Regulation of the successive reaction catalyzed by rat neuronal nitric oxide synthase

The rat neuronal nitric oxide synthase (nNOS) catalyzes two monooxygenase reactions successively from L-arginine (L-Arg) to L-citrulline (L-Cit) via N(omega)-hydroxy-L-arginine (OH-Arg) without most of OH-Arg leaving the substrate-binding site. In the steady-state reaction conditions, the amount of OH-Arg produced is about 1/30-1/50 that of L-Cit. We found in this study using nNOS purified from an Escherichia coli expression system that the ratio of the amount of OH-Arg to L-Cit (OH-Arg/L-Cit) increased to about 1 at low concentration of NADPH. In one cycle of the nNOS reaction, the decrease in NADPH concentration was found to reduce the rates of two monooxygenase reactions but had little effect on the rate constant of OH-Arg dissociation from the enzyme. The addition of NADP(+), the competitive inhibitor for NADPH, caused the decrease in the rates of monooxygenase reactions in a single cycle of the reaction and the increase in the ratio of OH-Arg/L-Cit in the steady state. At low CaM concentrations, the ratio of OH-Arg/L-Cit was about the same as that at high CaM. In a single cycle of the nNOS reaction, the rate of monooxygenation was not altered by the CaM concentration but the amount of metabolized L-Arg decreased with the decrease in CaM concentration, showing that the amount of active nNOS was regulated by complex formation between nNOS and CaM. It becomes clear that there are two regulatory mechanisms for the successive reaction of nNOS. One controls the rates of monooxygenations and the other controls the amount of active species of nNOS.     

L-citrulline production from L-arginine by macrophage nitric oxide synthase. The ureido oxygen derives from dioxygen.

Previously proposed mechanisms for the production of L-citrulline from L-arginine by macrophage nitric oxide (NO.) synthase involve either hydrolysis of arginine or hydration of an intermediate and thus predict incorporation of water oxygen into L-citrulline. Macrophage NO. synthase was incubated with L-arginine, NADPH, tetrahydrobiopterin, FAD, and dithiothreitol in H2(18)/16O2. L-Citrulline produced in this reaction was analyzed with gas chromatography/mass spectrometry. Its mass spectrum matched that of L-citrulline generated in H2(16)O/16O2. The base fragment ion of m/z 99 was shown to contain the ureido carbonyl group by using L-[guanidino-13C]arginine as substrate. When the enzyme reaction was performed in H2(16)O/18O2, the base fragment ion shifted to m/z 101 with L-[guanidino-12C]arginine as the substrate and to m/z 102 with L-[guanidino-13C]arginine. These results indicate that the ureido oxygen of the L-citrulline product of macrophage NO.synthase derives from dioxygen and not from water.     

Binding of L-arginine and imidazole suggests heterogeneity of rat brain neuronal nitric oxide synthase

Nitric oxide synthase (NOS) is inhibited by imidazole, which binds to the heme in a low-spin complex absorbing at 428 nm. Conversion by L-arginine of this complex into a high-spin species absorbing at 395 nm is a common method to determine the binding parameters of Arg. However, both Arg-competitive and noncompetitive inhibition of NOS by imidazole has been reported, and optical studies with neuronal NOS provided no evidence for imidazole affecting Arg binding. We investigated the cause for these paradoxical observations with recombinant rat brain neuronal NOS. Imidazole bound to nNOS with a K(d)(app) of 50 microM; tetrahydrobiopterin (BH4) lowered the affinity of nNOS for imidazole 4-fold. The enzyme behaved heterogeneously with respect to Arg binding. Most of nNOS (65-80%) showed competition between Arg and imidazole. In the presence of BH4, a K(d)(Arg) of 1 microM could be estimated for this fraction, as well as apparent association and dissociation rate constants of 2.5 x 10(6) M(-1) x s(-1) and 2.5 s(-1). A second fraction of nNOS (20-30%) exhibited little or no competition. Consequently, Arg binding did not cause dissociation of the imidazole complex for this fraction, and complete generation of the high-spin state by Arg could not be achieved in the presence of imidazole. A third fraction (< or =10%) bound Arg with low affinity (K(d) 1-2 mM). Because of this heterogeneity, titration curves with Arg became almost uninterpretable. We propose that this heterogeneous response of nNOS toward Arg and imidazole is underlying the apparently conflicting results reported in the literature.     

