Oxidation of N(omega)-hydroxyarginine analogues by NO-synthase: the simple, non amino acid N-butyl N'-hydroxyguanidine is almost as efficient an NO precursor as N(omega)-hydroxyarginine

Synthesis and hyperpolarisation of eNOS substrates for quantification of NO production by 1H NMR spectroscopy

Hyperpolarization enhances the intensity of the NMR signals of a molecule, whose in vivo metabolic fate can be monitored by MRI with higher sensitivity. SABRE is a hyperpolarization technique that could potentially be used to image nitric oxide (NO) production in vivo. This would be very important, because NO dysregulation is involved in several pathologies, including cardiovascular ones. The nitric oxide synthase (NOS) pathway leads to NO production via conversion of l-arginine into l-citrulline. NO is a free radical gas with a short half-life in vivo (≈5s), therefore direct NO quantification is challenging. An indirect method - based on quantifying conversion of an l-Arg- to l-Cit-derivative by 1H NMR spectroscopy - is herein proposed. A small library of pyridyl containing l-Arg derivatives was designed and synthesised. In vitro tests showed that compounds 4a-j and 11a-c were better or equivalent substrates for the eNOS enzyme (NO2- production=19-46μM) than native l-Arg (NO2- production=25μM). Enzymatic conversion of l-Arg to l-Cit derivatives could be monitored by 1H NMR. The maximum hyperpolarization achieved by SABRE reached 870-fold NMR signal enhancement, which opens up exciting future perspectives of using these molecules as hyperpolarized MRI tracers in vivo.

Synthesis of mono- and symmetrical di-N-hydroxy- and N-aminoguanidines

Novel mono- and symmetrical di-N-hydroxy- and N-aminoguanidines were readily prepared from the reaction of diverse hydroxylamines or hydrazines with reagent classes di(benzotriazol-1-yl)methanimine 6, (bis-benzotriazol-1-yl-methylene)amines 8a,b, benzotriazole-1-carboxamidines 10a-i, benzotriazole-1-carboximidamides 11a,b, and N'-hydroxy-1H-1,2,3-benzotriazole-1-carboximidamide 18. The preparation is described for a variety of N-hydroxy- and N-aminoguanidines with different substitution patterns in good yields.

Differential Effects of Alkyl- and Arylguanidines on the Stability and Reactivity of Inducible NOS Heme−Dioxygen Complexes

NO-Synthases are heme proteins that catalyze the oxidation of L-arginine into NO and L-citrulline. Some non-amino acid alkylguanidines may serve as substrates of inducible NOS (iNOS), while no NO* production is obtained from arylguanidines. All studied guanidines induce uncoupling between electrons transferred from the reductase domain and those required for NO formation. This uncoupling becomes critical with arylguanidines, leading to the exclusive formation of superoxide anion O2*- as well as hydrogen peroxide H2O2. To understand these different behaviors, we have conducted rapid scanning stopped-flow experiments with dihydrobiopterin (BH2) and tetrahydrobiopterin (BH4) to study, respectively, the (i) autoxidation and (ii) activation processes of heme ferrous-O2 complexes (Fe(II)O2) in the presence of eight alkyl- and arylguanidines. The Fe(II)O2 complex is more easily autooxidized by alkylguanidines (10-fold) and arylguanidines (100-fold) compared to L-arginine. In the presence of alkylguanidines and BH4, the oxygen-activation kinetics are very similar to those observed with L-arginine. Conversely, in the presence of arylguanidines, no Fe(II)O2 intermediate is detected. To understand such variations in reactivity and stability of Fe(II)O2 complex, we have characterized the effects of alkyl- and arylguanidines on Fe(II)O2 structure using the Fe(II)CO complex as a mimic. Resonance Raman and FTIR spectroscopies show that the two classes of guanidine derivatives induce different polar effects on Fe(II)CO environment. Our data suggest that the structure of the substituted guanidine can modulate the stability and the reactivity of heme-dioxygen complexes. We thus propose differential mechanisms for the electron- and proton-transfer steps in the NOS-dependent, oxygen-activation process, contingent upon whether alkyl- or arylguanidines are bound.

