Perferryl complex of nitric oxide synthase: role in secondary free radical formation

Neuronal nitric oxide synthase (NOS I) has been shown to generate nitric oxide (NO*) and superoxide (O(2)*-)during enzymatic cycling, the ratio of each free radical is dependent upon the concentration of L-arginine. Using spin trapping and electron paramagnetic resonance (EPR) spectroscopy, we recently reported that NOS I can oxidize ethanol (EtOH) to alpha-hydroxyethyl radical (CH(3)*CHOH). We speculated that the perferryl complex of NOS, (NOS-[Fe(5+)[double bond]O](3+)) was responsible for the generation of CH(3)*CHOH. Using potassium monopersulfate (KHSO(5)) to oxidize the heme of NOS I to NOS-[Fe(5+)[double bond]O](3+), we were able to demonstrate that this perferryl complex can oxidize L-arginine to L-citrulline and NO*. Even in the absence of L-arginine, EtOH was oxidized to CH(3)*CHOH by NOS-[Fe(5+)[double bond]O](3+). Sodium cyanide (NaCN), a heme blocker, inhibited the formation of CH(3)*CHOH by NOS.     

Involvement of the perferryl complex of nitric oxide synthase in the catalysis of secondary free radical formation

Neuronal nitric oxide synthase (NOS I) has been shown to generate nitric oxide (NO*) and superoxide (O(2)* during enzymatic cycling, and the ratio of each free radical is dependent upon the concentration of L-arginine. Using spin trapping and electron paramagnetic resonance spectroscopy, we detected alpha-hydroxyethyl radical (CH(3)*CHOH), produced during the NOS I metabolism of ethanol (EtOH). The generation of CH(3)*CHOH by NOS I was found to be Ca(2+)/calmodulin dependent. Superoxide dismutase prevented CH(3)*CHOH formation in the absence of L-arginine. However, in the presence of L-arginine, the production of CH(3)*CHOH was independent of O(2)* but dependent upon the concentration of L-arginine. Formation of CH(3)*CHOH was inhibited by substituting D-arginine for L-arginine, or inclusion of the NOS inhibitors N(G)-nitro-L-arginine methyl ester, N(G)-monomethyl-L-arginine and the heme blocker, sodium cyanide. The addition of potassium hydrogen persulfate to NOS I, generating the perferryl complex (NOS-[Fe(5+)=O](3+)) in the absence of oxygen and Ca(2+)/calmodulin, and EtOH resulted in the formation of CH(3)*CHOH. NOS I was found to produce the corresponding alpha-hydroxyalkyl radical from 1-propanol and 2-propanol, but not from 2-methyl-2-propanol. Data demonstrated that the perferryl complex of NOS I in the presence of L-arginine was responsible for catalyses of these secondary reactions.     

Redox function of tetrahydrobiopterin and effect of L-arginine on oxygen binding in endothelial nitric oxide synthase

Tetrahydrobiopterin (BH(4)), not dihydrobiopterin or biopterin, is a critical element required for NO formation by nitric oxide synthase (NOS). To elucidate how BH(4) affects eNOS activity, we have investigated BH(4) redox functions in the endothelial NOS (eNOS). Redox-state changes of BH(4) in eNOS were examined by chemical quench/HPLC analysis during the autoinactivation of eNOS using oxyhemoglobin oxidation assay for NO formation at room temperature. Loss of NO formation activity linearly correlated with BH(4) oxidation, and was recovered by overnight incubation with fresh BH(4). Thus, thiol reagents commonly added to NOS enzyme preparations, such as dithiothreitol and beta-mercaptoethanol, probably preserve enzyme activity by preventing BH(4) oxidation. It has been shown that conversion of L-arginine to N-hydroxy-L-arginine in the first step of NOS catalysis requires two reducing equivalents. The first electron that reduces ferric to the ferrous heme is derived from flavin oxidation. The issue of whether BH(4) supplies the second reducing equivalent in the monooxygenation of eNOS was investigated by rapid-scan stopped-flow and rapid-freeze-quench EPR kinetic measurements. In the presence of L-arginine, oxygen binding kinetics to ferrous eNOS or to the ferrous eNOS oxygenase domain (eNOS(ox)) followed a sequential mechanism: Fe(II) <--> Fe(II)O(2) --> Fe(III) + O(2)(-). Without L-arginine, little accumulation of the Fe(II)O(2) intermediate occurred and essentially a direct optical transition from the Fe(II) form to the Fe(III) form was observed. Stabilization of the Fe(II)O(2) intermediate by L-arginine has been established convincingly. On the other hand, BH(4) did not have significant effects on the oxygen binding and decay of the oxyferrous intermediate of the eNOS or eNOS oxygenase domain. Rapid-freeze-quench EPR kinetic measurements in the presence of L-arginine showed a direct correlation between BH(4) radical formation and decay of the Fe(II)O(2) intermediate, indicating that BH(4) indeed supplies the second electron for L-arginine monooxygenation in eNOS.     

