Functional analysis of whether the glycine residue of the GMN motif of the Arabidopsis MRS2/MGT/CorA-type Mg2+ channel protein AtMRS2-11 is critical for Mg2+ transport activity.

Magnesium (Mg2+) plays a critical role in many physiological processes. The AtMRS2/MGT family, which contains nine Arabidopsis genes (and two pseudogenes), belongs to a eukaryotic subset of the CorA superfamily of divalent cation transporters. AtMRS2-11/MGT10 possesses the signature GlyMetAsn sequence (the GMN motif) conserved in the CorA superfamily; however, little is known about the role of the GMN motif in AtMRS2. Direct measurement using the fluorescent dye mag-fura-2 revealed that reconstituted AtMRS2-11 mediated rapid Mg2+ uptake into proteoliposomes at extraliposomal Mg2+ concentrations of 10 and 20 mM. Mutations in the GMN motif, G417 to A, S or V, did not show a significant change in Mg2+ uptake relative to the wild-type protein. The G417W mutant exhibited a significant increase in Mg2+ uptake. The functional complementation assay in Escherichia coli strain TM2 showed that E. coli cells expressing AtMRS2-11 with mutations in G of the GMN motif did not grow in LB medium without Mg2+ supplementation, while growth was observed in LB medium supplemented with 0.5 mM Mg2+; no difference was observed between the growth of TM2 cells expressing the AtMRS2-11 G417W mutant and that of cells expressing wild-type AtMRS2-11. These results suggested that the Mg2+ transport activity of the AtMRS2-11 GMN-motif mutants was low at low physiological Mg2+ concentrations; thus, the Gly residue is critical for Mg2+ transport, and the Mg2+ transport activity of the GMN-motif mutants was increased at high Mg2+ concentrations.

Thermodynamic Characterization of the Ca2+-Dependent Interaction Between SOUL and ALG-2.

SOUL, a heme-binding protein-2 (HEBP-2), interacts with apoptosis-linked gene 2 protein (ALG-2) in a Ca2+-dependent manner. To investigate the properties of the interaction of SOUL with ALG-2, we generated several mutants of SOUL and ALG-2 and analyzed the recombinant proteins using pulldown assay and isothermal titration calorimetry. The interaction between SOUL and ALG-2 (delta3-23ALG-2) was an exothermic reaction, with 1:1 stoichiometry and high affinity (Kd = 32.4 nM) in the presence of Ca2+. The heat capacity change (ΔCp) of the reaction showed a large negative value (-390 cal/K·mol), which suggested the burial of a significant nonpolar surface area or disruption of a hydrogen bond network that was induced by the interaction (or both). One-point mutation of SOUL Phe100 or ALG-2 Trp57 resulted in complete loss of heat change, supporting the essential roles of these residues for the interaction. Nevertheless, a truncated mutant of SOUL1-143 that deleted the domain required for the interaction with ALG-2 Trp57 still showed 1:1 binding to ALG-2 with an endothermic reaction. These results provide a better understanding of the target recognition mechanism and conformational change of SOUL in the interaction with ALG-2.

The novel heme-dependent inducible protein, SRRD regulates heme biosynthesis and circadian rhythms.

Heme plays a role in the regulation of the expression of genes related to circadian rhythms and heme metabolism. In order to identify new heme-regulated proteins, an RNA sequence analysis using mouse NIH3T3 cells treated without or with 5-aminolevulinic acid (ALA) was performed. Among the changes observed in the levels of various mRNAs including heme oxygenase-1 (HO-1) and ALA synthase-1 (ALAS1), a mouse homologue of the plant circadian-regulating protein SRR1, SRR1 domain containing (SRRD) was induced by the ALA treatment. The expression of SRRD was dependent on heme biosynthesis, and increased the production of heme. SRRD was expressed under circadian rhythms, and influenced the expression of clock genes including PER2, BMAL1, and CLOCK. The knockout of SRRD arrested the growth of cells, indicating that SRRD plays roles in heme-regulated circadian rhythms and cell proliferation.