Reactivity of the heme-dioxygen complex of the inducible nitric oxide synthase in the presence of alternative substrates

Single turnover reactions of the inducible nitric oxide synthase oxygenase domain (iNOSoxy) in the presence of several non alpha-amino acid N-hydroxyguanidines and guanidines were studied by stopped-flow visible spectroscopy, and compared with reactions using the native substrates L-arginine (L-arg) or N(omega)-hydroxy-L-arginine (NOHA). In experiments containing dihydrobiopterin, a catalytically incompetent pterin, and each of the studied substrates, L-arg, butylguanidine (BuGua), para-fluorophenylguanidine (FPhGua), NOHA, N-butyl- and N-(para-fluorophenyl)-N'-hydroxyguanidines (BuNOHG and FPhNOHG), the formation of a iron(II) heme-dioxygen intermediate (Fe(II)O2) was always observed. The Fe(II)O2 species then decayed to iron(III) iNOSoxy at rates that were dependent on the nature of the substrate. Identical reactions containing the catalytically competent cofactor tetrahydrobiopterin (BH4), iNOSoxy and the three N-hydroxyguanidines, all exhibited an initial formation of an Fe(II)O2 species that was successively converted to an Fe(III)NO complex and eventually to high-spin iron(III) iNOSoxy. The formation and decay kinetics of the Fe(III)NO complex did not vary greatly as a function of the N-hydroxyguanidine structure, but the formation of Fe(III)NO was substoichiometric in the cases of BuNOHG and FPhNOHG. Reactions between BH4-containing iNOSoxy and BuGua exhibited kinetics similar to those of the corresponding reaction with L-arginine, with formation of an Fe(II)O2 intermediate that was directly converted to high-spin iron(III) iNOSoxy. In contrast, no Fe(II)O2 intermediate was observed in the reaction of BH4-containing iNOSoxy and FPhGua. Multi-turnover reaction of iNOS with FPhGua did not lead to formation of NO or to hydroxylation of the substrate, contrary to reactions with BuGua or L-arg. Our results reveal how different structural and chemical properties of NOS substrate analogues can impact on the kinetics and reactivity of the Fe(II)O2 intermediate, and support an important role for substrate pKa during NOS oxygen activation.

Relationship between the structure of guanidines and N-hydroxyguanidines, their binding to inducible nitric oxide synthase (iNOS) and their iNOS-catalysed oxidation to NO

The binding of several alkyl- and aryl-guanidines and N-hydroxyguanidines to the oxygenase domain of inducible NO-synthase (iNOS(oxy)) was studied by UV/Vis difference spectroscopy. In a very general manner, monosubstituted guanidines exhibited affinities for iNOS(oxy) that were very close to those of the corresponding N-hydroxyguanidines. The highest affinities were observed for the natural substrates, L-arginine and N(omega)-hydroxy-L-arginine (K(d) at the microm level). The deletion of either the CO2H or the NH2 function of their amino acid moiety led to dramatic decreases in the affinity. However, alkylguanidines with a relatively small alkyl chain exhibited interesting affinities, the best being observed for a butyl chain (K(d) =20 microM). Arylguanidines also bound to iNOS(oxy), however, with lower affinities (K(d) > 250 microm). Many N-alkyl- and N-aryl-N'-hydroxyguanidines are oxidized by iNOS with formation of NO, whereas only few alkylguanidines led to significant production of NO under identical conditions, and all the arylguanidines tested to date were unable to lead to the production of NO. The k(cat) values of NO production from the oxidation by iNOS of the studied N-hydroxyguanidines were found to vary independently of their affinity for the protein. The k(cat) values determined for the two-step oxidation of alkylguanidines to NO were not clearly related to the K(d) of these substrates toward iNOS(oxy). However, there is a qualitative relationship between these k(cat) values and the apparent rate constants of dissociation of the complex between iNOS(oxy) and the corresponding N-alkyl-N'-hydroxyguanidine (k(off) (app)) that were determined by stopped-flow UV/Vis spectroscopy. These data indicate that a key factor for efficient oxidation of a guanidine by iNOS to NO is the ability of the corresponding N-hydroxyguanidine to bind to the active site without being too rapidly released before its further oxidation. This explains why 4,4,4-trifluorobutylguanidine is so far the best non-alpha-amino acid guanidine substrate of iNOS with formation of NO, because the k(off) (app) of the corresponding N-hydroxyguanidine is particularly low. This suggests that the rational design of guanidines as new NO donors upon in situ oxidation by NOSs should take into account both thermodynamic and kinetic characteristics of the interaction of the protein not only with the guanidine but also with the corresponding N-hydroxyguanidine.

