UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Although a dysfunction of the calcium metabolism occurs in diabetes mellitus, alterations of Ca(2+) uptake induced by angiotensin II (ANG II) in renal proximal tubular cells (PTCs) grown in high-glucose medium are not fully elucidated. Thus, we examined whether high glucose concentrations can induce an alteration of the ANG II effect on the Ca(2+) uptake and its action mechanism in primary cultured renal PTCs. PTCs were exposed to different glucose concentrations (5-100 mM) and time intervals (0-48 h). There was a sustained increase of Ca(2+) uptake at glucose concentrations >15 mM. Thus, we selected 25 mM glucose and incubation for 48 h to maintain a hyperglycemic condition in vitro, unlike short-time regulatin. ANG II significantly inhibited the Ca(2+) uptake in a dose-dependent manner in a 5-mM glucose medium. In addition, downregulation of ANG II receptors appeared in a glucose dose dependent manner. However, PTCs treated with 25 mM glucose for 48 h, not 12 h, did not exhibit the inhibitory effect of ANG II (10(-7) M) on Ca(2+) uptake, although the inhibitory effect of ANG II on Ca(2+) uptake occurred in the presence of 25 mM mannitol or L-glucose. Staurosporine, bisindolylmaleimide I (protein kinase C, PKC, inhibitors), 12-o-tetradecanoylphorbol 13-acetate pretreatment, SQ 22536 (an adenylate cyclase inhibitor), and myristoylated protein kinase A inhibitor amide 14-22 (a protein kinase A inhibitor) blocked the 25-mM-glucose-induced alteration of ANG II effect on Ca(2+) uptake. These results suggest that both PKC and cyclic adenosine monophosphate (cAMP) pathways are involved in the high-glucose-induced alteration of ANG II effect on Ca(2+) uptake. Indeed, 25 mM glucose increased PKC activity and cAMP contents. In conclusion, a high glucose concentration altered ANG II induced inhibition of Ca(2+) uptake via PKC and cAMP pathways in the PTCs.
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PMID:High glucose levels alter angiotensin II-induced Ca(2+) uptake via PKC and cAMP pathways in renal proximal tubular cells. 1143 39

Protein kinase C (PKC) is a family of multifunctional isoenzymes, activated by diacylglycerols (DAGs), which play a central role in signal transduction and intracellular crosstalk by phosphorylating at serine/threonine residues an array of substrates, including cell-surface receptors, enzymes, contractile proteins, transcription factors and other kinases. Individual isozymes vary in their pattern of tissue and subcellular distribution, function and Ca2+/phospholipid cofactor requirements, and in diabetes there is widespread activation of the DAG-PKC pathway in metabolic, cardiovascular and renal tissues. In liver, muscle and adipose tissue, PKC isozymes have been implicated both as mediators and inhibitors of insulin action. Activation of DAG-sensitive PKC isoforms, such as PKC-theta and PKC-epsilon, down-regulates insulin receptor signalling and could be an important biochemical mechanism linking dysregulated lipid metabolism and insulin resistance in muscle. On the other hand, atypical PKC isozymes, such as PKC-zeta and PKC-lambda, have been identified as downstream targets of PI-3-kinase involved in insulin-stimulated glucose uptake, especially in adipocytes. Glucose-induced de novo synthesis of (palmitate-rich) DAG and sustained isozyme-selective PKC activation (especially but not exclusively PKC-beta) has been strongly implicated in the pathogenesis of diabetic microangiopathy and macroangiopathy through a host of undesirable effects on endothelial function, VSM contractility and growth, angiogenesis, gene transcription (in part by MAP-kinase activation) and vascular permeability. Interventions that increase DAG metabolism (e. g. vitamin E) and/or inhibit PKC isozymes (e. g. the beta-selective inhibitor LY333531) ameliorate the biochemical and functional consequences of DAG-PKC activation in experimental diabetes, for example improving retinal blood flow and albuminuria in parallel with reductions in membrane-associated PKC isozyme activities. Thus, a greater understanding of the functional diversity and pathophysiological regulation of PKC isozymes is likely to have important clinical and therapeutic benefits.
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PMID:Protein kinase C activation: isozyme-specific effects on metabolism and cardiovascular complications in diabetes. 1144 Mar 58

