The three nitric-oxide synthases differ in their kinetics of tetrahydrobiopterin radical formation, heme-dioxy reduction, and arginine hydroxylation

The nitric-oxide synthases (NOSs) make nitric oxide and citrulline from l-arginine. How the bound cofactor (6R)-tetrahydrobiopterin (H4B) participates in Arg hydroxylation is a topic of interest. We demonstrated previously that H4B radical formation in the inducible NOS oxygenase domain (iNOSoxy) is kinetically coupled to the disappearance of a heme-dioxy intermediate and to Arg hydroxylation. Here we report single turnover studies that determine and compare the kinetics of these transitions in Arg hydroxylation reactions catalyzed by the oxygenase domains of endothelial and neuronal NOSs (eNOSoxy and nNOSoxy). There was a buildup of a heme-dioxy intermediate in eNOSoxy and nNOSoxy followed by a monophasic transition to ferric enzyme during the reaction. The rate of heme-dioxy decay matched the rates of H4B radical formation and Arg hydroxylation in both enzymes. The rates of H4B radical formation differed such that nNOSoxy (18 s(-1)) > iNOSoxy (11 s(-1)) > eNOSoxy (6 s(-1)), whereas the lifetimes of the resulting H4B radical followed an opposite rank order. 5MeH4B supported a three-fold faster radical formation and greater radical stability relative to H4B in both eNOSoxy and nNOSoxy. Our results indicate the following: (i) the three NOSs share a common mechanism, whereby H4B transfers an electron to the heme-dioxy intermediate. This step enables Arg hydroxylation and is rate-limiting for all subsequent steps in the hydroxylation reaction. (ii) A direct correlation exists between pterin radical stability and the speed of its formation in the three NOSs. (iii) Uncoupled NO synthesis often seen for eNOS at low H4B concentrations may be caused by the slow formation and poor stability of its H4B radical.     

A conserved tryptophan in nitric oxide synthase regulates heme-dioxy reduction by tetrahydrobiopterin.

In nitric oxide synthase (NOS), (6R)-tetrahydrobiopterin (H(4)B) binds near the heme and can reduce a heme-dioxygen intermediate (Fe(II)O(2)) during Arg hydroxylation [Wei, C.-C., Wang, Z.-Q., Wang, Q., Meade, A. L., Hemann, C., Hille, R., and Stuehr, D. J. (2001) J. Biol. Chem. 276, 315-319]. A conserved Trp engages in aromatic stacking with H(4)B, and its mutation inhibits NO synthesis. To examine how this W457 impacts H(4)B redox function, we performed single turnover reactions with the mouse inducible NOS oxygenase domain (iNOSoxy) mutants W457F and W457A. Ferrous mutants containing Arg and H(4)B were mixed with O(2)-containing buffer, and then heme spectral transitions, H(4)B radical formation, and Arg hydroxylation were followed versus time. A heme Fe(II)O(2) intermediate was observed in W457A and W457F and had normal spectral characteristics. However, its disappearance rate (6.5 s(-1) in W457F and 3.0 s(-1) in W457A) was slower than in wild-type (12.5 s(-1)). Rates of H(4)B radical formation (7.1 s(-1) in W457F and 2.7 s(-1) in W457A) matched their rates of Fe(II)O(2) disappearance, but were slower than radical formation in wild-type (13 s(-1)). The extent of H(4)B radical formation in the mutants was similar to wild-type, but their radical decayed 2-4 times faster. These kinetic changes correlated with slower and less extensive Arg hydroxylation by the mutants (wild-type > W457F > W457A). We conclude that W457 ensures a correct tempo of electron transfer from H(4)B to heme Fe(II)O(2), possibly by stabilizing the H(4)B radical. Proper control of these parameters may help maximize Arg hydroxylation and minimize uncoupled O(2) activation at the heme.     

