Calmodulin-dependent regulation of mammalian nitric oxide synthase

The nitric oxide synthases are large, modular, dimeric enzymes composed of a reductase domain, which is related to cytochrome P450 reductase, and a structurally unique oxygenase domain containing a Cys-ligated haem. Both the neuronal and endothelial isoforms are activated by the reversible binding of calmodulin (CaM) at elevated intracellular Ca(2+) levels to produce NO as part of a number of cell signalling pathways. CaM binds to the linker region between the two domains and activates the enzyme by inducing intramolecular electron transfer. Protein-engineering experiments have shown that a series of unusual autoinhibitory inserts found only in the CaM-dependent NOS isoforms control both CaM binding and the structural rearrangement it induces. These lie in the reductase domain of the enzyme and include a 40-amino-acid autoinhibitory loop in the FMN-binding module, a 30-amino-acid extension to the C-terminus and the CaM-binding site itself. The substrate (NADPH) also plays an important role in defining the CaM-dependence of the reductase domain by inducing a tight conformational lock in the absence of CaM. Both the substrate and the conformational lock appear to be released on CaM binding; the resultant domain mobility leads to activation.

Rapid calmodulin-dependent interdomain electron transfer in neuronal nitric-oxide synthase measured by pulse radiolysis

Electron transfer within rat neuronal nitric-oxide synthase (nNOS) was investigated by pulse radiolysis. Radiolytically generated 1-methyl-3-carbamoyl pyridinium (MCP) radical was found to react predominantly with the heme of the enzyme with a second-order rate constant for heme reduction of 3 x 10(8) m(-1) s(-1). In the calmodulin (CaM)-bound enzyme a subsequent first-order phase was observed which had a rate constant of 1.2 x 10(3) s(-1). In the absence of CaM, this phase was absent. Kinetic difference spectra for nNOS reduction indicated that the second phase consisted of heme reoxidation accompanied by formation of a neutral flavin semiquinone, suggesting that it is heme to flavin electron transfer. Experiments with the heme proximal surface mutant, K423E, had no second phase, confirming that the mutation blocks interdomain electron transfer. With the autoinhibitory loop deletion mutant, Delta40, the slow phase was observed even in the absence of CaM consistent with the role of the loop in impeding interdomain electron transfer. The rate of heme to FMN electron transfer observed in the wild-type enzyme is approximately 1000 times faster than the FMN to heme electron transfer rate predicted during catalysis from kinetic modeling, suggesting that the catalytic process is slowed by kinetic gating.

Control of electron transfer in neuronal NO synthase

The nitric oxide synthases (NOSs) are dimeric flavocytochromes consisting of an oxygenase domain with cytochrome P450-like Cys-ligated haem, coupled to a diflavin reductase domain, which is related to cytochrome P450 reductase. The NOSs catalyse the sequential mono-oxygenation of arginine to N-hydroxyarginine and then to citrulline and NO. The constitutive NOS isoforms (cNOSs) are regulated by calmodulin (CaM), which binds at elevated concentrations of free Ca(2+), whereas the inducible isoform binds CaM irreversibly. One of the main structural differences between the constitutive and inducible isoforms is an insert of 40-50 amino acids in the FMN-binding domain of the cNOSs. Deletion of the insert in rat neuronal NOS (nNOS) led to a mutant enzyme which binds CaM at lower Ca(2+) concentrations and which retains activity in the absence of CaM. In order to resolve the mechanism of action of CaM activation we determined reduction potentials for the FMN and FAD cofactors of rat nNOS in the presence and absence of CaM using a recombinant form of the reductase domain. The results indicate that CaM binding does not modulate the reduction potentials of the flavins, but appears to control electron transfer primarily via a large structural rearrangement. We also report the creation of chimaeric enzymes in which the reductase domains of nNOS and flavocytochrome P450 BM3 (Bacillus megaterium III) have been exchanged. Despite its very different flavin redox potentials, the BM3 reductase domain was able to support low levels of CaM-dependent NO synthesis, whereas the NOS reductase domain did not effectively substitute for that of cytochrome P450 BM3.

