Nitric oxide-induced vasodilation of organic nitrate-tolerant rabbit aorta

It is postulated that the organic nitrate vasodilator agents, including glyceryl trinitrate (GTN) and isosorbide dinitrate (ISDN), are prodrugs, such that biotransformation to the active inorganic metabolite, nitric oxide (NO), occurs prior to the onset of vasodilation. Furthermore, it is proposed that organic nitrate tolerance in vascular tissue involves decreased formation of NO. To test this latter hypothesis, we examined vasodilation induced by NO, GTN, and ISDN in non-tolerant, GTN-tolerant, and ISDN-tolerant rabbit aortic rings (RARs). Isolated RARs were contracted submaximally with phenylephrine; the time of onset of relaxation and percent relaxation of tissue were determined in response to NO (0.3 microM), GTN (0.03 microM), and ISDN (0.12 microM) before and after a 1-h treatment with 500 microM GTN, 500 microM ISDN, or buffer only. The data demonstrated that the response to NO was not changed in GTN-tolerant and ISDN-tolerant tissues, in which there was virtually no GTN-induced or ISDN-induced relaxation. These results are consistent with the postulate that organic nitrate vasodilator drugs must undergo biotransformation to NO before vasodilation can occur and that the mechanism of organic nitrate tolerance involves decreased formation of NO.     

Differential biotransformation of glyceryl trinitrate by red blood cell-supernatant fraction and pulmonary vein homogenate

We have demonstrated previously that glyceryl trinitrate (GTN) undergoes biotransformation to two glyceryl dinitrate (GDN) metabolites in the human red blood cell-supernatant fraction (RBC-SF) by hemoglobin-mediated and sulfhydryl-dependent enzymatic mechanisms. In the present study, we have shown that biotransformation of GTN in rabbit RBC-SF yields a glyceryl-1,2-dinitrate (1,2-GDN)/glyceryl-1,3-dinitrate (1,3-GDN) ratio of 5.3. Following inhibition of hemoglobin-mediated biotransformation of GTN by carbon monoxide (CO), the 1,2-GDN/1,3-GDN ratio was 2.1. Following inhibition of sulfhydryl-dependent biotransformation by N-ethylmaleimide (NEM), the 1,2-GDN/1,3-GDN ratio was 30.0. We have demonstrated previously that for GTN-induced vasodilation of isolated bovine pulmonary vein (BPV), the 1,2-GDN/1,3-GDN ratio was 7.1, which indicated that a hemoprotein-dependent process was involved in GTN biotransformation. To determine if this was the case, the biotransformation of GTN (0.51 microM) was studied in BPV homogenates; 31.1 pmol GDN/mg BPV protein was formed in 20 min. The 1,2-GDN/1,3-GDN ratio was 1.1, which indicated that hemoprotein-mediated biotransformation did not occur. This conclusion was supported by the fact that CO did not inhibit GTN biotransformation. GTN biotransformation by BPV homogenate was inhibited 62% by NEM, 89% by boiling of the homogenate, and almost completely by boiling plus NEM. These results indicated that biotransformation of GTN by the BPV homogenate involved in a combination of enzymatic and nonenzymatic processes that were mostly sulfhydryl dependent. It is concluded that the mechanism for GTN biotransformation in isolated intact BPV, which yielded preferential formation of 1,2-GDN, was rendered nonfunctional upon tissue homogenization.     