Structure of tetrahydrobiopterin tunes its electron transfer to the heme-dioxy intermediate in nitric oxide synthase

How 6R-tetrahydrobiopterin (H(4)B) participates in Arg hydroxylation as catalyzed by the nitric oxide synthases (NOSs) is a topic of current interest. Previous work with the oxygenase domain of inducible NOS (iNOSoxy) demonstrated that H(4)B radical formation is kinetically coupled to disappearance of an initial heme-dioxy intermediate and to Arg hydroxylation in a single turnover reaction run at 10 degrees C [Wei, C.-C., Wang, Z.-Q., Wang, Q., Meade, A. L., Hemann, C., Hille, R., and Stuehr, D. J. (2001) J. Biol. Chem. 276, 315-319]. Here we used 5-methyl-H(4)B to investigate how pterin structure influences radical formation and associated catalytic steps. In the presence of Arg, the heme-dioxy intermediate in 5-methyl-H(4)B-bound iNOSoxy reacted at a rate of 35 s(-)(1), which is 3-fold faster than with H(4)B. This was coupled to a faster rate of 5-methyl-H(4)B radical formation (40 vs 12.5 s(-)(1)) and to a faster and more productive Arg hydroxylation. The EPR spectrum of the enzyme-bound 5-methyl-H(4)B radical had different hyperfine structure than the bound H(4)B radical and exhibited a 3-fold longer half-life after its formation. A crystal structure of 5-methyl-H(4)B-bound iNOSoxy revealed that there are minimal changes in conformation of the bound pterin or in its interactions with the protein as compared to H(4)B. Together, we conclude the following: (1) The rate of heme-dioxy reduction is linked to pterin radical formation and is sensitive to pterin structure. (2) Faster heme-dioxy reduction increases the efficiency of Arg hydroxylation but still remains rate limiting for the reaction. (3) The 5-methyl group influences heme-dioxy reduction by altering the electronic properties of the pterin rather than changing protein structure or interactions. (4) Faster electron transfer from 5-methyl-H(4)B may be due to increased radical stability afforded by the N-5 methyl group.     

A tetrahydrobiopterin radical forms and then becomes reduced during Nomega-hydroxyarginine oxidation by nitric-oxide synthase

Nitric-oxide synthases are flavoheme enzymes that catalyze two sequential monooxygenase reactions to generate nitric oxide (NO) from l-arginine. We investigated a possible redox role for the enzyme-bound cofactor 6R-tetrahydrobiopterin (H4B) in the second reaction of NO synthesis, which is conversion of N-hydroxy-l-arginine (NOHA) to NO plus citrulline. We used stopped-flow spectroscopy and rapid-freeze EPR spectroscopy to follow heme and biopterin transformations during single-turnover NOHA oxidation reactions catalyzed by the oxygenase domain of inducible nitric-oxide synthase (iNOSoxy). Significant biopterin radical (>0.5 per heme) formed during reactions catalyzed by iNOSoxy that contained either H4B or 5-methyl-H4B. Biopterin radical formation was kinetically linked to conversion of a heme-dioxy intermediate to a heme-NO product complex. The biopterin radical then decayed within a 200-300-ms time period just prior to dissociation of NO from a ferric heme-NO product complex. Measures of final biopterin redox status showed that biopterin radical decay occurred via an enzymatic one-electron reduction process that regenerated H4B (or 5MeH4B). These results provide evidence of a dual redox function for biopterin during the NOHA oxidation reaction. The data suggest that H4B first provides an electron to a heme-dioxy intermediate, and then the H4B radical receives an electron from a downstream reaction intermediate to regenerate H4B. The first one-electron transition enables formation of the heme-based oxidant that reacts with NOHA, while the second one-electron transition is linked to formation of a ferric heme-NO product complex that can release NO from the enzyme. These redox roles are novel and expand our understanding of biopterin function in biology.     

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.     

