Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.11.13 (protein kinase C)
 49,245 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A highly differentiated rat glucose-responsive insulin producing cell line INS-1 expresses high levels of insulin-like growth factor-II (IGF-II). Basal levels of IGF-II gene mRNA were expressed in cells cultured at 1-6 mmol/l glucose. At glucose concentrations of 10-20 mmol/l, IGF-II mRNA was increased more than threefold after 44 h of incubation. Levels of IGF-II mRNA in INS-1 cells incubated at 5.6 and 20 mmol/l glucose in the presence of 4 micrograms/ml actinomycin D are comparable and are not reduced during 20 h of treatment, indicating the high stability of IGF-II mRNA in this cell line. From the three rat IGF-II promoters, promoter 3 is by far the most active in INS-1 cells. The IGF-II promoter 3 activity and IGF-II mRNA production at high glucose concentrations increased threefold over their respective levels at low glucose concentration, suggesting that the glucose-induced IGF-II gene expression in this beta-cell line might be transcriptionally controlled. The up-regulation of IGF-II mRNA by glucose was not due to the increased intracellular cyclic AMP levels or protein kinase C activation. A protein kinase C activator had no effect on IGF-II gene expression, and an adenylate cyclase activator (forskolin), suppressed the stimulatory effects of glucose on the IGF-II mRNA. Under all the experimental conditions examined, the IGF-II and insulin genes were differentially regulated in INS-1 cells. The IGF-II gene expression and DNA synthesis, however, were regulated in parallel, suggesting that these two cellular activities are closely associated.
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PMID:Insulin-like growth factor-II gene expression in a rat insulin-producing beta-cell line (INS-1) is regulated by glucose. 758 78

The signaling pathways whereby glucose and hormonal secretagogues regulate insulin-secretory function, gene transcription, and proliferation of pancreatic beta-cells are not well defined. We show that in the glucose-responsive beta-cell line INS-1, major secretagogue-stimulated signaling pathways converge to activate 44-kDa mitogen-activated protein (MAP) kinase. Thus, glucose-induced insulin secretion was found to be associated with a small stimulatory effect on 44-kDa MAP kinase, which was synergistically enhanced by increased levels of intracellular cAMP and by the hormonal secretagogues glucagon-like peptide-1 and pituitary adenylate cyclase-activating polypeptide. Activation of 44-kDa MAP kinase by glucose was dependent on Ca2+ influx and may in part be mediated by MEK-1, a MAP kinase kinase. Stimulation of Ca2+ influx by KCl was in itself sufficient to activate 44-kDa MAP kinase and MEK-1. Phorbol ester, an activator of protein kinase C, stimulated 44-kDa MAP kinase by both Ca(2+)-dependent and -independent pathways. Nerve growth factor, independently of changes in cytosolic Ca2+, efficiently stimulated 44-kDa MAP kinase without causing insulin release, indicating that activation of this kinase is not sufficient for secretion. In the presence of glucose, however, nerve growth factor potentiated insulin secretion. In INS-1 cells, activation of 44-kDa MAP kinase was partially correlated with the induction of early response genes junB, nur77, and zif268 but not with stimulation of DNA synthesis. Our findings suggest a role of 44-kDa MAP kinase in mediating some of the pleiotropic actions of secretagogues on the pancreatic beta-cell.
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PMID:Glucose, other secretagogues, and nerve growth factor stimulate mitogen-activated protein kinase in the insulin-secreting beta-cell line, INS-1. 771 82

Tyrosine kinases are involved in cell signalling of growth factors such as insulin and insulin-like growth factor (IGF-I) and others. Insulin and IGF-I receptors which possibly feedback on insulin release are established in insulin-secreting cells. The role of tyrosine kinase in insulin secretion is controversial. Both the tyrosine kinase inhibitors tyrphostin 25 (TYR) and genistein (GEN), but not its structurally similar albeit biologically inactive analogue daidzein, increase insulin release at 16.7 mM glucose in INS-1 cells, an insulin secreting cell line. Tyrosine kinase activity is inhibited by GEN, but not diadzein. The inhibitory effects of either insulin or IGF-I on insulin release are abolished by 10(-4) M GEN but not by daidzein indicating an involvement of tyrosine kinase in the inhibitory effect of both insulin and IGF-I on insulin release. Since GEN was argued not to be specific for tyrosine kinase, several second messengers were investigated. cAMP is not influenced. The insulinotropic effect of acutely administered TPA is not influenced by GEN while in protein kinase C (PKC)-downregulated cells the insulinotropic effect of GEN is preserved: both indicate no involvement of PKC in GEN effect. Since pertussis toxin (PT) pretreatment has no effect on the inhibitory effects of IGF-I on insulin release, a PT-sensitive G-protein is not likely to be involved. The data indicate that tyrosine kinase is involved in the inhibitory effects of insulin and IGF on insulin release in INS-1 cells, possibly mediating the negative feedback effect.
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PMID:Role of tyrosine kinase in insulin release in an insulin secreting cell line (INS-1). 856 11

