Nitric oxide synthesis mechanism

Nitric oxide Ginsenosides enhance nitric oxide synthesis, with effects in the endothelium of the lungs, heart, and kidneys and in the corpus cavernosum (Kim H et al. 1992 Ko et al. 1996). This is a potential mechanism of ginseng-associated vasodilation. Effects on neuronal nitric oxide have not been specifically investigated. 

Mozaffarian N, Berman JW, Casadevall A. Enhancement of nitric oxide synthesis by macrophages represents an additional mechanism of action for amphotericin B. Antimicrob Agents Chemother 1997 41 1825. 

Liu, D., Homan, L.L., and Dillon, J.S., Genistein acutely stimulates nitric oxide synthesis in vascular endothelial cells by a cyclic adenosine 5 -monophosphate-dependent mechanism. Endocrinology, 145, 5532, 2004. 

The signal transduction mechanisms triggered by binding of ET-1 to its vascular receptors include stimulation of phospholipase C, formation of inositol trisphosphate, and release of calcium from the endoplasmic reticulum, which results in vasoconstriction. Conversely, stimulation of PGI2 and nitric oxide synthesis results in decreased intracellular calcium concentration and vasodilation. 

NITRIC OXIDE SYNTHESIS, SIGNALING MECHANISMS, INACTIVATION... 

Flurbiprofen is a propionic acid derivative with a possibly more complex mechanism of action than other NSAIDs. Its (S)( ) enantiomer inhibits COX nonselectively, but it has been shown in rat tissue to also affect tumor necrosis factor- (TNF- ) and nitric oxide synthesis. Flepatic metabolism is extensive its (R) +) and (S) ) enantiomers are metabolized differently, and it does not undergo chiral conversion. It does demonstrate enterohepatic circulation. 

Recent investigations have shed light on peculiarities of the NOS action mechanism the role of the H4B cofactor and CaM, and cooperativity in kinetic and thermodynamic properties of different components of the nitric oxide synthesis system. Stop flow experiments with eNOS (Abu-Soud et al., 2000) showed that calmodulin binding caused an increase in NADH-dependent flavin reduction from 0.13 to 86 s 1 at 10 °C. Under such conditions, in the presence of Arg, heme is reduced very slowly (0.005 s 1). Heme complex formation requires a relatively high concentration ofNO (>50 nM) and inhibits the entire process NADH oxidation and citrulline synthesis decreases 3-fold and Km increases 3-fold. NOS reactions were monitored at subzero temperatures in the presence of 50% ethylene glycol as an anti-freeze solvent (Bee et al., 1998). 

Dweik, R., Laskowski, D, Abu-Soud, HM, Kaneko, F. Hutte, R, Stuehr. DJ and Erzurum, SC. 1998. Nitric oxide synthesis in the lung. Regulation by oxygen through a kinetic mechanism. J. Clin. Invest. 101 660-666. 

Several mechanisms for this transient hypertension were postulated, for example stimulation of the vascular endothelium to secrete endothelin to inhibit nitric oxide synthesis. 

The mechanisms responsible for the contractile responses to AmB have not been identified. Theoretically, the drug can act either directly on the vascular smooth muscle or through release of secondary mediators. A large number of studies have examined putative indirect mechanisms of action. Those studies have revealed that neither renal denervation nor angiotensin II receptor blockade prevent the renal vasoconstriction or the reduction in GFR [87, 88]. Although Cutaia et al [89] demonstrated a toxic effect of AmB on endothelial cells, endothelin does not appear to be involved in the acute responses to AmB [88, 90] and reduced nitric oxide synthesis, consequent to endothelial injury is not involved in modulation of AmB-induced renal vasoconstriction [88]. 

Protein-mediated electron transfer is a device used in a diverse array of biological transformadons. Well-known electron transfer processes include the mitochondrial electron transport system, photosynthesis (Chapter 13), and nitrogen flxadon (Chapter 15). Less well known biochemical reactions in which electron transfer plays a crucial role include nitric oxide synthesis and the cytochrome P450 electron transport systems. Each of these mechanisms is briefly oudined. 

The vascular endothelium produces a number of substances that are released basally into the blood vessel wall to alter vascular smooth muscle tone. One such substance is endothelin (ET-1). Endothelin exerts its effects throughout the body, causing vasoconstriction as well as positive inotropic and chronotropic effects on the heart. The resulting increases in TPR and CO contribute to an increase in MAP. Synthesis of endothelin appears to be enhanced by many stimuli, including Ag II, vasopressin, and the mechanical stress of blood flow on the endothelium. Synthesis is inhibited by vasodilator substances such as prostacyclin, nitric oxide, and atrial natriuretic peptide. There is evidence that endothelin is involved with the pathophysiology of many cardiovascular diseases, including hypertension, heart failure, and myocardial infarction. Endothelin receptor antagonists are currently available for research use only. 