Magnesium uptake of Arabidopsis transporters, AtMRS2-10 and AtMRS2-11, expressed in Escherichia coli mutants: Complementation and growth inhibition by aluminum.

Magnesium (Mg2+) plays a critical role in many physiological processes. Mg2+ transport systems in Salmonella have been well documented, but those in Escherichia coli have not been fully elucidated. We examined the effects of corA, mgtA, yhiD and corC gene deletion on Mg2+ transport in E. coli. We obtained every combination of double, triple and quadruple mutants. The corA and mgtA double mutant required addition of 10 mM Mg2+ to Luria-Bertani (LB) medium for growth, and the corA, mgtA and yhiD triple mutant TM2 required a higher Mg2+ concentration. The Mg2+ requirement of the quadruple mutant was similar to that of TM2. The results demonstrated that either CorA or MgtA is necessary for normal E. coli growth in LB medium and that YhiD plays a role in Mg2+ transport under high Mg2+ growth conditions in E. coli. The Arabidopsis Mg2+ transporters, AtMRS2-10 and AtMRS2-11, were heterologously expressed in TM2 cells. TM2 cells expressing AtMRS2-10 and AtMRS2-11 could grow in LB medium that had been supplemented with 1 mM Mg2+ and without Mg2+ supplementation, respectively, and cell growth was inhibited by 2 mM AlCl3. The results indicated that the growth of TM2 expressing AtMRS2-10 and AtMRS2-11 reflected these AtMRS2 function for Mg2+ and aluminum. The E. coli TM2 cells are useful for functional analysis of Arabidopsis MRS2 proteins.

Changes in pH and NADPH regulate the DNA binding activity of neuronal PAS domain protein 2, a mammalian circadian transcription factor.

Neuronal PAS domain protein 2 (NPAS2) is a core clock transcription factor that forms a heterodimer with BMAL1 to bind the E-box in the promoter of clock genes and is regulated by various environmental stimuli such as heme, carbon monoxide, and NAD(P)H. In this study, we investigated the effects of pH and NADPH on the DNA binding activity of NPAS2. In an electrophoretic mobility shift (EMS) assay, the pH of the reaction mixture affected the DNA binding activity of the NPAS2/BMAL1 heterodimer but not that of the BMAL1/BMAL1 homodimer. A change in pH from 7.0 to 7.5 resulted in a 1.7-fold increase in activity in the absence of NADPH, and NADPH additively enhanced the activity up to 2.7-fold at pH 7.5. The experiments using truncated mutants revealed that N-terminal amino acids 1-61 of NPAS2 were sufficient to sense the change in both pH and NADPH. We further analyzed the kinetics of formation and DNA binding of the NPAS2/BMAL1 heterodimer at various pH values. In the absence of NADPH, a change in pH from 6.5 to 8.0 decreased the KD(app) value of the E-box from 125 to 22 nM, with an 8-fold increase in the maximal level of DNA binding for the NPAS2/BMAL1 heterodimer. The addition of NADPH resulted in a further decrease in KD(app) to 9 nM at pH 8.0. Furthermore, NPAS2-dependent transcriptional activity in a luciferase assay using NIH3T3 cells also increased with the pH of the culture medium. These results suggest that NPAS2 has a role as a pH and metabolite sensor in regulating circadian rhythms.

Functional reconstitution and characterization of the Arabidopsis Mg(2+) transporter AtMRS2-10 in proteoliposomes.