Cytochrome P-450 mediated biotransformation of organic nitrates

The vascular biotransformation of organic nitrates appears to be a prerequisite for their action as vasodilators. In the current study, we assessed the involvement of cytochrome P-450 in the denitration of glyceryl trinitrate and the enantiomers of isoidide dinitrate. Denitration of organic nitrates by the microsomal fraction of rat liver was NADPH dependent and followed apparent first-order kinetics. Under aerobic conditions, the t1/2 of D-isoidide dinitrate was significantly shorter than that of L-isoidide dinitrate (11.9 vs. 14.1 min, p less than or equal to 0.05), which is consistent with the greater potency of the D-enantiomer for vasodilation. Under anaerobic conditions, the denitration of glyceryl trinitrate was very rapid (t1/2 approximately 30 s). Organic nitrate biotransformation was inhibited by carbon monoxide, SKF 525A, and dioxygen. This suggests that the biotransformation of organic nitrates can occur through the direct interaction with the heme moiety of cytochrome P-450. The biotransformation of glyceryl trinitrate was catalyzed preferentially by those isoenzymes induced by phenobarbital. The biotransformation of glyceryl trinitrate was regioselective for 1,3-glyceryl dinitrate formation except in phenobarbital-induced microsomes under aerobic conditions, in which preferential formation of 1,2-glyceryl dinitrate occurred. These data suggest that cytochrome P-450 is involved in the biotransformation of organic nitrates and raises the possibility that vascular cytochrome P-450 may play a role in the mechanism-based biotransformation of organic nitrates, the result of which is vascular smooth muscle relaxation.     

Differential biotransformation of the enantiomers of isoidide dinitrate in isolated rat aorta

Previous studies have demonstrated that the D-enantiomer of isoidide dinitrate (IIDN) is 10-fold more potent than the L-enantiomer for relaxation and cyclic GMP accumulation in isolated rat aorta. To test whether preferential biotransformation of D-IIDN to a species that activates guanylate cyclase is the basis for this observed enantioselectivity, paired segments of rat aorta were exposed to D- and L-IIDN and the tissue accumulation of the parent compound and the formation of their respective metabolites (D- and L-isoidide mononitrate, IIMN) were determined. The extent of relaxation of rat aorta following exposure to 2 microM D-IIDN was greater than that by L-IIDN over a 5-minute time course, and this was associated with a higher rate of D-IIDN biotransformation to D-IIMN at all time points. In addition, the rate of D-IIDN biotransformation was greater than that of L-IIDN at most IIDN concentrations tested. By contrast, the amount of D- and L-IIDN in the tissue was the same at all time points and concentrations tested, indicating that selective uptake of D-IIDN into blood vessels did not occur. When tissues were made tolerant to organic nitrate-induced relaxation by treatment with a high concentration of glyceryl trinitrate, the biotransformation of both D- and L-IIDN was attenuated. This suggests that mechanism-based biotransformation may be affected during tolerance development. Furthermore, the association of preferential D-IIDN biotransformation with its greater potency for vasodilation and cyclic GMP accumulation suggests than an enantioselective site for biotransformation is an important component of organic nitrate-induced vasodilation.     

Biodegradation of glyceryl trinitrate by Penicillium corylophilum Dierckx.

Penicillium corylophilum Dierckx, isolated from a contaminated water wet, double-base propellant, was able to completely degrade glyceryl trinitrate (GTN) in a buffered medium (pH 7.0) containing glucose and ammonium nitrate. In the presence of 12 mg of initial fungal inoculum, GTN (48.5 to 61.6 mumol) was quantitatively transformed in a stepwise process to glyceryl dinitrate (GDN) and glyceryl mononitrate (GMN) within 48 h followed by a decrease in the GDN content with a concomitant increase in the GMN level. GDN was totally transformed to GMN within 168 h, and the complete degradation of GMN was achieved within 336 h. The presence of glucose and ammonium nitrate in the growth medium was essential for completion of the degradation of GTN and its metabolites. Complete degradation of GTN by a fungal culture has not been previously reported in the literature.     

