EC:1.5.1.19 - FACTA Search

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Query: EC:1.5.1.19 (NOS)
7,285 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The inducible nitric oxide synthase (iNOS) gene is expressed by hepatocytes in a number of physiologic and pathophysiologic conditions affecting the liver including septic and hemorrhagic shock. The molecular regulation of iNOS expression is complex and occurs at multiple levels in the gene expression pathway. The cytokines TNF-alpha, IL-1beta, and INF-gamma synergistically activate iNOS expression in the liver, and the human iNOS gene was first cloned from cytokine-stimulated hepatocytes. iNOS expression requires the transcription factor NF-kappaB and is down-regulated by steroids, TGF-beta, the heat shock response, p53, and nitric oxide (NO) itself. In vivo, hepatic iNOS induction is differentially regulated from the typical acute-phase reactants and is not expressed as a mandatory component of the acute phase response. Thus, numerous mechanisms have evolved to regulate iNOS expression during hepatocellular injury. Studies of the effects of NO in the liver demonstrate that induced NO synthesis plays an important role in hepatocyte function and protects the liver during sepsis and ischemia reperfusion. Its cytoprotective role is best exemplified in a rodent model of endotoxemia. Here the addition of the nonspecific NOS inhibitors significantly increased hepatic damage. NO exerts a protective effect through its ability to prevent intravascular thrombosis by inhibiting platelet adhesion and neutralizing toxic oxygen radicals. NO also exerts a protective effects both in vivo and in vitro by blocking TNF-alpha-induced apoptosis and hepatotoxicity, in part by a thiol-dependent inhibition of caspase-3-like protease activity. These studies demonstrate the cytoprotective effects of NO in the liver and suggest hepatic iNOS expression functions as an adaptive response to minimize inflammatory injury. In addition, NO has anti-tumor effects as well as known mutagenic effects, is involved in the systemic vasodilatation of cirrhosis, and has potent antimicrobial properties.
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PMID:Inducible nitric oxide synthase in the liver: regulation and function. 972 29

The shock syndrome has been classically considered as a consequence of both decreased tissue perfusion and O2 supply; however, in some types of shock like septic or traumatic ones, regional blood flows may be increased. A decade ago, mitochondrial alterations consistent with uncoupling of oxidative phosphorylation were reported in either endotoxemic or hemorrhagic experimental shock or in humans. Recently, the discovery of nitric oxide (NO) and its increase in the shock state, has opened new perspectives in the understanding of this problem. Nitric oxide produces vasodilatation and, at the same time, increases the mitochondrial production of O2 active species like superoxide anion. Both radicals react to form a strong oxidant that is able to nitrate the phenolic rings of proteins: peroxynitrite. This effect leads to the impairment of the activities of different mitochondrial enzymes like succinate dehydrogenase and ATPase and the mitochondrial function and finally, to decreased energy levels and to multiorgan failure. The increase in NO release is due to the effects of circulating peptides and of increased adhesion of neutrophils to the endothelium and to the positive effects of inflammatory mediators like TNF-alpha and cytokines on inducible NOS (iNOS) expression in endothelium and tissues. It is suggested that the shock state is the consequence of an imbalance between NO and O2 and their metabolites.
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PMID:[Shock: concepts for a definition]. 981 94

We have previously reported that mice lacking inducible nitric oxide synthase (NOS2) developed enhanced Th1 cell responses. We now investigated the mechanism by which NO modulates Th1 cells differentiation. Peritoneal macrophages from NOS2-deficient mice infected with Leishmania major in vivo or stimulated with IFN-gamma or lipopolysaccharide (LPS) in vitro produced significantly higher levels of IL-12 than those from heterozygous or wild-type mice. A macrophage cell line, J774, produced significant amounts of IL-12 following activation with LPS, or LPS plus IFN-gamma. This could be markedly enhanced by the NOS inhibitor L-NG monomethyl arginine (L-NMMA), but profoundly inhibited by the NO-generating compound S-nitroso-N-acetyl-penicillamine (SNAP). The effect of NO in this system is selective, since SNAP enhanced and L-NMMA decreased TNF-alpha synthesis by LPS-activated J774 cells. The differential effect of NO on IL-12 and TNF-alpha is at the transcriptional level and is activation dependent. Since IL-12 is a major inducer of Th1 cells which produce IFN-gamma that can activate macrophages to produce IL-12, our data demonstrate that NO can be an inhibitor of this feedback loop, preventing the excessive amplification of Th1 cells which are implicated in a range of immunopathologies.
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PMID:Nitric oxide regulates Th1 cell development through the inhibition of IL-12 synthesis by macrophages. 986 42

