一氧化氮合酶的遗传、生理研究进展

一氧化氮具有广泛的生理功能,哺乳动物体内的NO是由NO合酶(NOS)氧化L-精氨酸而合成的,合成后的NO迅速跨膜扩散释放,NO合成失调能介导多种疾病。催化NO生物合成的NOS有三种亚型:神经元型NOS(nNOS)、内皮型NOS(eNOS)和诱导型NOS(iNOS),目前,人的三型NOS已纯化并且已分子克隆成功,对一氧化氮合酶的遗传研究确认了NOS家族的基因结构和染色体定位。     

Pharmacological and genetical evidence supporting nitric oxide requirement for 2,4-epibrassinolide regulation of root architecture in Arabidopsis thaliana

Brassinosteroids (BRs) regulate various physiological processes, such as tolerance to stresses and root growth. Recently, a connection was reported between BRs and nitric oxide (NO) in plant responses to abiotic stress. Here we present evidence supporting NO functions in BR signaling during root growth process. Arabidopsis seedlings treated with BR 24-epibrassinolide (BL) show increased lateral roots (LR) density, inhibition of primary root (PR) elongation and NO accumulation. Similar effects were observed adding the NO donor GSNO to BR-receptor mutant bri1-1. Furthermore, BL-induced responses in the root were abolished by the specific NO scavenger c-PTIO. The activities of nitrate reductase (NR) and nitric oxide synthase (NOS)-like, two NO generating enzymes were involved in BR signaling. These results demonstrate that BR increases the NO concentration in root cells, which is required for BR-induced changes in root architecture.     

Phagocytosis is regulated by nitric oxide in murine microglia.

Nitric oxide (NO) is produced by inducible nitric oxide synthase (iNOS) in activated microglia and has been shown to participate in host defense mechanisms. However, the role of NO produced by constitutive nitric oxide synthase (cNOS) in microglia is poorly understood. In this report, NO was found to regulate phagocytosis in murine BV-2 microglial cells as quantified by flow cytometry. Addition of NO-generating compounds caused impaired phagocytosis as compared to untreated microglia. The addition of nitric oxide synthase (NOS) inhibitors to microglial cells resulted in potentiation of phagocytosis, suggesting that constitutive NO was participating in the regulation of phagocytosis. The inverse correlation between NO production and phagocytosis was also observed when Alzheimer's beta-amyloid peptide was added. With beta-amyloid treatment, constitutive NO production decreased while phagocytosis increased. Cell extracts prepared from untreated microglia were found to contain both neuronal and endothelial NOS isoforms, but not the inducible form. The correlation of spontaneous NO production with attenuated phagocytosis suggests that constitutive NOS enzymes participate in microglial regulation.     

Nitric oxide and reactive nitrogen species in airway epithelial signaling and inflammation

Nitric oxide (NO(.-)) is produced by many diverse cell types as a cellular or intracellular signaling molecule, by the activation of nitric oxide synthases (NOSs). All three known NOS isoforms are expressed within the respiratory tract and mediate various airway functional properties such as airway smooth muscle tone, ciliary function, epithelial electrolyte transport, and innate host defense. The respiratory epithelium is a major source of NO(.-), in which it regulates normal epithelial cell function and signaling as well as signaling pathways involved in airway inflammation. In addition to its normal physiological properties, increased airway NO(.-) production in inflammatory respiratory tract diseases such as asthma may activate additional signaling mechanisms to regulate inflammatory-immune pathways, and epithelial barrier (dys)function or repair. The biological actions of NO(.-) are controlled at various levels, including mechanisms that regulate NOS localization and activation, and variable oxidative metabolism of NO(.-), resulting in generation of bioactive reactive nitrogen species (RNS). Moreover, in addition to altered production of NO(.-) or RNS, the presence of various target enzymes and/or metabolic regulators of NO(.-)/RNS can be dramatically altered during airway inflammatory conditions, and contribute to alterations in NO(.-)-mediated signaling pathways in disease. This review summarizes current knowledge regarding NO(.-)-mediated epithelial signaling, as well as disease-related changes in airway NOS biology and target enzymes that affect NO(.-)/RNS signaling mechanisms. A detailed understanding of these various changes and their impact on NO(.-) signaling pathways are needed to fully appreciate the contributions of NO(.-)/RNS to airway inflammation and to develop suitable therapeutic approaches based on regulating NO(.-) function.     