Intra-subunit and inter-subunit electron transfer in neuronal nitric-oxide synthase: effect of calmodulin on heterodimer catalysis

In neuronal nitric-oxide synthase (nNOS), calmodulin (CaM) binding is thought to trigger electron transfer from the reductase domain to the heme domain, which is essential for O(2) activation and NO formation. To elucidate the electron-transfer mechanism, we characterized a series of heterodimers consisting of one full-length nNOS subunit and one oxygenase-domain subunit. The results support an inter-subunit electron-transfer mechanism for the wild type nNOS, in that electrons for catalysis transfer in a Ca(2+)/CaM-dependent way from the reductase domain of one subunit to the heme of the other subunit, as proposed for inducible NOS. This suggests that the two different isoforms form similar dimeric complexes. In a series of heterodimers containing a Ca(2+)/CaM-insensitive mutant (delta40), electrons transferred from the reductase domain to both hemes in a Ca(2+)/CaM-independent way. Thus, in the delta40 mutant electron transfer from the reductase domains to the heme domains can occur via both inter-subunit and intra-subunit mechanisms. However, NO formation activity was exclusively linked to inter-subunit electron transfer and was observed only in the presence of Ca(2+)/CaM. This suggests that the mechanism of activation of nNOS by CaM is not solely dependent on the activation of electron transfer to the nNOS hemes but may involve additional structural factors linked to the catalytic action of the heme domain.

alpha Arg-237 in Methylophilus methylotrophus (sp. W3A1) electron-transferring flavoprotein affords approximately 200-millivolt stabilization of the FAD anionic semiquinone and a kinetic block on full reduction to the dihydroquinone

The midpoint reduction potentials of the FAD cofactor in wild-type Methylophilus methylotrophus (sp. W3A1) electron-transferring flavoprotein (ETF) and the alphaR237A mutant were determined by anaerobic redox titration. The FAD reduction potential of the oxidized-semiquinone couple in wild-type ETF (E'(1)) is +153 +/- 2 mV, indicating exceptional stabilization of the flavin anionic semiquinone species. Conversion to the dihydroquinone is incomplete (E'(2) < -250 mV), because of the presence of both kinetic and thermodynamic blocks on full reduction of the FAD. A structural model of ETF (Chohan, K. K., Scrutton, N. S., and Sutcliffe, M. J. (1998) Protein Pept. Lett. 5, 231-236) suggests that the guanidinium group of Arg-237, which is located over the si face of the flavin isoalloxazine ring, plays a key role in the exceptional stabilization of the anionic semiquinone in wild-type ETF. The major effect of exchanging alphaArg-237 for Ala in M. methylotrophus ETF is to engineer a remarkable approximately 200-mV destabilization of the flavin anionic semiquinone (E'(2) = -31 +/- 2 mV, and E'(1) = -43 +/- 2 mV). In addition, reduction to the FAD dihydroquinone in alphaR237A ETF is relatively facile, indicating that the kinetic block seen in wild-type ETF is substantially removed in the alphaR237A ETF. Thus, kinetic (as well as thermodynamic) considerations are important in populating the redox forms of the protein-bound flavin. Additionally, we show that electron transfer from trimethylamine dehydrogenase to alphaR237A ETF is severely compromised, because of impaired assembly of the electron transfer complex.

Important role of tetrahydrobiopterin in no complex formation and interdomain electron transfer in neuronal nitric-oxide synthase

Neuronal nitric-oxide synthase (nNOS) is composed of a heme oxygenase domain and a flavin-bound reductase domain. Ca(2+)/calmodulin (CaM) is essential for interdomain electron transfer during catalysis, whereas the role of the catalytically important cofactor, tetrahydrobiopterin (H4B) remains elusive. The product NO appears to bind to the heme and works as a feedback inhibitor. The present study shows that the Fe(3+)-NO complex is reduced to the Fe(2+)-NO complex by NADPH in the presence of both l-Arg and H4B even in the absence of Ca(2+)/CaM. The complex could not be fully reduced in the absence of H4B under any circumstances. However, dihydrobiopterin and N(G)-hydroxy-l-Arg could be substituted for H4B and l-Arg, respectively. No direct correlation could be found between redox potentials of the nNOS heme and the observed reduction of the Fe(3+)-NO complex. Thus, our data indicate the importance of the pterin binding to the active site structure during the reduction of the NO-heme complex by NADPH during catalytic turnover.

