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-Arginine Depletion in Preeclampsia Orients Nitric Oxide Synthase Toward Oxidant Species
Abstract-Less nitric oxide (NO)-dependent vasodilation and excess formation of reactive oxygen species could explain poor placenta perfusion in preeclampsia, but the pathways involved are unknown. We tested the hypothesis that reduced NO activity and increased oxidative stress in preeclamptic placenta is related to a low bioavailability of L-arginine. Placental endothelial NO synthase (ecNOS) expression (by immunoperoxidase) and activity (by diaphorase and [ 3 H]L-citrulline formation) were comparable in normotensive pregnancy and in preeclampsia, whereas nitrotyrosine staining, a marker of peroxynitrite, was stronger in preeclamptic villi, confirming previously reported data. Oxidative tissue damage was documented in preeclamptic villi by strong 4-hydroxynonenal-lysine staining (by immunoperoxidase), which closely colocalized with nitrotyrosine. Concentration of the NO precursor L-arginine (by HPLC) in umbilical blood and in villous tissue was lower in preeclampsia than in normotensive pregnancy. This was not caused by a defective L-arginine transport, because gene expression of the CAT-1, 4F2hc, and LAT-1 cationic amino acid transporters (by real-time reverse-transcription polymerase chain reaction [RT-PCR]) was normal. Instead, gene expression (by real-time RT-PCR) and protein tissue content (by immunoperoxidase and Western blot) of arginase II-the enzyme that degrades arginine to ornithine-were higher in preeclamptic villi than in normotensive pregnancy. These results provide a biochemical explanation for defective NO activity and increased oxidative stress in preeclamptic placenta. In normal placenta, adequate concentration of L-arginine orients ecNOS toward NO. In preeclampsia, a lower than normal L-arginine concentration caused by arginase II overexpression redirects ecNOS toward peroxynitrite. Key Words: arginine Ⅲ nitric oxide synthase Ⅲ nitrites Ⅲ oxidative stress Ⅲ preeclampsia I n the past few years, evidence has accumulated suggesting that nitric oxide (NO), a potent endothelial-derived vasodilator, might be implicated in gestational vasodilation. 1,2 NO is synthesized from the amino acid L-arginine by a family of enzymes, the NO synthases (NOS). 3 While human placenta does not form inducible NOS (iNOS) or neuronal NOS (nNOS) mRNAs and proteins, 1 the endothelial isoform of NOS (ecNOS) is actually detectable in healthy placenta and is localized to the endothelium of the umbilical cord, chorionic plate, and stem villous vessels. 1 Conceivably, locally formed NO serves to maintain low vascular resistance besides attenuating the action of vasoconstrictors. 1 Besides, ecNOS is localized in villous cytotrophoblasts, 1,4 the specialized epithelial cells that aggregate into cell columns and invade the uterine interstitium and vasculature, anchoring the fetus to the mother and establishing blood flow to the placenta. 5 By virtue of its unique angiogenic/vasculogenic properties, 6,7 locally generated NO may be instrumental to promote this cytotrophoblast endovascular invasion that is an essential feature o...
Attenuation of chronic neuroinflammation by a nitric oxide‐releasing derivative of the antioxidant ferulic acid
Chronic neuroinflammation and oxidative stress contribute to the neurodegeneration associated with Alzheimer's disease and represent targets for therapy. Ferulic acid is a natural compound that expresses antioxidant and anti-inflammatory activities. Nitric oxide is also a key modulator of inflammatory responses. Grafting a nitric oxide-releasing moiety onto antiinflammatory drugs results in enhanced anti-inflammatory activity. We compared the effectiveness of ferulic acid with a novel nitric oxide-releasing derivative of ferulic acid in an animal model of chronic neuroinflammation that reproduces many interesting features of Alzheimer's disease. Lipopolysaccharide was infused into the 4th ventricle of young rats for 14 days. Various doses of ferulic acid or its nitric oxidereleasing derivative were administered daily. Both drugs produced a dose-dependent reduction in microglia activation within the temporal lobe. However, the nitric oxide-releasing ferulic acid derivative was significantly more potent. If we delayed the initiation of therapy for 14 days, we found no reduction in microglial activation. In addition, both drugs demonstrated antioxidant and hydroxyl radical scavenging abilities in in vitro studies. Overall, our results predict that a treatment using nitric oxide-releasing ferulic acid may attenuate the processes that drive the pathology associated with Alzheimer's disease if the treatment is initiated before the neuroinflammatory processes can develop.