Prenylcysteine carboxymethyltransferase, an enzyme involved in the post-translational modification of many signalling proteins, was characterized in insulin-secreting INS-1 cells and normal rat pancreatic islets. The activity of this enzyme was monitored by the methylation of an artificial substrate (a prenylated cysteine analogue) with S-adenosy1[methyl-3H]methionine as methyl donor. More than 95% of the methyltransferase activity was associated with the membranes, and high-salt treatment only partially extracted the enzyme from the membranes. The highest specific activity was in the insulin-granule-enriched 25000 g pellet obtained by differential centrifugation. However, a highly purified insulin-enriched fraction obtained by density centrifugation in Percoll did not exhibit methyltransferase activity. The analyses of marker enzymes for cellular organelles revealed that the methyltransferase was co-localized, with the plasma membrane and probably the endoplasmic reticulum, but not with the mitochondria or lysosomes. Guanosine 5'-[gamma-thio]-triphosphate failed to increase methyltransferase activity directly, although it promotes the methylation of GTP-binding proteins. Mastoparan, Ca2+, cAMP and the protein kinase C activator phorbol 12-myristate 13-acetate did not alter enzyme activity. In addition, methyltransferase activity was not stably modified by stimulation of intact cells using glucose or other agents. However, the carboxymethylation of certain low-molecular-mass G-proteins is increased by glucose stimulation; conversely, treatment of cells with N-acetyl-S-trans,trans-farnesyl-L-cysteine inhibited glucose- and forskolin-induced insulin secretion. These results suggest that the membrane-associated prenylcysteine carboxymethyltransferase may be constitutively active and that the methylation of target proteins in vivo is regulated by the access of these proteins to the methyltransferase, as well as by their active (GTP-liganded) configuration.
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PMID:Characterization of prenylcysteine methyltransferase in insulin-secreting cells. 864 28

Mitogen-activated protein (MAP)/ERK kinase (MEK)1 and MEK2 are the upstream activators of the MAP kinases, ERK1 and ERK2. MEK1 and MEK2 are approximately 85% identical in sequence but have unique inserts in their C-terminal domains. MEK isoform-specific antibodies were used to examine expression and regulation of each enzyme. MEK1 and MEK2 were expressed in approximately equal amounts in several cell lines; in some, MEK1 was present in slight excess. Activation of tyrosine kinase-containing receptors, heterotrimeric G proteins, and protein kinase C enhanced the activities of both MEK isoforms in 293 and PC12 cells. AIF4-stimulated both MEK1 and MEK2 in PC12 cells expressing a dominant interfering Ras mutant that prevents nerve growth factor-dependent activation of the cascade. Carbachol also stimulated the pathway in these cells. Thus, in addition to their ability to activate Ras/Raf and the downstream ERK pathway, heterotrimeric G proteins also appear to trigger a Ras-independent mechanism to regulate this kinase cascade. In U373, Chinese hamster ovary (CHO), and INS-1 cells, MEK1 was activated by regulators of ERKs, while MEK2 was not. These data suggest that, like the MAP kinases ERK1 and ERK2, in some cell settings the two similar MEK isoforms are differentially regulated.
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PMID:Differential regulation of mitogen-activated protein/ERK kinase (MEK)1 and MEK2 and activation by a Ras-independent mechanism. 932 44