Stabilization and characterization of a heme-oxy reaction intermediate in inducible nitric-oxide synthase

Nitric-oxide synthases (NOS) are heme-thiolate enzymes that N-hydroxylate L-arginine (L-Arg) to make NO. NOS contain a unique Trp residue whose side chain stacks with the heme and hydrogen bonds with the heme thiolate. To understand its importance we substituted His for Trp188 in the inducible NOS oxygenase domain (iNOSoxy) and characterized enzyme spectral, thermodynamic, structural, kinetic, and catalytic properties. The W188H mutation had relatively small effects on l-Arg binding and on enzyme heme-CO and heme-NO absorbance spectra, but increased the heme midpoint potential by 88 mV relative to wild-type iNOSoxy, indicating it decreased heme-thiolate electronegativity. The protein crystal structure showed that the His188 imidazole still stacked with the heme and was positioned to hydrogen bond with the heme thiolate. Analysis of a single turnover L-Arg hydroxylation reaction revealed that a new heme species formed during the reaction. Its build up coincided kinetically with the disappearance of the enzyme heme-dioxy species and with the formation of a tetrahydrobiopterin (H4B) radical in the enzyme, whereas its subsequent disappearance coincided with the rate of l-Arg hydroxylation and formation of ferric enzyme. We conclude: (i) W188H iNOSoxy stabilizes a heme-oxy species that forms upon reduction of the heme-dioxy species by H4B. (ii) The W188H mutation hinders either the processing or reactivity of the heme-oxy species and makes these steps become rate-limiting for l-Arg hydroxylation. Thus, the conserved Trp residue in NOS may facilitate formation and/or reactivity of the ultimate hydroxylating species by tuning heme-thiolate electronegativity.     

Why do nitric oxide synthases use tetrahydrobiopterin?

We are combining stopped-flow, stop-quench, and rapid-freezing kinetic methods to help clarify the unique redox roles of tetrahydrobiopterin (H(4)B) in NO synthesis, which occurs via the consecutive oxidation of L-arginine (Arg) and N-hydroxy-L-arginine (NOHA). In the Arg reaction, H(4)B radical formation is coupled to reduction of a heme Fe(II)O(2) intermediate. The tempo of this electron transfer is important for coupling Fe(II)O(2) formation to Arg hydroxylation. Because H(4)B provides this electron faster than can the NOS reductase domain, H(4)B appears to be a kinetically preferred source of the second electron for oxygen activation during Arg hydroxylation. A conserved Trp (W457 in mouse inducible NOS) has been shown to influence product formation by controlling the kinetics of H(4)B electron transfer to the Fe(II)O(2) intermediate. This shows that the NOS protein tunes H(4)B redox function. In the NOHA reaction the role of H(4)B is more obscure. However, existing evidence suggests that H(4)B may perform consecutive electron donor and acceptor functions to reduce the Fe(II)O(2) intermediate and then ensure that NO is produced from NOHA.     

Control of nitric oxide synthase dimer assembly by a heme-NO-dependent mechanism

Homodimer formation is a key step that follows heme incorporation during assembly of an active inducible nitric oxide synthase (iNOS). In cells, heme incorporation into iNOS becomes limited due to interaction between self-generated NO and cellular heme [Albakri, Q., and Stuehr, D. J. (1996) J. Biol. Chem. 271, 5414-5421]. Here we investigated if NO can regulate at points downstream in the process by inhibiting dimerization of heme-containing iNOS monomer. Heme-containing monomers were generated by treating iNOS dimer or iNOS oxygenase domain dimer (iNOSoxy) with urea. Both monomers dimerized when incubated with Arg and 6R-tetrahydrobiopterin (H4B), as shown previously [Abu-Soud, H. M., Loftus, M., and Stuehr, D. J. (1995) Biochemistry 34, 11167-11175]. The NO-releasing drug S-nitrosyl-N-acetyl-D,L-penicillamine (SNAP; 0-0.5 mM) inhibited dimerization of iNOS monomer in a dose- and time-dependent manner, without causing heme release. SNAP-pretreated monomer also did not dimerize in response to H4B plus Arg. SNAP converted Arg- and H4B-free iNOS dimer into monomer that could not redimerize, but had no effect on iNOS dimer preincubated with Arg and H4B. Anaerobic spectral analysis showed that NO from SNAP bound to the ferric heme of iNOSoxy monomer or dimer. Adding imidazole as an alternative heme ligand prevented SNAP from inhibiting iNOS monomer dimerization. We conclude that NO and related species can block iNOS dimerization at points downstream from heme incorporation. The damage to heme-containing monomer results from a reaction with the protein and appears irreversible. Although dimeric structure alone does not protect, it does enable Arg and H4B to bind and protect. Inhibition appears mediated by NO coordinating to the ferric heme iron of the monomer.     

