The generation of nitric oxide and carbon monoxide produces opposite effects on the release of immunoreactive interleukin-1beta from the rat hypothalamus in vitro: evidence for the involvement of different signaling pathways

Both the cytokine, interleukin-1 (IL-1), and the gaseous neurotransmitters, nitric oxide (NO) and carbon monoxide (CO), have been implicated in the control of neuroendocrine functions, such as the release of CRH and luteotropic hormone-releasing hormone from the hypothalamus. Though increased levels of IL-1 in this brain region are unambiguously associated with enhanced CRH and reduced luteotropic hormone-releasing hormone release, the net effects of the two gases are still unclear, but in vivo and in vitro evidence suggests that the generation of NO and CO within the hypothalamus might counteract the stimulatory effects of IL-1 and bacterial lipopolysaccharide on the neuroendocrine stress axis. In this study, we have investigated the effects of NO and CO on the release of immunoreactive (ir)-IL-1beta from the rat hypothalamus in vitro. It was observed that the NO donor, sodium nitroprusside (SNP), stimulates ir-IL-1beta release under basal conditions, whereas the increase in CO levels obtained with hemin, the CO precursor through the heme oxygenase pathway, has no effect on basal ir-IL-1beta release but inhibits release stimulated by high K+ concentrations. The opposite effects of the two gases on cytokine release seemed to be caused by the activation of different signaling pathways, because: 1) SNP, but not CO-saturated solutions, is able to increase cyclic GMP levels in hypothalamic tissue; 2) CO-saturated solutions increase PGE2 production and release from the hypothalamic explants, whereas SNP has no effect; 3) SNP-stimulated ir-IL-1beta release is counteracted by a selective inhibitor of soluble guanylyl cyclase, LY 83583, but not by a cyclooxygenase inhibitor, indomethacin; and 4) conversely, indomethacin, but not LY 83583, reverses the inhibitory effect of hemin on K+-stimulated ir-IL-1beta release. It is concluded that NO and CO signal in the rat hypothalamus via the activation of soluble guanylyl cyclase and cyclooxygenase, respectively.     

Heme oxygenase: the physiological role of one of its metabolites, carbon monoxide and interactions with zinc protoporphyrin, cobalt protoporphyrin and other metalloporphyrins

In 1991, we postulated that carbon monoxide, which is formed endogenously from heme catabolism catalyzed by heme oxygenase and shares some of the chemical and biological properties of nitric oxide, may play a role similar to that of nitric oxide as a widespread signal transduction mechanism for the regulation of cell function and communication. We review the experimental evidence that tests this postulate. Carbon monoxide appears to be involved in the neurophysiological phenomenon of long-term potentiation, which appears to play a key role in memory and learning. Zinc protoporphyrin, an inhibitor of heme oxygenase, prevents induction of long-term potentiation. Zinc protoporphyrin is an endogenous substance, the levels of which are increased in iron deficiency states and in lead poisoning, and by inhibiting heme oxygenase may modulate long-term potentiation and memory. It has been shown that, when cobalt protoporphyrin is injected into the medial nuclei of the rat hypothalamus, weight loss occurs. These nuclei contain heme oxygenase, and we postulate that weight loss is due to cobalt protoporphyrin induction of heme oxygenase and increased formation of carbon monoxide, which serves as a signal transduction mechanism in the medial hypothalamus to suppress appetite.     

Heme and the endothelium. Effects of nitric oxide on catalytic iron and heme degradation by heme oxygenase

We studied the effects of nitric oxide (NO) on the control of excess cellular heme and release of catalytically active iron. Endothelial cells (ECs) exposed to hemin followed by a NO donor have a ferritin content that is 16% that of cells exposed to hemin alone. Hemin-treated ECs experience a 3.5-fold rise in non-heme, catalytic iron 2 h later, but a hemin rechallenge 20 h later results in only a 24% increase. The addition of a NO donor after the first hemin exposure prevents this adaptive response, presumably due to effects on ferritin synthesis. NO donors were found to reduce iron release from hemin, while hemin accumulated in cells. A NO donor, in a dose-dependent fashion, inhibited heme oxygenase activity, measured by bilirubin production. Using low temperature EPR spectroscopy, heme oxygenase inhibition correlated with nitrosylation of free heme in microsomes. Nitrosylation of cellular heme prevented iron release, for while there was heme oxygenase-dependent release of iron in cells incubated with hemin for 24 h, the addition of a NO donor blocked iron release. This indicates that NO readily nitrosylates intracellular free heme and prevents its degradation by heme oxygenase. Nitrosylation of heme was found to reduce sensitization of cells to oxidative injury.     

