cells.
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PMID:Huntington's disease of the endocrine pancreas: insulin deficiency and diabetes mellitus due to impaired insulin gene expression. 1258 50

Ca(2+)/calmodulin-dependent protein kinase II is a member of a broad family of ubiquitously expressed Ca(2+) sensing serine/threonine-kinases. Ca(2+)/calmodulin-dependent protein kinase II is highly expressed in insulin secreting cells and is associated with insulin secretory granules and has been proposed to play an important role in exocytosis or in insulin granule transport to release sites. To elucidate its function the antisense sequence of the major beta-cell subtype, Ca(2+)/calmodulin-dependent protein kinase II delta(2), was stably expressed in INS-1 rat insulinoma cells. This caused a loss of Ca(2+)/calmodulin-dependent protein kinase II delta(2) expression at the mRNA and protein level, while the expression of the 95% homologous Ca(2+)/calmodulin-dependent protein kinase II gamma and of beta-cell specific proteins such as the homeodomain factor pancreatic-duodenal homeobox factor-1 (PDX-1, also referred to as islet/duodenum homeobox-1, IDX-1, insulin promoter factor-1, IPF-1 and somatostatin transactivating factor-1, STF-1), the glucagon-like peptide-1 (GLP-1) receptor and K(ATP)-channels K(IR)6.2/SUR-1 (sulfonylurea receptor-1) was not altered. Unexpectedly, the cells showed a large reduction of insulin gene expression, which was due to reduced insulin gene transcription. Electrophoretic mobility shift assays of PDX-1 binding to the insulin promoter A1 and E2/A3A4 elements showed additional bands indicating alterations of PDX-1 complex formation. Stable over expression of Ca(2+)/calmodulin-dependent protein kinase II delta(2), by contrast, was associated with elevated expression of insulin mRNA. Therefore, we conclude that Ca(2+)/calmodulin-dependent protein kinase II delta(2) links fuel-dependent increases in intracellular Ca(2+) concentrations to transcriptional regulation of genes related to the metabolic control of insulin secretion.
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PMID:Ca2+/calmodulin-dependent protein kinase II delta2 regulates gene expression of insulin in INS-1 rat insulinoma cells. 1260 Aug 4

Young diabetes-prone BioBreeding (BBdp) rats fed a diabetes-promoting, cereal-based, NIH-07 (NIH) diet have decreased islet area compared with rats fed a diabetes-retardant diet at a time when classic insulitis is minimal. This finding raised the possibility that islet homeostasis in BBdp rats may be abnormal. To investigate this possibility further, comparisons were made between BBdp and BB control (BBc) rats fed a diabetes-promoting NIH diet for 22 days after weaning. Pancreatic sections were fixed in Bouin's solution and evaluated using immunohistochemistry and image analysis by staining with antibodies for islet hormones: insulin, glucagon; cell proliferation markers: PCNA, BrdU; markers of islet neogenesis: PDX-1, cytokeratin 20; apoptosis was assessed by morphological changes and TUNEL staining. Body weight of BBdp rats was significantly smaller than BBc rats. Although the total number of islets was higher in BBdp compared with BBc, both islet and beta-cell fraction were similar. BBdp rats had a lower beta-cell mass than BBc rats, although this was not statistically significant. Alpha-cell fraction and beta-cell size were similar. Apoptotic bodies were rare in beta-cells but more frequent in acinar tissue of BBdp rats. When the day-night cycle was reversed to synchronize the apoptotic process, the number of apoptotic bodies in islets and in acinar cells was increased. Apoptotic bodies and BrdU+ or PCNA+ beta-cells were more frequently encountered in islets of BBdp rats. Although the frequency of CK20+ islets in BBdp rats was not different, CK20+ area fraction was smaller in BBdp. The number of extra-islet insulin+ and glucagon+ clusters (<4 cells) was significantly greater in BBdp rats. These data are consistent with an enhanced compensatory or "repair" process in the pancreas of BBdp rats that attempts to maintain islet cell mass by altering homeostasis through increased islet neogenesis.
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PMID:Altered islet homeostasis before classic insulitis in BB rats. 1268 39

