Kinetics Of CO Binding Research Articles

Transfer of Human α- to β-Hemoglobin via Its Chaperone Protein: EVIDENCE FOR A NEW STATE

The alpha-hemoglobin-stabilizing protein (AHSP), a small protein of 102 amino acids, is synthesized in red blood cell precursors. It binds specifically to alpha-hemoglobin (alpha-Hb) subunits acting as a chaperone protein, preventing the formation of alpha-hemoglobin-cytotoxic precipitates. We have engineered recombinant AHSP in a pGEX vector to study the functional consequence of interaction between AHSP and alpha-Hb. By in vitro binding assays, we have isolated the complexes glutathione S-transferase-AHSP.alpha-Hb and AHSP.alpha-Hb. The latter assembles as a heterodimer based on size-exclusion chromatography. These complexes exhibited monophasic CO binding kinetics, as observed for isolated alpha- and beta-subunits of hemoglobin. However, the rate of CO (or oxygen) binding to alpha-hemoglobin bound to its chaperone is three times slower than that observed for isolated alpha-hemoglobin, demonstrating a form that is intermediate to the R- and T-hemoglobin states. The physiologically relevant replacement of the chaperone by beta-hemoglobin chains could be detected by both ligand binding kinetics and tryptophan fluorescence quenching.

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 × 10 6 M −1 s −1. The addition of H4B led to a marked decrease in the rate to 0.59 × 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, N G-monomethyl- L-Arg (NMMA) and N G-nitro- L-Arg methyl ester (NAME) decreased the CO concentration-dependent rate constants of rebinding by half (0.43 × 10 6 M −1 s −1 for the NMMA-bound complex), whereas N 6-(l-iminoethyl)- L-Lys (NIL) and 7-nitro-1H-indazole (7-NI) increased the rate constants by more than 70% (up to 2.1 × 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.

Residues in the Distal Heme Pocket of Neuroglobin: IMPLICATIONS FOR THE MULTIPLE LIGAND BINDING STEPS

Amino acid residues in the ligand binding pocket of human neuroglobin have been identified by site-directed mutagenesis and their properties investigated by resonance Raman and flash photolysis methods. Wild-type neuroglobin has been shown to have six-coordinate heme in both ferric and ferrous states. Substitution of His96 by alanine leads to complete loss of heme, indicating that His96 is the proximal ligand. The resonance Raman spectra of M69L and K67T mutants were similar to those of wild-type (WT) neuroglobin in both ferric and ferrous states. By contrast, H64V was six-coordinate high-spin and five-coordinate high-spin in the ferric and ferrous states, respectively, at acidic pH. The spectra were pH-dependent and six-coordinate with the low-spin component dominating at alkaline pH. In a double mutant H64V/K67T, the high-spin component alone was detected in the both ferric and the ferrous states. This implies that His64 is the endogenous ligand and that Lys67 is situated nearby in the distal pocket. In the ferrous H64V and H64V/K67T mutants, the nu(Fe-His) stretching frequency appears at 221 cm(-1), which is similar to that of deoxymyoglobin. In the ferrous CO-bound state, the nu(Fe-CO) stretching frequency was detected at 521 and 494 cm(-1) in WT, M69L, and K67T, while only the 494 cm(-1) component was detected in the H64V and H64V/K67T mutants. Thus, the 521 cm(-1) component is attributed to the presence of polar His64. The CO binding kinetics were biphasic for WT, H64V, and K67T and monophasic for H64V/K67T. Thus, His64 and Lys67 comprise a unique distal heme pocket in neuroglobin.