A conserved Val to Ile switch near the heme pocket of animal and bacterial nitric-oxide synthases helps determine their distinct catalytic profiles

Nitric oxide (NO) release from nitric oxide synthases (NOSs) is largely dependent on the dissociation of an enzyme ferric heme-NO product complex (Fe(III)NO). Although the NOS-like protein from Bacillus subtilis (bsNOS) generates Fe(III)NO from the reaction intermediate N-hydroxy-l-arginine (NOHA), its NO dissociation is about 20-fold slower than in mammalian NOSs. Crystal structures suggest that a conserved Val to Ile switch near the heme pocket of bsNOS might determine its kinetic profile. To test this we generated complementary mutations in the mouse inducible NOS oxygenase domain (iNOSoxy, V346I) and in bsNOS (I224V) and characterized the kinetics and extent of their NO synthesis from NOHA and their NO-binding kinetics. The mutations did not greatly alter binding of Arg, (6R)-tetrahydrobiopterin, or alter the electronic properties of the heme or various heme-ligand complexes. Stopped-flow spectroscopy was used to study heme transitions during single turnover NOHA reactions. I224V bsNOS displayed three heme transitions involving four species as typically occurs in wild-type NOS, the beginning ferrous enzyme, a ferrous-dioxy (Fe(II)O(2)) intermediate, Fe(III)NO, and an ending ferric enzyme. The rate of each transition was increased relative to wild-type bsNOS, with Fe(III)NO dissociation being 3.6 times faster. In V346I iNOSoxy we consecutively observed the beginning ferrous, Fe(II)O(2), a mixture of Fe(III)NO and ferric heme species, and ending ferric enzyme. The rate of each transition was decreased relative to wild-type iNOSoxy, with the Fe(III)NO dissociation being 3 times slower. An independent measure of NO binding kinetics confirmed that V346I iNOSoxy has slower NO binding and dissociation than wild-type. Citrulline production by both mutants was only slightly lower than wild-type enzymes, indicating good coupling. Our data suggest that a greater shielding of the heme pocket caused by the Val/Ile switch slows down NO synthesis and NO release in NOS, and thus identifies a structural basis for regulating these kinetic variables.     

Catalytic reduction of a tetrahydrobiopterin radical within nitric-oxide synthase

Nitric-oxide synthases (NOS) are catalytically self-sufficient flavo-heme enzymes that generate NO from arginine (Arg) and display a novel utilization of their tetrahydrobiopterin (H(4)B) cofactor. During Arg hydroxylation, H(4)B acts as a one-electron donor and is then presumed to redox cycle (i.e. be reduced back to H(4)B) within NOS before further catalysis can proceed. Whereas H(4)B radical formation is well characterized, the subsequent presumed radical reduction has not been demonstrated, and its potential mechanisms are unknown. We investigated radical reduction during a single turnover Arg hydroxylation reaction catalyzed by neuronal NOS to document the process, determine its kinetics, and test for involvement of the NOS flavoprotein domain. We utilized a freeze-quench instrument, the biopterin analog 5-methyl-H(4)B, and a method that could separately quantify the flavin and pterin radicals that formed in NOS during the reaction. Our results establish that the NOS flavoprotein domain catalyzes reduction of the biopterin radical following Arg hydroxylation. The reduction is calmodulin-dependent and occurs at a rate that is similar to heme reduction and fast enough to explain H(4)B redox cycling in NOS. These results, in light of existing NOS crystal structures, suggest a "through-heme" mechanism may operate for H(4)B radical reduction in NOS.     