With the use of immunohistochemical technique, nerve biopsy is more informative for the diagnosis of inflammatory neuropathies. In chronic inflammatory demyelinating neuropathy, an increased number of T cells are frequently present in endoneurium, which is in contrast to hereditary neuropathies. In active demyelinating lesions, macrophages adhering nerve fibers showed stainings with TNF-alpha. NOS and cyclooxygenase-2 (COX-2). These molecules may act in concert to promote nerve damage. The inhibitor of COX-2, nimesulide, was effective on experimental allergic neuritis, even if given after the onset of clinical signs. A COX-2 inhibitor may have potential as an additional therapeutic agent in human inflammatory neuropathies. In vasculitic neuropathies, cell-mediated cytotoxicity may be involved in the pathogenesis of small vessel injury. Axonal injury may be caused by focal ischemia. However, an immune attack might be involved in nerve damage, since T cells and IL-12 positive cells were found in endoneurium of some patients with active vasculitis.
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PMID:[Immunopathology of inflammatory neuropathies]. 1037 18

Although NO appears important in rodent immune responses, its involvement in the human immune system is unclear. We report that human NK cells express constitutive endothelial NO synthase mRNA and protein, but not detectable levels of inducible NO synthase. They produce NO following activation by coculture with target cells or cross-linking with anti-CD16 mAb, and production is increased in the presence of IL-2. N-monomethyl-L-arginine (L-NMA), a NOS inhibitor, partially inhibited NK cell lysis of four different target cells (<40% inhibition at 500 microM L-NMA), but not granule release following coculture with target cells, or Fas ligand induction following cross-linking with anti-CD16 mAb. However, L-NMA augmented apoptosis of NK cells induced by activation through CD16 ligation or coculture with K562. An NO donor, S-nitroso-N-acetylpenicillamine (SNAP), suppressed apoptosis of NK cells induced by CD16 cross-linking or coculture with target cells, suggesting that endogenous NO production is involved in protection of NK cells from activation-induced apoptosis, thereby maintaining NK activity. SNAP also suppressed, and L-NMA enhanced, expression of TNF-alpha, reported to be involved in activation-induced NK cell death, in response to CD16 cross-linking. Suppression of anti-CD16-induced apoptosis by SNAP was reversed by the addition of rTNF-alpha. DNA-binding activity of the transcription factor, NF-AT, which is involved in TNF-alpha induction upon ligation of CD16, was inhibited by SNAP and enhanced by L-NMA. Our results suggest that down-regulation of TNF-alpha expression, possibly due to suppression of NF-AT activation, is a mechanism by which endogenous NO protects NK cells from activation-induced apoptosis, and maintains lytic capacity.
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PMID:Human NK cells express endothelial nitric oxide synthase, and nitric oxide protects them from activation-induced cell death by regulating expression of TNF-alpha. 1041 49