PIN inhibits nitric oxide and superoxide production from purified neuronal nitric oxide synthase

A protein inhibitor of neuronal nitric oxide synthase (nNOS) was identified and designated as PIN. PIN was reported to inhibit nNOS activity in cell lysates through disruption of enzyme dimerization. However, there has been lack of direct characterization of the effect of PIN on NO production from purified nNOS. Furthermore, nNOS also generates superoxide (.O(2)(-)) at low levels of L-arginine. It is unknown whether PIN affects .O(2)(-) generation from nNOS. Therefore, we performed direct measurements of the effects of PIN on NO and .O(2)(-) generation from purified nNOS using electron paramagnetic resonance spin trapping techniques. nNOS was isolated by affinity chromatography and a fusion protein CBP-PIN was used to probe the effect of PIN. While the tag CBP did not affect nNOS activity, CBP-PIN caused a dose-dependent inhibition on both NO and L-citrulline production. In the absence of L-arginine, strong .O(2)(-) generation was observed from nNOS, and this was blocked by CBP-PIN in a dose-dependent manner. With low-temperature polyacrylamide gel electrophoresis, neither CBP nor CBP-PIN was found to affect nNOS dimerization. Thus, these results suggested that PIN not only inhibits NO but also .O(2)(-) production from nNOS, and this is through a mechanism other than decomposition of nNOS dimers.     

Constitutive nitric oxide synthase from cerebellum is reversibly inhibited by nitric oxide formed from L-arginine.

The objective of this study was to determine whether constitutive nitric oxide (NO) synthase from rat cerebellum could be regulated by the two products of the reaction, NO and L-citrulline, utilizing L-arginine as substrate. NO synthase activity was determined by monitoring the formation of 3H-citrulline from 3H-L-arginine in the presence of added cofactors. The rate of citrulline formation in enzyme reaction mixtures was non-linear. Addition of superoxide dismutase (SOD; 100 units) inhibited NO synthase activity and made the rate of product formation more non-linear, whereas addition of oxyhemoglobin (HbO2; 30 microM) increased NO synthase activity, made the rate of product formation linear and also abolished the effect of SOD. Added NO (10 microM) inhibited NO synthase activity and this inhibition was potentiated by SOD and abolished by HbO2. Added L-citrulline (1 mM) did not alter NO synthase activity. The two NO donors, S-nitroso-N-acetylpenicillamine (200 microM) and N-methyl-N'-nitro-N-nitrosoguanidine (200 microM) mimicked the inhibitory effect of NO and inhibition of NO synthase activity by NO was reversible. These observations indicate clearly that NO formed during the NO synthase reaction or added to the enzyme reaction mixture causes a reversible inhibition of NO synthase activity. Thus, NO may function as a negative feedback modulator of its own synthesis.     

Catalase activity of oxygenase domain of rat neuronal nitric oxide synthase. Evidence for product formation from L-arginine

Nitric oxide synthases (NOSs) catalyze the formation of nitric oxide from L-arginine. We purified the heme containing, tetrahydrobiopterin-free, oxygenase domain of rat neuronal nitric oxide synthase (nNOSox) overexpressed in Escherichia coli. We found catalase activity in nNOSox. This is significant because H(2)O(2) may also be a product of nitric oxide synthases. We found H(2)O(2) assisted product formation from N-hydroxy-L-arginine and even from L-arginine both in the presence and in absence of tetrahydrobiopterin. We propose how heme moiety of the oxygenase domain alone is sufficient to carry out both steps of the NOS catalysis.     

Detection of nitrous oxide in the neuronal nitric oxide synthase reaction by gas chromatography-mass spectrometry

Using headspace gas chromatography-mass spectrometry, we detected significant amounts of nitrous oxide in the reaction products of the monooxygenase reaction catalyzed by neuronal nitric oxide synthase. Nitrous oxide is a dimerization product of nitroxyl anion; its presence in the reaction products indicates that the nitroxyl anion is a product of the neuronal nitric oxide synthase-catalyzed reaction.     

