Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:Q8IXL6 (RNS)
 1,091 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The effect of reactive oxygen/nitrogen species (ROS/RNS)(hydrogen peroxide -- H(2)O(2), superoxide anion radical O(2)*- and hydroxyl radical *OH -- the reaction products of hypoxanthine/xanthine oxidase system), nitric oxide (NO* from sodium nitroprusside -- SNP), and peroxynitrite (ONOO(-) from 3-morpholinosydnonimine -- SIN-1) on insulin mitogenic effect was studied in L6 muscle cells after one day pretreatment with/or without antioxidants. ROS/RNS inhibited insulin-induced mitogenicity (DNA synthesis). Insulin (0.1 microM), however, markedly improved mitogenicity in the muscle cells treated with increased concentrations (0.1, 0.5, 1 mM) of donors of H(2)O(2), O(2)*-, *OH, ONOO(-) and NO*. Cell viability assessed by morphological criteria was also monitored. Massive apoptosis was induced by 1 mM of donors of H(2)O(2) and ONOO(-), while NO* additionally induced necrotic cell death. Taken together, these results have shown that ROS/RNS provide a good explanation for the developing resistance to the growth promoting activity of insulin in myoblasts under conditions of oxidative or nitrosative stress. Cell viability showed that neither donor induced cell death when given below 0.5 mM. In order to confirm the deleterious effects of ROS/RNS prior to the subsequent treatment with ROS/RNS plus insulin one day pretreatment with selected antioxidants (sodium ascorbate - ASC (0.01, 0.1, 1 mM), or N-acetylcysteine - NAC (0.1, 1, 10 mM) was carried out. Surprisingly, at a low dose (micromolar) antioxidants did not abrogate and even worsened the concentration-dependent effects of ROS/RNS. In contrast, pretreatment with millimolar dose of ASC or NAC maintained an elevated mitogenicity in response to insulin irrespective of the ROS/RNS donor type used.
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PMID:Preconditioning with millimolar concentrations of vitamin C or N-acetylcysteine protects L6 muscle cells insulin-stimulated viability and DNA synthesis under oxidative stress. 1215 Oct 57

We have been investigating the potential utility of engineered cell lines as surrogates for primary islet cells in treatment of type 1 diabetes. To this end, two strategies that have emerged for procuring cell lines with resistance to immune-mediated damage are 1) selection of cytokine-resistant cell lines by growth of INS-1 insulinoma cells in iteratively increasing concentrations of interleukin (IL)-1beta + gamma-interferon (IFN-gamma), and 2) stable overexpression of the anti-apoptotic gene bcl-2 in INS-1 cells. Herein, we show that bcl-2-overexpressing cells are resistant to the cytotoxic effects of reactive oxygen and nitrogen species (ROS/RNS), but are only modestly protected against high concentrations of IL-1beta + INF-gamma, whereas the converse is true in cytokine selected cells. We also found that the combination of bcl-2 expression and cytokine selection confers a broader spectrum of resistance than either procedure alone, such that the resultant cells are highly resistant to cytokines and ROS/RNS, with no impairment in glucose-stimulated insulin secretion. INS-1-derived cells with combined bcl-2 expression and cytokine selection are also more resistant to damage induced by coculture with mitogen-activated peripheral blood mononuclear cells. Surprisingly, application of the cytokine selection procedure to bcl-2-overexpressing cells does not result in impairment of nuclear factor-kappaB translocation, iNOS expression, and NO production, as clearly occurs upon application of the selection procedure to cells without bcl-2 overexpression. Further investigation of the diverse pathways involved in the development of cytokine and ROS/RNS resistance may define simplified and specific strategies for preservation of beta-cell mass.
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PMID:Discrete and complementary mechanisms of protection of beta-cells against cytokine-induced and oxidative damage achieved by bcl-2 overexpression and a cytokine selection strategy. 1276 53