Nitric oxide (NO) has been implicated in the arterial vasodilation and associated vascular hyporesponsiveness to vasoconstrictors observed in liver cirrhosis. Bacteria, potent activators of NO and TNF-alpha synthesis, are found in the mesenteric lymph nodes (MLNs) of ascitic cirrhotic rats. Here, we investigated the impact of bacterial translocation (BT) to MLNs on TNF-alpha production, vascular NO release, and contractility in the mesenteric vasculature of ascitic cirrhotic rats. Vascular response to the alpha-adrenoagonist methoxamine, which is diminished in the superior mesenteric arterial beds of cirrhotic rats, is further blunted in the presence of BT. BT promoted vascular NO release in cirrhotic rats, an effect that depended on pressure-induced shear stress and was blocked by the NO inhibitor N(omega)-nitro-L-arginine. Removing the endothelium had the same effect. Endothelial NO synthase (eNOS), but not the inducible isoform (iNOS), was present in mesenteric vasculature of cirrhotic rats with and without BT, and its expression was enhanced compared with controls. TNF-alpha was induced in MLNs by BT and accumulated in parallel in the serum. This TNF-alpha production was associated with elevated levels of tetrahydrobiopterin (BH(4)), a TNF-alpha-stimulated cofactor and enhancer of eNOS-derived NO biosynthesis and NOS activity in mesenteric vasculature. These findings establish a link between BT to MLNs and increased TNF-alpha production and elevated BH(4) levels enhancing eNOS-derived NO overproduction, further impairing contractility in the cirrhotic mesenteric vasculature.
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PMID:Bacterial translocation in cirrhotic rats stimulates eNOS-derived NO production and impairs mesenteric vascular contractility. 1054 21

Since the identification, in 1954, of the first gene associated with resistance to Plasmodium falciparum, several genes, some of them being implicated in the regulation of the immune response, have been described as possible influences on cerebral pathology. This pathology depends primarily on the capacity of infected red blood cells to adhere to the endothelia of micro-vessels, leading to their occlusion. The major players of cerebral malaria potentially include: receptors expressed on the surface of the endothelial cell and known to interact with infected red blood cells, cytokines modulating the expression of these adhesion molecules, nitric oxide (NO) and Fc epsilon RII/CD23. Cells other than infected red blood cells, such as platelets, monocytes and lymphocytes, have the ability to adhere to these endothelial receptors and to one another, via different ligands, leading to a more complex situation and an increase in the degree of vessel occlusion. The polymorphism of all these molecules, implicated either in adhesion, in modulation of this adhesion or activation of the expression of diverse endothelial mediators should be an important field of study. Polymorphism of five of these molecules has been explored so far: ICAM-1, TNF-alpha, IL-1 beta, iNOS2 (inducible NOS) and CR-1 (complement receptor-1). To these studies, can be added those concerning mannose binding protein (MBP), a protein playing a role in innate immunity, and the class-I antigen HLA-B53. To date the only clear-cut result concerns TNF-alpha. With the other polymorphisms, either no association is found (IL-1RA, CR-1, MBP), or results are geographically heterogeneous (ICAM-1, HLA-B53), or contradictory (iNOS2). Most often, the approach followed has been the candidate gene approach, as part of case control studies. One of the main problems in this approach is the difficulty of establishing the control cohort. This difficulty disappears in family studies, which include their own controls. So far, the only results based on complex segregation analysis have been focused on parasite multiplication and not on cerebral malaria.
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PMID:[Immunogenetics and cerebral malaria]. 1057 60

Trehalose dimycolate (TDM), a glycolipid present in the cell wall of Mycobacterium spp., is a powerful immunostimulant. We have developed an original model of macrophage activation where TDM is injected in vivo to prime peritoneal macrophages. These primed macrophages do not express inducible NO synthase (NOS II), however, they can be fully activated, i.e. induced to express NOS II and to develop a NOS II-dependent antiproliferative activity, following in vitro exposure to low concentrations of LPS. In a previous paper, we have shown that TDM-priming of mouse peritoneal macrophages is mediated by the sequential production of IL-12 and IFN-gamma. In the present paper, we investigated the role of TNF in the priming of macrophages by TDM. By semi-quantitative RT-PCR, we have shown that TDM injection induced transcription of TNF-alpha in peritoneal cells. TNF-mRNA levels peaked 5 hours after TDM injection and remained elevated for at least 32 hours. TNF expression was absolutely necessary for macrophage priming, as injection of an anti-TNF monoclonal antibody, 4 h before and 20 hours after TDM injection, prevented LPS-dependent activation of macrophages in vitro. This result was confirmed by the inability of TDM to prime macrophages from LT-alpha/TNF-alpha knockout (LT/TNFKO) mice. In addition, analysis of LT/TNFKO mice treated with TDM revealed that induction of the IL-12 transcript in their peritoneal cells and expression of a functional NADPH oxidase in macrophages are TNF-independent events.
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PMID:Tumor necrosis factor is required for the priming of peritoneal macrophages by trehalose dimycolate. 1058 20