Magnesium (Mg(2+)) plays critical role in many physiological processes. The mechanism of Mg(2+) transport has been well documented in bacteria; however, less is known about Mg(2+) transporters in eukaryotes. The AtMRS2 family, which consists of 10 Arabidopsis genes, belongs to a eukaryotic subset of the CorA superfamily proteins. Proteins in this superfamily have been identified by a universally conserved GlyMetAsn motif and have been characterized as Mg(2+) transporters. Some members of the AtMRS2 family, including AtMRS2-10, may complement bacterial mutants or yeast mutants that lack Mg(2+) transport capabilities. Here, we report the purification and functional reconstitution of AtMRS2-10 into liposomes. AtMRS2-10, which contains an N-terminal His-tag, was expressed in Escherichia coli and solubilized with sarcosyl. The purified AtMRS2-10 protein was reconstituted into liposomes. AtMRS2-10 was inserted into liposomes in a unidirectional orientation. Direct measurement of Mg(2+) uptake into proteoliposomes revealed that reconstituted AtMRS2-10 transported Mg(2+) without any accessory proteins. Mutation in the GMN motif, M400 to I, inactivated Mg(2+) uptake. The AtMRS2-10-mediated Mg(2+) influx was blocked by Co(III)hexamine, and was independent of the external pH from 5 to 9. The activity of AtMRS2-10 was inhibited by Co(2+) and Ni(2+); however, it was not inhibited by Ca(2+), Fe(2+), or Fe(3+). While these results indicate that AtMRS2-10 has similar properties to the bacterial CorA proteins, unlike bacterial CorA proteins, AtMRS2-10 was potently inhibited by Al(3+). These studies demonstrate the functional capability of the AtMRS2 proteins in proteoliposomes to study structure-function relationships.

Effects of NAD(P)H and its derivatives on the DNA-binding activity of NPAS2, a mammalian circadian transcription factor.

NPAS2 is a transcription factor that regulates mammalian circadian rhythms. It has been suggested that NPAS2 DNA-binding activity is regulated by the intracellular redox state of NAD(P)H, although the mechanism remains unclear. To investigate the NAD(P)H interaction site of murine NPAS2, we performed electrophoretic mobility shift assays using several truncation mutants of the NPAS2 bHLH domain. Among the mutants, NPAS2 containing the N-terminal 61 residues formed a heterodimer with BMAL1 to bind DNA, and NAD(P)H enhanced the binding activity, while NAD(P)H inhibited the DNA-binding activity of the BMAL1 homodimer in a dose-dependent manner. NAD(P)H derivatives such as 2',5'-ADP, nicotinamide, nicotinic acid and nicotinic acid adenine dinucleotide (NAAD) did not affect the DNA-binding activity. Interestingly, NAD(P)(+), previously reported as an inhibitor, did not affect NPAS2 binding activity in the presence or absence of NAD(P)H in our system. These results suggest that NPAS2 DNA-binding activity is specifically enhanced by NAD(P)H independently of NAD(P)(+) and that the N-terminal 1-61 amino acids of NPAS2 are sufficient to sense NAD(P)H.

Exhaustive syntheses of naphthofluoresceins and their functions.

Naphthofluorescein and/or seminaphthofluorescein derivatives possessing the additional benzene units to one or both sides of fluorescein were exhaustively constructed through Friedel-Crafts type reactions between corresponding aroylbenzoic acids and dihydroxynaphthalenes. Compound 4 works as a one-dye pH indicator, which shows red in strong acid condition and blue in basic solution. Compound 23 (diacetate of compound 4) shows good transitivity to the HEK 293 cells and acts as a fluorescent pigment for the living cell imaging. Compounds 5, 6, and 9 show fluorescent emission in the NIR region (>700 nm) and imply the potentialities of NIR fluorescent probes.

Thermodynamic analysis of interactions between cofactor and neuronal nitric oxide synthase.