Roles of the heme proximal side residues tryptophan409 and tryptophan421 of neuronal nitric oxide synthase in the electron transfer reaction

Nitric oxide synthase (NOS) has an oxygenase domain with a thiol-coordinated heme active side similar to cytochrome P450. In contrast to cytochrome P450, however, conserved aromatic amino acids are situated in the heme proximal side of NOS. For example, in endothelial NOS (eNOS), the indole-ring nitrogen of Trp180 hydrogen-binds to the thiol of Cys186, the internal axial ligand to the heme. And, the aromatic side chain of Trp192 forms a bridge between this residue and the protein. Trp180 and Trp192 of eNOS correspond to Trp409 and Trp421 of neuronal NOS (nNOS), respectively. In order to understand the roles of the aromatic amino acids in catalysis, we generated Trp409His, Trp409Leu, Trp421His and Trp421Leu mutants of nNOS and determined their catalytic parameters. The Trp409Leu mutant was very poorly expressed in E. coli and was easily denatured during purification procedures. The NO formation activities of the Trp409His and Trp421Leu mutants were 11 and 25 micromol/min per micromol heme, respectively, and are lower than that (44 micromol/min per micromol heme) of the wild type. The activity (46 micromol/min per micromol heme) of the Trp421His mutant was comparable to that of the wild-type enzyme. However, NADPH oxidation rates of Trp421His (230 micromol/min per micromol heme) and Trp421Leu (104 micromol/min per microol heme) in the presence of L-Arg were much larger than those observed for the wild type (65 micromol/min per micromol heme) and the Trp409His mutant (43 micromol/min per micromol heme). The cytochrome c reduction rate of the Trp421His mutant was 6-fold larger than that of the wild type. The heme reduction rate with NADPH for the Trp421His mutant (0.09 min(-1)) was much lower than that (1.0 min(-1)) of the wild type. Taken together, it appears that Trp421 may be involved in inter-domain/inter-subunit electron transfer reactions.

Azo reduction of methyl red by neuronal nitric oxide synthase: the important role of FMN in catalysis

Nitric oxide synthase (NOS) is composed of an oxygenase domain and a reductase domain. The reductase domain has NADPH, FAD, and FMN binding sites. Wild-type nNOS reduced the azo bond of methyl red with a turnover number of approximately 130 min(-1) in the presence of Ca(2+)/calmodulin (CaM) and NADPH under anaerobic conditions. Diphenyleneiodonium chloride (DPI), a flavin/NADPH binding inhibitor, completely inhibited azo reduction. The omission of Ca(2+)/CaM from the reaction system decreased the activity to 5%. The rate of the azo reduction with an FMN-deficient mutant was also 5% that of the wild type. NADPH oxidation rates for the wild-type and mutant enzymes were well coupled with azo reduction. Thus, we suggest that electrons delivered from the FMN of the nNOS enzyme reduce the azo bond of methyl red and that this reductase activity is controlled by Ca(2+)/CaM.

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.

The 42-amino acid insert in the FMN domain of neuronal nitric-oxide synthase exerts control over Ca(2+)/calmodulin-dependent electron transfer

The neuronal and endothelial nitric-oxide synthases (nNOS and eNOS) differ from inducible NOS in their dependence on the intracellular Ca(2+) concentration. Both nNOS and eNOS are activated by the reversible binding of calmodulin (CaM) in the presence of Ca(2+), whereas inducible NOS binds CaM irreversibly. One major divergence in the close sequence similarity between the NOS isoforms is a 40-50-amino acid insert in the middle of the FMN-binding domains of nNOS and eNOS. It has previously been proposed that this insert forms an autoinhibitory domain designed to destabilize CaM binding and increase its Ca(2+) dependence. To examine the importance of the insert we constructed two deletion mutants designed to remove the bulk of it from nNOS. Both mutants (Delta40 and Delta42) retained maximal NO synthesis activity at lower concentrations of free Ca(2+) than the wild type enzyme. They were also found to retain 30% of their activity in the absence of Ca(2+)/CaM, indicating that the insert plays an important role in disabling the enzyme when the physiological Ca(2+) concentration is low. Reduction of nNOS heme by NADPH under rigorous anaerobic conditions was found to occur in the wild type enzyme only in the presence of Ca(2+)/CaM. However, reduction of heme in the Delta40 mutant occurred spontaneously on addition of NADPH in the absence of Ca(2+)/CaM. This suggests that the insert regulates activity by inhibiting electron transfer from FMN to heme in the absence of Ca(2+)/CaM and by destabilizing CaM binding at low Ca(2+) concentrations, consistent with its role as an autoinhibitory domain.