Binding of Oxygen and Carbon Monoxide to a Heme-regulated Phosphodiesterase from Escherichia coli: KINETICS AND INFRARED SPECTRA OF THE FULL-LENGTH WILD-TYPE ENZYME, ISOLATED PAS DOMAIN, AND MET-95 MUTANTS

The heme-regulated phosphodiesterase, Ec DOS, is a redox sensor that uses the heme in its PAS domain to regulate catalysis. The rate of O(2) association (k(on)) with full-length Ec DOS is extremely slow at 0.0019 microM(-1) s(-1), compared with >9.5 microM(-1) s(-1) for 6-coordinated globin-type hemoproteins, as determined by the stopped-flow method. This rate is dramatically increased (up to 16-fold) in the isolated heme-bound PAS domain. Dissociation constants (K(d)) calculated from the kinetic parameters are 340 and 20 microm for the full-length wild-type enzyme and its isolated PAS domain, respectively. Mutations at Met-95 in the isolated PAS domain, which may be a heme axial ligand in the Fe(II) complex, lead to a further increase in the k(on) value by more than 30-fold, and consequently, a decrease in the K(d) value to less than 1 microM. The k(on) value for CO binding to the full-length wild-type enzyme is also very low (0.00081 microM(-1) s(-1)). The kinetics of CO binding to the isolated PAS domain and its mutants are similar to those observed for O(2). However, the K(d) values for CO are considerably lower than those for O(2).

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

Heme-regulated eukaryotic initiation factor (eIF)-2α 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 μM −1s −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.

Role of the interdomain linker probed by kinetics of CO ligation to an endothelial nitric oxide synthase mutant lacking the calmodulin binding peptide (residues 503-517 in bovine).

Oxygenase and reductase domains in nitric oxide synthase are linked by a peptide region that binds calmodulin. Here we study the effects of modifying the length of the interdomain linker in a deletion mutant lacking 15 amino acids (residues 503-517) in bovine eNOS. The kinetics of CO ligation with the mutant were determined in the presence and absence of tetrahydrobiopterin and arginine and compared with the CO binding kinetics of wild-type eNOS and the eNOS oxygenase domain. In the mutant, electron flow is interrupted. The association kinetics of CO with both mutant and wild-type eNOS can be approximated with two kinetic phases, but the relative proportions change in the mutant. Both the abrogation of electron flow in the mutant and the differences in CO binding may be explained by an alteration in the docking of the FMN domain to the heme domain. We propose that the calmodulin binding residues form a helix that is critical for the proper alignment of the adjacent reductase and oxygenase domains within the active eNOS dimer in achieving proper electron transfer between them.

Relationships of Ligand Binding, Redox Properties, and Protonation in Coprinus cinereus Peroxidase

The pH dependence of the redox potentials and kinetics for CO association and dissociation was determined between pH 3.0 and 13.0 at 25 degrees C for the wild-type Coprinus cinereus fungal peroxidase and for a site-directed mutant in which Asp245, which is H-bonded to N delta of the imidazole of the proximal His183, was substituted with Asn. The determination of these functional properties allowed this information to be merged in a self-consistent fashion and to formulate for the first time a complete scheme employing the minimum number of groups required to describe the whole proton-linked behavior of both redox and ligand binding properties. The overall pH dependence can be accounted for by four redox- and ligand-linked groups. The proximal H-bond, which is strictly conserved in all peroxidases, will still be present in the site-specific mutant, but will no longer have an ionic character, and this event will bring about an alteration of redox equilibria and CO binding kinetics, envisaging a relevant role played by this H-bond also in modulating redox properties and ligand binding equilibria.

Structure and function of the globin and globin gene from the Antarctic mollusc Yoldia eightsi.