N-Hydroxy sulfonimidamides as new nitroxyl (HNO) donors

Chlorination and condensation of simple sulfinamides with O-benzyl and O-tert-butyl dimethyl siloxy hydroxylamine gives O-protected N-hydroxy sulfonimidamides. Deprotection of these compounds produces the corresponding sulfinamide and nitrous oxide, which provides evidence for the intermediacy of nitroxyl (HNO) and identifies these compounds as new potential HNO donors.

Importance of valine 567 in substrate recognition and oxidation by neuronal nitric oxide synthase

Nitric oxide (NO) is synthesised by a two-step oxidation of -arginine (L-Arg) in the active site of nitric oxide synthase (NOS) with formation of an intermediate, N omega-hydroxy-L-Arg (NOHA). Crystal structures of NOSs have shown the importance of an active-site Val567 residue (numbered for rat neuronal NOS, nNOS) interacting with non-amino acid substrates. To investigate the role of this Val residue in substrate recognition and NO-formation activity by nNOS, we generated and purified four Val567 mutants of nNOS, Val567Leu, Val567Phe, Val567Arg and Val567Glu. We characterized these proteins and tested their ability to generate NO from the oxidation of natural substrates L-Arg and NOHA, and from N-hydroxyguanidines previously identified as alternative substrates for nNOS. The Val567Leu mutant displayed lower NO formation activities than the wild type (WT) in the presence of all tested compounds. Surprisingly, the Val567Phe mutant formed low amounts of NO only from NOHA. These two mutants displayed lower affinity for L-Arg and NOHA than the WT protein. Val576Glu and Val567Arg mutants were much less stable and did not lead to any formation of NO. These results suggest that Val567 is an important residue for preserving the integrity of the active site, for substrate binding, and subsequently for NO-formation in nNOS.

Alternative nitric oxide-producing substrates for NO synthases

Nitric oxide (NO) is a key inter- and intracellular molecule involved in the maintenance of vascular tone, neuronal signaling, and host response to infection. The biosynthesis of NO in mammals involves a two-step oxidation of L-arginine (L-Arg) to citrulline and NO catalyzed by a particular class of heme-thiolate proteins, called NO-synthases (NOSs). The NOSs successively catalyze the Nomega-hydroxylation of the guanidine group of L-Arg with formation of Nomega-hydroxy-L-arginine (NOHA) and the oxidative cleavage of the CN(OH) bond of NOHA with formation of citrulline and NO. During the last decade, a great number of compounds bearing a CNH or CNOH function have been synthesized and studied as possible NO-producing substrates of recombinant NOSs. This includes derivatives of L-Arg and NOHA, N-alkyl (or aryl) guanidines, N,N'- or N,N-disubstituted guanidines, N-alkyl (or aryl) N'-hydroxyguanidines, N- (or O-) disubstituted N'-hydroxyguanidines, as well as amidoximes, ketoximes, and aldoximes. However, only those involving the NHC(NH2)=NH (or NOH) moiety have led to a significant formation of NO. All the N-monosubstituted N'-hydroxyguanidines that are well recognized by the NOS active site lead to NO with catalytic efficiences (kcat/Km) up to 50% of that of NOHA. This is the case of many N-aryl and N-alkyl N'-hydroxyguanidines, provided that the aryl or alkyl substituent is small enough to be accommodated by a NOS hydrophobic site located in close proximity of the NOS "guanidine binding site." As far as N-substituted guanidines are concerned, few compounds bearing a small alkyl group have been found to act as NO-producing substrates. The kcat value found for the best compound may reach 55% of the kcat of L-Arg oxidation. However, the best catalytic efficiency (kcat/Km) that was obtained with N-(4,4,4-trifluorobutyl) guanidine is only 100-fold lower than that of L-Arg. In a general manner, NOS II is a better catalyst that NOS I and III for the oxidation of exogenous guanidines and N-hydroxyguanidines to NO. This is particularly true for guanidines as the ones acting as substrates for NOS II have been found to be almost inactive for NOS I and NOS III. Thus, a good NO-producing guanidine substrate for the two latter isozymes remains to be found.