The generation of free radicals by nitric oxide synthase

Nitric oxide synthase (NOS) is an example of a family of heme-containing monooxygenases that, under the restricted control of a specific substrate, can generate free radicals. While the generation of nitric oxide (NO*) depends solely on the binding of L-arginine, NOS produces superoxide (O(2)*(-)) and hydrogen peroxide (H(2)O(2)) when the concentration of the substrate is low. Not surprisingly, effort has been put forth to understand the pathway by which NOS generates NO*, O(2)*(-) and H(2)O(2), including the role of substrate binding in determining the pathways by which free radicals are generated. By binding within the distal heme pocket near the sixth coordination position of the NOS heme iron, L-arginine alters the coordination properties of the heme iron that promotes formation of the perferryl complex NOS-[Fe(5+)=O](3+). This reactive iron intermediate has been shown to abstract a hydrogen atom from a carbon alpha to a heteroatom and generate carbon-centered free radicals. The ability of NOS to produce free radicals during enzymic cycling demonstrates that NOS-[Fe(5+)=O](3+) behaves like an analogous iron-oxo complex of cytochrome P-450 during aliphatic hydroxylation. The present review discusses the mechanism(s) by which NOS generates secondary free radicals that may initiate pathological events, along with the cell signaling properties of NO*, O(2)*(-) and H(2)O(2).     

Inefficient spin trapping of superoxide in the presence of nitric-oxide: implications for studies on nitric-oxide synthase uncoupling

Uncoupling of nitric-oxide synthase (NOS) by deficiency of the substrate L-arginine or the cofactor (6R)-5,6,7,8-tetrahydrobiopterin (BH4) is known to generate the reactive oxygen species H2O2 and superoxide. Discrimination between these two compounds is usually achieved by spin trapping of superoxide. We measured superoxide formation by uncoupled rat neuronal NOS, which contained one equivalent of tightly bound BH4 per dimer, using 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide (DEPMPO) as a spin trap. As expected, the Ca2+-stimulated enzyme exhibited reduced nicotinamide adenine dinucleotide phosphate (NADPH) oxidase activity that was accompanied by generation of superoxide and H2O2 in the absence of added L-arginine and BH4. Addition of BH4 (10 microM) did not significantly affect the rate of H2O2 formation but almost completely inhibited the apparent formation of superoxide, suggesting direct formation of H2O2. Although L-arginine (0.1 mM) increased the rate of NADPH oxidation about two-fold, the substrate largely attenuated apparent formation of both superoxide and H2O2, indicating that the spin trap did not efficiently outcompete the reaction between NO and superoxide. The efficiency of DEPMPO to scavenge superoxide in the presence of NO was studied by measuring free NO with a Clark-type electrode under conditions of NO/superoxide cogeneration. Neuronal NOS half-saturated with BH4 and the donor compound 3-morpholinosydnonimine (SIN-1) were used as enzymatic and nonenzymatic sources of NO/superoxide, respectively. Neither of the two systems gave rise to considerable NO signals in the presence of 50-100 mM DEPMPO, and even at 400 mM the spin trap uncovered less than 50% of the NO release that was detectable in the presence of 5000 U/ml superoxide dismutase. These results indicate that DEPMPO and all other currently available superoxide spin traps do not efficiently outcompete the reaction with NO. In addition, the similar behavior of nNOS and SIN-1 provides further evidence for NO as initial product of the NOS reaction.     