Crucial role of Lys(423) in the electron transfer of neuronal nitric-oxide synthase

Nitric-oxide synthase (NOS) is composed of an oxygenase domain having cytochrome P450-type heme active site and a reductase domain having FAD- and FMN-binding sites. To investigate the route of electron transfer from the reductase domain to the heme, we generated mutants at Lys(423) in the heme proximal site of neuronal NOS and examined the catalytic activities, electron transfer rates, and NADPH oxidation rates. A K423E mutant showed no NO formation activity (<0.1 nmol/min/nmol heme), in contrast with that (72 nmol/min/nmol heme) of the wild type enzyme. The electron transfer rate (0.01 min(-1)) of the K423E on addition of excess NADPH was much slower than that (>10 min(-1)) of the wild type enzyme. From the crystal structure of the oxygenase domain of endothelial NOS, Lys(423) of neuronal NOS is likely to interact with Trp(409) which lies in contact with the heme plane and with Cys(415), the axial ligand. It is also exposed to solvent and lies in the region where the heme is closest to the protein surface. Thus, it seems likely that ionic interactions between Lys(423) and the reductase domain may help to form a flavin to heme electron transfer pathway.

Autoxidation rates of neuronal nitric oxide synthase: effects of the substrates, inhibitors, and modulators

Autoxidation rates of the full-length neuronal nitric oxide synthase (nNOS) were analyzed and found to be composed of three phases, 60 s(-1) (28%), 5.5 s(-1) (11%) and 0.048 s(-1) (61%). Addition of L-Arg, N(G)-hydroxy-L-Arg (NHA), and N(G)-monomethyl-L-Arg markedly decreased the rate constants for the first and second phases down to 12-20 s(-1) and 0.32-2.6 s(-1), respectively. Addition of (6R)-5,6,7,8-tetrahydro-L-biopterin (H4B) increased the amplitude of the second phase up to 29% of the total. Addition of NHA decreased the rate of the first phase by 4.4-fold in the presence of H4B, whereas addition of L-Arg and other modulators did not significantly affect the rates under the same conditions. Thus, we deduce that (1) L-Arg stabilizes the O2-bound ferrous complex for efficient O-O bond cleavage to occur; (2) H4B influences the O2-bound ferrous complex in a fashion different from L-Arg; and (3) NHA induces a characteristic distal-site structure in the presence of H4B, reflecting a difference in the mechanism of activation of O2 in the first step (monooxygenation of L-Arg) and the second step (monooxygenation of NHA).

Marked enhancement in the reductive dehalogenation of hexachloroethane by a Thr319Ala mutation of cytochrome P450 1A2

Mutation of the conserved Thr319 residue to Ala of cytochrome P4501A2 (CYP1A2) increased the value of Vmax 9-fold for reductive dehalogenation of hexachloroethane in the reconstituted system under anaerobic conditions. The Thr319Ala mutation also increased the elimination over substitution product ratio by 5-fold. The addition of aliphatic alcohols increased by 22-fold the activity obtained with the wild type and varied the elimination over substitution product ratio. Increasing pH increased the ratio of elimination over substitution by primarily affecting the rate of elimination.

Chiral recognition at the heme active site of nitric oxide synthase is markedly enhanced by L-arginine and 5,6,7,8-tetrahydrobiopterin

The effects of substrate, L-Arg and cofactors, (6R)-L-erythro-5,6,7,8-tetrahydrobiopterin (H4B) and calmodulin (CaM), on chiral discrimination by rat neuronal nitric oxide synthase (nNOS) for binding the enantiomers of 1-(1-naphthyl)ethylamine (ligand I), 1-cyclohexylethylamine (ligand II), and 1-(4-pyridyl)ethanol (ligand III) were studied under anaerobic conditions by optical absorption spectroscopy. The ratio of the dissociation constant (Kd) values for the S- and R-enantiomers of ligand I (S/R) was 30, while the S/R ratio for ligand II and the R/S ratio for ligand III were 1.8 and < 0.14, respectively, in the presence of 0.15 microM H4B. However, in the presence of 1 mM L-Arg, the S/R ratio of the Kd values for ligand I was decreased down to 5.9. In the presence of both 1 mM L-Arg and 0.1 mM H4B, the S/R ratios for ligands I and II and the R/S ratio for ligand III were enormously increased up to 29, > 80, and 60, respectively. These and other spectral observations strongly suggest that strict chiral recognition at the active site of nNOS during catalysis is exhibited only in the presence of the active effector.