Isoform-selective substrates of nitric oxide synthase

Because of the double-edged nature of NO, the development of isoform-selective NOS substrates is a highly desirable goal. Given the striking similarity in the heme active sites of the three NOS isoforms, it presents an challenging problem. Several N-aryl-N'-hydroxyguanidines have recently been shown as substrates that are selective for iNOS over nNOS. Here, we report the first success that 3 is a good substrate for nNOS (70% activity of NOHA, K(m) approximately 40 +/- 6 microM) over iNOS.

Two modes of binding of N-hydroxyguanidines to NO synthases: first evidence for the formation of iron-N-hydroxyguanidine complexes and key role of tetrahydrobiopterin in determining the binding mode

The interaction of various N-alkyl- and N-aryl-N'-hydroxyguanidines with recombinant NOS containing or not containing tetrahydrobiopterin (BH(4)) was studied by visible, electronic paramagnetic resonance (EPR), and resonance Raman (RR) spectroscopy. N-Hydroxyguanidines interact with the oxygenase domain of BH(4)-free inducible NOS (BH(4)-free iNOS(oxy)), depending on the nature of their substituent, with formation of two types of complexes that are characterized by peaks around 395 (type I) and 438 nm (type II') during difference visible spectroscopy. The complex formed between BH(4)-free iNOS(oxy) and N-benzyl-N'-hydroxyguanidine 1 (type II') exhibited a Soret peak at 430 nm, EPR signals at g = 1.93, 2.24, and 2.38, and RR bands at 1374 and 1502 cm(-)(1) that are characteristic of a low-spin hexacoordinated Fe(III) complex. Analysis of its EPR spectrum according to Taylor's equations indicates that the cysteinate ligand of native BH(4)-free iNOS(oxy) is retained in that complex. Similar iron(III)-ligand complexes were formed upon reaction of 1 and several other N-hydroxyguanidines with BH(4)-free full-length iNOS and BH(4)-free nNOS(oxy). However, none of the tested N-hydroxyguanidines were able to form such iron(III)-ligand complexes with BH(4)-containing iNOS(oxy), indicating that a major factor involved in the mode of binding of N-hydroxyguanidines to NOS is the presence (or absence) of BH(4) in their active site. Another factor that plays a key role in the mode of binding of N-hydroxyguanidines to NOS is the nature of their substituent. The N-hydroxyguanidines bearing an N-alkyl substituent exclusively or mainly led to type II' iron-ligand complexes. Those bearing an N-aryl substituent mainly led to type II' complexes, even though some of them exclusively led to type I complexes. Interestingly, the K(s) values calculated for BH(4)-free iNOS(oxy)-N-hydroxyguanidine complexes were always lower when their substituents bore an aryl group (140-420 microM instead of 1000-3900 microM), suggesting the existence of pi-pi interactions between this group and an aromatic residue of the protein. Comparison of the spectral and physicochemical properties of the N-hydroxyguanidine complexes of BH(4)-free iNOS(oxy) (type II') with those of the previously described corresponding complexes of microperoxidase (MP-8) suggests that, in both cases, N-hydroxyguanidines bind to iron(III) via their oxygen atom after deprotonation or weakening of the O-H bond. The aforementioned results are discussed in relation with recent data about the transient formation of iron-product intermediates during the catalytic cycle of l-arginine oxidation by eNOS. They suggest that N-hydroxyguanidines could constitute a new class of good ligands of heme proteins.

Involvement of NO in the endothelium-independent relaxing effects of N(omega)-hydroxy-L-arginine and other compounds bearing a C=NOH function in the rat aorta