Despite many triumphs, a significant limitation of the usefulness of many of the available B-cell lines for the study of insulin secretion are either inappropriate or lack of responsiveness to glucose. Commonly employed cell lines generated prior to the 1990s following X-ray irradiation (RINm5F cells) or simian virus 40 B-cell transformation (HIT-T15 cells and BTC) fall into this category. More recent success has been achieved with the generation of INS-1 cells and MIN6 cells, but the production of these cell lines owes much to good fortune, dedication and hard work. In the present era, molecular biology techniques provide the opportunity to engineer novel pancreatic B-cell lines which possess many attributes of normal insulin-secreting cells. This review describes the electrofusion of normal NEDH rat pancreatic B-cells with immortal RINm5F cells to create three new glucose-responsive clonal insulin-secreting cells, designated BRIN-BG5, BRIN-BG7 and BRIN-BD11. These cell lines exhibit up to four-fold insulin-secretory responses to depolarization with 25 mmol/l K+, 7.68 mmol/l Ca2+, 10 mmol/l L-alanine, and activation of protein kinase C or adenylate cyclase with 10 nmol/l phorbol- 12-myristate-13-acetate or 25 micromol/l forskolin, respectively. The maximal insulin-secretory response of both BRIN-BG5 and BRIN-BG7 cells to glucose occurred at 8.4 mmol/l (1.9- and 1.8-fold increases, respectively). In contrast, 4.2-16.7 mmol/l glucose evoked a stepwise 2- to 3-fold of insulin release from BRIN-BD11 cells. The superior glucose responsiveness of BRIN-BD11 cells compared with BRIN-BG5 or BRIN-BG7 cells was associated with increased expression of GLUT-2 and a greater contribution of glucokinase to total glucose phosphorylating enzyme activity. Furthermore, BRIN-BD11 cells also showed appropriate responses to a diverse range of modulators of pancreatic B-cell function, including amino acids, neurotransmitters and sulphonylurea drugs. Collectively these observations indicate that genetic modification of insulin-secreting cells by electrofusion (or transfection with cDNA) offers a new avenue for generation of useful clonal glucose-responsive pancreatic B-cell lines for studies of insulin secretion and transplantation in insulin-dependent diabetes mellitus.
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PMID:Engineering cultured insulin-secreting pancreatic B-cell lines. 993 Sep 71

The effect of leptin on insulin secretion is controversial due to conflicting results in the literature. In the present study, we incubated insulin-producing rat insulinoma INS-1 cells for 60 min and examined the effects of recombinant murine leptin (20 nmol/l). We found that leptin (0.1-100 nmol/l) did not affect the insulin response to glucose (1-20 mmol/l). However, when cells were incubated with agents that increase the intracellular content of cAMP, i.e., glucagon-like peptide-1 (100 nmol/l), pituitary adenylate cyclase activating polypeptide (100 nmol/l), forskolin (2.5 micromol/l), dibutyryl-cAMP (1 mmol/l), or 3-isobutyl-1-methylxanthine (100 micromol/l), leptin significantly reduced insulin secretion (by 34-58%, P < 0.05-0.001). In contrast, when insulin secretion was stimulated by the cholinergic agonist carbachol (100 micromol/l) or the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (1 micromol/l), both of which activate protein kinase C, leptin was without effect. We conclude that leptin inhibits insulin secretion from INS-1 cells under conditions in which intracellular cAMP is increased. This suggests that the cAMP-protein kinase A signal transduction pathway is a target for leptin to inhibit insulin secretion in insulin-producing cells.
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PMID:Leptin inhibits insulin secretion induced by cellular cAMP in a pancreatic B cell line (INS-1 cells). 1051 32

Gastrin-releasing peptide (GRP) receptors are present in pancreatic islets, though their regulation is unknown except for homologous desensitization. The modulation of binding of GRP to mouse pancreatic islets and INS-1 cells was studied. At 60 min (steady-state), total binding of [(125)I-Tyr(15)] GRP was 1.62 per cent of total radioactivity per 50 islets; non-specific binding (presence of 1 mM unlabelled GRP(1-27)) was 0.05 to 0.61 per cent of total radioactivity. A preincubation with 1000 nM cholecystokinin (CCK(8)) or with 1000 nM glucose-dependent insulinotropic peptide (GIP) augmented the number of GRP binding sites but not their affinity. [(125)I-Tyr(15)]GRP binding to INS-1 cells was saturable (90 min) and specific with respect to compounds that are not chemically related to GRP (e.g. calcitonin gene-regulated peptide-CGRP and atrial natriuretic peptide-ANP). Displacement studies showed one binding site with a K(d) of 0.39 nM and a B(max) of 13.2 fmoles mg(-1) protein. When the cells were pretreated for 24 h with 10 nM GIP or CCK(8), only GIP but not CCK(8) increased the B(max) of the GRP binding site. The affinity (K(d)) was not changed by either compound. This effect of GIP pretreatment was not affected by downregulating PKC by TPA (phorbol ester; long-term pretreatment). These data indicate that: (1) specific binding sites for GRP are present in mouse pancreatic islets and INS-1 cells; (2) the GRP binding is upregulated by GIP in both islets and INS-1 cells and additionally by CCK(8 ), albeit only in islets; and (3) PKC does not seem to be involved in the up-regulation process. Thus a positive interplay between both the incretins GIP and CCK(8) and the neurotransmitter GRP is obvious.
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PMID:Modulation of gastrin-releasing peptide (GRP) receptors in insulin secreting cells. 1058 10