To date, the potency of pancreatic and duodenal homeobox gene 1 (PDX-1) in inducing differentiation into insulin-producing cells has been demonstrated in some cells and tissues. In order to carry out efficient screening of somatic tissues and cells that can transdifferentiate into beta-cell-like cells in response to PDX-1, we generated CAG-CAT-PDX1 transgenic mice carrying a transgene cassette composed of the chicken beta-actin gene (CAG) promoter and a floxed stuffer DNA sequence (CAT) linked to PDX-1 cDNA. When the mice were crossed with Alb-Cre mice, which express the Cre recombinase driven by the rat albumin gene promoter, PDX-1 was expressed in more than 50% of hepatocytes and cholangiocytes. The PDX-1 (+) livers expressed a variety of endocrine hormone genes such as insulin, glucagon, somatostatin, and pancreatic polypeptide. In addition, they expressed exocrine genes such as elastase-1 and chymotrypsinogen 1B. However, the mice exhibited marked jaundice due to conjugated hyperbilirubinemia, and the liver tissue displayed abnormal lobe structures and multiple cystic lesions. Thus, the in vivo ectopic expression of PDX-1 in albumin-producing cells was able to initiate but not complete the differentiation of liver cells into pancreatic cells. The conditional PDX-1 transgenic mouse system developed in this study appeared to be useful for efficient screening of PDX-1 responsive somatic tissues and cells.
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PMID:Ectopically expressed PDX-1 in liver initiates endocrine and exocrine pancreas differentiation but causes dysmorphogenesis. 1455 Mar 6

To determine the progenitor nature of centroacinar cells (CACs), we attempted to compare the expression pattern of endocrine cell markers and PDX-1 (pancreatic duodenal homeobox gene 1) in CACs of both the quiescent and the regenerating rat pancreas. In the normal pancreas, most CACs were relatively small cells with sparse cytoplasm and oval or elongated nuclei. In addition, we noticed a distinct population of a small number of large cells with round nuclei in the centroacinar region. By immunohistochemistry, 0.21% and 0.3% of CACs in normal rat pancreas were respectively found positive for glucagon and insulin, being large CACs and designated as GL-CAC and IL-CAC. They also exhibited the mRNA of each hormone by in situ hybridization (ISH). The ISH signal for glucagon but not insulin was also detected in a subset of small CACs (designated GS-CAC). The expression of PDX-1 was also observed in subsets of small and large CACs (PS-CAC and PL-CAC, respectively). After a 90% pancreatectomy, the relative frequency for GS-CACs, but not those for other CACs, was significantly reduced in two days after surgery. On day 7 after surgery, the number of GS-CACs recovered to preoperative levels, whereas GL-CACs, IL-CACs, PS-CAC, and PL-CAC gradually increased to about double in number. From these results, a portion of CACs was suggested to differentiated into endocrine cells. A possible cell lineage is discussed for endocrine neogenesis during pancreatic regeneration.
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PMID:The expression of pancreatic endocrine markers in centroacinar cells of the normal and regenerating rat pancreas: their possible transformation to endocrine cells. 1469 90

Understanding gene expression profiles during early human pancreas development is limited by comparison to studies in rodents. In this study, from the inception of pancreatic formation, embryonic pancreatic epithelial cells, approximately half of which were proliferative, expressed nuclear PDX1 and cytoplasmic CK19. Later, in the fetal pancreas, insulin was the most abundant hormone detected during the first trimester in largely non-proliferative cells. At sequential stages of early fetal development, as the number of insulin-positive cell clusters increased, the detection of CK19 in these cells diminished. PDX1 remained expressed in fetal beta cells. Vascular structures were present within the loose stroma surrounding pancreatic epithelial cells during embryogenesis. At 10 weeks post-conception (w.p.c.), all clusters containing more than ten insulin-positive cells had developed an intimate relationship with these vessels, compared with the remainder of the developing pancreas. At 12-13 w.p.c., human fetal islets, penetrated by vasculature, contained cells independently immunoreactive for insulin, glucagon, somatostatin and pancreatic polypeptide (PP), coincident with the expression of maturity markers prohormone convertase 1/3 (PC1/3), islet amyloid polypeptide, Chromogranin A and, more weakly, GLUT2. These data support the function of fetal beta cells as true endocrine cells by the end of the first trimester of human pregnancy.
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PMID:Beta cell differentiation during early human pancreas development. 1507 63

