Stopped-flow analysis of substrate binding to neuronal nitric oxide synthase.

The kinetics of binding L-arginine and three alternative substrates (homoarginine, N-methylarginine, and N-hydroxyarginine) to neuronal nitric oxide synthase (nNOS) were characterized by conventional and stopped-flow spectroscopy. Because binding these substrates has only a small effect on the light absorbance spectrum of tetrahydrobiopterin-saturated nNOS, their binding was monitored by following displacement of imidazole, which displays a significant change in Soret absorbance from 427 to 398 nm. Rates of spectral change upon mixing Im-nNOS with increasing amounts of substrates were obtained and found to be monophasic in all cases. For each substrate, a plot of the apparent rate versus substrate concentration showed saturation at the higher concentrations. K(-)(1), k(2), k(-)(2), and the apparent dissociation constant were derived for each substrate from the kinetic data. The dissociation constants mostly agreed with those calculated from equilibrium spectral data obtained by titrating Im-nNOS with each substrate. We conclude that nNOS follows a two-step, reversible mechanism of substrate binding in which there is a rapid equilibrium between Im-nNOS and the substrate S followed by a slower isomerization process to generate nNOS'-S: Im-nNOS + S if Im-nNOS-S if nNOS'-S + Im. All four substrates followed this general mechanism, but differences in their kinetic values were significant and may contribute to their varying capacities to support NO synthesis.     

Reduced neuronal nitric oxide synthase is involved in ischemia-induced hippocampal neurogenesis by up-regulating inducible nitric oxide synthase expression

Nitric oxide (NO), a free radical with signaling functions in the CNS, is implicated in some developmental processes, including neuronal survival, precursor proliferation, and differentiation. However, neuronal nitric oxide synthase (nNOS) -derived NO and inducible nitric oxide synthase (iNOS) -derived NO play opposite role in regulating neurogenesis in the dentate gyrus after cerebral ischemia. In this study, we show that focal cerebral ischemia reduced nNOS expression and enzymatic activity in the hippocampus. Ischemia-induced cell proliferation in the dentate gyrus was augmented in the null mutant mice lacking nNOS gene (nNOS−/−) and in the rats receiving 7-nitroindazole, a selective nNOS inhibitor, after stroke. Inhibition of nNOS ameliorated ischemic injury, up-regulated iNOS expression, and enzymatic activity in the ischemic hippocampus. Inhibition of nNOS increased and iNOS inhibitor decreased cAMP response element-binding protein phosphorylation in the ipsilateral hippocampus in the late stage of stroke. Moreover, the effects of 7-nitroindazole on neurogenesis after ischemia disappeared in the null mutant mice lacking iNOS gene (iNOS−/−). These results suggest that reduced nNOS is involved in ischemia-induced hippocampal neurogenesis by up-regulating iNOS expression and cAMP response element-binding protein phosphorylation.     

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.     

Inhibition of neuronal nitric oxide synthase by N-phenacyl imidazoles.

Nitric oxide (NO) mediates a series of physiological processes, including regulation of vascular tone, macrofage-mediated neurotoxicity, platelet aggregation, learning and long-term potentiation, and neuronal transmission. Although NO mediates several physiological functions, overproduction of NO can be detrimental and play multiple roles in several pathological diseases. Accordingly, more potent inhibitors, more selective for neuronal nitric oxide synthase (nNOS) than endothelial NOS (eNOS) or inducible NOS (iNOS), could be useful in the treatment of cerebral ischemia and other neurodegenerative diseases. We recently described the synthesis of a series of imidazole derivatives. Among them N-(4-nitrophenacyl) imidazole (A) and N-(4-nitrophenacyl)-2-methyl-imidazole (B) were considered selective nNOS inhibitors. In the present study the action mechanism of compounds A and B was analyzed. Spectral changes observed in the presence of compound A indicate that this inhibitor exerts its effect without interaction with heme iron. Moreover compounds A and B, inhibit nNOS "noncompetitively" versus arginine, but "competitively" versus BH(4).     