Inhibitory effects and spectral interactions of isomeric methoxyindazoles on recombinant nitric oxide synthases.

A series of isomeric methoxyindazoles has been evaluated as inhibitors of purified recombinant neuronal, inducible, and endothelial nitric oxide synthases (NOS). 7-Methoxyindazole (7-MI) was the most active compound of this series and displayed selectivity toward the constitutive neuronal (NOS I) and endothelial (NOS III) NOS isoforms, the inducible NOS II being almost insensitive to this inhibitor. 6-, 5-, and 4-Methoxyindazoles were almost inactive against all three NOS isoforms. Inhibition of NO and citrulline formation catalyzed by neuronal NOS in the presence of 7-MI appeared to be competitive versus both substrate L-arginine (L-arg) and (6R)-5,6,7,8-tetrahydrobiopterin (BH(4)) cofactor. 7-MI only slightly inhibited NADPH oxidase activity and was inactive against the cytochrome c (cyt c) reductase activity of neuronal NOS at concentrations up to 100-fold higher than its IC(50) value for inhibition of citrulline formation. UV/Vis and EPR studies indicated that 7-MI interacts with the oxygenase domain of neuronal NOS (NOS I(oxy)) in an identical manner but with a much lower affinity than 7-nitroindazole (7-NI). These results demonstrate that an indazole derivative bearing an electron-rich substituent in the 7-position is also a NOS I inhibitor and that such a compound presents strong similarities with the mechanism of inhibition of 7-NI.     

Differences in three kinetic parameters underpin the unique catalytic profiles of nitric-oxide synthases I, II, and III.

We previously reported the existence of a special auto-regulation property of neuronal nitric-oxide synthase (NOS) based on NO near-geminate combination and partial trapping of neuronal NOS (nNOS) through a futile regenerating pathway. On this basis, we developed a kinetic simulation model that was proven to predict nNOS catalytic specificities and mutations effects (Santolini, J., Adak, S., Curran, C. M., and Stuehr, D. J. (2001) J. Biol. Chem. 276, 1233-1243; Adak, S., Santolini, J., Tikunova, S., Wang, Q., Johnson, J. D., and Stuehr, D. J. (2001) J. Biol. Chem. 276, 1244-1252). Here we show that the same model simulates and explains the distinct catalytic behaviors of inducible and endothelial NOS (iNOS and eNOS). Their marked differences were linked to variations in three basic parameters (rates of ferric heme reduction, ferric heme.NO dissociation, and ferrous heme.NO oxidation) that together control partitioning between futile and productive pathways and their relative rates. We also incorporated feedback inhibition into the kinetic model to account for potential rebinding of accumulated solution NO. The model accurately simulated the different relative impacts of both NOS.NO interactions (near-geminate combination of NO versus rebinding of solution NO) on catalytic behavior of each NOS isoform, including their speed and extent of heme.NO complex accumulation, K(m) for O(2), and propensity to transform NO into a higher oxide. Thus, individual catalytic behavior of any NOS can be understood through a single unified kinetic model. Because the model defines how different settings of individual kinetic parameters control regulation by two distinct NOS.NO interactions, it sheds light on mechanisms, structural features, and scope of NOS regulation and its physiologic impact.     

Nitric oxide synthase is a cytochrome P-450 type hemoprotein.

Nitric oxide has emerged as an important mammalian metabolic intermediate involved in critical physiological functions such as vasodilation, neuronal transmission, and cytostasis. Nitric oxide synthase (NOS) catalyzes the five-electron oxidation of L-arginine to citrulline and nitric oxide. Cosubstrates for the reaction include molecular oxygen and NADPH. In addition, there is a requirement for tetrahydrobiopterin. NOS also contains the coenzymes FAD and FMN and demonstrates significant amino acid sequence homology to NADPH-cytochrome P-450 reductase. Herein we report the identification of the inducible macrophage NOS as a cytochrome P-450 type hemoprotein. The pyridine hemochrome assay showed that the NOS contained a bound protoporphyrin IX heme. The reduced carbon monoxide binding spectrum shows an absorption maximum at 447 nm indicative of a cytochrome P-450 hemoprotein. A mixture of carbon monoxide and oxygen (80%/20%) potently inhibited the reaction (73-79%), showing that the heme functions directly in the oxidative conversion of L-arginine to nitric oxide and citrulline. Additionally, partially purified NOS from rat cerebellum was inhibited by CO, suggesting that this isoform may also contain a P-450-type heme. NOS is the first example of a soluble cytochrome P-450 in eukaryotes. In addition, the presence of FAD and FMN indicates that this is the first catalytically self-sufficient mammalian P-450 enzyme, containing both a reductase and a heme domain on the same polypeptide.     