YC-1 enhances the responsiveness of tolerant vascular smooth muscle to glyceryl trinitrate

A major limitation of the use of organic nitrates in cardiovascular medicine is the development of tolerance, which has been attributed, in part, to a decrease in their metabolic activation in the vascular smooth muscle cell. Recently, 3-(5'-hydroxymethyl-2'-furyl)-1-benzylindazole (YC-1) was shown to potentiate vascular smooth muscle responsiveness to glyceryl trinitrate (GTN), sodium nitroprusside, and the nitric oxide donor NOC 18, in organic nitrate-naive vascular smooth muscle. We used GTN-tolerant rabbit aortic rings (RARs) to test the hypothesis that a non-vasorelaxant concentration of YC-1 enhances the ability of the prototypical organic nitrate GTN to relax vascular smooth muscle and elevate intravascular cGMP under conditions of GTN tolerance. Treatment with YC-1 (3 microM) produced a left shift of the GTN concentration-response curve and decreased the EC50 value for GTN-induced relaxation in both GTN-tolerant and non-tolerant RARs (P < 0.05). Intravascular cGMP elevation induced by GTN was enhanced in the presence of YC-1 in GTN-tolerant and non-tolerant RARs (P < 0.05). These observations indicate that YC-1, or similarly acting drugs, may be useful in overcoming the tolerance that develops during sustained GTN therapy, and that its mechanism may involve enhanced cGMP formation.     

Patterns of isosorbide dinitrate and glyceryl trinitrate metabolites formed by selected segments of the rabbit gastrointestinal tract

Homogenates of selected segments of the rabbit gastrointestinal tract (GIT) were studied for their ability to biotransform isosorbide dinitrate (ISDN) and glyceryl trinitrate (GTN) to their mono- and di-nitrate metabolites, respectively. In addition, preferential formation of certain metabolites was investigated by examination of the patterns of metabolites formed by the various homogenates. After a 30-min incubation of ISDN with GIT homogenates (pH 7.4, 37 degrees C), the percent disappearance of ISDN and the ratio of isosorbide-2-mononitrate (2-ISMN) to isosorbide-5-mononitrate (5-ISMN) were as follows: stomach, 32%, 0.8; duodenum, 65%, 0.1; jejunum, 59%, 0.2; ileum, 38% , 1.2; cecum, 33%, 2.7; and colon, 32%, 3.4. After a 5-min incubation of GTN with GIT homogenates, the percent disappearance of GTN and the ratio of glyceryl-1,3-dinitrate (1,3-GDN) to glyceryl-1,2-dinitrate (1,2-GDN) were as follows: duodenum, 54%, 0.65; ileum, 73%, 0.68; and colon, 61%, 0.17. Incubation of 2 x 10(-7) M ISDN with mucosal and muscularis homogenates of duodenum, jejunum, and ileum resulted in significant losses of ISDN with an equimolar formation of the mononitrate metabolites. Most of the metabolic activity for ISDN resided in the mucosal layer of each section. The ratio of 2-ISMN to 5-ISMN varied in each section (stomach to colon) and cross section (mucosal versus muscularis) of the GIT. We conclude that the metabolism of ISDN and GTN by the GIT may contribute to the high clearance of these organic nitrates, and the low oral bioavailability of ISDN. Also, multiple mechanisms appear to be involved in the biotransformation of ISDN and GTN in the rabbit GIT.     

A comparative study of glyceryl trinitrate biotransformation and glyceryl trinitrate induced relaxation in bovine pulmonary artery and vein

Recent evidence supports the hypothesis that the mechanism by which glyceryl trinitrate induces relaxation of vascular smooth muscle involves the biotransformation of glyceryl trinitrate. This study was conducted to determine if there was a direct correlation between the capacity of vascular smooth muscle preparations to biotransform glyceryl trinitrate and their sensitivity to the relaxant effect of this organic nitrate. Isolated bovine pulmonary arteries and veins were contracted submaximally and cumulative dose-response relationships to glyceryl trinitrate were obtained; the vein was approximately 10 times more sensitive than the artery to glyceryl trinitrate induced relaxation. In a separate series of experiments, these vascular tissues were contracted submaximally and incubated with 0.5 microM [14C]glyceryl trinitrate for 2 min, during which glyceryl trinitrate induced relaxation was monitored. At 2 min, tissue samples were taken for determination of glyceryl trinitrate and glyceryl-1,2- and 1,3-dinitrate content by thin-layer chromatography and liquid scintillation spectrometry. Biotransformation of glyceryl trinitrate to glyceryl dinitrate occurred concomitantly with relaxation of these blood vessels. The concentration of glyceryl dinitrate in the vein was significantly less than that in the artery (p less than or equal to 0.05), even though significantly greater relaxation of the vein than the artery was observed (p less than or equal to 0.05). From these data, a simple linear relationship between glyceryl trinitrate biotransformation and relaxation is not apparent.     