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.     

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.     

Discovery and development of neuronal nitric oxide synthase inhibitors

The role of neuronally derived nitric oxide (NO) in neurotransmission and neural injury remains an area of active investigation. NO generation has been postulated to be involved in the deleterious events surrounding ischemia/reperfusion injury either directly or via the production of more reactive oxidants such as peroxynitrite. In our search for novel therapeutics for the treatment of a variety of neurological diseases including stroke, we have discovered novel, potent, and selective inhibitors of the neuronal nitric oxide synthase (nNOS) isoform. These compounds have proven to be effective in models of ischemia/reperfusion supporting the role of nNOS in these processes. The effects of these compounds as well as additional aspects critical to their development will be presented.     

Nitrosyl-heme structures of Bacillus subtilis nitric oxide synthase have implications for understanding substrate oxidation

The crystal structures of nitrosyl-heme complexes of a prokaryotic nitric oxide synthase (NOS) from Bacillus subtilis (bsNOS) reveal changes in active-site hydrogen bonding in the presence of the intermediate N(omega)-hydroxy-l-arginine (NOHA) compared to the substrate l-arginine (l-Arg). Correlating with a Val-to-Ile residue substitution in the bsNOS heme pocket, the Fe(II)-NO complex with both l-Arg and NOHA is more bent than the Fe(II)-NO, l-Arg complex of mammalian eNOS [Li, H., Raman, C. S., Martasek, P., Masters, B. S. S., and Poulos, T. L. (2001) Biochemistry 40, 5399-5406]. Structures of the Fe(III)-NO complex with NOHA show a nearly linear nitrosyl group, and in one subunit, partial nitrosation of bound NOHA. In the Fe(II)-NO complexes, the protonated NOHA N(omega) atom forms a short hydrogen bond with the heme-coordinated NO nitrogen, but active-site water molecules are out of hydrogen bonding range with the distal NO oxygen. In contrast, the l-Arg guanidinium interacts more weakly and equally with both NO atoms, and an active-site water molecule hydrogen bonds to the distal NO oxygen. This difference in hydrogen bonding to the nitrosyl group by the two substrates indicates that interactions provided by NOHA may preferentially stabilize an electrophilic peroxo-heme intermediate in the second step of NOS catalysis.     

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.     

Target recognition of apocalmodulin by nitric oxide synthase I peptides

An increasing number of proteins are found that are regulated by the Ca(2+)-free state of calmodulin, apocalmodulin. Many of these targets harbor a so-called IQ motif within their primary sequence, but several target proteins of apocalmodulin lack this motif. We investigated whether the Ca(2+)-dependent calmodulin-binding site of nitric oxide synthase I could be transformed into a target site of apocalmodulin. Synthetic peptides representing the wild-type amino acid sequence and several peptides carrying mutations were studied by isothermal titration calorimetry and fluorescence spectroscopy. A single amino acid substitution of a negative charge to a positive charge can convert a classical Ca(2+)-dependent binding site of calmodulin into a target site for apocalmodulin. In addition, the introduction of hydrophobic amino acids increases the apparent binding affinity from the micromolar to the nanomolar range. Binding of wild-type and mutant peptides to Ca(2+)-calmodulin was enthalpically driven, and binding to apocalmodulin was entropically driven. Our data indicate that only a few selected amino acid positions in a calmodulin-binding site determine its Ca(2+) dependency.     