The mechanism of adaptation of haemoglobin from the Antarctic mollusc Yoldia eightsi to its low-temperature environment is a decrease in the oxygen affinity via an increased ligand-dissociation rate. At 2 degrees C this haemoglobin has an oxygen affinity similar to other haemoglobins at 25 degrees C. At 25 degrees C, Yoldia haemoglobin shows a low oxygen affinity, resembling that of human deoxyhaemoglobin. The mechanism involves a lower binding energy to oxygen, suggesting a loss or weakening of the usual hydrogen bond, leading to a higher oxygen-dissociation rate. However, Yoldia haemoglobin has the usual distal and proximal histidines, so the primary structure alone does not provide an obvious explanation for the low affinity. The CO-binding kinetics are biphasic, with the fraction of slow phase increasing at higher protein concentrations, indicating the formation of dimers or a higher level of polymerization. The protein-protein interaction appears to be of hydrophobic nature, since it can be partially reversed by addition of ethylene glycol as co-solvent. While the CO-association rates differ by a factor of 10, the oxygen equilibrium data could be simulated with a single affinity. The Yoldia haemoglobin gene contains three introns, interrupting the coding region at position NA1.2, B12.2 and G7.0. The conservation of the B12.2 and G7.0 introns is in contrast with the unprecedented NA1.2 intron. Phylogenetic analyses reveal a gene tree where the Yoldia haemoglobin gene is separated from other mollusc globin genes, confirming the specific adaptation of the Yoldia haemoglobin.

Measurement of rate constants for reactions of O2, CO, and NO with hemoglobin.

The kinetics of O2, CO, and NO binding to mammalian hemoglobins (Hbs) have been studied for 75 yr, starting with the original rapid mixing experiments of Hartridge and Roughton (1). Over the last 20 yr, these measurements have been extended to time scales ranging from hours to picoseconds. Numerous articles have been written about rapid mixing and photolysis instruments, methods for defining specific association and dissociation rate constants, and algorithms for analyzing the results in terms of specific models for cooperative ligand binding (2–10). A comprehensive review of these techniques and methods, however, is beyond the scope of this book. Instead, a practical guide to determining rate constants for O2, CO, and NO binding to native and recombinant Hbs is presented, with a special emphasis on tetrameric adult human Hb (HbA).

Substrates modulate the rate-determining step for CO binding in cytochrome P450cam (CYP101). A high-pressure stopped-flow study.

The high-pressure stopped-flow technique is applied to study the CO binding in cytochrome P450cam (P450cam) bound with homologous substrates (1R-camphor, camphane, norcamphor and norbornane) and in the substrate-free protein. The activation volume DeltaV # of the CO on-rate is positive for P450cam bound with substrates that do not contain methyl groups. The kon rate constant for these substrate complexes is in the order of 3 x 10(6) M(-1) x s(-1). In contrast, P450cam complexed with substrates carrying methyl groups show a negative activation volume and a low kon rate constant of approximately 3 x 10(4) M(-1) x s(-1). By relating kon and DeltaV # with values for the compressibility and the influx rate of water for the heme pocket of the substrate complexes it is concluded that the positive activation volume is indicative for a loosely bound substrate that guarantees a high solvent accessibility for the heme pocket and a very compressible active site. In addition, subconformers have been found for the substrate-free and camphane-bound protein which show different CO binding kinetics.

Mutational effects at the subunit interfaces of human hemoglobin: evidence for a unique sensitivity of the T quaternary state to changes in the hinge region of the alpha 1 beta 2 interface.

A set of variant human hemoglobins, each with an Ala or Gly substitution at a single residue, has been prepared, and the kinetics of their reactions with carbon monoxide have been measured. This reaction is rate-limited by the binding of the first CO to the deoxygenated T state of the protein. The magnitudes of the effects of the mutations on CO combination vary widely, and, with the exception of beta Y145, the residues with the most significant effects on these kinetics are found in the hinge region of the alpha 1 beta 2 interface. Mixed-metal hybrids, with zinc protoporphyrin IX in place of heme on both alpha or both beta subunits, were prepared for beta W37E, beta W37A, alpha Y140G, and alpha Y140A, hinge region variants causing large kinetic changes, and for beta Y145G. Such hybrids permit measurements of the kinetics of CO binding to only the heme-containing alpha or beta subunits within the unliganded hemoglobin tetramer. Mutations at beta 37 and alpha 140 have global effects on the T state, increasing the rates of CO binding to both types of subunits. Mutation of beta Y145 has a large effect on the beta subunits in the deoxygenated T state, but very little effect on the alpha subunits. Oxygen equilibria measurements on the crystalline T state of beta W37E also indicate large affinity increases in both subunits of this variant. The overall oxygen equilibria of the variant hemoglobins in solution are sensitive to numerous variables besides the properties of the deoxygenated T state. In contrast to CO combination kinetics, the residues whose alterations cause the largest changes in overall oxygen equilibria in solution are scattered seemingly randomly within the alpha 1 beta 2 interface.