Reduction of organic nitrates catalysed by xanthine oxidoreductase under anaerobic conditions.

Xanthine oxidoreductase catalyses the anaerobic reduction of glyceryl trinitrate (GTN), isosorbide dinitrate and isosorbide mononitrate to inorganic nitrite using xanthine or NADH as reducing substrates. Reduction rates are much faster with xanthine as reducing substrate than with NADH. In the presence of xanthine, urate is produced in essentially 1:1 stoichiometric ratio with inorganic nitrite, further reduction of which is relatively slow. Organic nitrates were shown to interact with the FAD site of the enzyme. In the course of reduction of GTN, xanthine oxidoreductase was progressively inactivated by conversion to its desulpho form. It is proposed that xanthine oxidoreductase is one of several flavoenzymes that catalyse the conversion of organic nitrate to inorganic nitrite in vivo. Evidence for its further involvement in reduction of the resulting nitrite to nitric oxide is discussed.     

Effect of 5-isosorbide mononitrate on isosorbide dinitrate-induced relaxation of rabbit aortic rings

The ability of isosorbide dinitrate (ISDN) and its two metabolites, 5-isosorbide mononitrate (5-ISMN) and 2-isosorbide mononitrate (2-ISMN), to relax phenylephrine-contracted rabbit aortic rings was compared. The three organic nitrates demonstrated similar efficacy. ISDN was found to be the most potent (median effective dose (ED50); 1.5 X 10(-7) +/- 1.1 X 10(-7) M), followed by 2-ISMN (ED50, 1.8 X 10(-6) +/- 9 X 10(-7) M) and 5-ISMN (ED50, 8.2 X 10(-6) +/- 3.6 X 10(-6) M). The log dose-response curve of ISDN in rabbit aortic rings was constructed in the absence and presence of three fixed concentrations of 5-ISMN (5 X 10(-6), 10(-5), and 3 X 10(-5) M). No shift in the ISDN dose-response curve at high ISDN concentrations was noted in the presence of 5-ISMN. Using the isobolographic method with fixed ISDN/5-ISMN ratio mixtures, no evidence for an antagonistic effect of 5-ISMN on ISDN-induced vasodilation was obtained. Analysis of the fixed ISDN/5-ISMN ratio mixture responses by the median-effect plot showed no antagonistic effect. It is concluded that in rabbit aortic rings 5-ISMN, the major metabolite of ISDN, is not an antagonist of ISDN at a "nitrate receptor," and no support is provided for the hypothesis that the accumulation in plasma of metabolites (e.g., 5-ISMN) with longer half-lives than the parent drug explains tolerance to organic nitrates.     

Comparison of glyceryl trinitrate-induced with pentaerythrityl tetranitrate-induced in vivo formation of superoxide radicals: effect of vitamin C.