Unusual role of Tyr588 of neuronal nitric oxide synthase in controlling substrate specificity and electron transfer

Nitric oxide (NO) is synthesized from l-Arg via N(G)-hydroxyl-l-Arg (NHA) in the heme active site of nitric oxide synthase (NOS). According to the crystal structure of other NOS isoforms, the carboxylate group of l-Arg hydrogen bonds to the hydroxyl group of the conserved Tyr588 residue in the heme distal site of neuronal NOS (nNOS). Indeed, the nNOS mutations Tyr588His, Tyr588Ser, and Tyr588Phe markedly increased the dissociation constants for l-Arg and NHA by 2.2-8.2-fold and 1.5-3.9-fold, respectively. Similarly, Tyr588His and Tyr588Ser mutations markedly decreased the l-Arg-driven NO formation rates by 50 and 30% than that of the wild type, respectively. However, the catalytic activities of the same mutants using NHA were higher than that of the wild type by up to 136%. As a result, the turnover ratio of NHA to l-Arg was 4.12 for the Tyr588Ser mutant, compared with 1.07 for the wild-type enzyme. Intriguingly, heme reduction rates for the Tyr588 mutants were much lower than for wild type by two orders of magnitude.     

Upregulation of neuronal nitric oxide synthase in skeletal muscle by swim training

Exercise enhances cardiac output and blood flow to working skeletal muscles but decreases visceral perfusion. The alterations in nitric oxide synthase (NOS) activity and/or expression of the cardiopulmonary, skeletal muscle, and visceral organs induced by swim training are unknown. In sedentary and swim-trained rats (60 min twice/day for 3-4 wk), we studied the alterations in NOS in different tissues along with hindquarter vasoreactivity in vivo during rest and mesenteric vascular bed reactivity in vitro. Hindquarter blood flow and conductance were reduced by norepinephrine in both groups to a similar degree, whereas N(G)-nitro-L-arginine methyl ester reduced both indexes to a greater extent in swim-trained rats. Vasodilator responses to ACh, but not bradykinin or S-nitroso-N-acetyl-penicillamine, were increased in swim-trained rats. Ca(2+)-dependent NOS activity was enhanced in the hindquarter skeletal muscle, lung, aorta, and atria of swim-trained rats together with increased expression of neuronal NOS in the hindquarter skeletal muscle and endothelial NOS in the cardiopulmonary organs. Mesenteric arterial bed vasoreactivity was unaltered by swim training. Physiological adaptations to swim training are characterized by enhanced hindquarter ACh-induced vasodilation with upregulation of neuronal NOS in skeletal muscle and endothelial NOS in the lung, atria, and aorta.     

Selective L-nitroargininylaminopyrrolidine and L-nitroargininylaminopiperidine neuronal nitric oxide synthase inhibitors

Selective inhibition of the localized excess production of NO by neuronal nitric oxide synthase (nNOS) has been targeted as a potential means of treating various neurological disorders. Based on observations from the X-ray crystal structures of complexes of nNOS with two nNOS-selective inhibitors, (4S)-N-{4-amino-5-[(2-amino)ethylamino]pentyl}-N'-nitroguanidine (L-Arg(NO2)-L-Dbu-NH2 (1) and 4-N-(Nomega-nitro-L-argininyl)-trans-4-amino-L-proline amide (2), a series of descarboxamide analogues was designed and synthesized (3-7). The most potent compound was aminopyrrolidine analogue 3, which exhibited better potency and selectivity for nNOS than parent compound 2. In addition, 3 provided higher lipophilicity and a lower molecular weight than 2, therefore having better physicochemical properties. Nalpha-Methylated analogues (8-11) also were prepared for increased lipophilicity of the inhibitors, but they had 4- to 5-fold weaker binding affinity compared to their parent compounds.     

Efficient formation of nitric oxide from selective oxidation of N-aryl N'-hydroxyguanidines by inducible nitric oxide synthase