Formation of a pterin radical in the reaction of the heme domain of inducible nitric oxide synthase with oxygen

The heme domain (iNOS(heme)) of inducible nitric oxide synthase (NOS) was expressed in Escherichia coli and purified to homogeneity. Rapid freeze-quench (RFQ) EPR was used to monitor the reaction of the reduced iNOS(heme) with oxygen in the presence and absence of substrate. In these reactions, heme oxidation occurs at a rate of approximately 15 s(-)(1) at 4 degrees C. A transient species with a g = 2.0 EPR signal is also observed under these conditions. The spectral properties of the g = 2.0 signal are those of an anisotropic organic radical with S = (1)/(2). Comparison of the EPR spectra obtained when iNOS(heme) is reconstituted with N5-(14)N- and (15)N-substituted tetrahydrobiopterin (H(4)B) shows a hyperfine interaction with the pterin N5 nitrogen and identifies the radical as the one-electron oxidized form (H(3)B.) of the bound H(4)B. Substitution of D(2)O for H(2)O reveals the presence of hyperfine-coupled exchangeable protons in the H(4)B radical. This radical forms at a rate of 15-20 s(-)(1), with a slower decay rate that varies (0.12-0.7 s(-)(1)) depending on the substrate. At 127 ms, H(3)B. accumulates to a maximum of 80% of the total iNOS(heme) concentration in the presence of arginine but only to approximately 2.8% in the presence of NHA. Double-mixing RFQ experiments, where NHA is added after the formation of H(3)B., show that NHA does not react rapidly with H(3)B. and suggest that NHA instead prevents the formation of the H(4)B radical. These data constitute the first direct evidence for an NOS-bound H(3)B. and are most consistent with a role for H(4)B in electron transfer in the NOS reaction.     

Structures of tetrahydrobiopterin binding-site mutants of inducible nitric oxide synthase oxygenase dimer and implicated roles of Trp457.

To better understand potential roles of conserved Trp457 of the murine inducible nitric oxide synthase oxygenase domain (iNOS(ox); residues 1-498) in maintaining the structural integrity of the (6R)-5,6,7,8-tetrahydrobiopterin (H(4)B) binding site located at the dimer interface and in supporting H(4)B redox activity, we determined crystallographic structures of W457F and W457A mutant iNOS(ox) dimers (residues 66-498). In W457F iNOS(ox), all the important hydrogen-bonding and aromatic stacking interactions that constitute the H(4)B binding site and that bridge the H(4)B and heme sites are preserved. In contrast, the W457A mutation results in rearrangement of the Arg193 side chain, orienting its terminal guanidinium group almost perpendicular to the ring plane of H(4)B. Although Trp457 is not required for dimerization, both Trp457 mutations led to the increased mobility of the N-terminal H(4)B binding segment (Ser112-Met114), which might indicate reduced stability of the Trp457 mutant dimers. The Trp457 mutant structures show decreased pi-stacking with bound pterin when the wild-type pi-stacking Trp457 position is occupied with the smaller Phe457 in W457F or positive Arg193 in W457A. The reduced pterin pi-stacking in these mutant structures, relative to that in the wild-type, implies stabilization of reduced H(4)B and destabilization of the pterin radical, consequently slowing electron transfer to the heme ferrous-dioxy (Fe(II)O(2)) species during catalysis. These crystal structures therefore aid elucidation of the roles and importance of conserved Trp457 in maintaining the structural integrity of the H(4)B binding site and of H(4)B-bound dimers, and in influencing the rate of electron transfer between H(4)B and heme in NOS catalysis.     

Distinct dimer interaction and regulation in nitric-oxide synthase types I,II, and III