Glyceryl trinitrate (GTN) and pentaerythrityl tetranitrate (PETN) are among the most known organic nitrates that are used in cardiovascular therapy as vasodilators. However, anti-ischemic therapy with organic nitrates is complicated by the induction of nitrate tolerance. When nitrates are metabolized to release nitric oxide (NO), there is considerable coproduction of superoxide radicals in vessels leading to inactivation of NO. However, nitrate-induced increase of superoxide radical formation in vivo has not been reported. In this work, the authors studied the in vivo formation of superoxide radicals induced by treatment with PETN or GTN and determined the antioxidant effect of vitamin C. The formation of superoxide radicals was determined by the oxidation of 1-hydroxy-3-carboxy-pyrrolidine (CP-H) to paramagnetic 3-carboxy-proxyl (CP) using electron spin resonance spectroscopy. CP-H (9 mg/kg intravenous bolus and 0.225 mg/kg per minute continuous intravenous GTN or PETN 130 microg/kg) were infused into anesthetized rabbits. Every 5 min, blood samples were obtained from Arteria carotis to measure the CP formation. Both PETN and GTN showed similar vasodilator effects. Formation of CP in blood after infusions of GTN and PETN were 2.0+/-0.4 microM and 0.98+/-0.23 microM, respectively. Pretreatment with 30 mg/kg vitamin C led to a significant decrease in CP formation: 0.27+/-0.14 microM (vitamin C plus GTN) and 0.34+/-0.15 microM (vitamin C plus PETN). Pretreatment of animals with superoxide dismutase (15,000 units/kg) significantly inhibited nitrate-induced nitroxide formation. Therefore, in vivo infusion of GTN or PETN in rabbits increased the formation of superoxide radicals in the vasculature. PETN provoked a minimal stimulation of superoxide radical formation without simultaneous development of nitrate tolerance. The data suggest that the formation of superoxide radicals induced by organic nitrate correlates with the development of nitrate tolerance. The effect of vitamin C on CP formation leads to the conclusion that vitamin C can be used as an effective antioxidant for protection against nitrate-induced superoxide radical formation in vivo.     

Continuous treatment with organic nitrate affects hepatic cytochrome P450

We previously reported that cytochrome P450 (P450) is a key enzyme of organic nitrate biotransformation and that P450 levels of the heart and its vessels markedly decreased at the development of nitrate tolerance. Escape from tolerance of organic nitrate by induction of cytochrome P450. Most organic nitrates, including nitroglycerin (NTG), are metabolized in the liver, where nitric oxide (NO) is concomitantly produced from the organic nitrates. Therefore, organic nitrate administration may also affect hepatic P450 levels, since the liver is the major organ of P450-related metabolism. Male Wistar rats were intravenously administrated NTG or isosorbide dinitrate (ISDN) for 24-96 h. Hepatic P450 was drastically decreased after 48 h or 72 h of continuous NTG or ISDN infusion, when nitrate tolerance was observed, but it recovered 48 h after cessation of the drug administration. hemeoxygenase-1 (HO-1) was induced within 24 h of continuous NTG infusion, but it returned to normal levels 48 h after cessation of the NTG. The administration of sodium nitroprusside, an agent to which the animals showed no tolerance, did not induce HO-1 or P450 depletion as judged by SDS-PAGE in combination with Western-blotting. These results suggest that P450-dependent drug metabolism may be drastically affected after continuous organic nitrate administration.     

A common enzyme may be responsible for the conversion of organic nitrates to nitric oxide in vascular microsomes.

We compared the nitric oxide (NO)-generating behavior of nitroglycerin (NTG), pentaerythritol trinitrate (PEtriN) and isosorbide dinitrate (ISDN), in the microsomal preparation of bovine coronary artery smooth muscle cells. The comparative NO generating activities among these nitrates were consistent with their relative reported vasodilating activities. Consistent with our previous observations with NTG, 400 microM bromosulfophthalein did not affect NO generation from PEtriN and ISDN in vascular microsomes while 400 microM 1-chloro-2,4-dinitrobenzene completely inhibited NO generation from these nitrates. Gel filtration chromatography with solubilized microsomes of bovine aortic smooth muscle cells showed the primary activity of NO generation from all three nitrates to be eluted at about 200 kD, consistent with that found with solubilized microsomes from the bovine coronary artery microsomes. These results suggest that organic nitrates may be converted to NO by one common enzyme in vascular microsomes.     