Heme pocket disorder in myoglobin: reversal by acid-induced soft refolding.

The protein folding process of heme proteins entails generation of not only a correct global polypeptide structure, but also a correct, functionally competent heme environment. We employed a variety of spectroscopic approaches to probe the structure and dynamics of the heme pocket of a recombinant sperm whale myoglobin. The conformational characteristics were examined by circular dichroism, time-resolved fluorescence spectroscopy, FTIR spectroscopy, and optical absorption spectroscopy in the temperature range 300-20 K. Each of these spectroscopic probes detected modifications confined exclusively to the heme pocket of the expressed myoglobin relative to the native protein. The functional properties were examined by measuring the kinetics of CO binding after flash-photolysis. The kinetics of the expressed myoglobin were more heterogeneous than those of the native protein. Mild acid exposure of the ferric derivative of the recombinant protein resulted in a protein with "nativelike" spectroscopic properties and homogeneous CO binding kinetics. The heme pocket modifications observed in this recombinant myoglobin do not derive from inverted heme. In contrast, when native apomyoglobin is reconstituted with the heme in vitro, the heme pocket disorder could be attributed exclusively to 180 degrees rotation of the bound heme [La Mar, G. N., Toi, H., and Krishnamoorthi, R. (1984) J. Am. Chem. Soc. 106, 6395-6401; Light, W. R., Rohlfs, R. J., Palmer, G., and Olson, J. S. (1987) J. Biol. Chem. 262, 46-52]. We conclude that exposure to low pH decreases the affinity of globin for the heme and allows an extended conformational sampling or "soft refolding" to a nativelike conformation.

Kinetics of CO binding to the haem domain of murine inducible nitric oxide synthase: differential effects of haem domain ligands.

The binding of CO to the murine inducible nitric oxide synthase (iNOS) oxygenase domain has been studied by laser flash photolysis. The effect of the (6R)-5,6,7,8-tetrahydro-L-biopterin (BH(4)) cofactor L-arginine and several Type I L-arginine analogues/ligands on the rates of CO rebinding has been evaluated. The presence of BH(4) in the iNOS active site has little effect on the rebinding of protein-caged haem-CO pairs (geminate recombination), but decreases the bimolecular association rates 2-fold. Addition of L-arginine to the BH(4)-bound complex completely abolishes geminate recombination and results in a further 80-fold decrease in the overall rate of bimolecular association. Three of the Type I ligands, S-ethylisothiourea, L-canavanine and 2,5-lutidine, displaced the CO from the haem iron upon addition to the iNOS oxygenase domain. The Type I ligands significantly decreased the rate of bimolecular binding of CO to the haem iron after photolysis. Most of these ligands also completely abolished geminate recombination. These results are consistent with a relatively open distal pocket that allows CO to bind unhindered in the active site of murine iNOS in the absence of L-arginine or BH(4). In the presence of BH(4) and L-arginine, however, the enzyme adopts a more closed structure that can greatly reduce ligand access to the haem iron. These observations are discussed in terms of the known structure of iNOS haem domain and solution studies of ligand binding in iNOS and neuronal NOS isoenzymes.

Kinetics of CO binding to the haem domain of murine inducible nitric oxide synthase: differential effects of haem domain ligands

