Nitric oxide synthase activities in human myometrium and villous trophoblast throughout pregnancy

OBJECTIVE: To study the changes in nitric oxide synthase activities in human myometrium and trophoblast throughout pregnancy and around delivery. METHODS: Samples of villous trophoblast were collected from women undergoing elective cesarean delivery at term (n = 12) or voluntary termination of pregnancy in the first (n = 27) or second (n = 11) trimesters of pregnancy. Myometrial samples were obtained from nonpregnant women undergoing hysterectomy (n = 5) and pregnant women both before (n = 7) and after (n = 7) the onset of spontaneous labor at term. Nitric oxide synthase activity was quantified for homogenized samples using the L-citrulline assay in the presence and absence of calcium. RESULTS: The highest levels of nitric oxide synthase activity were found in first-trimester villi (range 2-29 nmol L-citrulline/minute/g protein), with a significant fall in activity in the third trimester (range 2-10 nmol L-citrulline/minute/g protein; P < .001 for both calcium-dependent and calcium-independent activity). Myometrial activities were relatively low compared with those in the trophoblast (0-2 nmol L-citrulline/minute/g protein), with no significant differences in calcium-dependent activities between subgroups. Myometrial calcium-independent activities were lower in pregnant than in nonpregnant women (P = .007), with those in labor having levels higher than those not in labor (P = .048). CONCLUSION: Levels of nitric oxide synthase activity are relatively high in villous trophoblast, particularly during the first trimester. Although the contribution to total nitric oxide production in the uterus by myometrial nitric oxide synthase appears to be relatively small, nitric oxide produced by the trophoblast may play a role in maintaining uterine quiescence by a paracrine effect. Further work is needed to test this hypothesis and explore other possible roles for trophoblast-derived nitric oxide in early pregnancy.     

Nitric oxide

Nitric oxide (NO) is a gas with diverse biological activities produced from arginine by NO synthases. It is capable of interacting with a number of molecules, most notably superoxide, forming peroxynitrite, which, in turn, can mediate bactericidal or cytotoxic reactions. Nitric oxide also mediates smooth muscle relaxation, neurotransmission, and modulation of inflammation in a number of organ systems and pathophysiologic conditions. Modulation of NO by administration of inhaled NO for respiratory distress syndromes and infusion of NO synthase inhibitors in bacterial sepsis are ongoing. Levels of exhaled NO are being evaluated for their utility in assessing inflammation in respiratory disorders such as asthma.     

Nitric oxide and lipid peroxidation

Nitric oxide (NO) is a free radical produced enzymatically in biological systems from the guanidino group of L-arginine. Its large spectrum of biological effects is achieved through chemical interactions with different targets including oxygen (O2), superoxide (O2o-) and other oxygen reactive species (ROS), transition metals and thiols. Superoxide anions and other ROS have been reported to react with NO to produce peroxynitrite anions that can decompose to form nitrogen dioxide (NO2) and hydroxyl radial (OHo). Thus, NO has been reported to have a dual effect on lipid peroxidation (prooxidant via the peroxynitrite or antioxydant via the chelation of ROS). In the present study we have investigated in different models the in vitro and in vivo action of NO on lipid peroxidation. Copper-induced LDL oxidation were used as an in vitro model. Human LDL (100 micrograms ApoB/ml) were incubated in oxygene-saturated PBS buffer in presence or absence of Cu2+ (2.5 microM) with increasing concentrations of NO donnors (sodium nitroprussiate or nitroso-glutathione). LDL oxidation was monitored continuously for conjugated diene formation (234 nm) and 4-hydroxynonenal (HNE) accumulation. Exogenous NO prevents in a dose dependent manner the progress of copper-induced oxidation. Ischaemia-reperfusion injury (I/R), characterized by an overproduction of ROS, is used as an in vivo model. Anaesthetized rats were submitted to 1 hour renal ischaemia following by 2 hours of reperfusion. Sham-operated rats (SOP) were used as control. Lipid peroxidation was evaluated by measuring the HNE accumulated in rats kidneys in presence or absence of L-arginine or D-arginine infusion. L-arginine, but not D-arginine, enhances HNE accumulation in I/R but not in SOP (< 0.050 pmol/g tissue in SOP versus 0.6 nmol/g tissue in I/R), showing that, in this experimental conditions, NO produced from L-arginine, enhances the toxicity of ROS. This study shows that the pro- or antioxydant effects of NO are different in vivo and in vitro and could be driven by environmental conditions such as pH, relative concentrations of NO and ROS, ferryl species.     