Thermodynamic analysis of L-arginine and N omega-hydroxy-L-arginine binding to nitric oxide synthase

Isothermal titration calorimetry has been used to determine thermodynamic parameters of substrate binding to the oxygenase domain of neuronal nitric oxide synthase (nNOS(oxy)) in the presence of the cofactor tetrahydrobiopterin. The intermediate N(omega)-hydroxy-L-arginine (NHA) has a larger affinity than L-Arginine (L-Arg) for nNOS(oxy), with K(d)=0.4+/-0.1 microM and 1.7+/-0.3 microM at 25 degrees C, respectively. nNOS(oxy) binds NHA and L-Arg with DeltaH -4.1+/-0.2 and -1.0+/-0.1 kcal/mol and DeltaS=15 and 23 cal/Kmol respectively. NHA binding is more exothermic probably due to formation of an extra hydrogen bond in the active site compared to L-Arg. The changes in heat capacity (DeltaC(p)) are relatively small for binding of both NHA and L-Arg (-53+/-18 and -95+/-23 cal/L mol, respectively), which indicates that hydrophobic interactions contribute little to binding.     

Novel inhibitors of neuronal nitric oxide synthase

Selective inhibitors of neuronal nitric oxide synthase (nNOS), which are devoid of any effect on the endothelial isoform (eNOS), may be required for the treatment of some neurological disorders. In our search for novel nNOS inhibitors, we recently described some 1-[(Aryloxy)ethyl]-1H-imidazoles as interesting molecules for their selectivity for nNOS against eNOS. This work reports a new series of 1-[(Aryloxy)alkyl]-1H-imidazoles in which a longer methylene chain is present between the imidazole and the phenol part of molecule. Some of these molecules were found to be more potent nNOS inhibitors than the parent ethylenic compounds, although this increase in potency resulted in a partial loss of selectivity. The most interesting compound was investigated to establish its mechanism of action and was found to interact with the tetrahydrobiopterin (BH(4)) binding site of nNOS, without interference with any other cofactors or substrate binding sites.     

Kinetic characteristics of nitric oxide synthase from rat brain.

The relationship between the rate of synthesis of nitric oxide (NO) and guanylate cyclase stimulation was used to characterize the kinetics of the NO synthase from rat forebrain and of some inhibitors of this enzyme. The NO synthase had an absolute requirement for L-arginine and NADPH and did not require any other cofactors. The enzyme had a Vmax. of 42 pmol of NO formed.min-1.mg of protein-1 and a Km for L-arginine of 8.4 microM. Three analogues of L-arginine, namely NG-monomethyl-L-arginine, NG-nitro-L-arginine and NG-iminoethyl-L-ornithine inhibited the brain NO synthase. All three compounds were competitive inhibitors of the enzyme with Ki values of 0.7, 0.4 and 1.2 microM respectively.     

L-arginine analogs as alternate substrates for nitric oxide synthase

The L-arginine analogs, N(delta)-methyl-L-arginine (deltaMA) and L-canavanine, were used to probe the role of the N delta nitrogen of L-arginine in the reaction catalyzed by nitric oxide synthase (NOS). deltaMA was synthesized and found to be a partial alternate substrate and a weak, reversible inhibitor of NOS with a Ki equal to 1.4 mM. deltaMA undergoes hydroxylation; however, it is not converted further, hence it functions as a partial substrate. L-Canavanine was converted to an L-homoserine presumably via initial hydroxylation and decomposition. The mechanism of this reaction and products of this reaction were not probed further.     