The effects of nitric oxide on prostanoid production and release by human umbilical vein endothelial cells

Human umbilical vein endothelial cells (HUVEC) express and synthesize both constitutive and inducible nitric oxide synthase (NOS) and cyclo-oxygenase (COX) enzymes, and have been extensively used as an in vitro model to investigate the role of these enzymes in the patho-physiology of placenta-fetal circulation. In this study we investigated the role of NO in regulating prostanoid production and release from HUVEC. Both untreated and IL-1beta-treated HUVEC were exposed to various NOS inhibitors and NO donors in short-term (1 or 3 hours) experiments, and the effects on prostanoid production were evaluated through the measurement of prostaglandins (PG) I2, E2 and F2alpha released in the incubation medium. We found that the inhibition of inducible NOS but not endothelial NOS antagonizes the IL-1beta-induced increase in PGI2 release. However, NOS inhibitors do not modify baseline PGI2 production. Pharmacological levels of NO, obtained with various NO donors, inhibit basal and IL-1beta-stimulated PG release.     

Nitric oxide synthase from cerebellum catalyzes the formation of equimolar quantities of nitric oxide and citrulline from L-arginine.

This study examined whether constitutive nitric oxide (NO) synthase from rat cerebellum catalyzes the formation of equimolar amounts of NO plus citrulline from L-arginine under various conditions. Citrulline was determined by monitoring the formation of 3H-citrulline from 3H-L-arginine. NO was determined by monitoring the formation of total NOx (NO+nitrite [NO2-] + nitrate [NO3-]) by chemiluminescence after reduction of NOx to NO by acidic vanadium (III). Equal quantities of NO plus citrulline were generated from L-arginine and the formation of both products was linear for about 20 min at 37 degrees C provided L-arginine was present in excess to maintain a zero order reaction rate. Deletion of NADPH, addition of the calmodulin antagonist calmidazolium, or addition of NO synthase inhibitors (NG-methyl-L-arginine, NG-amino-L-arginine) abolished or markedly inhibited the formation of both NO and citrulline. The Km for L-arginine (14 microM; 18 microM) and the Vmax of the reaction (0.74 nmol/min/mg protein; 0.67 nmol/min/mg protein) were the same whether NO or citrulline formation, respectively, was monitored. These observations indicate clearly that NO and citrulline are formed in equimolar quantities from L-arginine by the constitutive isoform of NO synthase from rat cerebellum.     

Role of neuronal nitric oxide synthase in the regulation of the neuroendocrine stress response in rodents: insights from mutant mice

Nitric oxide (NO) is a free radical gas synthesised from arginine and oxygen by enzymes of the family of the nitric oxide synthase. In particular, the neuronal nitric oxide synthase (nNOS) is highly expressed by cells of the hypothalamic paraventricular nucleus, where the sympatho-adrenal system, the hypothalamic-pituitary-adrenal axis and the hypothalamic-neurohypophyseal system originate. These structures are deputed to regulate the neuroendocrine stress response. In the past years, evidence has been accumulated to suggest that NO of nNOS origin plays a significant role in modulating the activity of the above mentioned systems under acute stressor exposure. The availability of nNOS knock-out mice allowed to investigate not only the physiological consequences of a constitutive lack of NO of nNOS origin at the hormonal and molecular level, but also to examine possible behavioural alterations. In this review, we shall discuss and confront the current trends of research in this area, especially focusing on the latest findings gained from genetically modified mice.     

Nitric oxide, a biological double-faced janus--is this good or bad?