The thermodynamics of cofactor binding to the isolated reductase domain (Red) of nNOS and its mutants have been studied by isothermal titration calorimetry. The NADP(+) and 2',5'-ADP binding stoichiometry to Red were both 1:1, consistent with a one-site kinetic model instead of a two-site model. The binding constant (K(D) = 71 nM) and the large heat capacity change (ΔC(p) = -440 cal mol(-1) K(-1)) for 2',5'-ADP were remarkably different from those for NADP(+) (1.7 µM and -140 cal mol(-1) K(-1), respectively). These results indicate that the nicotinamide moiety as well as the adenosine moiety has an important role in binding to nNOS. They also suggest that the thermodynamics of the conformational change in Red caused by cofactor binding are significantly different from the conformational changes that occur in cytochrome c reductase, in which the nicotinamide moiety of the cofactor is not essential for binding. Analysis of the deletion mutant of the autoinhibitory helix (RedΔ40) revealed that the deletion resulted in a decrease in the binding affinity of 2',5'-ADP with more unfavorable enthalpy gain. In the case of RedCaM, which contains a calmodulin (CaM) binding site, the presence of Ca(2+)/CaM caused a 6.7-fold increase in the binding affinity for 2',5'-ADP that was mostly due to the favorable entropy change. These results are consistent with a model in which Ca(2+)/CaM induces a conformational change in NOS to a flexible "open" form from a "closed" form that locked by cofactor binding, and this change facilitates the electron transfer required for catalysis.

Effects of mutations in the heme domain on the transcriptional activity and DNA-binding activity of NPAS2.

The heme domain of neuronal PAS domain protein 2 (NPAS2), a transcription factor that regulates the mammalian circadian rhythm, has been suggested to act as a sensor for carbon monoxide. To characterize the role of the heme domain in this function, we investigated the effects of PASA domain mutants, in the context of full-length NPAS2, on the transcriptional activity of the mouse Period 1 gene in NIH3T3 cells. Mutation of the endogenous ligand for ferrous heme (H119A or H171A) resulted in remarkably reduced transcriptional activity. In gel-shift assays, H119A or H171A mutants of the isolated basic helix-loop-helix (bHLH)-PASA domain impaired heterodimer formation with BMAL1, resulting in loss of DNA binding to the canonical E-box (CACGTG). These results indicate that the transcriptional activities of the mutants correlated well with their DNA-binding activities, suggesting that local conformational changes near the axial ligands of the PASA domain are responsible for its regulation of transcription.

Circadian clock disruption by selective removal of endogenous carbon monoxide.

Circadian rhythms are regulated by transcription-translation feedback loops (TTFL) of clock genes. Previous studies have demonstrated that core transcriptional factors, NPAS2 and CLOCK, in the TTFL can reversibly bind carbon monoxide (CO) in vitro. However, little is known about whether endogenous CO, which is continuously produced during a heme metabolic process, is involved in the circadian system. Here we show that selective removal of endogenous CO in mice considerably disrupts rhythmic expression of the clock genes. A highly selective CO scavenger, hemoCD1, which is a supramolecular complex of an iron(II)porphyrin with a per-O-methyl-ß-cyclodextrin dimer, was used to remove endogenous CO in mice. Intraperitoneal administration of hemoCD1 to mice immediately reduced the amount of internal CO. The removal of CO promoted the bindings of NPAS2 and CLOCK to DNA (E-box) in the murine liver, resulting in up-regulation of the E-box-controlled clock genes (Per1, Per2, Cry1, Cry2, and Rev-erbα). Within 3 h after the administration, most hemoCD1 in mice was excreted in the urine, and heme oxygenase-1 (HO-1) was gradually induced in the liver. Increased endogenous CO production due to the overexpression of HO-1 caused dissociation of NPAS2 and CLOCK from E-box, which in turn induced down-regulation of the clock genes. The down-regulation continued over 12 h even after the internal CO level recovered to normal. The late down-regulation was ascribed to an inflammatory response caused by the endogenous CO reduction. The CO pseudo-knockdown experiments provided the clear evidence that endogenous CO contributes to regulation in the mammalian circadian clock.

The homologous Arabidopsis MRS2/MGT/CorA-type Mg2+ channels, AtMRS2-10 and AtMRS2-1 exhibit different aluminum transport activity.