Apelin activates L-arginine/nitric oxide synthase/nitric oxide pathway in rat aortas

Apelin was recently found to be an inotropic polypeptide in isolated rat hearts, and intravenous injection of apelin can induce a transient decrease in blood pressure. To illustrate the mechanism of apelin-induced vasodilation, we observed the in vitro effects of apelin on the L-arginine (L-Arg)/nitric oxide (NO) pathway in the incubated, isolated rat aorta. Apelin stimulated vascular NO(2)(-) product and NOS activation in a concentration- and time-dependent manner. Compared with no apelin treatment, incubation with apelin (10(-9), 10(-8), and 10(-7)mol/L) increased NO(2)(-) product by 33%, 46%, and 69% (all p<0.01), respectively, and Ca(2+)-dependent constitutive NOS (cNOS) activity by 200%, 460%, and 550% (all p<0.01), respectively. However, Ca(2+)-independent NOS (iNOS) activity was not significantly altered (p>0.05). Apelin incubation (10(-9), 10(-8), and 10(-7)mol/L) increased L-Arg uptake by 130%, 180%, and 240% (all p<0.01), respectively. The mRNA level of cationic amino acid transporters, CAT-1 and CAT-2B, in rat aortic tissues treated with 10(-7)mol/L apelin was increased by 110% and 128%, respectively (both p<0.01). Incubation with 10(-7)mol/L apelin elevated eNOS mRNA and protein levels, by 53% (p<0.05) and 319% (p<0.01), respectively. Collectively, these results demonstrate that apelin directly activated the vascular L-Arg/NOS/NO pathway, which could be one of the important mechanisms of apelin-regulated vascular function.     

Biosynthesis of nitric oxide and citrulline from L-arginine by constitutive nitric oxide synthase present in rabbit corpus cavernosum.

The objective of this study was to determine whether a constitutive isoform of nitric oxide (NO) synthase is present in rabbit corpus cavernosum that could account for the involvement of the L-arginine-NO pathway in neurogenically-elicited relaxation of the corpus cavernosum and, therefore, penile erection. Citrulline was determined by monitoring the formation of 3H-citrulline from 3H-L-arginine. NO was determined by monitoring the formation of total NO(x) (NO+nitrite [NO2-]+nitrate [NO3-]) by chemiluminescence after reduction of NO(x) to NO by acidic vanadium (III). Equimolar quantities of NO plus citrulline were generated from L-arginine and the formation of both products was time-dependent at 37 degrees C. NO synthase activity was distributed almost entirely to the cytosolic fraction. Enzymatic activity was completely dependent on NADPH, calmodulin, and calcium. Addition of tetrahydrobiopterin increased NO synthase activity by about 30 percent. The NO synthase inhibitor NG-nitro-L-arginine, abolished enzymatic activity. The Km for L-arginine was 17 microM and the Vmax of the reaction was 18 pmol/min/mg protein. These observations indicate that a cytosolic, constitutive isoform of NO synthase, like that found in brain neuronal tissue, is present in rabbit corpus cavernosum.     

Nitric oxide synthase from cerebellum catalyzes the formation of equimolar quantities of nitric oxide and citrulline from L-arginine.

This study examined whether constitutive nitric oxide (NO) synthase from rat cerebellum catalyzes the formation of equimolar amounts of NO plus citrulline from L-arginine under various conditions. Citrulline was determined by monitoring the formation of 3H-citrulline from 3H-L-arginine. NO was determined by monitoring the formation of total NOx (NO+nitrite [NO2-] + nitrate [NO3-]) by chemiluminescence after reduction of NOx to NO by acidic vanadium (III). Equal quantities of NO plus citrulline were generated from L-arginine and the formation of both products was linear for about 20 min at 37 degrees C provided L-arginine was present in excess to maintain a zero order reaction rate. Deletion of NADPH, addition of the calmodulin antagonist calmidazolium, or addition of NO synthase inhibitors (NG-methyl-L-arginine, NG-amino-L-arginine) abolished or markedly inhibited the formation of both NO and citrulline. The Km for L-arginine (14 microM; 18 microM) and the Vmax of the reaction (0.74 nmol/min/mg protein; 0.67 nmol/min/mg protein) were the same whether NO or citrulline formation, respectively, was monitored. These observations indicate clearly that NO and citrulline are formed in equimolar quantities from L-arginine by the constitutive isoform of NO synthase from rat cerebellum.     