The binding of CO to the murine inducible nitric oxide synthase (iNOS) oxygenase domain has been studied by laser flash photolysis. The effect of the (6R)-5,6,7,8-tetrahydro-l-biopterin (BH4) cofactor l-arginine and several Type I l-arginine analogues/ligands on the rates of CO rebinding has been evaluated. The presence of BH4 in the iNOS active site has little effect on the rebinding of protein-caged haem–CO pairs (geminate recombination), but decreases the bimolecular association rates 2-fold. Addition of l-arginine to the BH4-bound complex completely abolishes geminate recombination and results in a further 80-fold decrease in the overall rate of bimolecular association. Three of the Type I ligands, S-ethylisothiourea, l-canavanine and 2,5-lutidine, displaced the CO from the haem iron upon addition to the iNOS oxygenase domain. The Type I ligands significantly decreased the rate of bimolecular binding of CO to the haem iron after photolysis. Most of these ligands also completely abolished geminate recombination. These results are consistent with a relatively open distal pocket that allows CO to bind unhindered in the active site of murine iNOS in the absence of l-arginine or BH4. In the presence of BH4 and l-arginine, however, the enzyme adopts a more closed structure that can greatly reduce ligand access to the haem iron. These observations are discussed in terms of the known structure of iNOS haem domain and solution studies of ligand binding in iNOS and neuronal NOS isoenzymes.

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd1 nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd1 nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd1 nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd1 nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd(1) nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation.

cd(1) nitrite reductase from Pseudomonas stutzeri is a di-haem- containing enzyme, comprising a c-type haem and a d-type haem. Studies with the highly related cd(1) nitrite reductase of Pseudomonas aeruginosa have established that this enzyme undergoes fast (microsecond) and global structural relaxation upon CO photodissociation from the reduced enzyme. A key difference between the Ps. aeruginosa and Ps. stutzeri enzyme is the absence of a flexible N-terminal extension in the Ps. stutzeri enzyme. In Ps. aeruginosa cd(1) nitrite reductase the N-terminal extension wraps around the second subunit of the homodimer and with Tyr(10) stabilizing a water molecule co-ordinated to the d(1)-haem. Given the intimate association of the N-terminal extension with the d(1)-haem, we hypothesized that the presence of the N-terminal extension likely contributes to the fast structural reorganization seen during photodissociation of CO from the reduced enzyme. In the present study we have investigated the kinetics of CO association and CO photodissociation of Ps. stutzeri cd(1) nitrite reductase (which lacks the N-terminal arm seen in the Ps. aeruginosa enzyme) to probe the role and influence of the N-terminal arm in the fast global structural reorganization seen with Ps. aeruginosa. Surprisingly, we find that Ps. stutzeri cd(1) nitrite reductase also undergoes fast structural reorganization during CO photodissociation. We also show, in stopped-flow experiments, that the kinetics of CO binding and dissociation with reduced Ps. stutzeri cd(1) nitrite reductase are similar to those observed with Ps. aeruginosa enzyme, thus ruling out a major role for the N-terminal flexible arm found in Ps. aeruginosa in the kinetics of these processes. Our data indicate that global structural reorganization following CO photodissociation is an intrinsic property of the haem domains in cd(1) nitrite reductases. The absence of an N-terminal extension, as in the Ps. stutzeri cd(1) nitrite reductase, does not lead to loss of global structural reorganization following CO photodissociation.

Kinetics of CO binding and CO photodissociation in Pseudomonas stutzeri cd1 nitrite reductase: probing the role of extended N-termini in fast structural relaxation upon CO photodissociation