Magnesium (Mg2+) plays a critical role in many physiological processes. The AtMRS2/MGT family, which consists of nine Arabidopsis genes (and two pseudo-genes) belongs to a eukaryotic subset of the CorA superfamily of divalent cation transporters. AtMRS2-10 and AtMRS2-1 possess the signature GlyMetAsn sequence conserved in the CorA superfamily; however, they have low sequence conservation with CorA. Direct measurement using the fluorescent dye mag-fura-2 revealed that reconstituted AtMRS2-10 and AtMRS2-1 mediated rapid Mg2+ uptake into proteoliposomes. The rapid Mg2+ uptake through AtMRS2-10 was inhibited by aluminum. An assay using the Al-sensitive dye morin indicated Al uptake into the proteoliposomes through AtMRS2-10. AtMRS2-10 also exhibited Ni2+ transport activity but almost no Co2+ transport activity. The rapid Mg2+ uptake through AtMRS2-1 was not inhibited by aluminum. Al uptake into the proteoliposomes through AtMRS2-1 was not observed. The functional complementation assay in Escherichia coli strain TM2 showed that AtMRS2-1 was capable of mediating Mg2+ uptake. Heterologous expression using the E. coli mutant cells also showed that the E. coli cells expressing AtMRS2-1 was more resistant to aluminum than the E. coli cells expressing AtMRS2-10. The results suggested that AtMRS2-10 transported Al into the E. coli cells, and then the transported Al inhibited the growth of E. coli. AtMRS2-1 has been localized to the Arabidopsis tonoplast, indicating that AtMRS2-1 is exposed to much higher concentration of aluminum than AtMRS2-10. Under the conditions, it may be required that the Mg2+ transport of AtMRS2-1 is insensitive to Al inhibition, and AtMRS2-1 is impermeable to Al.

Spectroscopic and DNA-binding characterization of the isolated heme-bound basic helix-loop-helix-PAS-A domain of neuronal PAS protein 2 (NPAS2), a transcription activator protein associated with circadian rhythms.

Neuronal PAS domain protein 2 (NPAS2) is a circadian rhythm-associated transcription factor with two heme-binding sites on two PAS domains. In the present study, we compared the optical absorption spectra, resonance Raman spectra, heme-binding kinetics and DNA-binding characteristics of the isolated fragment containing the N-terminal basic helix-loop-helix (bHLH) of the first PAS (PAS-A) domain of NPAS2 with those of the PAS-A domain alone. We found that the heme-bound bHLH-PAS-A domain mainly exists as a dimer in solution. The Soret absorption peak of the Fe(III) complex for bHLH-PAS-A (421 nm) was located at a wavelength 9 nm higher than for isolated PAS-A (412 nm). The axial ligand trans to CO in bHLH-PAS-A appears to be His, based on the resonance Raman spectra. In addition, the rate constant for heme association with apo-bHLH-PAS (3.3 x 10(7) mol(-1) x s(-1)) was more than two orders of magnitude higher than for association with apo-PAS-A (< 10(5) mol(-1) x s(-1)). These results suggest that the bHLH domain assists in stable heme binding to NPAS2. Both optical and resonance Raman spectra indicated that the Fe(II)-NO heme complex is five-coordinated. Using the quartz-crystal microbalance method, we found that the bHLH-PAS-A domain binds specifically to the E-box DNA sequence in the presence, but not in the absence, of heme. On the basis of these results, we discuss the mode of heme binding by bHLH-PAS-A and its potential role in regulating DNA binding.

CO binding study of mouse heme-regulated eIF-2alpha kinase: kinetics and resonance Raman spectra.