Endogenous nitric oxide synthase inhibitors are responsible for the L-arginine paradox

L-Arginine, the substrate of nitric oxide (NO) synthases (NOSs), is found in the mammalian organism at concentrations by far exceeding K(M) values of these enzymes. Therefore, additional L-arginine should not enhance NO formation. In vivo, however, increasing L-arginine concentration in plasma has been shown repeatedly to increase NO production. This phenomenon has been named the L-arginine paradox; it has found no satisfactory explanation so far. In the present work, evidence for the hypothesis that the endogenous NOS inhibitors methylarginines, asymmetric dimethylarginine being the most powerful (IC(50) 1.5 microM), are responsible for the L-arginine paradox is presented.     

Hydroxyl-terminated peptidomimetic inhibitors of neuronal nitric oxide synthase

The X-ray structure of previously studied dipeptidomimetic inhibitors bound in the active site of neuronal nitric oxide synthase (nNOS) presented a possibility for optimizing the strength of enzyme-inhibitor interactions as well as for enhancing bioavailability. These desirable properties may be attainable by replacement of the terminal amino group of the parent compounds (1-6) with a hydroxyl group (11-13, and 18-20). The hypothesized effect would be twofold: first, a change from a positively charged amino group to a neutral hydroxyl group might afford more drug-like character and blood-brain barrier permeability to the inhibitors; second, as suggested by docking studies, the incorporated hydroxyl group might displace an active site water molecule with which the terminal amino group of the original compounds indirectly hydrogen bonds. In vitro activity assays of the hydroxyl-terminated analogs (11-13 and 18-20) showed greater than an order of magnitude increase in K(i) values (decreased potency) relative to the amino-terminated compounds. These experimental data support the importance to enzyme binding of a potential electrostatic interaction relative to a hydrogen bonding interaction.     

Tetrahydrobiopterin-dependent inhibition of superoxide generation from neuronal nitric oxide synthase.

The binding of calcium/calmodulin stimulates electron transfer between the reductase and oxygenase domains of neuronal nitric oxide synthase (nNOS). Here, we demonstrate using electron spin resonance spin-trapping with 5-diethoxyphosphoryl-5-methyl-1-pyrroline N-oxide that pterin-free nNOS generates superoxide from the reductase and the oxygenase domain by a calcium/calmodulin-dependent mechanism. Tetrahydrobiopterin (BH(4)) diminishes the formation of superoxide by a mechanism that does not cause inhibition of NADPH consumption. In contrast, BH(4) analogs 7,8-dihydrobiopterin and sepiapterin do not affect superoxide yields. L-Arginine alone inhibits the generation of superoxide by nNOS but not by C331A-nNOS mutant that has a low affinity for L-arginine. A greater decrease in superoxide yields is observed when nNOS is preincubated with L-arginine. This effect is in accordance with the slow binding rates of L-arginine to NOS in the absence of BH(4). L-Arginine alone or in combination with BH(4) decreases the rates of NADPH consumption. The effect of L-arginine on superoxide yields, however, was less dramatic than that caused by BH(4) as much higher concentrations of L-arginine are necessary to attain the same inhibition. In combination, L-arginine and BH(4) inhibit the formation of superoxide generation and stimulate the formation of L-citrulline. We conclude that, in contrast to L-arginine, BH(4) does not inhibit the generation of superoxide by controlling electron transfer through the enzyme but by stimulating the formation of the heme-peroxo species.     

Cyclopropyl- and methyl-containing inhibitors of neuronal nitric oxide synthase

Inhibitors of neuronal nitric oxide synthase have been proposed as therapeutics for the treatment of different types of neurological disorders. On the basis of a cis-3,4-pyrrolidine scaffold, a series of trans-cyclopropyl- and methyl-containing nNOS inhibitors have been synthesized. The insertion of a rigid electron-withdrawing cyclopropyl ring decreases the basicity of the adjacent amino group, which resulted in decreased inhibitory activity of these inhibitors compared to the parent compound. Nonetheless, three of them exhibited double-digit nanomolar inhibition with high nNOS selectivity on the basis of in vitro enzyme assays. Crystal structures of nNOS and eNOS with these inhibitors bound provide a basis for detailed structure–activity relationship (SAR) studies. The conclusions from these studies will be used as a guide in the future development of selective NOS inhibitors.