Glucagon-like peptide-1 (GLP-1), an insulinotropic and glucoincretin hormone, is a potentially important therapeutic agent in the treatment of diabetes. We previously provided evidence that GLP-1 induces pancreatic beta-cell growth nonadditively with glucose in a phosphatidylinositol-3 kinase (PI-3K)-dependent manner. In the present study, we investigated the downstream effectors of PI-3K to determine the precise signal transduction pathways that mediate the action of GLP-1 on beta-cell proliferation. GLP-1 increased extracellular signal-related kinase 1/2, p38 mitogen-activated protein kinase (MAPK), and protein kinase B activities nonadditively with glucose in pancreatic beta(INS 832/13) cells. GLP-1 also caused nuclear translocation of the atypical protein kinase C (aPKC) zeta isoform in INS as well as in dissociated normal rat beta-cells as shown by immunolocalization and Western immunoblotting analysis. Tritiated thymidine incorporation measurements showed that the p38 MAPK inhibitor SB203580 suppressed GLP-1-induced beta-cell proliferation. Further investigation was performed using isoform-specific pseudosubstrates of classical (alpha, beta, and gamma) or zeta aPKC isoforms. The PKCzeta pseudosubstrate suppressed the proliferative action of GLP-1, whereas the inhibitor of classical PKC isoforms had no effect. Overexpression of a kinase-dead PKCzeta acting as a dominant negative protein suppressed GLP-1-induced proliferation. In addition, ectopic expression of a constitutively active PKCzeta mutant stimulated tritiated thymidine incorporation to the same extent as GLP-1, and the glucoincretin had no growth-promoting action under this condition. The data indicate that GLP-1-induced activation of PKCzeta is implicated in the beta-cell proliferative signal of the insulinotropic hormone. The results are consistent with a model in which GLP-1-induced PI-3K activation results in PKCzeta translocation to the nucleus, which may play a role in the pleiotropic effects (DNA synthesis, metabolic enzymes, and insulin gene expression) of the glucoincretin.
Diabetes 2001 Oct
PMID:Protein kinase Czeta activation mediates glucagon-like peptide-1-induced pancreatic beta-cell proliferation. 1157 4

The present study was designed to examine the effect of aldose reductase (AR) overexpression on the development of diabetic neuropathy by using mice transgenic for human AR. At 8 weeks of age, transgenic mice (Tg) and non-transgenic littermates (Lm) were made diabetic with streptozotocin. After 8 weeks of untreated diabetes, plasma glucose levels and the reduction in body weight were similar between the groups of diabetic animals. Despite the comparable levels of hyperglycaemia, levels of sorbitol and fructose were significantly greater in the peripheral nerve of diabetic Tg than in diabetic Lm (both P < 0.01). Ouabain sensitive Na(+),K(+)-ATPase activity was similarly decreased in both diabetic Tg and Lm. Protein kinase C activity in the sciatic nerve membrane fraction was unaffected by diabetes in Lm, but was reduced by nearly 40% in the diabetic Tg. Although both groups of diabetic animals exhibited a significant decrease in tibial nerve motor nerve conduction velocity (MNCV), this decrease was significantly more severe (P < 0.01) in diabetic Tg than in diabetic Lm. Consistent with these findings, nerve fibre atrophy was significantly more severe in diabetic Tg than in diabetic Lm (P < 0.01). These findings implicate increased polyol pathway activity in the pathogenesis of diabetic neuropathy. In support of this hypothesis, treating diabetic Tg with an aldose reductase inhibitor (WAY121-509, 4 mg/kg/day) for 8 weeks significantly prevented the accumulation of sorbitol, the decrease in MNCV and the increased myelinated fibre atrophy in diabetic Tg.
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PMID:Neuropathy in diabetic mice overexpressing human aldose reductase and effects of aldose reductase inhibitor. 1170 99

An arteriograph was used to assess myogenic tone, smooth muscle contractility and the influence of endothelial function on mesenteric resistance artery reactivity in insulin-resistant mice (C57BL/KsJ-db/db) and age- and gender-matched wild-type mice. Increases in transmural pressure induced myogenic tone in arteries from both control and db/db mice. At 12 and 16 weeks of age, greater tone developed in diabetic than in control mice. In control, but not in db/db mice, pretreatment of arteries with L-NAME potentiated myogenic tone. Indomethacin and SQ29548 (PGH2/TXA2 receptor antagonist) had no efffect in control, but inhibited myogenic tone in db/db mice. Endothelium-dependent vasodilation induced by acetylcholine and bradykinin, was depressed in db/db mice and potentiated by SQ29548 and LY333531 (protein kinase C(beta) inhibitor). Messenger RNA expression levels for PKC(beta) were over-expressed 2.5-fold in db/db relative to those in control mice. However, expression levels of mRNA for eNOS, PKC(alpha), and PKC(xi) were similar in the db/db and control mice. Collectively, these results suggest that the greater myogenic tone in resistance arteries from diabetic mice may be attributable, to greater amounts of one or more vasoconstricting prostanoids. Our data indicate that in diabetic mice, basal and agonist-stimulated NO releases are depressed and NO-mediated vasorelaxation in these mice may be countered by an endogenous vasoconstrictive prostanoid. This prostanoid-induced vasoconstriction is mediated by a PKC(beta)-dependent mechanism. Therefore, heightened activation of PKC(beta) and release of a vasoconstrictor prostanoid could play a role in endothelial dysfunction associated with type II diabetes.
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PMID:Influence of type II diabetes on arterial tone and endothelial function in murine mesenteric resistance arteries. 1174 Jan 57