cd 1 nitrite reductase from Pseudomonas stutzeri is a di-haem- containing enzyme, comprising a c-type haem and a d-type haem. Studies with the highly related cd1 nitrite reductase of Pseudomonas aeruginosahave established that this enzyme undergoes fast (microsecond) and global structural relaxation upon CO photodissociation from the reduced enzyme. A key difference between the Ps. aeruginosa and Ps. stutzerienzyme is the absence of a flexible N-terminal extension in the Ps. stutzeri enzyme. In Ps. aeruginosacd1 nitrite reductase the N-terminal extension wraps around the second subunit of the homodimer and with Tyr10 stabilizing a water molecule co-ordinated to the d1-haem. Given the intimate association of the N-terminal extension with the d1-haem, we hypothesized that the presence of the N-terminal extension likely contributes to the fast structural reorganization seen during photodissociation of CO from the reduced enzyme. In the present study we have investigated the kinetics of CO association and CO photodissociation of Ps. stutzericd1 nitrite reductase (which lacks the N-terminal arm seen in the Ps. aeruginosa enzyme) to probe the role and influence of the N-terminal arm in the fast global structural reorganization seen with Ps. aeruginosa. Surprisingly, we find that Ps. stutzericd1 nitrite reductase also undergoes fast structural reorganization during CO photodissociation. We also show, in stopped-flow experiments, that the kinetics of CO binding and dissociation with reduced Ps. stutzericd1 nitrite reductase are similar to those observed with Ps. aeruginosa enzyme, thus ruling out a major role for the N-terminal flexible arm found in Ps. aeruginosain the kinetics of these processes. Our data indicate that global structural reorganization following CO photodissociation is an intrinsic property of the haem domains in cd1 nitrite reductases. The absence of an N-terminal extension, as in the Ps. stutzericd1 nitrite reductase, does not lead to loss of global structural reorganization following CO photodissociation.

Carbon monoxide binding by de novo heme proteins derived from designed combinatorial libraries.

Carbon monoxide binding was studied in a collection of de novo heme proteins derived from combinatorial libraries of sequences designed to fold into 4-helix bundles. The design of the de novo sequences was based on the previously reported "binary code" strategy, in which the patterning of polar and nonpolar amino acids is specified explicitly, but the exact identities of the side chains are varied extensively.(1) The combinatorial mixture of amino acids included histidine and methionine, which ligate heme iron in natural proteins. However, no attempt was made to explicitly design a heme binding site. Nonetheless, as reported previously, approximately half of the binary code proteins bind heme.(2) This collection of novel heme proteins provides a unique opportunity for an unbiased assessment of the functional potentialities of heme proteins that have not been prejudiced either by explicit design or by evolutionary selection. To assess the capabilities of the de novo heme proteins to bind diatomic ligands, we measured the affinity for CO, the kinetics of CO binding and release, and the resonance Raman spectra of the CO complexes for eight de novo heme proteins from two combinatorial libraries. The CO binding affinities for all eight proteins were similar to that of myoglobin, with dissociation constants (K(d)) in the low nanomolar range. The CO association kinetics (k(on)) revealed that the heme environment in all eight of the de novo proteins is partially buried, and the resonance Raman studies indicated that the local environment around the bound CO is devoid of hydrogen-bonding groups. Overall, the CO binding properties of the de novo heme proteins span a narrow range of values near the center of the range observed for diverse families of natural heme proteins. The measured properties of the de novo heme proteins can be considered as a "default" range for CO binding in alpha-helical proteins that have neither been designed to bind heme or CO, nor subjected to genetic selections for heme or CO binding.

Kinetics of CO and NO Ligation with the Cys331 → Ala Mutant of Neuronal Nitric-oxide Synthase

Nitric-oxide synthases (NOS) catalyze the conversion of l-arginine to NO, which then stimulates many physiological processes. In the active form, each NOS is a dimer; each strand has both a heme-binding oxygenase domain and a reductase domain. In neuronal NOS (nNOS), there is a conserved cysteine motif (CX(4)C) that participates in a ZnS(4) center, which stabilizes the dimer interface and/or the flavoprotein-heme domain interface. Previously, the Cys(331) --> Ala mutant was produced, and it proved to be inactive in catalysis and to have structural defects that disrupt the binding of l-Arg and tetrahydrobiopterin (BH(4)). Because binding l-Arg and BH(4) to wild type nNOS profoundly affects CO binding with little effect on NO binding, ligand binding to the mutant was characterized as follows. 1) The mutant initially has behavior different from native protein but reminiscent of isolated heme domain subchains. 2) Adding l-Arg and BH(4) has little effect immediately but substantial effect after extended incubation. 3) Incubation for 12 h restores behavior similar but not quite identical to that of wild type nNOS. Such incubation was shown previously to restore most but not all catalytic activity. These kinetic studies substantiate the hypothesis that zinc content is related to a structural rather than a catalytic role in maintaining active nNOS.