Isoforms of cytochrome P450 on organic nitrate-derived nitric oxide release in human heart vessels.

Glutathione S-transferases and the cytochrome P450 system have been proposed for the vascular biotransformation systems in the metabolic activation of organic nitrates. The present study was designed to elucidate the role of human cytochrome P450 isoforms on nitric oxide formation from organic nitrates using lymphoblast microsomes transfected with human CYP isoforms cDNA. CYP3A4-transfected microsomes had the most effective potential of nitric oxide formation from isosorbide dinitrate. Anti-CYP3A2 antibody (which cross-reacts with CYP3A4) or ketoconazole (an inhibitor of the CYP3A superfamily) inhibited nitric oxide formation from isosorbide dinitrate in rat heart microsomes. Immunohistochemistry of human heart also showed intense bindings of CYP3A4 antibody in the endothelium of the endocardium and coronary vessels. These results suggest that the CYP3A4-NADPH-cytochrome P450 reductase system specifically participates in nitric oxide formation from isosorbide dinitrate.     

Phosphodiesterase type 5 inhibitor sildenafil citrate does not potentiate the vasodilative properties of nebivolol in rat aorta

BACKGROUND: Sildenafil citrate (SIL) is contraindicated in patients with coronary heart disease who are treated with nitric oxide (NO) donators such as organic nitrates, as it potentiates NO-mediated vasodilation. The present study investigated whether SIL also affects the vasodilatory effects of nebivolol (NEB), a selective beta1-adrenoceptor blocker with an additional, endothelium-dependent NO-liberating property, in comparison to the combination SIL/glycerol trinitrate (GTN). METHODS AND RESULTS: Experiments were performed in isolated vessel rings of rat aorta (Wistar rats, 8-12 weeks), which had been pre-contracted with phenylephrine (10(-5) M). Isometric tension was measured by a force transducer, and cumulative concentration-response curves were obtained for each drug. The rank order of vasodilatory potency as measured by the concentration needed to achieve 50% relaxation (EC50) was GTN (0.08 microM) > SIL (1.25 microM) > or = NEB (3.5 microM). In the presence of both therapeutic (1 nM) and high (1 microM) concentrations of SIL, vasodilation of GTN was potentiated as indicated by a significant increase in vasodilatory potency (EC50 GTN + low SIL: 0.019 microM, EC50 GTN + high SIL: 0.002 microM; both P < 0.01 vs. GTN). In contrast, SIL did not potentiate the vasodilatory effect of NEB (EC50 NEB + low SIL: 5.01 microM, EC50 NEB + high SIL: 3.2 microM; n.s. vs. NEB). CONCLUSIONS: These data demonstrate that SIL does not potentiate NEB-induced vasodilation in vitro. These findings indicate that the interaction between SIL and NO-donators/organic nitrates does not apply to the NO-liberating properties of NEB. Our findings suggest that SIL may safely be used in hypertensive patients treated with NEB.     

Bioactivation of nitroglycerin by purified mitochondrial and cytosolic aldehyde dehydrogenases