Carbon monoxide regulates cerebral blood flow in epileptic seizures but not in hypercapnia

Carbon monoxide (CO) is an endogenously produced gas sharing many properties with nitric oxide (NO), notably activating soluble guanylate cyclase and relaxing blood vessels. The brain can generate high quantities of CO from a constitutive enzyme, haem oxygenase (HO-2). To determine whether CO is involved in the regulatory mechanisms of cerebral blood flow (CBF), two conditions associated with a reproducible CBF increase were studied in rats: epileptic seizures induced by kainate, and hypercapnia. The HO inhibitor tin protoporphyrin (Sn-PP) did not modify the basal level of CBF, significantly reduced the increase in CBF during status epilepticus, and did not affect the cerebrovascular response to hypercapnia. It is concluded that CO participates in the regulation of CBF in specific conditions, notably those associated with glutamate release.     

Gaseous transmitters and neuroendocrine regulation

Recent work has demonstrated that the brain has the capacity to synthesize impressive amounts of the gases nitric oxide (NO) and carbon monoxide (CO). There is growing evidence that these gaseous molecules function as novel neural messengers in the brain. This article reviews the pertinent literature concerning the putative role of NO and CO as critical neurotransmitters and biological mediators of the neuroendocrine axis. Abundant evidence is presented which suggests that NO has an important role in the control of reproduction due to its ability to control GnRH secretion from the hypothalamus. NO potently stimulates GnRH secretion and also appears to mediate the action of one of the major transmitters controlling GnRH secretion, glutamate. Evidence is presented which suggests that NO stimulates GnRH release due to its ability to modulate the heme-containing enzyme, guanylate cyclase, which leads to enhanced production of the second messenger molecule, cGMP. A physiological role for NO in the preovulatory LH surge was also evidenced by findings that inhibitors and antisense oligonucleotides to nitric oxide synthase (NOS) attenuate the steroid-induced and preovulatory LH surge. CO may also play a role in stimulating GnRH secretion as heme molecules stimulate GnRH release in vitro, an effect which requires heme oxygenase activity and is blocked by the gaseous scavenger molecule, hemoglobin. Evidence is also reviewed which suggests that NO acts to restrain the hypothalamic-pituitary-adrenal (HPA) axis, as it inhibits HPA stimulation by various stimulants such as interleukin-1 beta, vasopressin, and inflammation. This effect fits a proinflammatory role of NO as it leads to suppression of the release of the anti-inflammatory corticosteroids from the adrenal. Although not as intensely studied as NO, CO has been shown to suppress stimulated CRH release and may also function to restrain the HPA axis. Evidence implicating NO in the control of prolactin and growth hormone secretion is also reviewed and discussed, as is the possible role of NO acting directly at the anterior pituitary. Taken as a whole, the current data suggest that the diffusible gases, NO and CO, act as novel transmitters in the neuroendocrine axis and mediate a variety of important neuroendocrine functions.     

Role of nitric oxide and carbon monoxide in modulating the ACTH response to immune and nonimmune signals