Macrophage oxidation of L-arginine to nitrite and nitrate: nitric oxide is an intermediate

Previous studies have shown that murine macrophages immunostimulated with interferon gamma and Escherichia coli lipopolysaccharide synthesize NO2-, NO3-, and citrulline from L-arginine by oxidation of one of the two chemically equivalent guanido nitrogens. The enzymatic activity for this very unusual reaction was found in the 100,000g supernatant isolated from activated RAW 264.7 cells and was totally absent in unstimulated cells. This activity requires NADPH and L-arginine and is enhanced by Mg2+. When the subcellular fraction containing the enzyme activity was incubated with L-arginine, NADPH, and Mg2+, the formation of nitric oxide was observed. Nitric oxide formation was dependent on the presence of L-arginine and NADPH and was inhibited by the NO2-/NO3- synthesis inhibitor NG-monomethyl-L-arginine. Furthermore, when incubated with L-[guanido-15N2]arginine, the nitric oxide was 15N-labeled. The results show that nitric oxide is an intermediate in the L-arginine to NO2-, NO3-, and citrulline pathway. L-Arginine is required for the activation of macrophages to the bactericidal/tumoricidal state and suggests that nitric oxide is serving as an intracellular signal for this activation process in a manner similar to that very recently observed in endothelial cells, where nitric oxide leads to vascular smooth muscle relaxation [Palmer, R. M. J., Ashton, D. S., & Moncada, S. (1988) Nature (London) 333, 664-666].     

Differential effects of mutations in human endothelial nitric oxide synthase at residues Tyr-357 and Arg-365 on L-arginine hydroxylation and GN-hydroxy-L-arginine oxidation

Biosynthesis of nitric oxide (NO) is catalyzed by NO synthase (NOS) through a two-step oxidation of L-arginine (Arg) with formation of an intermediate, GN-hydroxy-L-Arg (NHA). In this study we have employed mutagenesis to investigate how residues Y357 and R365 which interact primarily with the substrate Arg and (6R)-5,6,7,8-tetrahydro-L-biopterin (H(4)B) modulate these two steps of the NOS reaction. Mutant Y357F preserved most wild-type heme characteristics and NADPH oxidation ability. However, mutation of this residue markedly increased the dissociation constants for both Arg and NHA by 20-fold and decreased the NO synthesis from Arg by 85% compared to that of wild type. Mutation of Y357 had less effect on the rate of NO generated from NHA. Mutant R365L purified in the presence of Arg had a normal heme environment and retained 9 and 55% of the wild-type NO formation rate from Arg and NHA, respectively. When Arg was removed from buffer, R365L instantly became a low-spin state (Soret peak at 418 nm) with the resultant loss of H(4)B and instability of the heme-CO complex. The low-spin R365L exhibited an NADPH oxidation rate higher than that of wild type. Its Arg-driven NO formation was decreased to near the limit of detection, whereas the rate of NHA-driven NO synthesis was one third that of wild type. This NHA-driven NO formation completely relied on H(4)B and was not sensitive to superoxide dismutase or catalase but was inhibited by imidazole. The wild-type eNOS required 14 microM NHA and 0.39 microM H(4)B to reach the half-maximal NHA-driven NO formation rate (EC(50)), while R365L needed 59 microM NHA and 0.73 microM H(4)B to achieve EC(50). The differential effect of mutation on Arg and NHA oxidation suggests that distinct heme-based active oxidants are responsible for each step of NO synthesis.     

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.     