The mechanisms of vasorelaxation elicited by N(omega)-hydroxy-L-arginine (L-NOHA) and other compounds bearing a C=NOH function and the structural determinants governing this effect were investigated in rat aorta. L-NOHA, formamidoxime, five aromatic monosubstituted amidoximes, and one aromatic monosubstituted ketoxime elicited relaxation in endothelium-denuded rings. N-Hydroxyguanidine and substituted N-hydroxyguanidines were markedly less active. Relaxations induced by L-NOHA and by the most active studied compound, 4-chlorobenzamidoxime (ClBZA), were unmodified by the presence of endothelium. In endothelium-denuded rings, they were blunted by the NO scavenger 2-phenyl-4,4,5,5-tetramethyl-imidazoline-1-oxyl-3-oxide (300 microM) and by the inhibitor of guanylyl-cyclase activation 1H[1,2,4,]oxadiazolo[4,3-a]quinoxalin-1-one (1 microM). In addition, L-NOHA- and ClBZA both caused cGMP accumulation. L-Arginine, but not D-arginine (1 mM), antagonized the effect of L-NOHA but not ClBZA. Both L-NOHA- and ClBZA-induced relaxations were inhibited by the NAD(P)H-dependent enzymes inhibitor diphenyliodonium (30 microM) and the NAD(P)H-dependent reductases inhibitor 7-ethoxyresorufin (10 microM), but they were unmodified by the cytochrome P450 (P450) inhibitor proadifen (10 microM) and by the NO synthase inhibitor N(omega)-nitro-L-arginine methyl ester (L-NAME, 300 microM). These results show that L-NOHA and other compounds with a C=NOH function can cause endothelium-independent relaxation in the rat aorta. They suggest that activation of guanylyl cyclase and NO formation is implicated in relaxation and that a 7-ethoxyresorufin-sensitive NAD(P)H-dependent pathway is involved. On one hand, L-NOHA and amidoximes may be useful tools for characterizing this pathway in blood vessels and, on the other, may offer a novel approach for treating vascular diseases with impaired endothelial NO activity.

Novel substrates for nitric oxide synthases

Enzymatic generation of nitric oxide (NO) by nitric oxide synthase (NOS) consists of two oxidation steps. The first step converts L-arginine to N(G)-hydroxy-L-arginine (NOHA), a key intermediate, and the second step converts NOHA to NO and L-citrulline. To fully probe the substrate specificity of the second enzymatic step, an extensive structural screening was carried out using a series of N-alkyl (and N-aryl) substituted-N'-hydroxyguanidines (1-14). Among the eleven N-alkyl-N'-hydroxyguanidines evaluated, N-n-propyl (2), N-iso-propyl (3), N-n-butyl (4), N-s-butyl (5), N-iso-butyl (6), N-pentyl (8) and N-iso-pentyl (9) derivatives were efficiently oxidized by the three isoenzymes of NOS (nNOS, iNOS and eNOS) to generate NO. N-Butyl-N'-hydroxyguanidine (4) was the best substrate for iNOS (K(m)=33 microM) and N-iso-propyl-N'-hydroxyguanidine (3) was the best substrate for nNOS (K(m)=56 microM). When the alkyl substituents were too small (such as ethyl 1) or too large (such as hexyl 10 and cyclohexyl 11), the activity decreased significantly. This suggests that the van der Waals interaction between the alkyl group and the hydrophobic cavity in the NOS active site contributes significantly to the relative reactivity of compounds 3-11. Moreover, five N-aryl-N'-hydroxyguanidines were found to be good substrates for iNOS, but not substrates for eNOS and nNOS. N-phenyl-N'-hydroxyguanidine was the best substrate among them (K(m)=243 microM). This work demonstrates that N-alkyl substituted hydroxyguanidine compounds are novel NOS substrates which 'short-circuit' the first oxidation step of NOS, and N-aryl substituted hydroxyguanidine compounds are isoform selective NOS substrate.

Electron supply and catalytic oxidation of nitrogen by cytochrome P450 and nitric oxide synthase

Cytochrome P450 and nitric oxide synthase (NOS) oxidize nitrogen atoms, although the substrates and transformations are highly restricted for NOS. The first reaction catalyzed by NOS is mediated by a P450-like ferryl species, although it is generated by a distinct process in which a tetrahydrobiopterin molecule in NOS serves as a transient electron donor. The second NOS reaction appears to be mediated by an iron dioxygen precursor of the ferryl species. The transient tetrahydrobiopterin radical formed in these reactions is quenched by electron transfer from the NOS flavin domain. Electron transfer from the flavins is controlled by the binding of calmodulin, the presence of peptide inserts in the flavin domain, the substrate structure, and phosphorylation of the enzyme.