Homodimer formation activates all nitric-oxide synthases (NOSs). It involves the interaction between two oxygenase domains (NOSoxy) that each bind heme and (6R)-tetrahydrobiopterin (H4B) and catalyze NO synthesis from L-Arg. Here we compared three NOSoxy isozymes regarding dimer strength, interface composition, and the ability of L-Arg and H4B to stabilize the dimer, promote its formation, and protect it from proteolysis. Urea dissociation studies indicated that the relative dimer strengths were NOSIIIoxy > NOSIoxy > NOSIIoxy (endothelial NOSoxy (eNOSoxy) > neuronal NOSOXY (nNOSoxy) > inducible NOSoxy (iNOSoxy)). Dimer strengths of the full-length NOSs had the same rank order as judged by their urea-induced loss of NO synthesis activity. NOSoxy dimers containing L-Arg plus H4B exhibited the greatest resistance to urea-induced dissociation followed by those containing either molecule and then by those containing neither. Analysis of crystallographic structures of eNOSoxy and iNOSoxy dimers showed more intersubunit contacts and buried surface area in the dimer interface of eNOSoxy than iNOSoxy, thus revealing a potential basis for their different stabilities. L-Arg plus H4B promoted dimerization of urea-generated iNOSoxy and nNOSoxy monomers, which otherwise was minimal in their absence, and also protected both dimers against trypsin proteolysis. In these respects, L-Arg alone was more effective than H4B alone for nNOSoxy, whereas for iNOSoxy the converse was true. The eNOSoxy dimer was insensitive to proteolysis under all conditions. Our results indicate that the three NOS isozymes, despite their general structural similarity, differ markedly in their strengths, interfaces, and in how L-Arg and H4B influence their formation and stability. These distinguishing features may provide a basis for selective control and likely help to regulate each NOS in its particular biologic milieu.     

Activation of peroxynitrite by inducible nitric-oxide synthase: a direct source of nitrative stress

In mammals, nitric oxide (NO) is an essential biological mediator that is exclusively synthesized by nitric-oxide synthases (NOSs). However, NOSs are also directly or indirectly responsible for the production of peroxynitrite, a well known cytotoxic agent involved in numerous pathophysiological processes. Peroxynitrite reactivity is extremely intricate and highly depends on activators such as hemoproteins. NOSs present, therefore, the unique ability to both produce and activate peroxynitrite, which confers upon them a major role in the control of peroxynitrite bioactivity. We report here the first kinetic analysis of the interaction between peroxynitrite and the oxygenase domain of inducible NOS (iNOSoxy). iNOSoxy binds peroxynitrite and accelerates its decomposition with a second order rate constant of 22 x 10(4) m(-1)s(-1) at pH 7.4. This reaction is pH-dependent and is abolished by the binding of substrate or product. Peroxynitrite activation is correlated with the observation of a new iNOS heme intermediate with specific absorption at 445 nm. iNOSoxy modifies peroxynitrite reactivity and directs it toward one-electron processes such as nitration or one-electron oxidation. Taken together our results suggest that, upon binding to iNOSoxy, peroxynitrite undergoes homolytic cleavage with build-up of an oxo-ferryl intermediate and concomitant release of a NO(2)(.) radical. Successive cycles of peroxynitrite activation were shown to lead to iNOSoxy autocatalytic nitration and inhibition. The balance between peroxynitrite activation and self-inhibition of iNOSoxy may determine the contribution of NOSs to cellular oxidative stress.     

A tryptophan that modulates tetrahydrobiopterin-dependent electron transfer in nitric oxide synthase regulates enzyme catalysis by additional mechanisms

Nitric oxide synthases (NOSs) are flavo-heme enzymes that require (6R)-tetrahydrobiopterin (H(4)B) for activity. Our single-catalytic turnover study with the inducible NOS oxygenase domain showed that a conserved Trp that interacts with H(4)B (Trp457 in mouse inducible NOS) regulates the kinetics of electron transfer between H(4)B and an enzyme heme-dioxy intermediate, and this in turn alters the kinetics and extent of Arg hydroxylation [Wang, Z.-Q., et al. (2001) Biochemistry 40, 12819-12825]. To investigate the impact of these effects on NADPH-driven NO synthesis by NOS, we generated and characterized the W457A mutant of inducible NOS and the corresponding W678A and W678F mutants of neuronal NOS. Mutant defects in protein solubility and dimerization were overcome by purifying them in the presence of sufficient Arg and H(4)B, enabling us to study their physical and catalytic profiles. Optical spectra of the ferric, ferrous, heme-dioxy, ferrous-NO, ferric-NO, and ferrous-CO forms of each mutant were similar to that of the wild type. However, the mutants had higher apparent K(m) values for H(4)B and in one mutant for Arg (W457A). They all had lower NO synthesis activities, uncoupled NADPH consumption, and a slower and less prominent buildup of enzyme heme-NO complex during steady-state catalysis. Further analyses showed the mutants had normal or near-normal heme midpoint potential and heme-NO complex reactivity with O(2), but had somewhat slower ferric heme reduction rates and markedly slower reactivities of their heme-dioxy intermediate. We conclude that the conserved Trp (1) has similar roles in two different NOS isozymes and (2) regulates delivery of both electrons required for O(2) activation (i.e., kinetics of ferric heme reduction by the NOS flavoprotein domain and reduction of the heme-dioxy intermediate by H(4)B). However, its regulation of H(4)B electron transfer is most important because this ensures efficient coupling of NADPH oxidation and NO synthesis by NOS.     