EPR studies on the photo-induced intermediates of ferric NO complexes of rat neuronal nitric oxide synthase trapped at low temperature.

Rat neuronal nitric oxide synthase (nNOS) was expressed in Escherichia coli and purified. Although the nitric oxide (NO) complex of the ferric heme was EPR-silent, photo-illumination at 5 K to the NO complex of the ferric nNOS in the substrate-free form produced a new high spin EPR signal similar to that of the ferric heme of N(omega)-nitro-L-arginine-bound nNOS, suggesting that the photo-dissociated NO might move away from the heme. Low photo-dissociability of NO in this complex indicated less restricted movement of the dissociated NO in the distal region of the heme, which might result in the rapid rebinding of the NO to the ferric heme at 5 K. In the presence of substrate L-arginine, derivatives, or product L-citrulline, the photo-products from the ferric NO complexes exhibited large novel EPR signals with a spin-coupled interaction between the ferric heme (S = 5/2) and the photolyzed NO (S = 1/2), suggesting a stereochemically restricted interaction between the photo-dissociated NO and the guanidino- or the ureido-group of the substrate analogues at the distal heme region of nNOS. The photo-product from the NO complex produced from citrulline-bound nNOS might be the same intermediate species as that formed in the last step of the catalytic cycle.     

Kinetics of NO ligation with nitric-oxide synthase by flash photolysis and stopped-flow spectrophotometry

Nitric-oxide synthase (NOS) catalyzes conversion of L-arginine to nitric oxide, which subsequently stimulates a host of physiological processes. Prior work suggests that NOS is inhibited by NO, providing opportunities for autoregulation. This contribution reports that NO reacts rapidly (ka congruent with 2 x 10(7) M-1 s-1) with neuronal NOS in both its ferric and ferrous oxidation states. Association kinetics are almost unaffected by L-arginine or the cofactor tetrahydrobiopterin. There is no evidence for the distinct two phases previously reported for association kinetics of CO. Small amounts of geminate recombination of NO trapped in a protein pocket can be observed over nanoseconds, and a much larger amount is inferred to take place at picosecond time scales. Dissociation rates are also very fast from the ferric form, in the neighborhood of 50 s-1, when measured by extrapolating association rates to the zero NO concentration limit. Scavenging experiments give dissociation rate constants more than an order of magnitude slower: still quite fast. For the ferrous species, extrapolation is not distinguishable from zero, while scavenging experiments give a dissociation rate constant near 10(-4) s-1. Implications of these results for interactions near the heme binding site are discussed.     

Regulation of the properties of the heme-NO complexes in nitric-oxide synthase by hydrogen bonding to the proximal cysteine

Nitric-oxide synthase (NOS) catalyzes the formation of NO and citrulline from l-arginine and oxygen. However, the NO so formed has been found to auto-inhibit the enzymatic activity significantly. We hypothesized that the NO reactivity is in part controlled by hydrogen bonding between the conserved tryptophan residue (position 409 in the neuronal isoform of NOS (nNOS)) and the cysteine residue that forms the proximal bond to the heme. By using resonance Raman spectroscopy and NO as a probe of the heme environment, we show that in the W409F and W409Y mutants of the oxygenase domain of the neuronal enzyme (nNOSox), the Fe-NO bond in the Fe3+NO complex is weaker than in the wild type enzyme, consistent with the loss of a hydrogen bond on the sulfur atom of the proximal cysteine residue. The weaker Fe-NO bond in the W409F and W409Y mutants might result in a faster rate of NO dissociation from the ferric heme in the Trp-409 mutants as compared with the wild type enzyme, which could contribute to the lower accumulation of the inhibitory NO-bound complexes observed during catalysis with the Trp-409 mutants (Adak, S., Crooks, C., Wang, Q., Crane, B. R., Tainer, J. A., Getzoff, E. D., and Stuehr, D. J. (1999) J. Biol. Chem. 274, 26907-26911). The optical and resonance Raman spectra of the Fe2+NO complexes of the Trp-409 mutants differ from those of the wild type enzyme and indicate that a significant population of a five-coordinate Fe2+NO complex is present. These data show that the hydrogen bond provided by the Trp-409 residue is necessary to maintain the thiolate coordination when NO binds to the ferrous heme. Taken together our results indicate that the heme environment on the proximal side of nNOS is critical for the formation of a stable iron-cysteine bond and for the control of the electronic properties of heme-NO complexes.     