Oxidation of N-hydroxyguanidines by cytochromes P450 and NO-synthases and formation of nitric oxide

Microsomal cytochromes P450 and tetrahydrobiopterin (BH4) free-NOS II catalyze the oxidation of N-hydroxyguanidines by NADPH and O2 with formation of nitrogen oxides including NO. These reactions are not selective in terms of substrates, as they occur on most N-hydroxyguanidines, and of products, as they not only lead to corresponding ureas but also to cyanamides. These non selective reactions are mainly due to O2- derived from the oxidase function of those hemeproteins. By contrast, NO synthase (NOS) containing BH4 catalyze the selective monooxygenation of some N-hydroxyguanidines by NADPH and O2 with formation of NO and the corresponding ureas in a 1:1 molar ratio. Those reactions are not inhibited by superoxide dismutase (SOD) and are performed by the NOS Fe(II)-O2 complex. The endogenous NOS substrate N(omega)-hydroxy-L-arginine (NOHA), and its close analogue homo-NOHA, are selectively oxidized in this manner by NOS whereas nor-NOHA and dinor-NOHA are not. Moreover, some non alpha-amino acid N-hydroxyguanidines act as NOS substrates in a manner similar to NOHA. This includes a small number of simple N-alkyl N'-hydroxyguanidines with R(alkyl) propyl, butyl, and pentyl, and some N-aryl N'-hydroxyguanidines that involve a relatively small and preferably electron-rich aryl substituent. The best exogenous substrate of NOS reported so far is N-butyl N'-hydroxyguanidine; this compound is oxidized by NOS II with formation of NO with a catalytic efficiency (kcat/Km) only two times lower than NOHA itself. N-butyl N'-hydroxyguanidine is also a good substrate for NOS I and NOS III. However, some N-aryl N'-hydroxyguanidines, with Ar = p-chlorophenyl and p-methylphenyl, are selective substrates of NOS II. These results show that exogenous N-hydroxyguanidines not bearing an alpha-amino acid function are efficiently and selectively oxidized by NOS with forrmation of NO. They open the way toward the research of new NO donors based on selective substrates of each class of NOS.

First non-alpha-amino acid guanidines acting as efficient NO precursors upon oxidation by NO-synthase II or activated mouse macrophages

A study of the oxidation of a series of guanidines related to L-arginine (L-Arg) and of various alkyl- and arylguanidines, by recombinant NO-synthase II (NOS II), led us to the discovery of the first non-alpha-amino acid guanidine substrate of NOS, acting as an efficient NO precursor. This compound, 3-(trifluoromethyl)propylguanidine, 4, led to a rate of NO formation (k(cat) = 220 +/- 50 min(-1)) only 2 times lower than that of L-Arg. Formation of 1 mol of NO upon NOS II-catalyzed oxidation of 4 occurred with consumption of 2.9 mol of NADPH, which corresponds to a 52% coupling between electron transfer and oxygenation of its guanidine function. Its oxidation by activated mouse macrophages in an L-Arg-free medium resulted in NO(2)(-) formation that was inhibited by classical NOS inhibitors with a rate only 2-3 times lower than that observed with L-Arg itself. These results open the way toward the research of selective, stable guanidine substrates of NOS that could be interesting, new NO donors after in situ oxidation by a given NOS isoform.

Electrochemical and peroxidase oxidation study of N'-hydroxyguanidine derivatives as NO donors

The electrochemical properties of a series of N-substituted-N'-hydroxyguanidines were studied. Two oxidation potentials of each compound were obtained by cyclic voltammetry. The E(ox1) values were from 0.51 to 0.62V, while the E(ox2) values were from 1.14 to 1.81V in acetonitrile solution. Next, their enzymatic controlled NO release abilities were evaluated. All N'-hydroxyguanidines exhibited efficient NO release abilities under the oxidation by horseradish peroxidase in the presence of H(2)O(2).