Nitric oxide and radiation enteritis

Mice with mutations at the downless (dl) locus have defects in hair follicle, tooth, sweat gland, preputial gland, Meibomian gland, and tail development. The dl phenotype is analogous to the human genetic disorder termed autosomal hypohidrotic (or anhidrotic) ectodermal dysplasia (HED). On the basis of the identification of two related transgenic insertional mutations in the downless gene, yeast artificial chromosomes (YACs) were identified that map to the critical region of mouse Chromosome (Chr) 10. To determine which of the YACs contain the dl gene, we generated YAC transgenic mice by mouse embryo microinjections. The 200-kb YAC B25.D9 was found to rescue all of the downless defects. In addition, the transgenic YAC rescued the dominant Sleek (Dlslk) allele. Since the sequences within the YAC are entirely deleted in one of the transgenic mutants, our results establish that Sleek encodes a dominant-negative protein whose effects can be reversed by expression of extra copies of the wild-type locus.     

Nitric oxide in invertebrates

Nitric oxide (NO) is considered an important signaling molecule implied in different physiological processes, including nervous transmission, vascular regulation, immune defense, and in the pathogenesis of several diseases. The presence of NO is well demonstrated in all vertebrates. The recent data on the presence and roles of NO in the main invertebrate groups are reviewed here, showing the widespread diffusion of this signaling molecule throughout the animal kingdom, from higher invertebrates down to coelenterates and even to prokaryotic cells. In invertebrates, the main functional roles described for mammals have been demonstrated, whereas experimental evidence suggests the presence of new NOS isoforms different from those known for higher organisms. Noteworthy is the early appearance of NO throughout evolution and striking is the role played by the nitrergic pathway in the sensorial functions, from coelenterates up to mammals, mainly in olfactory-like systems. All literature data here reported suggest that future research on the biological roles of early signaling molecules in lower living forms could be important for the understanding of the nervous-system evolution.     

Nitric oxide and inflammatory bowel diseases

1. The present study was performed to investigate the effects of captopril on both dopaminergic and cholinergic neurotransmission in the rat central nervous system. 2. Slices of rat striatum were prepared and prelabelled with [3H]-dopamine or [3H]-choline. Slices were continuously superfused with Krebs'-Ringer solution and electrical stimulation (1 Hz) was performed. 3. Captopril significantly inhibited stimulation-evoked [3H]-dopamine release from rat striatal slices in a concentration-dependent manner (S2/S1 ratios: control 0.835 +/- 0.018 (n = 6); 1 x 10(-5) mol/L captopril 0.597 +/- 0.035 (n = 6; P < 0.05); 5 x 10(-5) mol/L captopril 0.561 +/- 0.041 (n = 6; P < 0.05)). However, the basal release of [3H]-dopamine was not affected by captopril. 4. Captopril also reduced stimulation-evoked [3H]-acetylcholine release in the striatum (S2/S1 ratios: control 0.891 +/- 0.016 (n = 6); 1 x 10(-5) mol/L captopril 0.794 +/- 0.011 (n = 6; P < 0.05)). 5. These results show that captopril inhibits the release of both dopamine and acetylcholine in the rat striatum. Although the mechanisms underlying the neurosuppressive effects of captopril remain to be determined, the findings suggest that the inhibition of dopaminergic and cholinergic neurotransmission may be related to the central action of the angiotensin-converting enzyme inhibitor.     

Nitric oxide and low-density lipoprotein oxidation

Immune status was determined in a representative sample of elderly people by measuring lymphocyte subsets in whole-blood samples as part of an epidemiological study of the population aged 65 and over. Venepuncture was undertaken in more than 500 individuals who took part in an extensive interview that focused on the lifestyle and psychosocial determinants of healthy aging. The results show that median levels of all lymphocyte subsets tend to decline as the age of the sample increases. In the total sample there were significant age effects (p < 0.05) on total lymphocytes, CD3, CD4, and CD19 (B cells); age differences did not reach significance for CD8 and CD57. There were also significant sex differences (p < 0.05) on CD3, CD4, and CD19, and in all cases women had higher values than men. When we selected a particularly healthy subsample who did not report any illness and took no medication, the findings were unchanged. We conclude that the peripheral expression of lymphocytes appears little affected by aging-related illnesses in the general population, but is affected by aging itself. The study provides reference values for the lymphocyte measures, which can be regarded as having greater validity than the values usually cited.     

Nitric oxide in learning and memory

The role of nitric oxide in the central nervous system is described. The main part of this article concerns the problem of learning and memory.     

Nitric oxide in vascular remodeling

Vascular remodeling is a series of structural changes in blood vessels. Therefore, it may be conceivable that any humoral factors and physical forces acting on the vascular wall are involved in the remodeling processes. Cells in the vascular wall respond to the humoral and physical factors and may induce extracellular matrix, cell adhesion molecules and other humoral factors. They even grow so that cellular and noncellular components deviate from the normal population. We discuss the relationship among nitric oxide (NO), pressure and growth of smooth muscles. Decreased NO may be a consequence as well as a cause of high pressure. Similarly, high pressure is a cause as well as a consequence of decreased NO. Remodeling could be a consequence of both high pressure and decreased NO. Thus, vascular remodeling is a complex dynamic state, where any causes and results are influenced by each other. Interaction of NO and pressure is one such complexity.     