Diabetes mellitus is one of the most common chronic diseases affecting millions of people worldwide. Cardiovascular complication including myocardial infarction is one of the major causes of death in diabetic patients. Diabetes mellitus induces abnormal pathological findings including cell hypertrophy, neuropathy, interstitial fibrosis, myocytolysis and apoptosis and lipid deposits in the heart. In addition, the cytoplasmic organelles of cardiomyocytes including the plasma membrane, mitochondrion and sarcoplasmic reticulum are also impaired in both type I and type II diabetes. Hyperglycaemia is a major aetiological factor in the development of diabetic cardiomyopathy in patients suffering from diabetes. Hyperglycaemia promotes the production of reactive oxygen (ROS) and nitrogen species (RNS). The release of ROS and RNS induces oxidative stress leading to abnormal gene expression, faulty signal transduction and apoptosis of cardiomyocytes. Hyperglycaemia also induces apoptosis by p53 and the activation of the cytochrome c-activated caspase-3 pathway. Stimulation of connective tissue growth factor and the formation of advanced glycation end products in extracellular matrix proteins induces collagen cross-linking and contribute to the fibrosis observed in the interstitium of the heart of diabetic subjects. In terms of signal transduction, defects in intracellular Ca2+ signalling due to alteration of expression and function of proteins that regulate intracellular Ca2+ also occur in diabetes. All of these abnormalities result in gross dysfunction of the heart. Beta-adrenoreceptor antagonists, ACE inhibitors, endothelin-receptor antagonist (Bonestan), adrenomedullin, hormones (insulin, IGF-1) and antioxidants (magniferin, metallothionein, vitamins C and E) reduce interstitial fibrosis and improve cardiac function in diabetic cardiomyopathy.
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PMID:Molecular and cellular basis of the aetiology and management of diabetic cardiomyopathy: a short review. 1536 3

Methylglyoxal (MG) is a metabolite of glucose. Our previous study demonstrated an elevated MG level with an increased oxidative stress in vascular smooth muscle cells (VSMCs) from spontaneously hypertensive rats. Whether MG causes the generation of nitric oxide (NO) and superoxide anion (O2*-), leading to peroxynitrite (ONOO-) formation in VSMCs, was investigated in the present study. Cultured rat thoracic aortic SMCs (A-10) were treated with MG or other different agents. Oxidized DCF, reflecting H2O2 and ONOO- production, was significantly increased in a concentration- and time-dependent manner after the treatment of SMCs with MG (3-300 microM) for 45 min-18 h (n = 12). MG-increased oxidized DCF was effectively blocked by reduced glutathione or N-acetyl-l-cysteine, as well as L-NAME (p < 0.05, n = 12). Both O2*- scavenger SOD and NAD(P)H oxidase inhibitor DPI significantly decreased MG-induced oxidized DCF formation. MG significantly and concentration-dependently increased NO and O2*- generation in A-10 cells, which was significantly inhibited by L-NAME and SOD or DPI, respectively. In conclusion, MG induces significant generation of NO and O2*- in rat VSMCs, which in turn causes ONOO- formation. An elevated MG level and the consequential ROS/RNS generation would alter cellular signaling pathways, contributing to the development of different insulin resistance states such as diabetes or hypertension.
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PMID:Methylglyoxal-induced nitric oxide and peroxynitrite production in vascular smooth muscle cells. 1560 12

Previously, we reported that mitogenicity in L6 muscle cells was stimulated by insulin but inhibited by reactive oxygen/nitrogen species (ROS/RNS; []) and that preincubation with sodium ascorbate (ASC) protected from either the impaired DNA synthesis and/or loss of cell viability. Now, we addressed the question how ascorbate (AA) rescued DNA synthesis in L6 muscle cells being challenged with ROS/RNS. We assumed that AA might be able to influence insulin signaling. We found that insulin elevated the protein levels of both PKB/Akt kinase phosphorylated at Serine(473) (pS473-Akt), and c-Jun phosphorylated at Serine63, Serine73 (pS63, pS73-c-Jun) residues, respectively. A short-term treatment experiment (0 - 45 min) revealed that either insulin (0.1 muM) or hydrogen peroxide (0.1, 0.5 mM; H2O2) increased the pS473-Akt and pS63, pS73-c-Jun protein levels, although the effect of ROS/RNS peaked earlier (5 min) than that of insulin (45 min). Astonishingly, the elevated levels of both pS473-Akt and pS63, pS73-c-Jun in response to insulin were reduced by the concomitant treatment with H2O2 in a dose-dependent fashion. In contrast, a 4-hour preincubation with ASC (1 mM) augmented the signal from pS473-Akt and pS63, pS73-c-Jun, when both insulin and H2O2 were added. Moreover, a 24 h preincubation with ASC also elevated the pS473-Akt and pS63, pS73-c-Jun levels in response to insulin irrespective to ROS/RNS co-treatment. During chronic treatment studies, ROS/RNS stimulated neither phosphorylation of Akt nor c-Jun, indicating that ROS/RNS-dependent activation of the above-mentioned proteins was short-term and transient. Furthermore, higher levels of pS473 Akt and pS63, pS73-c-Jun after preincubation with ASC suggest that by this route AA could protect insulin-induced mitogenicity. Basal levels of Akt and its target p70(S6K) remained constant regardless of treatment. These results suggest that AA defends the insulin-stimulated mitogenicity hampered by ROS/RNS most likely by the amplification of insulin signal at the level of pS473-Akt and pS63, pS73-c-Jun, respectively.
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PMID:Preincubation with sodium ascorbate potentiates insulin-dependent PKB/Akt and c-Jun phosphorylation in L6 rat myoblasts challenged with reactive oxygen/nitrogen species. 1590 68