The role played by nitric oxide (NO) and carbon monoxide (CO) was explored in the adult male rat by determining whether antagonizing the activity of the enzymes responsible for the formation of these gases altered the response of the hypothalamic-pituitary-adrenal (HPA) axis to immune (cytokines) or nonimmune (mild electroshocks) signals. The arginine derivative Nomeganitro-L-arginine-methylester (L-NAME), which inhibits all three NO synthase (NOS) isoforms [inducible (i), endothelial (e) and neuronal (n)] significantly augments the ACTH response to blood-borne cytokines, but decreases it in rats exposed to shocks or other physico-emotional stresses. The effect of L-NAME in both models is mimicked by L-nitroarginine (L-NNA) and L-nitromethylarginine (L-NMMA), which block constitutive (e and n) forms of NOS, but not by aminoguanidine (which blocks iNOS) or 7-nitroindazole (which specifically blocks nNOS). Despite the ability of L-NAME to markedly augment the stimulatory effect of vasopressin on ACTH secretion, removal of this peptide does not interfere with the interaction between L-NAME and systemically administered interleukin-1beta (IL-1beta). In contrast, blockade of prostaglandin formation prevents both the stimulatory effect of IL-1beta on ACTH release, and its potentiation by L-NAME. In contrast to the investigation of the importance of endogenous NO, studies focused on the role of CO remain scarce. Our preliminary results suggest that while blockade of the formation of this gas decreases the ACTH response to various stimuli, it also significantly interferes with the effect of L-NAME in rats systemically administered cytokines, and further decreases the ACTH response to shocks in animals also injected with arginine analogs. These results indicate the possible presence of functional interactions between NO and CO in regulating the activity of the HPA axis. Our present working hypothesis is that in the presence of elevated circulating cytokine levels, endogenous NO acts presynaptically to inhibit the release of ACTH secretagogues from nerve terminals in the infundibulum. As the acute ACTH response to these immune proteins is believed to primarily depend on events taking place within the median eminence, blockade of NO formation results in exaggerated ACTH release. During exposure to shocks and other nonimmune stresses, on the other hand, increased ACTH secretion is primarily due to activation of hypothalamic neurons. In this case, because of the stimulatory influence of endogenous NO on hypothalamic perikarya that manufacture corticotropin-releasing factor (CRF) and/or of the afferents to these neurons, blockade of NOS activity blunts CRF production, and consequently ACTH release. What remains undetermined is the net effect of the opposite influences of NO during long-term exposure to immune or nonimmune stress. Finally, it is possible that the conflicting results reported by investigators who study the role of NO and CO in isolated cell preparations may reflect, at least in part, these opposite effects of NO on different elements of the HPA axis.     

A sensitive microassay reveals marked regional differences in the capacity of rat brain to generate carbon monoxide

Heme oxygenase activity is the sole known physiological source for the production of carbon monoxide (CO), a gaseous messenger candidate. A sensitive radioenzymatic microassay was validated to study regional distribution of heme oxygenase activity within the rat brain. The assay utilized a 14,000 X g supernatant of brain homogenate and [14C]heme as the substrate. Thin layer chromatography revealed that incubation of cerebellar supernatant with (14C]heme yielded a single reaction product, indistinguishable from bilirubin, that was selectively extracted into toluene. Radioactivity in toluene increased linearly in respect to time and added protein, was totally dependent on NADPH and was not detected with boiled homogenate. The reaction was dose-dependently inhibited by Zn-protoporphyrin IX (IC50 0.3 microM) and by an antibody generated against rat NADPH-cytochrome P450 reductase indicating specific involvement of heme oxygenase. As little as 36 fmol [14C]bilirubin/min could be readily detected requiring only microgram-quantities of cerebellar homogenate. Heme oxygenase activity measurements from discrete brain regions revealed for the first time marked differences in enzyme activity with the increasing order: frontal cortex < cerebellum = caudate-putamen < hippocampus = hypothalamus = colliculi < trapezoid body. This activity pattern closely reflects the distribution of immunoreactivity and mRNA for heme oxygenase. The present microassay should offer a valuable tool for studies directly assessing a possible role for CO in neural signaling.     

Heme oxygenase-1-derived carbon monoxide contributes to the suppression of acute hypertensive responses in vivo

The enzyme heme oxygenase, which exists in inducible (HO-1) and constitutive (HO-2) isoforms, catalyzes the degradation of heme to biliverdin and CO in mammalian tissues. CO has been implicated in the control of vascular tone in a manner similar to that for NO. In the present study, we investigated the contribution of the heme oxygenase/CO pathway to the modulation of acute hypertensive responses in vivo induced by (1) alphaalphaHb, a chemically modified hemoglobin known to scavenge NO, and (2) NG-nitro-L-arginine methyl ester (L-NAME), a competitive NOS inhibitor. Experiments were carried out in conscious rats in which femoral arteries and veins were surgically catheterized 1 or 5 days before treatment with the vasoconstrictor agents. Intravenous infusion of alphaalphaHb (8% solution) or L-NAME (30 micromol/kg) [corrected] produced an acute and significant increase in mean arterial pressure (P<0.05) in rats at 5 days after catheter implantation. In contrast, no change in blood pressure was observed when alphaalphaHb or L-NAME was infused 1 day after the surgical intervention. The suppression of the hypertensive response observed at 1 day after surgery correlated with a significant (P<0.05) HO-1 expression in aorta, heart, and liver as well as increased aortic CO production and cGMP levels. At 1 day after surgery, pretreatment of animals with the heme oxygenase inhibitor zinc protoporphyrin IX (50 micromol/kg IP) markedly decreased aortic CO and cGMP levels and completely restored the vasoconstrictor effects of both alphaalphaHb and L-NAME. These results provide evidence for a crucial role of the heme oxygenase/CO pathway in the regulation of blood pressure under stress conditions in vivo.     