Aromatic residues and neighboring Arg414 in the (6R)-5,6,7, 8-tetrahydro-L-biopterin binding site of full-length neuronal nitric-oxide synthase are crucial in catalysis and heme reduction with NADPH

Nitric-oxide synthase (NOS) requires the cofactor, (6R)-5,6,7, 8-tetrahydrobiopterin (H4B), for catalytic activity. The crystal structures of NOSs indicate that H4B is surrounded by aromatic residues. We have mutated the conserved aromatic acids, Trp(676), Trp(678), Phe(691), His(692), and Tyr(706), together with the neighboring Arg(414) residue within the H4B binding region of full-length neuronal NOS. The W676L, W678L, and F691L mutants had no NO formation activity and had very low heme reduction rates (<0.02 min(-1)) with NADPH. Thus, it appears that Trp(676), Trp(678), and Phe(691) are important to retain the appropriate active site conformation for H4B/l-Arg binding and/or electron transfer to the heme from NADPH. The mutation of Tyr(706) to Leu and Phe decreased the activity down to 13 and 29%, respectively, of that of the wild type together with a dramatically increased EC(50) value for H4B (30-40-fold of wild type). The Tyr(706) phenol group interacts with the heme propionate and Arg(414) amine via hydrogen bonds. The mutation of Arg(414) to Leu and Glu resulted in the total loss of NO formation activity and of the heme reduction with NADPH. Thus, hydrogen bond networks consisting of the heme carboxylate, Tyr(706), and Arg(414) are crucial in stabilizing the appropriate conformation(s) of the heme active site for H4B/l-Arg binding and/or efficient electron transfer to occur.     

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.     

Formation and reactions of the heme-dioxygen intermediate in the first and second steps of nitric oxide synthesis as studied by stopped-flow spectroscopy under single-turnover conditions

To better understand the mechanism of nitric oxide (NO) synthesis, we studied conversion of N-hydroxy-L-arginine (NOHA) or L-arginine (Arg) to citrulline and NO under single-turnover conditions using the oxygenase domain of neuronal nitric oxide synthase (nNOSoxy) and rapid scanning stopped-flow spectroscopy. When anaerobic nNOSoxy saturated with H(4)B and NOHA was provided with 0.5 or 1 electron per heme and then exposed to air at 25 degrees C, it formed 0.5 or 1 mol of citrulline/mol of heme, respectively, indicating that NOHA conversion had 1:1 stoichiometry with respect to electrons added. Identical experiments with Arg produced substoichiometric amounts of NOHA or citrulline even when up to 3 electrons were provided per heme. Transient spectral intermediates were investigated at 10 degrees C. For NOHA, four species were observed in the following sequence: starting ferrous nNOSoxy, a transient ferrous-dioxygen complex, a transient ferric-NO complex, and ferric nNOSoxy. For Arg, transient intermediates other than the ferrous-dioxygen species were not apparent during the reaction. Our results provide a kinetic framework for formation and reactions of the ferrous-dioxygen complex in each step of NO synthesis and establish that (1) the ferrous-dioxy enzyme reacts quantitatively with NOHA but not with Arg and (2) its reaction with NOHA forms 1 NO/heme, which immediately binds to form a ferric heme-NO complex.     