Reactive oxygen and nitrogen species (ROS and RNS) recently emerged as critical signaling molecules in cardiovascular research. Several studies over the past decade have shown that physiological effects of vasoactive factors are mediated by these reactive species and, conversely, that altered redox mechanisms are implicated in the occurrence of metabolic and cardiovascular diseases. Oxidant stress occurs when ROS and/or RNS production exceeds the cell natural antioxidant systems, and pathological events ensue. Cardiovascular risk factors are associated with an imbalance of the redox equilibrium toward oxidative stress, leading to endothelial activation and proinflammatory processes implicated in atherogenesis and metabolic disorders. Recent studies indicate that insulin and insulin-sensitizing drugs activate antiinflammatory pathways that may limit oxidant stress in insulin target tissues. The main goal of this brief review is to discuss recent progress in the field of cellular redox signaling as it pertains to insulin modulation of vascular endothelial function in cardiovascular diseases.
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PMID:Redox modulation of insulin signaling and endothelial function. 1599 61

Cardiovascular disease affects approximately 60% of the adult population over the age of 65 and represents the number one cause of death in the United States. Coronary atherosclerosis is responsible for the vast majority of the cardiovascular events, and a number of cardiovascular risk factors have been identified. In recent years, it has become clear that insulin resistance and endothelial dysfunction play a central role in the pathogenesis of atherosclerosis. Much evidence supports the presence of insulin resistance as the fundamental pathophysiologic disturbance responsible for the cluster of metabolic and cardiovascular disorders, known collectively as the metabolic syndrome. Endothelial dysfunction is an important component of the metabolic or insulin resistance syndrome and this is demonstrated by inadequate vasodilation and/or paradoxical vasoconstriction in coronary and peripheral arteries in response to stimuli that release nitric oxide (NO). Deficiency of endothelial-derived NO is believed to be the primary defect that links insulin resistance and endothelial dysfunction. NO deficiency results from decreased synthesis and/or release, in combination with exaggerated consumption in tissues by high levels of reactive oxygen (ROS) and nitrogen (RNS) species, which are produced by cellular disturbances in glucose and lipid metabolism. Endothelial dysfunction contributes to impaired insulin action, by altering the transcapillary passage of insulin to target tissues. Reduced expansion of the capillary network, with attenuation of microcirculatory blood flow to metabolically active tissues, contributes to the impairment of insulin-stimulated glucose and lipid metabolism. This establishes a reverberating negative feedback cycle in which progressive endothelial dysfunction and disturbances in glucose and lipid metabolism develop secondary to the insulin resistance. Vascular damage, which results from lipid deposition and oxidative stress to the vessel wall, triggers an inflammatory reaction, and the release of chemoattractants and cytokines worsens the insulin resistance and endothelial dysfunction.From the clinical standpoint, much experimental evidence supports the concept that therapies that improve insulin resistance and endothelial dysfunction reduce cardiovascular morbidity and mortality. Moreover, interventional strategies that reduce insulin resistance ameliorate endothelial dysfunction, while interventions that improve tissue sensitivity to insulin enhance vascular endothelial function. There is general agreement that aggressive therapy aimed simultaneously at improving insulin-mediated glucose/lipid metabolism and endothelial dysfunction represents an important strategy in preventing/delaying the appearance of atherosclerosis. Interventions that 1 correct carbohydrate and lipid metabolism, 2 improve insulin resistance, 3 reduce blood pressure and restore vascular reactivity, and 4 attenuate procoagulant and inflammatory responses in adults with a high risk of developing cardiovascular disease reduce cardiovascular morbidity and mortality. Whether these benefits hold when the same prevention strategies are applied to younger, high-risk individuals remains to be determined.
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PMID:Insulin resistance and endothelial dysfunction: the road map to cardiovascular diseases. 1650 74