The oxygen and carbon monoxide reactions of heme oxygenase

The O2 and CO reactions with the heme, alpha-hydroxyheme, and verdoheme complexes of heme oxygenase have been studied. The heme complexes of heme oxygenase isoforms-1 and -2 have similar O2 and CO binding properties. The O2 affinities are very high, KO2 = 30-80 microM-1, which is 30-90-fold greater than those of mammalian myoglobins. The O2 association rate constants are similar to those for myoglobins (kO2' = 7-20 microM-1 s-1), whereas the O2 dissociation rates are remarkably slow (kO2 = 0.25 s-1), implying the presence of very favorable interactions between bound O2 and protein residues in the heme pocket. The CO affinities estimated for both isoforms are only 1-6-fold higher than the corresponding O2 affinities. Thus, heme oxygenase discriminates much more strongly against CO binding than either myoglobin or hemoglobin. The CO binding reactions with the ferrous alpha-hydroxyheme complex are similar to those of the protoheme complex, and hydroxylation at the alpha-meso position does not appear to affect the reactivity of the iron atom. In contrast, the CO affinities of the verdoheme complexes are >10,000 times weaker than those of the heme complexes because of a 100-fold slower association rate constant (kCO' approximately 0. 004 microM-1 s-1) and a 300-fold greater dissociation rate constant (kCO approximately 3 s-1) compared with the corresponding rate constants of the protoheme and alpha-hydroxyheme complexes. The positive charge on the verdoporphyrin ring causes a large decrease in reactivity of the iron.     

Differential regulation of hepatic arterial and portal venous vascular resistance by nitric oxide and carbon monoxide in rats

Nitric oxide (NO), a gaseous mediator that accounts for the biological activity of endothelium-derived relaxing factor, has been shown to play an important role in the reduction of basal vascular tone in multiple vascular beds, including the hepatic circulation. On the other hand, recent studies have provided first evidence that endogenously generated carbon monoxide (CO) may exert vasodilatory effects in the hepatic portal vein and within sinusoids. Thus, we defined the differential role of NO and CO in the regulation of vascular resistance in the two inflows to the liver in the normal rat in vivo. Male Sprague-Dawley rats were anesthetized with pentobarbital sodium and surgically instrumented in order to study the change in hepatic arterial (Rha) and portal venous vascular resistance (Rpv) in response to intravenous bolus administration of either the NO-synthase inhibitor N(omega)-nitro-L-arginine methyl ester (L-NAME) (1 mg/kg; n = 7 animals) or of tin protoporphyrin-IX (SnPP-IX) (50 micromol/kg), a specific inhibitor of the CO-generating enzyme heme oxygenase (n = 8 animals). While L-NAME caused a substantial increase in Rha, Rpv increased only slightly under these conditions. In sharp contrast, SnPP-IX did not affect Rha, but caused a profound increase in Rpv. In conclusion, Rha and Rpv are differentially regulated by NO and CO in the normal rat liver in vivo, i.e., NO serves as a potent vasodilator in the hepatic arterial circulation, but exerts only a minor vasodilatory effect in the portal venous vascular bed. In contrast, while there is no intrinsic CO-mediated vasodilation in the hepatic artery, CO acts to maintain portal venous vascular tone in a relaxed state.     

Thiol compounds interact with nitric oxide in regulating heme oxygenase-1 induction in endothelial cells. Involvement of superoxide and peroxynitrite anions