Three different oxygen-induced radical species in endothelial nitric-oxide synthase oxygenase domain under regulation by L-arginine and tetrahydrobiopterin

Endothelial nitric-oxide synthase (eNOS) plays important roles in vascular physiology and homeostasis. Whether eNOS catalyzes nitric oxide biosynthesis or the synthesis of reactive oxygen species such as superoxide, hydrogen peroxide, and peroxynitrite is dictated by the bioavailability of tetrahydrobiopterin (BH(4)) and L-arginine during eNOS catalysis. The effect of BH(4) and L-arginine on oxygen-induced radical intermediates has been investigated by single turnover rapid-freeze quench and EPR spectroscopy using the isolated eNOS oxygenase domain (eNOS(ox)). Three distinct radical intermediates corresponding to >50% of the heme were observed during the reaction between ferrous eNOS(ox) and oxygen. BH(4)-free eNOS(ox) produced the superoxide radical very efficiently in the absence of L-arginine. L-Arginine decreased the formation rate of superoxide by an order of magnitude but not its final level or EPR line shape. For BH(4)-containing eNOS(ox), only a stoichiometric amount of BH(4) radical was produced in the presence of L-arginine, but in its absence a new radical was obtained. This new radical could be either a peroxyl radical of BH(4) or an amino acid radical was in the vicinity of the heme. Formation of this new radical is very rapid, >150 s(-1), and it was subsequently converted to a BH(4) radical. The trapping of the superoxide radical by cytochrome c in the reaction of BH(4)(-) eNOS(ox) exhibited a limiting rate of approximately 15 s(-1), the time for the superoxide radical to leave the heme pocket and reach the protein surface; this reveals a general problem of the regular spin-trapping method in determining radical formation kinetics. Cytochrome c failed to trap the new radical species. Together with other EPR characteristics, our data strongly support the conclusion that this new radical is not a superoxide radical or a mixture of superoxide and biopterin radicals. Our study points out distinct roles of BH(4) and L-arginine in regulating eNOS radical intermediates. BH(4) prevented superoxide formation by chemical conversions of the Fe(II)O(2) intermediate, and l-arginine delayed superoxide formation by electronic interaction with the heme-bound oxygen.     

pH-dependent studies reveal an efficient hydroxylation mechanism of the oxygenase component of p-hydroxyphenylacetate 3-hydroxylase

p-Hydroxyphenylacetate (HPA) 3-hydroxylase (HPAH) catalyzes the hydroxylation of HPA at the ortho-position to yield 3,4-dihydroxyphenylacetate. The enzyme is a flavin-dependent two-component monooxygenase that consists of a reductase component and an oxygenase component (C(2)). C(2) catalyzes the hydroxylation of HPA using oxygen and reduced FMN as co-substrates. To date, the effects of pH on the oxygenation of the two-component monooxygenases have never been reported. Here, we report the reaction kinetics of C(2)·FMNH(-) with oxygen at various pH values investigated by stopped-flow and rapid quenched-flow techniques. In the absence of HPA, the rate constant for the formation of C4a-hydroperoxy-FMN (～1.1 × 10(6) m(-1)s(-1)) was unaffected at pH 6.2-9.9, which indicated that the pK(a) of the enzyme-bound reduced FMN was less than 6.2. The rate constant for the following H(2)O(2) elimination step increased with higher pH, which is consistent with a pK(a) of >9.4. In the presence of HPA, the rate constants for the formation of C4a-hydroperoxy-FMN (～4.8 × 10(4) m(-1)s(-1)) and the ensuing hydroxylation step (15-17 s(-1)) were not significantly affected by the pH. In contrast, the following steps of C4a-hydroxy-FMN dehydration to form oxidized FMN occurred through two pathways that were dependent on the pH of the reaction. One pathway, dominant at low pH, allowed the detection of a C4a-hydroxy-FMN intermediate, whereas the pathway dominant at high pH produced oxidized FMN without an apparent accumulation of the intermediate. However, both pathways efficiently catalyzed hydroxylation without generating significant amounts of wasteful H(2)O(2) at pH 6.2-9.9. The decreased accumulation of the intermediate at higher pH was due to the greater rates of C4a-hydroxy-FMN decay caused by the abolishment of substrate inhibition in the dehydration step at high pH.