Characterization of L-arginine transporters in rat renal inner medullary collecting duct

Previous work from our laboratory has demonstrated that the inner medullary collecting duct (IMCD) expresses a large amount of nitric oxide synthase (NOS) activity. The present study was designed to characterize the transport of NOS substrate, L-arginine, in a suspension of bulk-isolated IMCD cells from the Sprague-Dawley rat kidney. Biochemical transport studies demonstrated an L-arginine transport system in IMCD cells that was saturable and Na(+) independent (n = 6). L-Arginine uptake by IMCD cells was inhibited by the cationic amino acids L-lysine, L-homoarginine, and L-ornithine (10 mmol/l each) and unaffected by the neutral amino acids L-leucine, L-serine, and L-glutamine. Both L-ornithine (n = 6) and L-lysine (n = 6) inhibited NOS enzymatic activity in a dose-dependent manner in IMCD cells, supporting the important role of L-arginine transport for NO production by this tubular segment. Furthermore, RT-PCR of microdissected IMCD confirmed the presence of cationic amino acid transporter CAT1 mRNA, whereas CAT2A, CAT2B, and CAT3 were not detected. These results indicate that L-arginine uptake by IMCD cells occurs via system y(+), is encoded by CAT1, and may participate in the regulation of NO production in this renal segment.     

Inhibition of protein synthesis by activation of NMDA receptors in cultured retinal cells: a new mechanism for the regulation of nitric oxide production

The synthesis of nitric oxide (NO) is limited by the intracellular availability of L-arginine. Here we show that stimulation of NMDA receptors promotes an increase of intracellular L-arginine which supports an increase in the production of NO. Although L-[3H]arginine uptake measured in cultured chick retina cells incubated in the presence of cycloheximide (CHX, a protein synthesis inhibitor) was inhibited approximately 75% at equilibrium, quantitative thin-layer chromatography analysis showed that free intracellular L-[3H]arginine was six times higher in CHX-treated than in control cultures. Extracellular L-[3H]citrulline levels increased threefold in CHX-treated groups, an effect blocked by NG-nitro-L-arginine, a NO synthase (NOS) inhibitor. NMDA promoted a 40% increase of free intracellular L-[3H]arginine in control cultures, an effect blocked by the NMDA antagonist 2-amino 5-phosphonovaleric acid. In parallel, NMDA promoted a reduction of 40-50% in the incorporation of 35[S]methionine or L-[3H]arginine into proteins. Western blot analysis revealed that NMDA stimulates the phosphorylation of eukaryotic elongation factor 2 (eEF2, a factor involved in protein translation), an effect inhibited by (+)-5-methyl-10,11-dihydro-5H-dibenzo[a,d]cyclohepten-5,10-imine maleate (MK801). In conclusion, we have shown that the stimulation of NMDA receptors promotes an inhibition of protein synthesis and a consequent increase of an intracellular L-arginine pool available for the synthesis of NO. This effect seems to be mediated by activation of eEF2 kinase, a calcium/calmodulin-dependent enzyme which specifically phosphorylates and blocks eEF2. The results raise the possibility that NMDA receptor activation stimulates two different calmodulin-dependent enzymes (eEF2 kinase and NOS) reinforcing local NO production by increasing precursor availability together with NOS catalytic activity.     