The book focuses on three main themes catalyst preparation and activation, reaction mechanism, and process-related topics. A panel of expert contributors discusses synthesis of catalysts, carbon nanomaterials, nitric oxide calcinations, the influence of carbon, catalytic performance issues, chelating agents, and Cu and alkali promoters. They also explore Co/silica catalysts, thermodynamic control, the Two Alpha model, co-feeding experiments, internal diffusion limitations. Fe-LTFT selectivity, and the effect of co-fed water. Lastly, the book examines cross-flow filtration, kinetic studies, reduction of CO emissions, syncrude, and low-temperature water-gas shift. 

Activation of brain H receptors also stimulates cGMP synthesis [19]. Outside the brain, histamine is known to relax vascular smooth muscle by activation of endothelial H receptors, thereby increasing endothelial Ca2+ concentrations and stimulating the synthesis and release of nitric oxide. The latter, a diffusible agent, then activates the smooth muscle guanylyl cyclase [30]. Although less is known about these mechanisms in the CNS, there is evidence that brain H receptor activation can produce effects that depend on guanylyl cyclase activity [19]. 

Besides cholesterol efflux from arterial wall and its role in RCT, additional properties of HDL have been proposed for its protective anti-atherogenic activities. HDL protects vascular function by a number of potential alternative mechanisms, including inhibition of LDL oxidation [8,9], platelet aggregation and coagulation [10], and endothelial monocyte adhesion [11], as well as promotion of endothelial nitric oxide synthase (eNOS) [12], and prostacyclin synthesis [13-15]. The proposed alternate protective mechanisms for HDL are attractive but many of them lack validation under in vivo conditions. 

Nitric acid synthesis, platinum-group metal catalysts in, 19 621 Nitric acid wet spinning process, 11 189 Nitric oxide (NO), 13 791-792. See also Nitrogen oxides (NOJ affinity for ruthenium, 19 638—639 air pollutant, 1 789, 796 cardioprotection role, 5 188 catalyst poison, 5 257t chemistry of, 13 443—444 control of, 26 691—692 effect on ozone depletion, 17 785 mechanism of action in muscle cells, 5 109, 112-113 oxidation of, 17 181 in photochemical smog, 1 789, 790 reduction with catalytic aerogels, l 763t, 764... 

Glutamine synthetase, a brain Mn enzyme, is located mainly in astrocytes, and its synthesis may be modulated by nitric oxide (496). Inhibition of this enzyme could be relevant to aging diseases (497). There is evidence that human NT2-N neurons die via ionotropic glutamate receptor-mediated mechanisms when exposed to hypoxia in the presence of glutamate (498). 

Penile erection occurs by relaxation of the smooth muscle of the corpus cavernosum, increasing blood flow into the penis and producing erection and rigidity. In a parallel fashion, vaginal pressure stimulation increases blood velocity and flow into clitoral arteries (Lavoisier et al. 1995). Cavernosal vasodilation is accomplished by neurotransmitters released from the cavernosal nerve and endothelial cells. One of the most important transmitters in this cascade is nitric oxide (NO), which induces synthesis of cyclic GMP from guanylate cyclase (Rajfer et al. 1992). Thus, ginkgo s vascular mechanisms could be responsible for some of the putative sexual effects. 

There are several mechanisms whereby antidepressants can modify intracellular events that occur proximal to the posts)maptic receptor sites. Most attention has been paid to the actions of antidepressants on those pathways that are controlled by receptor-coupled second messengers (such as cyclic AMP, inositol triphosphate, nitric oxide and calcium binding). However, it is also possible that chronic antidepressant treatment may affect those pathways that involve receptor interactions with protein tyrosine kinases, by increasing specific growth factor synthesis or by regulating the activity of proinflammatory cytokines. These pathways are particularly important because they control many aspects of neuronal function that ultimately underlie the ability of the brain to adapt and respond to pharmacological and environmental stimuli. One mechanism whereby antidepressants could increase the s)mthesis of trophic factors is... 

Silylated triphosphanes and triphosphides, synthesis, 31 188-194 yields, 31 194 Silylenes, 29 2-6 addition reactions, 29 4-6 to butadiene, 29 4 to ethylene, 29 4 to hexadienes, 29 5 mechanism, 29 4 nitric oxide scavenging, 29 4 complexes, 25 37, 51, 116, 118 as catalyst intermediates, 25 118 extrusion from disilanes, 25 114, 118 halides, 3 225 from hydridosilanes, 25 14 insertion into element-hydrogen bonds, 29 3-4... 

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