CO binding studies of nitric oxide synthase: effects of the substrate, inhibitors and tetrahydrobiopterin

The dissociation constant (Kd) for CO from neuronal nitric oxide synthase heme in the absence of the substrate and cofactor was less than 10(-3) microM. In the presence of L-Arg, it dramatically increased up to 1 microM. In the presence of inhibitors such as N(G)-nitro-L-arginine methyl ester and 7-nitroindazole (NI), the Kd value further increased up to more than 100 microM. Addition of the cofactor, 5,6,7,8-tetrahydrobiopterin (H4B), increased the Kd value by 10-fold in the presence of L-Arg, whereas it decreased the value to less than one 250th in the presence of NI. Addition of H4B increased the recombination rate constant (k(on)) for CO by more than two-fold in the presence of L-Arg or N6-(1-iminoethyl)-L-lysine, whereas it decreased the k(on) value by three-fold in the presence of L-thiocitrulline. Thus, the binding fashion of some of inhibitors, such as NI, may be different from that of L-Arg with respect to the H4B effect.

Probing electron transfer in flavocytochrome P-450 BM3 and its component domains

Rapid events in the processes of electron transfer and substrate binding to cytochrome P-450 BM3 from Bacillus megaterium and its constituent haem-containing and flavin-containing domains have been investigated using stopped-flow spectrophotometry. The formation of a blue semiquinone flavin form occurs during the NADPH-dependent reduction of the flavin domain and a species with a similar absorption maximum is also seen during reduction of the holoenzyme by NADPH. EPR spectroscopy confirms the formation of the flavin semiquinone. The formation of this semiquinone is transient during fatty acid monooxygenation by the holoenzyme, but in the presence of excess NADPH the species reforms once fatty acid is exhausted. Electron transfers through the reductase domain are too rapid to limit the fatty acid monooxygenation reaction. The substrate-binding-induced haem iron spin-state shift also occurs much faster than the Kcat at 25 degrees C. The rate of first electron transfer to the haem domain is also rapid; but it is of the order of 5-10-times larger than the Kcat for the enzyme (dependent on the fatty acid used). Given that two successive electron transfers to haem iron are required for the oxygenation reaction, these rates are likely to exert some control over the rate of fatty acid oxygenation reactions. The presence of large amounts of NADPH also results in decreased rates of electron transfer from flavin to haem iron. In the difference spectrum of the active fatty acid hydroxylase, features indicative of a high-spin iron haem accumulate. These are in accordance with the presence of large amounts of an Fe(3+)-product bound enzyme during turnover and indicate that product release may also contribute to rate limitation. Taken together, these data suggest that the catalytic rate is not determined by the accumulation of a single intermediate in the reaction scheme, but rather that it is controlled in a series of steps.

New insights into the catalytic cycle of flavocytochrome b2

Flavocytochrome b2 from Saccharomyces cerevisiae couples L-lactate dehydrogenation to cytochrome c reduction in the mitochondrial intermembrane space. The catalytic cycle for this process can be described in terms of five consecutive electron-transfer events. L-Lactate dehydrogenation results in the two-electron reduction of FMN. The two electrons are individually passed to b2-heme (intramolecular electron transfer) and then onto cytochrome c (intermolecular electron transfer). At 25 degrees C, I 0.10, in the presence of saturating concentrations of ferricytochrome c and L-lactate, the catalytic cycle progresses with rate constant 104 (+/- 5) s-1 [per L-lactate oxidized; Miles, C. S., Rouviere-Fourmy, N., Lederer, F., Mathews, F. S., Reid, G. A., & Chapman, S. K. (1992) Biochem. J. 285, 187-192]. Stopped-flow spectrophotometry has been used to show that the major rate-limiting step in the catalytic cycle is electron transfer from flavin semiquinone to b2-heme. This conclusion is based on the observation that pre-steady-state flavin oxidation by ferricytochrome c takes place at 120 s-1. Although flavin oxidation involves several other electron transfer steps, these are considered too fast to contribute significantly to the rate constant. It was also shown that the reaction product, pyruvate, is able to inhibit pre-steady-state flavin oxidation (Ki = 40 +/- 17 mM) consistent with reports that it acts as a noncompetitive inhibitor in the steady state at high concentrations [Ki = 30 mM; Lederer, F. (1978) Eur. J. Biochem, 88, 425-431]. This novel way of measuring the electron transfer rate constant is directly applicable to the catalytic cycle and has enabled us to derive a self-consistent model for it, based also on data collected for enzyme reduction [Miles, C. S., Rouviere-Fourmy, N., Lederer, F., Mathews, F. S., Reid, G. A., & Chapman, S. K. (1992) Biochem. J. 285, 187-192] and its interaction with cytochrome c [Daff, S., Sharp, R. E., Short, D. M., Bell, C., White, P., Manson, F. D. C., Reid, G. A., & Chapman, S. K. (1996) Biochemistry 35, 6351-6357]. Rapid-freezing quenched-flow EPR has been used to confirm the model by demonstrating that during steady-state turnover of the enzyme approximately 75% of the flavin is in the semiquinone oxidation state.