Heme-regulated eukaryotic initiation factor (eIF)-2alpha kinase (HRI) regulates the synthesis of globin chains in reticulocytes with heme availability. In the present study, CO binding kinetics to the 6-coordinated Fe(II) heme of the amino-terminal domain of mouse HRI and resonance Raman spectra of the Fe(II)-CO complex are examined to probe the character of the heme environment. The CO association rate constant, k(on)', and CO dissociation rate constant, k(off), were 0.0029 microM(-1)s(-1) and 0.003 s(-1), respectively. These values are very slow compared with those of mouse neuroglobin and sperm whale myoglobin, while the k(off) value of HRI was close to those of the 6-coordinated hemoglobins from Chlamydomonas and barley (0.0022 and 0.0011 s(-1)). The dissociation rate constant of an endogenous ligand, which occurs prior to CO association, was 18.3 s(-1), which was lower than those (197 and 47 s(-1)) of the same 6-coordinated hemoglobins. Resonance Raman spectra suggest that the Fe-C-O adopts an almost linear and upright structure and that the bound CO interacts only weakly with nearby amino acid residues.

Spectroscopic characterization of the isolated heme-bound PAS-B domain of neuronal PAS domain protein 2 associated with circadian rhythms.

Neuronal PAS domain protein 2 (NPAS2) is an important transcription factor associated with circadian rhythms. This protein forms a heterodimer with BMAL1, which binds to the E-box sequence to mediate circadian rhythm-regulated transcription. NPAS2 has two PAS domains with heme-binding sites in the N-terminal portion. In this study, we overexpressed wild-type and His mutants of the PAS-B domain (residues 241-416) of mouse NPAS2 and then purified and characterized the isolated heme-bound proteins. Optical absorption spectra of the wild-type protein showed that the Fe(III), Fe(II) and Fe(II)-CO complexes are 6-co-ordinated low-spin complexes. On the other hand, resonance Raman spectra indicated that both the Fe(III) and Fe(II) complexes contain mixtures of 5-co-ordinated high-spin and 6-co-ordinated low-spin complexes. Based on inverse correlation between nu(Fe-CO) and nu(C-O) of the resonance Raman spectra, it appeared that the axial ligand trans to CO of the heme-bound PAS-B is His. Six His mutants (His266Ala, His289Ala, His300Ala, His302Ala, His329Ala, and His335Ala) were generated, and their optical absorption spectra were compared. The spectrum of the His335Ala mutant indicated that its Fe(III) complex is the 5-co-ordinated high-spin complex, whereas, like the wild-type, the complexes for the five other His mutants were 6-co-ordinated low-spin complexes. Thus, our results suggest that one of the axial ligands of Fe(III) in PAS-B is His335. Also, binding kinetics suggest that heme binding to the PAS-B domain of NPAS2 is relatively weak compared with that of sperm whale myoglobin.

CO binding to the isolated oxygenase domain of neuronal nitric oxide synthase: effects of inhibitors and mutations at the substrate-binding site.

In order to understand the heme distal structure of neuronal nitric oxide synthase (nNOS), we studied the binding affinity of CO for the ferrous wild type enzyme and the Glu592Ala and Tyr588His substrate binding-site mutants (generated in the oxygenase domain, nNOSox) in the presence of substrates and inhibitors. The CO binding affinities (K(d) = 10-21 mM) of nNOSox in the presence of the substrates, L-Arg and NHA, or inhibitors such as NAME and agmatine were more than two-fold lower than in their absence (K(d) = 5 mM). The presence of NIL strongly inhibited CO binding and gave a K(d) of more than 100 mM. These effects were not observed for the Glu592Ala mutant. The trend in CO binding affinities observed for the Tyr588His mutant was similar to that of the wild type enzyme. The presence of the isolated reductase domain did not affect CO binding. We discuss the role of substrate and inhibitor binding in CO complexation as well as in catalysis.

Cyanide binding study of neuronal nitric oxide synthase: effects of inhibitors and mutations at the substrate binding site.