Inducible nitric oxide synthase (NOS II) efficiently catalyzes the oxidation of N-(4-chlorophenyl)N'-hydroxyguanidine 1 by NADPH and O2, with concomitant formation of the corresponding urea and NO. The characteristics of this reaction are very similar to those of the NOS-dependent oxidation of endogenous Nomega-hydroxy-L-arginine (NOHA), i.e., (i) the formation of products resulting from an oxidation of the substrate C=N(OH) bond, the corresponding urea and NO, in a 1:1 molar ratio, (ii) the absolute requirement of the tetrahydrobiopterin (BH4) cofactor for NO formation, and (iii) the strong inhibitory effects of L-arginine (L-arg) and classical inhibitors of NOSs. N-Hydroxyguanidine 1 is not as good a substrate for NOS II as is NOHA (Km = 500 microM versus 15 microM for NOHA). However, it leads to relatively high rates of NO formation which are only 4-fold lower than those obtained with NOHA (Vm = 390 +/- 50 nmol NO min-1 mg protein-1, corresponding roughly to 100 turnovers min-1). Preliminary results indicate that some other N-aryl N'-hydroxyguanidines exhibit a similar behavior. These results show for the first time that simple exogenous compounds may act as NO donors after oxidative activation by NOSs. They also suggest a possible implication of NOSs in the oxidative metabolism of certain classes of xenobiotics.     

Glutathione depletion is accompanied by increased neuronal nitric oxide synthase activity

The effect of glutathione depletion, in vivo, on rat brain nitric oxide synthase activity has been investigated and compared to the effect observed in vitro with cultured neurones. Using L-buthionine sulfoximine rat brain glutathione was depleted by 62%. This loss of glutathione was accompanied by a significant increase in brain nitric oxide synthase activity by up to 55%. Depletion of glutathione in cultured neurones, by approximately 90%, led to a significant 67% increase in nitric oxide synthase activity, as judged by nitrite formation, and cell death. It is concluded that depletion of neuronal glutathione results in increased nitric oxide synthase activity. These findings may have implications for our understanding of the pathogenesis of neurodegenerative disorders in which loss of brain glutathione is considered to be an early event.     

Hydroxyethylene isosteres of selective neuronal nitric oxide synthase inhibitors

Nitric oxide (NO) is an important second messenger molecule for blood pressure homeostasis, as a neurotransmitter, and in the immune defense system. Excessive NO can lead to neurodegeneration and connective tissue damage. Three different isozymes of the enzyme nitric oxide synthase regulate NO production in endothelial (eNOS), neuronal (nNOS), and macrophage (iNOS) cells. Whereas creating a lower level of NO in some cells could be beneficial, it also could be detrimental to the protective effects that NO has on other cells. Therefore, it is essential that therapeutic NOS inhibitors be made that are subtype selective. Previously, we reported a series of nitroarginine-containing dipeptide amides as potent and selective nNOS inhibitors. Here we synthesize peptidomimetic hydroxyethylene isosteres of these dipeptide amides for potential increased bioavailability. None of the compounds is as potent or selective as the dipeptide amides, but they exhibit good inhibition and selectivity. When the terminal amino group was converted to a hydroxyl group, potency and selectivity greatly diminished, supporting the importance of the terminal amino group for binding.     

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.     

On the substrate specificity of nitric oxide synthase.

Nitric oxide (.NO) synthase (NOS) activity in subcellular fractions from cultured endothelial cells (EC) and lipopolysaccharide-activated J774.2 monocyte/macrophages was investigated by monitoring the .NO-mediated increase in intracellular cyclic GMP in LLC-PK1 pig kidney epithelial cells. The constitutive NOS in EC (NOSc) was largely membrane-bound, whereas the inducible NOS in J774.2 cells (NOSi) was equally distributed among cytosol and membrane(s). Both the cytosolic NOSc in EC and the membrane-bound NOSi in J774.2 cells were strictly Ca(2+)-dependent, whereas the membrane-bound NOSc in EC and the cytosolic NOSi in J774.2 cells were not. L-Homoarginine and L-arginine-containing small peptides, such as L-arginyl-L-phenylalanine, replaced L-arginine as a substrate for the NOSc in EC and the Ca(2+)-independent NOSi in J774.2 cells, but not the Ca(2+)-dependent NOSi. Thus, irrespective of their intracellular localisation, at least three isoforms of NOS exist, which can be differentiated by their substrate specificity and Ca(2+)-dependency.