Nitric oxide (NO) is a biological messenger molecule produced by one of the essential amino acids L-arginine by the catalytic action of the enzyme NO synthase (NOS). The dual role of NO as a protective or toxic molecule is due to several factors, such as; the isoform of NOS involved, concentration of NO and the type of cells in which it is synthesised, the availability of the substrate L-arginine, generation of guanosine 3,5'-cyclic monophosphate (cGMP) from soluble guanylate cyclase and the overall extra and intracellular environment in which NO is produced. NOS activation as a result of trauma (calcium influx) or infection leads to NO production, which activates its downstream receptor sGC to synthesise cGMP and/or leads to protein nitrosylation. This may lead to one or more systemic effects including altered neurotransmission which can be protective or toxic, vaso/bronchodilatation in the cardiovascular and respiratory systems and enhanced immune activity against invading pathogens. In addition to these major functions, NO plays important role in thermoregulation, renal function, gastrointestinal motility, endocrine function, and various functions of the urogenital system ranging from renin secretion to micturation; spermatogenesis to penile erection; and ovulation to implantation and parturition. A schematic summary of the functions of NO and the various isoforms of NOS expressed in body systems is shown in figure 1. In this review, the historical background, biochemistry and biosynthesis of NO and its enzymes together with the mechanism of NO actions in physiology and pathophysiology are discussed.     

Constitutive and inducible nitric oxide synthases incorporate molecular oxygen into both nitric oxide and citrulline.

Nitric oxide (NO) is synthesized by a number of cells from a guanidino nitrogen atom of L-arginine by the action of either constitutive or inducible NO synthases, both of which form citrulline as a co-product. We have determined the source of the oxygen in both NO and in citrulline formed by the constitutive NO synthase from the vascular endothelium and brain and by the inducible NO synthase from the murine macrophage cell line J774. All these enzymes incorporate molecular oxygen both into NO and into citrulline. Furthermore, activated J774 cells form NO from omega-hydroxyl-L-arginine, confirming the proposal that this compound is an intermediate in the biosynthesis of NO.     

一氧化氮对心肌的抑制性保护作用

内皮型与神经型一氧化氮合酶(eNOS,nNOS)在心肌细胞内持续表达,而细胞应激可引起诱导型NOS(iNOS)表达.心肌细胞结构型eNOS与nNOS源性NO,在生理条件下对心肌主要发挥4方面的抑制作用:减缓心肌细胞搏动频率,轻度抑制心肌细胞收缩功能,加速心肌细胞舒张并增加顺应性,以及轻度抑制线粒体电子传递而增强氧利用效...     

Nitric oxide in physiology and pathology

Summary Nitric oxide (NO) can exert a multitude of biological actions. NO, formed froml-arginine by a calcium-dependent enzyme (NO synthase) plays a key physiological role in regulating vascular tone and integrity. NO, formed by a constitutive neuronal isoform of NO synthase, likewise plays an important neuromodulator role. By contrast, high levels of NO can be generated following induction of a calcium-independent isoform of NO synthase. This excessive production of NO can provoke hypotension such as that observed in septic shock, and can exert cytotoxic actions leading to tissue injury and inflammation. Selective inhibitors of this inducible isoform thus have therapeutic potential in a number of disease states.     

外源NO对NaCl胁迫下黄瓜幼苗生长和根系谷胱甘肽抗氧化酶系统的影响

以津春2号黄瓜为材料,采用营养液水培的方法,研究了外源一氧化氮(NO)对黄瓜幼苗生长和根系谷胱甘肽抗氧化酶系统的影响.结果表明,(1)正常生长条件下添加NO能促进黄瓜幼苗生长,而添加亚甲基蓝(MB-1)显著抑制黄瓜幼苗的生长;(2)添加NO显著缓解了NaCl胁迫对黄瓜幼苗生长的抑制,提高根系还原型谷胱甘肽(GSH)含量、抗坏血酸过氧化物酶(APX)和谷胱甘肽还原酶(GR)活性,而氧化型谷胱甘肽(GSSG)含量略有下降,同时缓解了NaCl胁迫下抗坏血酸(ASA)含量的下降幅度;(3)NaCl胁迫下添加NO的同时添加MB-1可部分解除NO的作用,与NaCl胁迫下单独添加NO处理比较,GR活性、GSH和ASA含量均降低,GSSG含量提高,APX先升高后下降.研究发现,外源NO可能通过鸟苷酸环化酶(cGC)介导来调节NaCl胁迫下黄瓜幼苗根系GR活性和GSH、GSSG、ASA含量,提高抗氧化酶活性和非酶抗氧化物质含量,增强植株对活性氧的清除能力,减少膜脂过氧化,缓解NaCl胁迫对黄瓜幼苗造成的伤害.     