In order to understand the heme distal structure of neuronal nitric oxide synthase (nNOS), we studied cyanide binding to the ferric wild-type and substrate binding site mutants, Glu592Ala and Tyr588His, of the isolated oxygenase domain in the absence and presence of substrates and inhibitors. Cyanide bound to isolated heme-bound oxygenase domains (nNOSox) in the absence of the substrates with the dissociation constant (K(d)) of 3.1 mM. The presence of the substrates, L-Arg and NHA, did not change the K(d) value. However, cyanide binding was almost abolished in the presence of inhibitors such as NAME, thiocitrulline and 7-NI. The effect of the inhibitors were not observed for the Glu592Ala mutant, while similar strong inhibiting effects were observed for the Tyr588His mutant. We discuss the binding fashion of those inhibitors to the heme substrate binding site of nNOS.

Analysis of the kinetics of CO binding to neuronal nitric oxide synthase by flash photolysis: dual effects of substrates, inhibitors, and tetrahydrobiopterin.

The effects of substrates, inhibitors and tetrahydrobiopterin (H4B) on CO rebinding to the isolated heme-bound oxygenase domain (nNOSox) of neuronal nitric oxide synthase were examined by laser flash photolysis. The rate constant of CO recombination with substrate and inhibitor-free nNOSox in the absence of H4B was 1.0 x 10(6) M(-1) s(-1). The addition of H4B led to a marked decrease in the rate to 0.59 x 10(6) M(-1) s(-1). Interestingly, the substrates, L-Arg and N-hydroxy-L-Arg (NHA), altered CO binding behavior in that the binding rate was modified to CO concentration-independent, both with and without H4B. In the absence of H4B, agmatine, NG-monomethyl-L-Arg (NMMA) and NG-nitro-L-Arg methyl ester (NAME) decreased the CO concentration-dependent rate constants of rebinding by half (0.43 x 10(6) M(-1) s(-1) for the NMMA-bound complex), whereas N6-(l-iminoethyl)-L-Lys (NIL) and 7-nitro-1H-indazole (7-NI) increased the rate constants by more than 70% (up to 2.1 x 10(6) M(-1) s(-1) for the NIL-bound complex). In the presence of H4B, the binding rate was independent of CO concentration for the agmatine-bound complex. The differential effects of the inhibitors on the CO concentration-dependent rate constants were significantly diminished for the H4B-bound system. Interestingly, these variable effects of inhibitors on the CO binding rate were more pronounced in the absence of H4B. Accordingly, we suggest that H4B significantly influences CO binding by altering the CO access channel, and further reduces the divergent effects of different inhibitors.

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.

Catalytically functional flavocytochrome chimeras of P450 BM3 and nitric oxide synthase.

P450 BM3 and the nitric oxide synthases are related classes of flavocytochrome mono-oxygenase enzymes, containing NADPH-dependent FAD- and FMN-containing oxidoreductase modules fused to heme b-containing oxygenase domains. Domain-swap hybrids of these two multi-domain enzymes were created by genetic engineering of different segments of reductase and heme domains from neuronal nitric oxide synthase and P450 BM3, as a means of investigating the catalytic competence and substrate-binding properties of the fusions and the influence of tetrahydrpbiopterin and calmodulin binding regions on the electron transfer kinetics of the chimeras. Despite marked differences in hybrid stability and solubility, four catalytically functional chimeras were created that retained good reductase activity and which could be expressed successfully in Escherichia coli and purified. All of the BM3 reductase domain chimeras (chimeras I-III) exhibited inefficient flavin-to-heme inter-domain electron transfer, diminishing their oxygenase activity. However, the chimera containing the neuronal nitric oxide synthase reductase domain (chimera IV) showed good oxygenase domain activity, indicating that the flavin-to-heme electron transfer reaction is relatively efficient in this case. The data reinforce the importance of the nature of inter-domain linker constitution in multi-domain enzymes, and the difficulties posed in attempts to create chimeric enzymes with enhanced catalytic properties.