Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0011849 (diabetes)
 277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The ob gene encodes a protein that, in mutant form, is associated with obesity and type II diabetes in mice. Sequence analysis has revealed no similarities to other proteins, however, and no clues as to possible functions. The possibility nonetheless remains that ob is functionally or ancestrally related to other proteins, whose sequences are divergent to the point that only a comparison of three-dimensional structures might detect relationship. To explore this possibility, we conduct a 'threading' search of a 3-dimensional structure database, to determine whether the ob protein might adopt a fold similar to any known structure. This search reveals that the ob sequence is compatible, at a significance level of P < 0.05, with structures from the family of helical cytokines that includes interleukin-2 and growth hormone. A structural model of ob based upon these results is physically and biologically plausible and leads to testable predictions, including the prediction that ob may activate the JAK-STAT pathway, via binding to a receptor resembling those of the cytokine family.
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PMID:Threading analysis suggests that the obese gene product may be a helical cytokine. 758 24

New Zealand Obese (NZO) mice exhibit a polygenic syndrome of hyperphagia, obesity, hyperinsulinemia, and hyperglycemia similar to that observed in young diabetes mutant mice on the C57BLKS/J background (C57BLKS/J-Lepr(db)/Lepr(db)). Here we show that in NZO this syndrome is accompanied by a marked elevation of the leptin protein in adipose tissue and serum. The promoter region and the complementary DNA of the ob gene of NZO mice, including its 5'-untranslated region, are identical with the wild-type sequence (C57BL, BALB/c), except that the transcription start is located 5 bp upstream of the reported site. In contrast to C57BLKS/J+/+ and C57BL/6J-Lep(ob)/Lep(ob) mice, NZO mice failed to respond to recombinant leptin (7.2 microg/g) with a reduction of food intake. Leptin receptor messenger RNA as detected by PCR appears as abundant in hypothalamic tissue of NZO mice as in tissue from lean mice. Ten nucleotide polymorphisms are found in the complementary DNA of the leptin receptor, resulting in two conservative substitutions (V541I and V651I) in the extracellular part of the receptor and one nonconservative substitution (T1044I) in the intracellular domain between the presumed Jak and STAT binding boxes. However, these mutations are also present in the related lean New Zealand Black strain (body fat at 9 weeks: New Zealand Black, 6.2 +/- 1.3%; NZO, 17.0 +/- 1.7%). Thus, the polymorphic leptin receptor seems to play only a minor, if any, role in the obesity and hyperleptinemia of the NZO mouse. It is suggested that the main defect in NZO is located distal from the leptin receptor or at the level of leptin transport into the central nervous system.
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PMID:Hyperleptinemia, leptin resistance, and polymorphic leptin receptor in the New Zealand obese mouse. 932 35

Leptin is the product of OB gene. This 16 kDa protein is produced by mature adipocytes and is secreted in plasma. Its plasma levels are strongly correlated with adipose mass in rodents as well as in humans. Leptin inhibits food intake, reduces body weight and stimulates energy expenditure. It has been suggested that leptin could be the link between obesity and diabetes. Recent experiments in rodents have shown that leptin expression in adipocytes is also regulated at short-term by hormones and nutrients. Leptin expression increases after food intake and decreases during fasting and diabetes. Insulin and glucocorticoids increase leptin expression, whereas catecholamines, via beta-adrenergic receptors and cAMP, and long-chain fatty acids (and thiazolidinediones), via PPARy, inhibit leptin expression. Leptin is a cytokine that binds to transmembrane receptors similar to the receptors of cytokine family (type IL-6), and transmit their information inside the cell, after dimerisation. A short-form of leptin receptor (with a cytoplasmic domain of 34 amino residues) has been identified in the choroid plexus. This type of receptor should be used for leptin transport across the blood-brain barrier. Then leptin binds to a long-form of leptin receptor in the hypothalamus (with a cytoplasmic domain of 302 amino residues) and decreases the production of neuropeptide Y, a neuromediator of food intake. The long-form of leptin receptor, transmits its information via the Janus Kinases (JAK) who subsequently phosphorylate transcription factors of the STAT family. Intermediary forms of leptin receptor have been identified in other tissues: liver, heart, skeletal muscles, endocrine pancreas. The role of leptin receptors in these tissues remains obscure, but is of considerable interest. Recent studies have shown that leptin inhibits insulin secretion and have anti-insulin effects on liver and adipose tissue. If these effects are confirmed, leptin could play a role similar to TNF alpha and could participate in the insulin-resistance of obesity and type II diabetes.
Diabetes Metab 1997 Sep
PMID:Is leptin the link between obesity and insulin resistance? 934 38