Metabolism of nitroglycerin (GTN) to 1,2-glycerol dinitrate (GDN) and nitrite by mitochondrial aldehyde dehydrogenase (ALDH2) is essentially involved in GTN bioactivation resulting in cyclic GMP-mediated vascular relaxation. The link between nitrite formation and activation of soluble guanylate cyclase (sGC) is still unclear. To test the hypothesis that the ALDH2 reaction is sufficient for GTN bioactivation, we measured GTN-induced formation of cGMP by purified sGC in the presence of purified ALDH2 and used a Clark-type electrode to probe for nitric oxide (NO) formation. In addition, we studied whether GTN bioactivation is a specific feature of ALDH2 or is also catalyzed by the cytosolic isoform (ALDH1). Purified ALDH1 and ALDH2 metabolized GTN to 1,2- and 1,3-GDN with predominant formation of the 1,2-isomer that was inhibited by chloral hydrate (ALDH1 and ALDH2) and daidzin (ALDH2). GTN had no effect on sGC activity in the presence of bovine serum albumin but caused pronounced cGMP accumulation in the presence of ALDH1 or ALDH2. The effects of the ALDH isoforms were dependent on the amount of added protein and, like 1,2-GDN formation, were sensitive to ALDH inhibitors. GTN caused biphasic sGC activation with apparent EC(50) values of 42 +/- 2.9 and 3.1 +/- 0.4 microm in the presence of ALDH1 and ALDH2, respectively. Incubation of ALDH1 or ALDH2 with GTN resulted in sustained, chloral hydrate-sensitive formation of NO. These data may explain the coupling of ALDH2-catalyzed GTN metabolism to sGC activation in vascular smooth muscle.     

Vascular Bioactivation of Nitroglycerin by Aldehyde Dehydrogenase-2: REACTION INTERMEDIATES REVEALED BY CRYSTALLOGRAPHY AND MASS SPECTROMETRY*

Aldehyde dehydrogenase-2 (ALDH2) catalyzes the bioactivation of nitroglycerin (glyceryl trinitrate, GTN) in blood vessels, resulting in vasodilation by nitric oxide (NO) or a related species. Because the mechanism of this reaction is still unclear we determined the three-dimensional structures of wild-type (WT) ALDH2 and of a triple mutant of the protein that exhibits low denitration activity (E268Q/C301S/C303S) in complex with GTN. The structure of the triple mutant showed that GTN binds to the active site via polar contacts to the oxyanion hole and to residues 268 and 301 as well as by van der Waals interactions to hydrophobic residues of the catalytic pocket. The structure of the GTN-soaked wild-type protein revealed a thionitrate adduct to Cys-302 as the first reaction intermediate, which was also found by mass spectrometry (MS) experiments. In addition, the MS data identified sulfinic acid as the irreversibly inactivated enzyme species. Assuming that the structures of the triple mutant and wild-type ALDH2 reflect binding of GTN to the catalytic site and the first reaction step, respectively, superposition of the two structures indicates that denitration of GTN is initiated by nucleophilic attack of Cys-302 at one of the terminal nitrate groups, resulting in formation of the observed thionitrate intermediate and release of 1,2-glyceryl dinitrate. Our results shed light on the molecular mechanism of the GTN denitration reaction and provide useful information on the structural requirements for high affinity binding of organic nitrates to the catalytic site of ALDH2.     

Effect of in vivo nitrate tolerance on hypersensitivity to NO donors after NO-synthase blockade

Animals treated with nitric oxide synthase (NOS) inhibitors exhibit marked hypersensitivity to the blood pressure lowering effects of exogenous nitric oxide (NO) donors. We used this model as a sensitive index to evaluate the relative importance of reduced biotransformation of glyceryl trinitrate (GTN) to NO in the development of nitrate tolerance. NOS-blockade hypertension using N(G)-nitro-L-arginine methyl ester (L-NAME) caused a marked enhancement of the mean arterial pressure (MAP) decrease mediated by GTN in nontolerant rats. However, even large doses of GTN were unable to change the MAP in GTN-tolerant, NOS-blockade hypertensive animals. In contrast, the MAP responses to the spontaneous NO donor sodium nitroprusside (SNP) were completely unaltered in either tolerant rats or tolerant NOS-blockade hypertensive animals, indicating that NO-dependent vasodilatory mechanisms remain intact despite the development of GTN tolerance. The MAP-lowering effects of GTN in NOS-blockade hypertensive animals were restored 48 h after cessation of chronic GTN exposure. These alterations in the pharmacodynamic response to GTN during tolerance development and reversal were associated with parallel changes in the pattern of GTN metabolite formation, suggesting that the activity of one or more enzymes involved in nitrate metabolism was altered as a consequence of chronic GTN exposure. These findings suggest that the vasodilation resulting from the vascular biotransformation of GTN to NO (or a closely related species) is severely compromised in nitrate-tolerant animals, and that although other mechanisms may contribute to the vascular changes observed following the development of GTN tolerance, decreased GTN bioactivation is likely the most important.     