Heavy metals and neuroimmunomodulation in Mytilus edulis

Immunocytes of mussels are the chief immune defense in these organisms. When an immunocyte becomes activated there is a conspicuous change in its morphology (i.e., from round to amoeboid) that can be quantified using image analytical tools. Active immunocytes will typically show larger perimeters and areas and a smaller shape factor. Immunocytes exposed to heavy metals become inactive (Cd, Hg and Pb) thus with smaller perimeters (e.g., Pb2+ 2 ppm: P = 69.72 micron) and areas (e.g., Pb2+ 2 ppm: A = 270 micron2) and larger shape factors (Pb2 2 ppm: SF = 0.65) than the unexposed control cells (alpha = 0.05). Xenobiotics may also interfere with neuroimmunomodulation processes such as nitric oxide (NO) release. The release of NO is catalyzed by a calcium dependent constitutive nitric oxide synthase (cNOS). Presently, we are exploring the effects of heavy metals and other pollutants on cNOS activity, measured as real time NO release, in immunocytes and pedal ganglia from M. edulis. Preliminary results suggest that immunocytes exposed to Pb2+ (5 ppm) cause NO release and does not seem to inhibit further NO release in the presence of morphine. The possible implications of NO mediated Pb2+ neurotoxicity are also explored.     

In Vivo Expression of Inducible Nitric Oxide Synthase in Cerebellar Neurons

Abstract: In the CNS, nitric oxide (NO) functions as both neuromodulator and neurotoxic agent. In vivo neuronal expression of NO synthase (NOS) has been attributed to constitutive NOS—both the neuronal and the endothelial types. The other class of NOS—the inducible NOS (iNOS)—is known to mediate toxic effects of NO in various tissues. In this study, we show for the first time that direct intracerebellar injection of endotoxin and cytokine (lipopolysaccharide and interferon-γ) induced in vivo neuronal expression of the iNOS gene, as demonstrated by fluorescent in situ hybridization and immunohistochemical staining analyzed by confocal laser-scanning microscopy. This raises the possibility that neuronal iNOS might contribute significantly to the vulnerability of the brain to various insults.     

Nitric oxide and nitric oxide synthase activity in plants

Research on NO in plants has gained considerable attention in recent years mainly due to its function in plant growth and development and as a key signalling molecule in different intracellular processes in plants. The NO emission from plants is known since the 1970s, and now there is abundant information on the multiple effects of exogenously applied NO on different physiological and biochemical processes of plants. The physiological function of NO in plants mainly involves the induction of different processes, including the expression of defence-related genes against pathogens and apoptosis/programmed cell death (PCD), maturation and senescence, stomatal closure, seed germination, root development and the induction of ethylene emission. NO can be produced in plants by non-enzymatic and enzymatic systems. The NO-producing enzymes identified in plants are nitrate reductase, and several nitric oxide synthase-like activities, including one localized in peroxisomes which has been biochemically characterized. Recently, two genes of plant proteins with NOS activity have been isolated and characterized for the first time, and both proteins do not have sequence similarities to any mammalian NOS isoform. However, different evidence available indicate that there are other potential enzymatic sources of NO in plants, including xanthine oxidoreductase, peroxidase, cytochrome P450, and some hemeproteins. In plants, the enzymatic production of the signal molecule NO, either constitutive or induced by different biotic/abiotic stresses, may be a much more common event than was initially thought.