Regulation of many aspects of cell behaviour occurs through the interaction of cytokines with specific cell surface receptors, resulting in the activation of cytoplasmic signal transduction pathways. Although cellular responses to cytokines are tightly controlled, few molecules have been identified which are able to switch these signals off. The suppressors of cytokine signalling (SOCS) proteins are a new family of negative regulators of cytokine signal transduction. SOCS proteins contain a variable amino-terminal region, a central Src-homology 2 (SH2) domain and a novel conserved carboxy-terminal motif termed the SOCS box. The expression of SOCS proteins is induced by cytokine. Once expressed, SOCS downregulate JAK/STAT pathways and hence the biological response. Recent studies, primarily reliant on overexpression of proteins, indicate that SOCS may be involved in modulating additional pathways, suggesting that they may play a more general role in regulating cellular responses to cytokine. The analysis of knockout mice will clarify the physiological role of SOCS in regulating cytokine responsiveness. Mutations leading to the loss of SOCS activity may give rise to cytokine hyperresponsiveness and may contribute to the development of diseases such as diabetes and cancer. Small molecule effectors which modify SOCS function may potentially be useful therapeutics for the treatment of certain diseases.
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PMID:SOCS: suppressors of cytokine signalling. 978 73

Use of a real-time bedside glucose monitor was analyzed during the course of management of diabetic ketoacidosis (DKA) in children. Simultaneous determinations of blood glucose were obtained, using three methods: bedside glucose meter (One Touch II), laboratory glucose analyzer (YSI 2300 STAT), and a real-time bedside glucose monitor (VIA 1-01G Blood Chemistry monitor). Study patients included seventeen patients < 18 years of age admitted to a Pediatric Intensive Care Unit, with blood samples obtained during treatment of DKA by continuous insulin infusion. Four patients did not complete the study. Three experienced temporary technical problems with the monitor, and four required repeat IV placement. Duration of monitor use ranged between 6 and 47 h (mean 24 +/- 4 h). Blood glucose values ranged between 2.6 and 22.5 mmol/l. Overall correlation of blood glucose values were as follows: 0.965, 0.965, 0.973, VIA 1-01G vs. One Touch II, VIA 1-01G vs. YSI 2300 STAT, and One Touch II vs. YSI 2300 STAT, respectively (all P-values < 0.0001). This real-time bedside glucose monitor is accurate at glucose values < 13.8 mmol/l, and reliable for rapid, repetitive analyses. Results indicate that blood glucose values obtained using this real-time monitor are comparable to those using standard methods of measurement, and that this device is clinically applicable for use in management of children with DKA.
Diabetes Res Clin Pract 1999 Jun
PMID:Evaluation of a real-time blood glucose monitor in children with diabetic ketoacidosis. 1046 40