Protein kinase C (PKC) activation, enhanced by hyperglycemia, is associated with many tissue abnormalities observed in diabetes. Akt is a serine/threonine kinase that mediates various biological responses induced by insulin. We hypothesized that the negative regulation of Akt in the vasculature by PKC could contribute to insulin resistant states and, may therefore play a role in the pathogenesis of cardiovascular disease. In this study, we specifically looked at the ability of PKC to inhibit Akt activation induced by insulin in cultured rat aortic vascular smooth muscle cells (VSMCs). Activation of Akt was determined by immunoblotting with a phospho-Akt antibody that selectively recognizes Ser473 phosphorylated Akt. A PKC activator, phorbol 12-myristate 13-acetate (PMA), inhibited insulin-dependent Akt phosphorylation. However, PMA did not inhibit platelet-derived growth factor (PDGF)-induced activation of Akt. We further showed that the PKC inhibitor, G06983, blocked the PMA-induced inhibition of Akt phosphorylation by insulin. In addition, we demonstrated that PMA inhibited the insulin-induced tyrosine phosphorylation of insulin receptor substrate-1 (IRS-1). From these data, we conclude that PKC is a potent negative regulator of the insulin signal in the vasculature, which indicate an important role of PKC in the development of insulin resistance in cardiovascular disease.
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PMID:Protein kinase C inhibits insulin-induced Akt activation in vascular smooth muscle cells. 1178 57

We hypothesized that exercise training might prevent diabetes mellitus in Psammomys obesus. Animals were assigned to three groups: high-energy diet (CH), high-energy diet and exercise (EH), and low-energy diet (CL). The EH group ran on a treadmill 5 days/wk, twice a day. After 4 wk, 93% of the CH group were diabetic compared with only 20% of the EH group. There was no difference in weight gain among the groups. Both EH and CH groups were hyperinsulinemic. Epididymal fat (% of body weight) was higher in the CH group than in either the EH and or the CL group. Protein kinase C (PKC)-delta activity and serine phosphorylation were higher in the EH group. No differences were found in tyrosine phosphorylation of the insulin receptor, insulin receptor substrate-1, and phosphatidylinositol 3-kinase among the groups. We demonstrate for the first time that exercise training effectively prevents the progression of diabetes mellitus type 2 in Psammomys obesus. PKC-delta may be involved in the adaptive effects of exercise in skeletal muscles that lead to the prevention of type 2 diabetes mellitus.
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PMID:Physical exercise prevents the development of type 2 diabetes mellitus in Psammomys obesus. 1178 69

Albert Renold strived to gain insight into the abnormalities of human diabetes by defining the pathophysiology of the disease peculiar to a given animal. He investigated the Israeli desert-derived spiny mice (Acomys cahirinus), which became obese on fat-rich seed diet. After a few months hyperplasia and hypertrophy of beta-cells occurred leading to a sudden rupture, insulin loss and ketosis. Spiny mice were low insulin responders, which is probably a characteristic of certain desert animals, protecting against insulin oversecretion when placed on an abundant diet. We have compared the response to overstimulation of several mutant diabetic species and nutritionally induced nonmutant animals when placed on affluent diet. Some endowed with resilient beta-cells sustain long-lasting oversecretion, compensating for the insulin resistance, without lapsing into overt diabetes. Some with labile beta cells exhibit apoptosis and lose their capacity of coping with insulin resistance after a relatively short period. The wide spectrum of response to insulin resistance among different diabetes prone species seems to represent the varying response of human beta cells among the populations. In search for the molecular background of insulin resistance resulting from overnutrition we have studied the Israeli desert gerbil Psammomys obesus (sand rat), which progresses through hyperinsulinemia, followed by hyperglycemia and irreversible beta cell loss. Insulin resistance was found to be the outcome of reduced activation of muscle insulin receptor tyrosine kinase by insulin, in association with diminished GLUT4 protein and DNA content and overexpression of PKC isoenzymes, notably of PKCepsilon. This overexpression and translocation to the membrane was discernible even prior to hyperinsulinemia and may reflect the propensity to diabetes in nondiabetic species and represent a marker for preventive action. By promoting the phosphorylation of serine/threonine residues on certain proteins of the insulin signaling pathway, PKCepsilon exerts a negative feedback on insulin action. PKCepsilon was also found to attenuate the activity of PKB and to promote the degradation of insulin receptor, as determined by co-incubation in HEK 293 cells. PKCepsilon overexpression was related to the rise in muscle diacylglycerol and lipid content, which are prevalent on lascivious nutrition especially if fat-rich. Thus, Psammomys illustrates the probable antecedents of the development of worldwide diabetes epidemic in human populations emerging from food scarcity to nutritional affluence, inappriopriate to their metabolic capacity.
Int J Exp Diabetes Res 2001
PMID:Albert Renold memorial lecture: molecular background of nutritionally induced insulin resistance leading to type 2 diabetes--from animal models to humans. 1179 38