A conserved tryptophan 457 modulates the kinetics and extent of N-hydroxy-L-arginine oxidation by inducible nitric-oxide synthase

In the oxygenase domain of mouse inducible nitric-oxide synthase (iNOSoxy), a conserved tryptophan residue, Trp-457, regulates the kinetics and extent of l-Arg oxidation to N(omega)-hydroxy-l-arginine (NOHA) by controlling electron transfer between bound (6R)-tetrahydrobiopterin (H(4)B) cofactor and the enzyme heme Fe(II)O(2) intermediate (Wang, Z. Q., Wei, C. C., Ghosh, S., Meade, A. L., Hemann, C., Hille, R., and Stuehr, D. J. (2001) Biochemistry 40, 12819-12825). To investigate whether NOHA oxidation to citrulline and nitric oxide (NO) is regulated by a similar mechanism, we performed single turnover reactions with wild type iNOSoxy and mutants W457F and W457A. Ferrous proteins containing NOHA plus H(4)B or NOHA plus 7,8-dihydrobiopterin (H(2)B), were mixed with O(2)-containing buffer, and then heme spectral transitions and product formation were followed versus time. All three proteins formed a Fe(II)O(2) intermediate with identical spectral characteristics. In wild type, H(4)B increased the disappearance rate of the Fe(II)O(2) intermediate relative to H(2)B, and its disappearance was coupled to the formation of a Fe(III)NO immediate product prior to formation of ferric enzyme. In W457F and W457A, the disappearance rate of the Fe(II)O(2) intermediate was slower than in wild type and took place without detectable build-up of the heme Fe(III)NO immediate product. Rates of Fe(II)O(2) disappearance correlated with rates of citrulline formation in all three proteins, and reactions containing H(4)B formed 1.0, 0.54, and 0.38 citrulline/heme in wild type, W457F, and W457A iNOSoxy, respectively. Thus, Trp-457 modulates the kinetics of NOHA oxidation by iNOSoxy, and this is important for determining the extent of citrulline and NO formation. Our findings support a redox role for H(4)B during NOHA oxidation to NO by iNOSoxy.

N-Aryl N'-hydroxyguanidines, a new class of NO-donors after selective oxidation by nitric oxide synthases: structure-activity relationship

The formation of nitric oxide (NO) was followed during the oxidation of 37 N-hydroxyguanidines or related derivatives, including 18 new N-aryl N'-hydroxyguanidines, by recombinant inducible nitric oxide synthase (NOS II). Several N-aryl N'-hydroxyguanidines bearing a relatively small, electron-donating para subtituent, such as H, F, Cl, CH(3), OH, OCH(3), and NH(2), led to NO formation rates between 8 and 41% of that of NO formation from the natural NOS substrate, N(omega)-hydroxy-L-arginine (NOHA). The characteristics of these reactions were very similar to those previously reported for the oxidation of NOHA by NOS:(i) the strict requirement of NOS containing (6R)-5,6,7,8-tetrahydro-L-biopterin, reduced nicotinamide adenine dinucleotide phosphate, and O(2) for the oxidation to occur, (ii) the formation of NO and the corresponding urea in a 1:1 molar ratio, and (iii) a strong inhibitory effect of the classical NOS inhibitors such as N(omega)-nitro-L-arginine and S-ethyl-iso-thiourea. Structure-activity relationship studies showed that two structural factors are crucial for NO formation from compounds containing a C(triple bond)NOH function. The first one is the presence of a monosubstituted N-hydroxyguanidine function, since disubstituted N-hydroxyguanidines, amidoximes, ketoximes, and aldoximes failed to produce NO. The second one is the presence of a N-phenyl ring bearing a relatively small, not electron-withdrawing para substituent that could favorably interact with a hydrophobic cavity close to the NOS catalytic site. The k(cat) value for NOS II-catalyzed oxidation of N-para-fluorophenyl N'-hydroxyguanidine was 80% of that found for NOHA, and its k(cat)/K(m) value was only 9-fold lower than that of NOHA. Interestingly, the K(m) value found for NOS II-catalyzed oxidation of N-(3-thienyl) N'-hydroxyguanidine was 25 microM, almost identical to that of NOHA. Recombinant NOS I and NOS III also oxidize several N-aryl N'-hydroxyguanidines with the formation of NO, with a clearly different substrate specificity. The best substrates of the studied series for NOS I and NOS III were N-(para-hydroxyphenyl) and N-(meta-aminophenyl) N'-hydroxyguanidine, respectively. Among the studied compounds, the para-chlorophenyl and para-methylphenyl derivatives were selective substrates of NOS II. These results open the way toward a new class of selective NO donors after in situ oxidation by each NOS family.