Interferon-gamma (IFN-gamma) is known to exert deleterious effects on pancreatic beta-cells and is implicated in the development of type 1 (autoimmune) diabetes mellitus. In this study, we investigated signaling mechanisms mediating the effects of IFN-gamma in pancreatic beta-cells using a differentiated rat insulin-secreting cell line, INS-1, with special reference to the activation of transcription factors STAT (signal transducers and activators of transcription)1 and NF-kappaB. Exposure of INS-1 cells to 100 IU/ml IFN-gamma for 24 h resulted in significant inhibition of nutrient-induced insulin secretion associated with impaired metabolism. In combination with tumor necrosis factor-alpha (TNF-alpha) (50 ng/ml), IFN-gamma elicited severe cytotoxicity and induced the expression of the inducible isoform of nitric oxide synthase (iNOS) mRNA. IFN-gamma promoted tyrosine phosphorylation and DNA-binding of STAT1 through Janus kinase (JAK)1 activation without apparent phosphorylation of JAK2. TNF-alpha did not affect STAT1 activation, but stimulated DNA-binding and transcriptional activity of NF-kappaB, both of which were further increased by IFN-gamma. These effects of IFN-gamma and TNF-alpha seem physiologically relevant, because either inhibition of STAT1 by the tyrosine kinase inhibitor herbimycin A or that of NF-kappaB by sulfasalazine resulted in the reduction of iNOS mRNA expression. In conclusion, IFN-gamma activates STAT1 and potentiates TNF-alpha-induced NF-kappaB activation in INS-1 cells, thereby inducing iNOS and cell destruction.
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PMID:Synergistic activation of NF-kappab and inducible isoform of nitric oxide synthase induction by interferon-gamma and tumor necrosis factor-alpha in INS-1 cells. 1082 33

In this report we summarize evidence to support a model for the development of Graves' disease. The model suggests that Graves' disease is initiated by an insult to the thyrocyte in an individual with a normal immune system. The insult, infectious or otherwise, causes double strand DNA or RNA to enter the cytoplasm of the cell. This causes abnormal expression of major histocompatibility (MHC) class I as a dominant feature, but also aberrant expression of MHC class II, as well as changes in genes or gene products needed for the thyrocyte to become an antigen presenting cell (APC). These include increased expression of proteasome processing proteins (LMP2), transporters of antigen peptides (TAP), invariant chain (Ii), HLA-DM, and the co-stimulatory molecule, B7, as well as STAT and NF-kappaB activation. A critical factor in these changes is the loss of normal negative regulation of MHC class I, class II, and thyrotropin receptor (TSHR) gene expression, which is necessary to maintain self-tolerance during the normal changes in gene expression involved in hormonally-increased growth and function of the cell. Self-tolerance to the TSHR is maintained in normals because there is a population of CD8- cells which normally suppresses a population of CD4+ cells that can interact with the TSHR if thyrocytes become APCs. This is a host self-defense mechanism that we hypothesize leads to autoimmune disease in persons, for example, with a specific viral infection, a genetic predisposition, or even, possibly, a TSHR polymorphism. The model is suggested to be important to explain the development of other autoimmune diseases including systemic lupus or diabetes.
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PMID:Graves' disease: a host defense mechanism gone awry. 1112 19

Apoptosis is likely to be the main form of beta-cell death in immune-mediated diabetes mellitus in rodents and possibly in humans. Clarification of the regulation of beta-cell death could indicate novel sites for therapeutic intervention in Type I (insulin-dependent) diabetes mellitus. We review the molecular effectors and signal transduction of immune-mediated beta-cell apoptosis. Data obtained on non-obese diabetic (NOD) mice suggest that macrophages and CD4+ T-cells are the main cellular effectors, whereas CD8+ T-cells are more important initiators of the immune process leading to beta-cell death. Perforin could be the effector molecule utilized by CD8+ T-cell initiation, whereas CD4+ mediated beta-cell destruction is mostly dependent on Fas/FasL and the cytokines IFNgamma and TNF-alpha. The macrophage cytokine IL-1beta in combination with IFN-gamma and TNF-alpha, plays an important role for beta-cell dysfunction and death. Signal transduction by these cytokines involves: (i) binding to specific receptors, (ii) signal transduction by cytosolic kinases (especially the so-called mitogen- and stress-activated protein kinases) and/or phosphatases, (iii) mobilization of diverse transcription factors - with nuclear factor kappaB (NF-kappaB), AP-1 and STAT-1 probably playing key roles for beta-cell apoptosis; (iv) up-regulation or down-regulation of gene transcription. Recent data obtained by microarray and proteomic analysis suggest that the process of beta-cell apoptosis depends on the parallel and/or sequential up-regulation and down-regulation of considerable numbers of genes, which can be grouped in gene modules or patterns according to their functions. A detailed characterization of these "gene modules", and of the signalling pathways and transcription factors regulating them could allow us to understand the ultimate mechanisms leading to beta-cell apoptosis.
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PMID:A choice of death--the signal-transduction of immune-mediated beta-cell apoptosis. 1179 13