Inhibition of nitrovasodilator- and acetylcholine-induced relaxation and cyclic GMP accumulation by the cytochrome P-450 substrate, 7-ethoxyresorufin.

We examined the effect of the cytochrome P-450 substrate, 7-ethoxyresorufin (7-ER), and its corresponding product, resorufin, on nitrovasodilator- and endothelium-dependent relaxation of isolated rat aorta. The EC50 value for glyceryl trinitrate (GTN) induced relaxation was increased over 100-fold by 7-ER and less than 3-fold by resorufin. The EC50 value for sodium nitroprusside (SNP) induced relaxation was increased approximately 12-fold by 7-ER, acetylcholine (ACh) induced relaxation was abolished, and relaxation induced by isopropylnorepinephrine was not significantly affected. GTN-, SNP-, and ACh-induced increases in cyclic GMP accumulation were inhibited by 7-ER, as were basal cyclic GMP levels in endothelium-intact, but not endothelium-denuded tissues. 7-ER decreased GTN biotransformation in intact aorta and decreased the regioselective formation of glyceryl-1,2-dinitrate. The activation by GTN and SNP of aortic guanylyl cyclase in broken cell preparations was not affected by 7-ER, indicating that the inhibitory effect of 7-ER is probably not due to a direct interaction with guanylyl cyclase. The inhibitory effect of 7-ER on GTN-induced relaxation was not altered by the addition of superoxide dismutase, suggesting that 7-ER does not act by increasing superoxide anion concentration (which would serve to increase the degradation of nitric oxide (NO) formed during vascular GTN biotransformation). Our data provide further evidence for the role of the cytochrome P-450--cytochrome P-450 reductase system in the biotransformation of GTN to an activator (presumably nitric oxide) of guanylyl cyclase. The data are consistent with a mode of action of 7-ER involving either competitive inhibition of vascular cytochrome P-450 or uncoupling of vascular cytochrome P-450 reductase from cytochrome P-450. The data also suggest that the cytochrome P-450 system facilitates NO release from SNP and that 7-ER has an inhibitory effect on endothelial nitric oxide synthase.     

Aerobic Growth on Nitroglycerin as the Sole Carbon, Nitrogen, and Energy Source by a Mixed Bacterial Culture

Nitroglycerin (glycerol trinitrate [GTN]), an explosive and vasodilatory compound, was metabolized by mixed microbial cultures from aeration tank sludge previously exposed to GTN. Aerobic enrichment cultures removed GTN rapidly in the absence of a supplemental carbon source. Complete denitration of GTN, provided as the sole C and N source, was observed in aerobic batch cultures and proceeded stepwise via the dinitrate and mononitrate isomers, with successive steps occurring at lower rates. The denitration of all glycerol nitrate esters was found to be concomitant, and 1,2-glycerol dinitrate (1,2-GDN) and 2-glycerol mononitrate (2-GMN) were the primary GDN and GMN isomers observed. Denitration of GTN resulted in release of primarily nitrite-N, indicating a reductive denitration mechanism. Biomass growth at the expense of GTN was verified by optical density and plate count measurements. The kinetics of GTN biotransformation were 10-fold faster than reported for complete GTN denitration under anaerobic conditions. A maximum specific growth rate of 0.048 ± 0.005 h⁻¹ (mean ± standard deviation) was estimated for the mixed culture at 25°C. Evidence of GTN toxicity was observed at GTN concentrations above 0.3 mM. To our knowledge, this is the first report of complete denitration of GTN used as a primary growth substrate by a bacterial culture under aerobic conditions.