Metabolic syndrome consists of a cluster of metabolic conditions, such as hypertriglyceridemia, hyper-low-density lipoproteins, hypo-high-density lipoproteins, insulin resistance, abnormal glucose tolerance and hypertension, that-in combination with genetic susceptibility and abdominal obesity-are risk factors for type 2 diabetes, vascular inflammation, atherosclerosis, and renal, liver and heart disease. One of the defects in metabolic syndrome and its associated diseases is excess cellular oxidative stress (mediated by reactive oxygen and nitrogen species, ROS/RNS) and oxidative damage to mitochondrial components, resulting in reduced efficiency of the electron transport chain. Recent evidence indicates that reduced mitochondrial function caused by ROS/RNS membrane oxidation is related to fatigue, a common complaint of MS patients. Lipid replacement therapy (LRT) administered as a nutritional supplement with antioxidants can prevent excess oxidative membrane damage, restore mitochondrial and other cellular membrane functions and reduce fatigue. Recent clinical trials have shown the benefit of LRT plus antioxidants in restoring mitochondrial electron transport function and reducing moderate to severe chronic fatigue. Thus LRT plus antioxidant supplements should be considered for metabolic syndrome patients who suffer to various degrees from fatigue.
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PMID:Metabolic syndrome and mitochondrial function: molecular replacement and antioxidant supplements to prevent membrane peroxidation and restore mitochondrial function. 1724 17

In this review we updated the fatty acid (FA) effects on skeletal muscle metabolism. Abnormal FA availability induces insulin resistance and accounts for several of its symptoms and complications. Efforts to understand the pathogenesis of insulin resistance are focused on disordered lipid metabolism and consequently its effect on insulin signaling pathway. We reviewed herein the FA effects on metabolism, signaling, regulation of gene expression and oxidative stress in insulin resistance. The elevated IMTG content has been associated with increased intracellular content of diacylglycerol (DAG), ceramides and long-chain acyl-coenzyme A (LCA-CoA). This condition has been shown to promote insulin resistance by interfering with phosphorylation of proteins of the insulin pathway including insulin receptor substrate-1/2 (IRS), phosphatidylinositol-3-kinase, (PI3-kinase) and protein kinase C. Although the molecular mechanism is not completely understood, elevated reactive oxygen (ROS) and nitrogen species (RNS) are involved in this process. Elevated ROS/RNS activates nuclear factor-kappaB (NFkB), which promotes the transcription of proinflammatory tumoral necrosis factor alpha (TNFalpha), decreasing the insulin response. Therefore, oxidative stress induced by elevated FA availability may constitute one of the major causes of insulin resistance in skeletal muscle.
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PMID:Updating the effects of fatty acids on skeletal muscle. 1854 63

Type 2 diabetes mellitus, the most prevalent and serious metabolic disease worldwide, is believed to result from the interaction between genetical and lifestyle factors. In genetically predisposed people, the combination of a hypercaloric ingestion and reduced physical activity is responsible for the appearance of insulin resistance. This state can be overcomed, until a certain point, with increments of insulin secretion (hyperinsulinemia). However, an insufficient compensation leads to a state of glucose intolerance, which can evolve to diabetes, according to actual knowledge. The noxious effects of the hyperglycemia, allied with the possible increase of free fatty acids, are mediated by highly reactive molecules, oxygen and nitrogen free radicals species (ROS and RNS). Recent data suggests that these reactive species are signalling molecules and are involved in the regulation of the cellular function, being its increased production or reduced elimination a cause of oxidative stress. Indeed, those free radicals act directly through oxidative damage on macromolecules (proteins, lipids, DNA) or indirectly, activating single transduction pathways sensible to stress mechanisms. In this review, we will consider the pathways recognized as the more significant in stress mechanisms, namely: NF-kB, JNK/SAPK, p38 MAPK, PKC, AGE/RAGE, hexosamines and poliol. These signalling cascades are believed to be responsible for the insulin resistance and reduced insulin secretion, therefore the use of innocuous antioxidant substances such as vitamin C, E and the a-lipoic acid, is seen as a possible step for type 2 diabetic complications management. We will also discuss acetylsalicylic acid potentialities in the above-mentioned pathologies.
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PMID:[Oxidative stress and its effects on insulin resistance and pancreatic beta-cells dysfunction: relationship with type 2 diabetes mellitus complications]. 1867 21


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