In Vitro Metabolism of (Nitrooxy)butyl Ester Nitric Oxide-Releasing Compounds: Comparison with Glyceryl Trinitrate
We investigated the in vitro metabolism of two (nitrooxy)butyl ester nitric oxide (NO) donor derivatives of flurbiprofen and ferulic acid, [1,1Ј-biphenyl]-4-acetic acid-2-fluoro-␣-methyl-4-(nitrooxy)butyl ester (HCT 1026) and 3-(4-hydroxy-3-methoxyphenyl)-2-propenoic acid 4-(nitrooxy)butyl ester (NCX 2057), respectively, in rat blood plasma and liver subcellular fractions compared with (nitrooxy)butyl alcohol (NOBA) and glyceryl trinitrate (GTN). HCT 1026 and NCX 2057 undergo rapid ubiquitous carboxyl ester hydrolysis to their respective parent compounds and NOBA. The nitrate moiety of this latter is subsequently metabolized to inorganic nitrogen oxides (NOx), predominantly in liver cytosol by glutathione S-transferase (GST) and to a lesser extent in liver mitochondria. If, however, in liver cytosol, the carboxyl ester hydrolysis is prevented by an esterase inhibitor, the metabolism at the nitrate moiety level does not occur.In blood plasma, HCT 1026 and NCX 2057 are not metabolized to NOx, whereas a slow but sustained NO generation in deoxygenated whole blood as detected by electron paramagnetic resonance indicates the involvement of erythrocytes in the bioactivation of these compounds. Differently from NOBA, GTN is also metabolized in blood plasma and more quickly metabolized by different GST isoforms in liver cytosol. The cytosolic GST-mediated denitration of these organic nitrates in liver limits their interaction with other intracellular compartments to possible generation of NO and/or their subsequent availability and bioactivation in the systemic circulation and extrahepatic tissues. We show the possibility of modulating the activity of hepatic cytosolic enzymes involved in the metabolism of (nitrooxy)butyl ester compounds, thus increasing the therapeutic potential of this class of compounds.The therapeutic potential of organic nitrates has been known for more than 120 years since the use of glyceryl trinitrate (GTN) in the treatment of angina pectoris. Moreover, the pharmaceutical development of organic nitrates containing adjunct pharmacophores was reported over 40 years ago, and these were observed to manifest biological properties beyond those of the parent compound (Hodosan et al., 1969). However, there has been an explosion of activity in the area of hybrid nitrates over the past decade, stimulated by a growing realization that nitrates may represent new therapeutic agents in different areas (Keeble and Moore, 2002). Despite this, the metabolism of several organic nitrates is still to be elucidated. The exact mechanism whereby nitric oxide (NO) is generated from organic nitrates is still unknown, and several mechanisms have been proposed and rejected. Although nonenzymatic pathways involving endogenous sulfhydryl groups (Ignarro et al., 1980) or hemoglobin (Bennett et al., 1986;Cosby et al., 2003) have been suggested to mediate the biotransformation to NO, the attention has also shifted to an enzyme-catalyzed mechanism (Needleman, 1976). Several enzymes have been proposed to be directly or i...
Direct and Irreversible Inhibition of Cyclooxygenase-1 by Nitroaspirin (NCX 4016)
Benzoic acid, 2-(acetyl-oxy)-3-[(nitrooxy)methyl]phenyl ester (NCX 4016), a new drug made by an aspirin molecule linked, through a spacer, to a nitric oxide (NO)-donating moiety, is now under clinical testing for the treatment of atherothrombotic conditions. Aspirin exerts its antithrombotic activity by irreversibly inactivating platelet cyclooxygenase (COX)-1. NCX 4016 in vivo undergoes metabolism into deacetylated and/or denitrated metabolites, and it is not known whether NCX 4016 needs to liberate aspirin to inhibit COX-1, or whether it can block it as a whole molecule. The aim of our study was to evaluate the effects of NCX 4016 and its analog or metabolites on platelet COX-1 and whole blood COX-2 and on purified ovine COX (oCOX)-1 and oCOX-2. In particular, we have compared the mechanism by which NCX 4016 inhibits purified oCOX enzymes with that of aspirin using a spectrophotometric assay. All the NCX 4016 derivatives containing acetylsalicylic acid inhibited the activity of oCOX-1 and oCOX-2, whereas the deacetylated metabolites and the nitric oxide-donating moiety were inactive. Dialysis experiments showed that oCOX-1 inhibition by NCX 4016, similar to aspirin, is irreversible. Reversible COX inhibitors (indomethacin) or salicylic acid incubated with the enzyme before NCX 4016 prevent the irreversible inhibition of oCOX-1 by NCX 4016 as well as by aspirin. In conclusion, our data show that NCX 4016 acts as a direct and irreversible inhibitor of COX-1 and that the presence of a spacer and NO-donating moiety in the molecule slows the kinetics of COX-1 inhibition by NCX 4016, compared with aspirin.
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