Thiols are very important antioxidants that protect cells against oxidative insults. Recently, a different and new physiological role has been defined for these compounds because of their involvement in nitric oxide (NO) binding and transport in biological systems. In view of these characteristics, we examined the effect of thiols and NO on the expression of the inducible form of heme oxygenase (HO-1), a stress protein that degrades heme to carbon monoxide and biliverdin. Cultured bovine aortic endothelial cells exposed to the NO donors sodium nitroprusside (SNP) and S-nitroso-N-acetylpenicillamine (SNAP) resulted in increased heme oxygenase activity and HO-1 expression. Co-incubation with N-acetylcysteine, a precursor of glutathione synthesis, significantly attenuated heme oxygenase induction by SNP and SNAP, and a reduction in heme oxygenase activity was also observed when cells were preincubated with N-acetylcysteine for 16 h prior to exposure to NO donors. This effect appears to be associated with NO stabilization by thiols through the formation of S-nitrosothiols. Hydroxocobalamin, a specific NO scavenger, significantly decreased endothelial heme oxygenase activity, indicating a direct involvement of NO released by NO donors to regulate the expression of this stress protein. Moreover, superoxide anion (O-2) and its reaction product with NO, peroxynitrite (ONOO-), were found to partially contribute to the observed NO-mediated activation of endothelial heme oxygenase. Thus, we suggest the existence of a dynamic equilibrium among free NO, O-2, and endogenous glutathione, which might constitute an interactive signaling mechanism modulating stress and adaptive responses in tissues.     

Estradiol coupling to endothelial nitric oxide stimulates gonadotropin-releasing hormone release from rat median eminence via a membrane receptor

The median eminence (ME), which is the common termination field for adenohypophysiotropic systems, has been shown to produce nitric oxide (NO), a signaling molecule involved in neuroendocrine secretion. Using an ex vivo technique, 17beta-estradiol exposure to ME fragments, including vascular tissues, stimulated NO release within seconds in a concentration-dependent manner, whereas 17alpha-estradiol or testosterone had no effect. 17Beta-estradiol conjugated to BSA (E2-BSA) also stimulated NO release, suggesting mediation by a membrane surface receptor. Tamoxifen, an estrogen receptor inhibitor, antagonized the action of both 17beta-estradiol and E2-BSA. Furthermore, estradiol-stimulated NO stimulates GnRH release. This was demonstrated by hemoglobin (a NO scavenger), N(omega)-nitro-L-arginine methyl ester, and L-N5-(1-iminoethyl)ornithine (nitric oxide synthase inhibitors) inhibition of estradiol stimulated NO and GnRH release. In this regard, L-N5-(1-iminoethyl)ornithine, specific for endotheliol constitutive nitric oxide synthase, was significantly more potent, suggesting that the estradiol-stimulated NO release arose from vascular endothelial cells. Additionally, the NO-stimulated GnRH release occurs via guanylyl cyclase activation in GnRH nerve terminals, as ODQ, a potent and selective inhibitor of NO-sensitive guanylyl cyclase, abolished the estradiol-stimulated GnRH release. The results suggest that at physiological concentrations, 17beta-estradiol may have immediate actions on ME endothelial cells via nongenomic signaling pathways leading to NO-stimulated GnRH release.     

Role of endogenous carbon monoxide in central regulation of arterial pressure

We investigated the contribution of neural mechanisms to the arterial pressure increase produced by zinc deuteroporphyrin 2,4-bis glycol (ZnDPBG), an inhibitor of endogenous carbon monoxide synthesis. The arterial baroreceptor reflex control of heart rate was examined in rats with and without ZnDPBG pretreatment (45 micromol/kg IP) by analysis of the arterial pressure-heart rate relationship during infusions of phenylephrine or sodium nitroprusside to vary arterial pressure. ZnDPBG increased arterial pressure from 110 +/- 3 to 126 +/- 2 mm Hg without eliciting bradycardia. The maximum gain of the heart rate response to changes in arterial pressure was attenuated by ZnDPBG treatment (-1.9 +/- 0.3 versus -4.8 +/- 1.0 bpm/mm Hg). The possibility that ZnDPBG elevates arterial pressure by attenuating baroreceptor reflex function was addressed by comparing the pressor response to ZnDPBG (45 micromol/kg IP) in rats with and without sinoaortic denervation. The pressor effect of ZnDPBG was similar in rats with and without arterial baroreceptor deafferentation, implying that the increase in pressure is not simply the consequence of attenuated baroreceptor reflex function per se. The possibility that ZnDPBG increases arterial pressure via an effect on the nucleus tractus solitarii (NTS) also was investigated. ZnDPBG (1 nmol in 100 nL) injected into the NTS of rats increased arterial pressure from 111 +/- 4 to 126 +/- 5 mm Hg, and this effect was reversed by an ipsilateral microinjection of carbon monoxide into the NTS. Accordingly, the pressor effect of ZnDPBG may rely on inhibition of carbon monoxide production in the NTS. This implies that carbon monoxide formed by brain heme oxygenase plays a role in the central regulation of arterial pressure.     