IA-2, a member of the protein tyrosine phosphatase family, represents a major target autoantigen in type 1 diabetes. To study the regulation of IA-2 gene expression, we used INS-1 insulinoma cells to analyze beta-cell signal transduction pathways as well as the effect of metabolic and hormonal factors involved in the regulation of the insulin secretory pathway. Quantitative competitive reverse transcriptase-polymerase chain reaction revealed that an increase of cellular cAMP mediated by forskolin (10 micromol/l, 24 h) or 3-isobutyl-1-methylxanthine (100 micromol/l, 24 h) induced maximal stimulation of IA-2 mRNA levels (451 +/- 85 and 338 +/- 86% compared with basal conditions; P < 0.001). In contrast, activation of protein kinase C (PKC) by short-term treatment with phorbol 12-myristate 13-acetate (PMA) (1 micromol/l, 6 h) did not alter IA-2 expression, whereas depletion of PKC by prolonged culturing (24 h) exerted a significant inhibition (57 +/- 24%; P < 0.05). cAMP-dependent upregulation was confirmed by the findings that glucagon (10 micromol/l, 24-48 h) increased levels of IA-2 mRNA (190 +/- 35%; P < 0.05), whereas short-term incubation with high glucose concentration showed no effect. However, prolonged incubation in high glucose (21 mmol/l) induced a time- and dose-dependent increase of IA-2 mRNA expression, reaching maximal values after 144 h (285 +/- 68%; P < 0.05). These studies demonstrate that stimuli of insulin secretion that operate by activation of adenylate cyclase generating cAMP significantly increase IA-2 gene expression. In contrast, activation of PKC by high glucose concentration or PMA exerted no effect, suggesting that IA-2 gene expression is not simply coupled to insulin secretion, but may be involved in the fine regulation of beta-cell function. These findings may be important to clarify the function of IA-2 in beta-cells and elucidate mechanisms involved in the induction of autoimmunity to IA-2.
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PMID:Regulation of the diabetes-associated autoantigen IA-2 in INS-1 pancreatic beta-cells. 1090 70

Exposure of pancreatic islets to cytokines such as interleukin (IL)-1beta induces a variety of proinflammatory genes including type II nitric-oxide synthase (iNOS) which produces nitric oxide (NO). NO is thought to be a major cause of islet beta-cell dysfunction and apoptotic beta-cell death, which results in type I diabetes. Since protein kinase C (PKC) mediates some of the actions of cytokines in other cell types, our aim was to assess the role of PKC in IL-1beta-induced iNOS expression in pancreatic beta-cells. PKCdelta, but not PKCalpha, was specifically activated in the rat INS-1 beta-cell line by IL-1beta as assessed by membrane translocation. Moreover, iNOS expression and NO production were significantly attenuated by the PKCdelta specific inhibitor rottlerin and overexpression of a PKCdelta kinase-dead mutant protein. Conversely, overexpression of PKCdelta wild type protein significantly potentiated this response. These results were confirmed at the mRNA level by reverse transcriptase-polymerase chain reaction. However, a role at the level of transcriptional regulation appeared unlikely, since PKCdelta was not required for the activation of NF-kappaB, activating protein 1, and activating transcription factor 2 signaling pathways in response to IL-1beta. There was, however, a significant increase in iNOS mRNA stability mediated by PKCdelta wild type, while PKCdelta kinase-dead acted reciprocally, reducing iNOS mRNA stability. The results indicate that, in addition to transcriptional activation, mRNA stabilization is a key component of the mechanism by which IL-1beta stimulates iNOS expression in beta-cells and that PKCdelta plays an essential role in this process. PKCdelta activation may therefore have significant consequences with regard to cellular function and viability when beta-cells are exposed to IL-1beta and potentially other cytokines.
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PMID:Protein kinase Cdelta activation by interleukin-1beta stabilizes inducible nitric-oxide synthase mRNA in pancreatic beta-cells. 1108 60


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