TNF-alpha-induced cytotoxicity is mediated by the intracellular "death domain" of the 55-kDa TNF-alpha receptor and has been demonstrated to be coupled with induction of inducible nitric oxide synthase (iNOS), leading to generation of nitric oxide radicals (NO*). Because it is still widely unknown, to what extent NO* participates in the execution of TNF-alpha-induced apoptosis, NO* production, iNOS expression, and enzyme activity in relation to TNF-alpha-induced apoptotic cell death were investigated in the human breast cancer cell line MCF-7 and various other malignant cell lines. Incubation with TNF-alpha led to induction of iNOS mRNA and protein as well as enhancement of NOS activity. Augmented synthesis of NO2, the stable end product of NO* generation, was significantly correlated with augmented rates of cell death. Measurement of TNF-alpha-triggered production of reactive oxygen species (ROS) suggested a major role for NO* within the generated oxygen radicals. Dying cells showed characteristic features of apoptosis. Addition of cycloheximide (CX) enhanced apoptotic cell death by increasing iNOS activity. L-Nitro-arginine-methylester (L-NAME), a competitive NOS-inhibitor, and iNOS antisense oligonucleotides effectively prevented NO2 generation and apoptosis. Evaluation of iNOS expression during TNF-alpha-induced cell death in various malignant cell lines demonstrated iNOS positivity for all TNF-alpha-sensitive cells. The only primarily resistant line was iNOS negative. In a resistant variant of MCF-7, iNOS mRNA was still detectable; however, treatment with TNF-alpha did not enhance NOS activity. TNF-alpha sensitivity and NO2 production were completely restored by the addition of CX. Taken together, iNOS induction plays an essential role in TNF-alpha-induced apoptosis of the investigated cell lines. Further studies are necessary to define the impact of NO* in relation to other specific effectors of apoptosis such as the caspases.
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PMID:Induction of inducible nitric oxide synthase is an essential part of tumor necrosis factor-alpha-induced apoptosis in MCF-7 and other epithelial tumor cells. 1061 18

The pyrogenic response to supernatant fluids obtained from human peripheral blood mononuclear cells (PBMC) stimulated with staphylococcal enterotoxin A (SEA) was characteristic of a response to an endogenous pyrogen in that it was brief and monophasic and was destroyed by heating supernatant fluids at 70 degrees C for 30 min. The febrile responses were in parallel with the levels of interleukin-1 (IL-1), tumor necrosis factor (TNF), interferon-gamma (IFN-gamma), IL-2, and IL-6 in supernatant fluids obtained from PBMC treated with SEA. Both the pyrogenicity and the levels of IL-1, TNF, IFN-gamma, IL-2, and IL-6 in supernatant fluids started to rise at 6 to 18 h and reached their peak levels at 24 to 96 h after SEA incubation. Both the fever and the increased levels of IL-1, TNF, IFN-gamma, IL-2, and IL-6 in supernatant fluids obtained from the SEA-stimulated PBMC were decreased by incubating SEA-PBMC with anisomycin (a protein synthesis inhibitor), aminoguanidine (an inhibitor of inducible nitric oxide synthase [NOS]), or dexamethasone (an inhibitor of NOS). The febrile response to supernatant fluids obtained from the SEA-stimulated PBMC was attenuated by adding either anti-IL-1beta, anti-TNF-alpha, or anti-IFN-gamma monoclonal antibody (MAb) to supernatant fluids. The antipyretic effects exerted by anti-IL-1beta MAb were greater than those exerted by anti-TNF-alpha or anti-IFN-gamma MAb. The data suggest that SEA acts through the NOS mechanisms in PBMC to stimulate synthesis of pyrogenic cytokines (in particular, the IL-1beta).
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PMID:Staphylococcal enterotoxin A acts through nitric oxide synthase mechanisms in human peripheral blood mononuclear cells to stimulate synthesis of pyrogenic cytokines. 1072 95

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