Studies on hyperthermia combined with arterial blockade for treatment of tumors: (Part I) effectiveness of hyperthermia combined with arterial ligation

The role of nitric oxide (NO) in glucose-induced insulin secretion was studied in pancreatic beta-cells, HIT-T15. A role for NO is suggested since glucose stimulated NO production in a concentration-dependent manner. NG-monomethyl-L-arginine, a potent inhibitor of nitric oxide synthase, significantly inhibited glucose-induced nitric oxide production as well as insulin release in HIT-T15. Furthermore, this inhibitory effect can be reversed by sodium nitroprusside (SNP), a well known NO donor. While SNP alone did not stimulate insulin release, it potentiated the secretory response of HIT-T15 cells to glucose by approximately two-fold. Potentiation by SNP appears to be mediated by NO, since (i) the potentiation was completely abolished by 10 microM hemoglobin, a scavenger of NO; and (ii) was not affected by rhodanese plus sodium thiosulphate. Neither hemoglobin alone nor the combination of rhodanese and sodium thiosulphate had any effect on glucose induced insulin release. These results are consistent with the hypothesis that glucose-induced formation of NO may potentiate the effect of glucose by a positive feedback mechanism.     

Carbon monoxide, a novel neural messenger, does not modulate extracellular glutamate concentration in forebrain ischemia

We investigated the role of carbon monoxide as a neural modulator of extracellular glutamate concentration in rat hippocampus CA1 in transient forebrain ischemia by using metalloporphyrins, which block the production of carbon monoxide through the inhibition of heme oxygenase (HO) activity. Infusion of 10 and 100 microM zinc protoporphyrin IX, which inhibits nitric oxide synthase activity as well as HO activity, significantly increased glutamate concentration compared with that on the vehicle-treated side. However, infusion of 100 microM tin mesoporphyrin IX, which inhibits only HO activity, did not affect glutamate concentration in ischemia. Our results therefore do not support the hypothesis that carbon monoxide acts as a neural messenger through the modulation of extracellular glutamate concentration in ischemia.     

Carbon monoxide: an endogenous modulator of the nitric oxide-cyclic GMP signaling system

Carbon monoxide (CO) is an activator of soluble guanylyl cyclase and is implicated as a neuronal messenger. CO production, nitric oxide synthase (NOS) activity, and guanosine 3',5'-monophosphate (cGMP) levels were quantitated in cerebellar granule cell cultures. Metabolic labeling experiments enabled the direct measurement of neuronal CO production in vitro. CO production is significant, and peaked during early stages of culture. NOS activity and cGMP levels synchronously increased as cells matured. Whereas inhibition of NOS depleted cGMP in mature cultures, inhibitors of CO production potentiated the nitric oxide (NO)-mediated cGMP increase. Exogenous CO at similar concentrations to endogenous levels blocked the NO-mediated cGMP increase. These results directly demonstrate that endogenous neuronal CO production is high and indicate that while NO is the major regulator of cGMP in these neurons, CO may modulate the NO-cGMP signaling system.     

Verapamil SR/trandolapril combination therapy for the elderly hypertensive patient. German VeraTran Hypertension Study Group

There are conflicting reports in the literature concerning the neuroprotective effect of ascorbic acid on excitotoxic processes in which excessive glutamate release and nitric oxide are supposed to be major factors. To study the influence of ascorbate on the nitric oxide modulated glutamate release rat striatal slices, preloaded with the tritiated glutamate analog D-aspartate, were used. The high potassium-induced efflux of D-[3H]aspartate was concentration dependently stimulated by the nitric oxide donors sodium nitroprusside, S-nitroso-N-acetylpenicillamine (SNAP) or 5-amino 3-morpholinyl-1,2,3-oxadiazolium chloride (SIN-1), as well as by solutions of gaseous nitric oxide and, interestingly, by cyanide. Only the stimulation of D-[3H]aspartate release by SNAP and nitroprusside was affected by ascorbate in terms of a highly significant potentiation. Ascorbate was shown to exert its effect primarily by influencing the decomposition of these nitric oxide donors rather than by a direct interaction of ascorbate with nitric monoxide on glutamate release.