A full biphasic insulin response is the most sensitive index for well-coupled beta-cell signal transduction. While first-phase insulin response is extremely sensitive to potentiating and inhibiting modulations, full expression of second-phase response requires near maximally activated beta-cell fuel metabolism. In the isolated rat pancreas, accelerated calcium entry or activation of protein kinase (PK)-A or PKC result in no insulin response in the absence of fuel metabolism. At submaximal levels of beta-cell fuel secretagogue, arginine (which promotes calcium entry) or glucagon (which activates PKA) produces a small first-phase insulin response but minimal or no second-phase response; carbachol (which activates PKC and promotes calcium entry) generates biphasic insulin response in the presence of minimal fuel (3.3 mmol/l glucose). Glucagon produces full biphasic response in the presence of 10.0 mmol/l glucose, whereas arginine requires near-maximal stimulatory glucose (16.7 mmol) to produce full biphasic insulin response. Thus, PKA and PKC signal pathways potentiate primary signals generated by fuel secretagogues to induce full biphasic insulin response, while calcium recruitment alone is insufficient to potentiate primary signals generated at low levels of fuel secretagogue. We suggest that three families of PKs (calmodulin-dependent PK [CaMK], PKA, and PKC) function as distal amplifiers for stimulus-secretion coupling signals originating from fuel metabolism, as well as from incretins acting through membrane receptors, adenylate cyclase, and phospholipase C. Several isoenzymes of PKA and PKC are present in pancreatic beta-cells, but the specific function of most is still undefined. Each PK isoenzyme is activated and subsequently phosphorylates its specific effector protein by binding to a highly specific anchoring protein. Some diabetes-related beta-cell derangements may be linked to abnormal function of one or more PK isoenzymes. Identification and characterization of the specific function of the individual PK isoenzymes may provide the tool to improve the insulin response of the diabetic patient.
Diabetes 2002 Feb
PMID:Beta-cell protein kinases and the dynamics of the insulin response to glucose. 1181 61

A number of novel genes that are up-regulated in diabetic kidneys have been identified. Recently, transforming growth factor-beta (TGF-beta)--driven secreted proteins, i.e., connective tissue growth factor (CTGF) and gremlin, were identified. They are up-regulated in kidneys of diabetic animals and modulate the biology of mesangial cells. CTGF mediates TGF-beta--induced matrix overproduction by the mesangial cells. Gremlin is a putative antagonist of bone morphogenetic protein-2 that blocks mesangial cell proliferation. Thus, gremlin may modulate the biology of mesangium by stimulating mesangial cell proliferation and in turn production of matrix. In addition, transcriptionally regulated kinases, serum glucocorticoid-regulated kinase and munc-13 have been identified. The former stimulates renal tubular Na+ transport and is involved in hyperfiltraion of diabetic kidneys by a Na+ transport feedback mechanism. Munc-13 has been shown to induce apoptosis in hyperglycemic state via diacylglycerol-activated, PKC-independent signaling pathway. Another pathway relevant to diabetic nephropathy is polyol pathway, where glucose is reduced to sorbitol by aldose reductase. Recently, a renal-specific reductase of the aldo-keto reductase family was isolated. It is up-regulated in diabetic mice, and this could serve as a suitable target for gene therapy in renal complications of diabetes. Several mitochondrial genome-encoded genes, such as, cytochrome oxidase and NADH dehydrogenase, are up-regulated in diabetic kidneys. A novel nuclear-encoded mitochondrial gene, i.e., translocase inner mitochondrial membrane 44 (Tim44), is up-regulated in diabetic kidneys, and it may also serve as another target for molecular therapeutic intervention at the core storage energy sites, i.e., mitochondria. In this review, these novel differentially regulated genes that respond to hyperglycemic stress are described, and they may serve as possible targets for gene therapy in the treatment of diabetic nephropathy.
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PMID:Gene expression and identification of gene therapy targets in diabetic nephropathy. 1184 17

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