Inhibition of superoxide generation from neuronal nitric oxide synthase by heat shock protein 90: implications in NOS regulation

Besides NO, neuronal NO synthase (nNOS) also produces superoxide (O(2)(-.) at low levels of L-arginine. Recently, heat shock protein 90 (hsp90) was shown to facilitate NO synthesis from eNOS and nNOS. However, the effect of hsp90 on the O(2)(-.) generation from NOS has not been determined yet. The interrelationship between its effects on O(2)(-.) and NO generation from NOS is also unclear. Therefore, we performed electron paramagnetic resonance measurements of O(2)(-.) generation from nNOS to study the effect of hsp90. Purified rat nNOS generated strong O(2)(-.) signals in the absence of L-arginine. In contrast to its effect on NO synthesis, hsp90 dose-dependently inhibited O(2)(-.) generation from nNOS with an IC(50) of 658 nM. This inhibition was not due to O(2)(-.) scavenging because hsp90 did not affect the O(2)(-.) generated by xanthine oxidase. At lower levels of L-arginine where marked O(2)(-.) generation occurred, hsp90 caused a more dramatic enhancement of NO synthesis from nNOS as compared to that under normal L-arginine. Significant O(2)(-.) production was detected from nNOS even at intracellular levels of L-arginine. Adding hsp90 prevented this O(2)(-.) production, leading to enhanced nNOS activity. Thus, these results demonstrated that hsp90 directly inhibited O(2)(-.) generation from nNOS. Inhibition of O(2)(-.) generation may be an important mechanism by which hsp90 enhances NO synthesis from NOS.     

Renal medullary nitric oxide deficit of Dahl S rats enhances hypertensive actions of angiotensin II

Studies were designed to examine the hypothesis that the renal medulla of Dahl salt-sensitive (Dahl S) rats has a reduced capacity to generate nitric oxide (NO), which diminishes the ability to buffer against the chronic hypertensive effects of small elevations of circulating ANG II. NO synthase (NOS) activity in the outer medulla of Dahl S rats (arginine-citrulline conversion assay) was significantly reduced. This decrease in NOS activity was associated with the downregulation of protein expression of NOS I, NOS II, and NOS III isoforms in this region as determined by Western blot analysis. In anesthetized Dahl S rats, we observed that a low subpressor intravenous infusion of ANG II (5 ng. kg(-1). min(-1)) did not increase the concentration of NO in the renal medulla as measured by a microdialysis with oxyhemoglobin trapping technique. In contrast, ANG II produced a 38% increase in the concentration of NO (87 +/- 8 to 117 +/- 8 nmol/l) in the outer medulla of Brown-Norway (BN) rats. The same intravenous dose of ANG II reduced renal medullary blood flow as determined by laser-Doppler flowmetry in Dahl S, but not in BN rats. A 7-day intravenous ANG II infusion at a dose of 3 ng. kg(-1). min(-1) did not change mean arterial pressure (MAP) in the BN rats but increased MAP in Dahl S rats from 120 +/- 2 to 138 +/- 2 mmHg (P < 0.05). ANG II failed to increase MAP after NO substrate was provided by infusion of L-arginine (300 microg. kg(-1). min(-1)) into the renal medulla of Dahl S rats. Intravenous infusion of L-arginine at the same dose had no effect on the ANG II-induced hypertension. These results indicate that an impaired NO counterregulatory system in the outer medulla of Dahl S rats makes them more susceptible to the hypertensive actions of small elevations of ANG II.     

Implications for isoform-selective inhibitor design derived from the binding mode of bulky isothioureas to the heme domain of endothelial nitric-oxide synthase

Nitric oxide produced by nitric-oxide synthase (NOS) is not only involved in a wide range of physiological functions but also in a variety of pathological conditions. Isoform-selective NOS inhibitors are highly desirable to regulate the NO production of one isoform beneficial to normal physiological functions from the uncontrolled NO production of another isoform that accompanies certain pathological states. Crystal structures of the heme domain of the three NOS isoforms have revealed a very high degree of similarity in the immediate vicinity of the heme active site illustrating the challenge of isoform-selective inhibitor design. Isothioureas are potent NOS inhibitors, and the structures of the endothelial NOS heme domain complexed with isothioureas bearing small S-alkyl substituents have been determined (Li, H., Raman, C.S., Martásek, P., Král, V., Masters, B.S.S., and Poulos, T.L. (2000) J. Inorg. Biochem. 81, 133--139). In the present communication, the binding mode of larger bisisothioureas complexed to the endothelial NOS heme domain has been determined. These structures afford a structural rationale for the known inhibitory activities. In addition, these structures provide clues on how to exploit the longer inhibitor substituents that extend out of the active site pocket for isoform-selective inhibitor design.