Nitric oxide regulates wound healing

Nitric oxide (NO) synthesis occurs during wound healing, but its role has not been defined. To study the effect of NO on wound repair, S-methyl isothiouronium (MITU, a competitive inhibitor of NO synthase) was administered at a dose of 10, 50, and 100 mg/kg body weight/day, using intraperitoneally implanted miniosmotic pumps. Groups of 10 male Balb/C mice underwent a dorsal skin incision and polyvinyl alcohol sponges were inserted subcutaneously. The animals were sacrificed 10 days postwounding and wound breaking strength and hydroxyproline content of sponges, an index of reparative collagen deposition, were determined. Some sponges were used to harvest wound fluid and infiltrating cells, which were then incubated overnight with or without 1 mM MITU. Nitrite and nitrate, stable end products of NO, were measured in wound fluid and in wound cell culture supernatants. Continuous intraperitoneal infusion of MITU significantly decreased wound fluid nitrite/nitrate concentrations in a dose dependent manner (P < 0.01). Inhibition of wound NO synthesis by 100 mg MITU/kg/day was paralleled by lowered wound collagen accumulation (P < 0.01) and wound breaking strength (P < 0.01). In vitro NO synthesis by wound cells obtained from animals treated with 100 mg MITU/kg/day was not significantly different from controls (12.6 +/- 1.2 vs 10.7 +/- 0.6 nmole NO2 + NO3/microgram DNA), reflecting the reversible inhibition of NO synthase by MITU. However, NO production was equally inhibited in wound infiltrating cells by the in vitro addition of MITU (83% vs 85%, respectively). These data suggest that nitric oxide synthesis is critical to wound collagen accumulation and acquisition of mechanical strength.     

Nitric oxide in respiratory diseases

Recent reports have described a pathogenic role of nitric oxide in several respiratory disease. It is specially useful in the adult respiratory distress syndrome, where it acts as a selective vasodilator and improves gas exchange, decreasing pulmonary shunting. Although it has a proven bronchodilator effect, its therapeutic role in diseases such as asthma and chronic limitation of airway flow is not well defined. This article review the metabolism, mechanisms of action, potential uses and adverse effects of nitric oxide in respiratory disease.     

Nitric oxide and the non-adrenergic non-cholinergic neurotransmission

In the early 1960s, the first evidence was reported demonstrating neurally mediated responses in the presence of adrenergic and cholinergic antagonists, leading to the introduction of the concept of non-adrenergic non-cholinergic neurotransmission. The inhibitory component of this part of the autonomic nervous system has been illustrated in numerous organ systems mediating a wide range of physiological events. Since the discovery of these nerves, several substances have been proposed as putative neurotransmitter, with ATP and vasoactive intestinal polypeptide as main candidates. Finally, the ongoing research on the nature of the substance released by these nerves has generated the nitrergic theory proposing nitric oxide as putative neurotransmitter. By now, increasing evidence is reported to support the idea that inhibitory neurons release more neurotransmitters, interacting with each other at pre- and/or postsynaptic levels.     

Nitric oxide in renal health and disease

Nitric oxide (NO) is a labile radical gas that is widely acclaimed as one of the most important molecules in biology. Through covalent modifications of target proteins and redox reactions with oxygen and superoxide radical and transition metal prosthetic groups, NO plays a critical role in many vital biological processes, including the control of vascular tone, neurotransmission, ventilation, hormone secretion, inflammation, and immunity. Moreover, NO has been shown to influence a host of fundamental cellular functions, such as RNA synthesis, mitochondrial respiration, glycolysis, and iron metabolism. NO is formed from L-arginine by NO synthases (NOSs), a family of related enzymes encoded by separate unlinked genes. The different NOS isozymes exhibit disparate tissue and intrarenal distributions and are governed by unique regulatory mechanisms. In the kidney, NO participates in several vital processes, including the regulation of glomerular and medullary hemodynamics, the tubuloglomerular feedback response, renin release, and the extracellular fluid volume. While NO serves beneficial roles as a messenger and host defense molecule, excessive NO production can be cytotoxic, the result of NO's reaction with reactive oxygen and nitrogen species, leading to peroxynitrite anion formation, protein tyrosine nitration, and hydroxyl radical production. Indeed, NO may contribute to the evolution of several commonly encountered renal diseases, including immune-mediated glomerulonephritis, postischemic renal failure, radiocontrast nephropathy, obstructive nephropathy, and acute and chronic renal allograft rejection. Moreover, impaired NO production has been implicated in the pathogenesis of volume-dependent hypertension. This duality of NO's beneficial and detrimental effects has created extraordinary interest in this molecule and the need for a detailed understanding of NO biosynthesis.