Suppressor of cytokine signaling-1 (SOCS-1) is a negative regulator of the Jak-STAT (signal transducer and activator of transcription cytokine) signaling pathway but may also regulate other pathways. At least in vitro, SOCS-1 inhibits the action of multiple cytokines. By studying the effects of SOCS-1 deficiency, we investigated whether SOCS-1 is involved in preventing cytokine-induced death of pancreatic islet cells, a potential mechanism of insulin deficiency in autoimmune diabetes. Tumor necrosis factor (TNF) + interferon-gamma (IFNgamma) was more potent at inducing cell death in SOCS-1-/- islets than in wild type. Individually, these cytokines did not induce cell death. The titration of the two cytokines suggested that this increased cell death was because of hypersensitivity to TNF. Interleukin-1 + IFNgamma induced the same level of cell death in SOCS-1-/- and wild-type islets, suggesting that the sensitivity of islets to IFNgamma or interleukin-1-mediated cytotoxicity is not affected by SOCS-1 deficiency. Additionally, SOCS-1-/- beta cells were responsive to lower concentrations of TNF measured by class I major histocompatibility complex up-regulation. The TNF + IFNgamma damage of islets was mediated by inducible nitric-oxide synthase (iNOS), and increased iNOS expression and nitric oxide production were found in SOCS-1-/- islets following cytokine treatment. A further analysis revealed that SOCS-1 deficiency results in augmented TNF signaling via the p38 mitogen-activated protein kinase pathway but not NFkappaB or c-Jun N-terminal kinase pathways. Increased p38 signaling may be responsible for the increased iNOS expression in SOCS-1-/- islets. Therefore, these findings provide evidence that physiological levels of SOCS-1 negatively regulate TNF signaling.
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PMID:Suppressor of cytokine signaling-1 regulates the sensitivity of pancreatic beta cells to tumor necrosis factor. 1203 39

Ciliary neurotrophic factor (CNTF) is primarily known for its roles as a lesion factor released by the ruptured glial cells that prevent neuronal degeneration. However, CNTF has also been shown to cause weight loss in a variety of rodent models of obesity/type II diabetes, whereas a modified form also causes weight loss in humans. CNTF administration can correct or improve hyperinsulinemia, hyperphagia, and hyperlipidemia associated with these models of obesity. In order to investigate the effects of CNTF on fat cells, we examined the expression of CNTF receptor complex proteins (LIFR, gp130, and CNTFRalpha) during adipocyte differentiation and the effects of CNTF on STAT, Akt, and MAPK activation. We also examined the ability of CNTF to regulate the expression of adipocyte transcription factors and other adipogenic proteins. Our studies clearly demonstrate that the expression of two of the three CNTF receptor complex components, CNTFRalpha and LIFR, decreases during adipocyte differentiation. In contrast, gp130 expression is relatively unaffected by differentiation. In addition, preadipocytes are more sensitive to CNTF treatment than adipocytes, as judged by both STAT 3 and Akt activation. Despite decreased levels of CNTFRalpha expression in fully differentiated 3T3-L1 adipocytes, CNTF treatment of these cells resulted in a time-dependent activation of STAT 3. Chronic treatment of adipocytes resulted in a substantial decrease in fatty-acid synthase and a notable decline in SREBP-1 levels but had no effect on the expression of peroxisome proliferator-activated receptor gamma, acrp30, adipocyte-expressed STAT proteins, or C/EBPalpha. However, CNTF resulted in a significant increase in IRS-1 expression. CNTFRalpha receptor expression was substantially induced in the fat pads of four rodent models of obesity/type II diabetes as compared with lean littermates. Moreover, we demonstrated that CNTF can activate STAT 3 in adipose tissue and skeletal muscle in vivo. In summary, CNTF affects adipocyte gene expression, and the specific receptor for this cytokine is induced in rodent models of obesity/type II diabetes.
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PMID:The regulation and activation of ciliary neurotrophic factor signaling proteins in adipocytes. 1242 52


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