The pancreatic ductal stem cells are known to differentiate into islets of Langerhans; however, their yield is limited and the islet population is not defined. Therefore, the aims of the present study were to improvise a methodology for obtaining large numbers of islets in vitro and to characterize their morphological and functional status for islet cell banking and transplantation. Pancreatic ductal epithelial cell cultures were set in serum-free medium. Monolayers of epithelial cells in culture gave rise to islet-like clusters within 3-4 weeks. The identity of neoislets was confirmed by dithizone staining and analysis of the gene expression for endocrine markers by reverse transcriptase-polymerase chain reaction (RT-PCR). The islet population obtained was analysed by image analysis and insulin secretion in response to secretagogues. The cellular extracts from neoislets were immunoreactive to anti-insulin antibody and expressed insulin, glucagon, GLUT-2, PDX-1 and Reg-1 genes. The islets generated within 3-4 weeks exhibited a mixed population of large- and small-sized islets with clear cut dichotomy in the pattern of their insulin secretion in response to L-arginine and glucose. These neoislets maintained their structural and functional integrity on cryopreservation and transplantation indicating their suitability for islet cell banking. Thus, the present study describes an improved method for obtaining a constant supply of large numbers of islets from pancreatic ductal stem cell cultures. The newly generated islets undergo functional maturation indicating their suitability for transplantation.
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PMID:Analysis of morphological and functional maturation of neoislets generated in vitro from pancreatic ductal cells and their suitability for islet banking and transplantation. 1522 35

Strategies to differentiate progenitor cells into beta cells in vitro have been considered as an alternative to increase beta cell availability prior to transplantation. It has recently been suggested that nestin-positive cells could be multipotential stem cells capable of expressing endocrine markers upon specific stimulation; however, this issue still remains controversial. Here, we characterized short- and long-term islet cell cultures derived from three different human islet preparations, with respect to expression of nestin and islet cell markers, using confocal microscopy and semi-quantitative RT-PCR. The number of nestin-positive cells was found to be strikingly high in long-term cultures. In addition, a large proportion (49.7%) of these nestin-positive cells, present in long-term culture, are shown to be proliferative, as judged by BrdU incorporation. The proportion of insulin-positive cells was found to be high in short-term (up to 28 days) cultures and declined thereafter, when cells were maintained in the presence of 10% serum, concomitantly with the decrease in insulin and PDX-1 expression. Interestingly, insulin and nestin co-expression was observed as a rare event in a small proportion of cells present in freshly isolated human islets as well as in purified islet cells cultured in vitro for long periods of time. In addition, upon long-term subculturing of nestin-positive cells in 10% serum, we observed reappearance of insulin expression at the mRNA level; when these cultures were shifted to 1% serum for a month, expression of insulin, glucagon and somatostatin was also detected, indicating that manipulating the culture conditions can be used to modulate the nestin-positive cell's fate. Attempts to induce cell differentiation by plating nestin-positive cells onto Matrigel revealed that these cells tend to aggregate to form islet-like clusters, but this is not sufficient to increase insulin expression upon short-term culture. Our data corroborate previous findings indicating that, at least in vitro, nestin-positive cells may undergo the early stages of differentiation to an islet cell phenotype and that long-term cultures of nestin-positive human islet cells may be considered as a potential source of precursor cells to generate fully differentiated/ functional beta cells.
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PMID:Co-localization of nestin and insulin and expression of islet cell markers in long-term human pancreatic nestin-positive cell cultures. 1559 Sep 72


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