Interaction of cytochrome c with flavocytochrome b2

Flavocytochrome b2 from Saccharomyces cerevisiae couples L-lactate dehydrogenation to cytochrome c reduction. At 25 degrees C, 0.10 M ionic strength, and saturating L-lactate concentration, the turnover rate is 207 s-1 [per cytochrome c reduced; Miles, C. S., Rouviere, N., Lederer, F., Mathews, F. S., Reid, G. A., Black, M. T., & Chapman, S. K. (1992) Biochem. J. 285, 187-192]. The second-order rate constant for cytochrome c reduction in the pre-steady-state has been determined by stopped-flow spectrophotometry to be 34.8 (+/- 0.9) muM-1 s-1 in the presence of 10 mM L-lactate. This rate constant has been found to be dependent entirely on the rate of complex formation, the electron-transfer rate in the pre-formed complex being in excess of 1000 s-1. Inhibition of the pre-steady-state reduction of cytochrome c by either zinc-substituted cytochrome c or ferrocytochrome c has led to the estimation of a Kd for the catalytically competent complex of 8 microM, and from this the dissociation rate constant of 280 s-1, a value much less than the actual electron-transfer rate. The inhibition observed is only partial which indicates that electron transfer from the 1:1 complex to another cytochrome c can occur and that alternative electron transfer sites exist. The cytochrome c binding site proposed by Tegoni et al. [Tegoni, M., White, S. A., Roussel, A., Mathews, F. S. & Cambillau, C. (1993) Proteins 16, 408-422] has been tested using site-directed mutagenesis. Mutations designed to affect the complex stability and putative electron-transfer pathway had little effect, suggesting that the primary cytochrome c binding site on flavocytochrome b2 lies elsewhere. The combination of tight binding and multiple electron-transfer sites gives flavocytochrome b2 a low K(m) and a high kcat, maximizing its catalytic efficiency. In the steady-state, the turnover rate is therefore largely limited by other steps in the catalytic cycle, a conclusion which is discussed in the preceding paper in this issue [Daff, S., Ingledew, W. J., Reid, G. A., & Chapman, S. K. (1996) Biochemistry 35, 6345-6350].

Strategic manipulation of the substrate specificity of Saccharomyces cerevisiae flavocytochrome b2

Flavocytochrome b2 from Saccharomyces cerevisiae acts physiologically as an L-lactate dehydrogenase. Although L-lactate is its primary substrate, the enzyme is also able to utilize a variety of other (S)-2-hydroxy acids. Structural studies and sequence comparisons with several related flavoenzymes have identified the key active-site residues required for catalysis. However, the residues Ala-198 and Leu-230, found in the X-ray-crystal structure to be in contact with the substrate methyl group, are not well conserved. We propose that the interaction between these residues and a prospective substrate molecule has a significant effect on the substrate specificity of the enzyme. In an attempt to modify the specificity in favour of larger substrates, three mutant enzymes have been produced: A198G, L230A and the double mutant A198G/L230A. As a means of quantifying the overall kinetic effect of a mutation, substrate-specificity profiles were produced from steady-state experiments with (S)-2-hydroxy acids of increasing chain length, through which the catalytic efficiency of each mutant enzyme with each substrate could be compared with the corresponding wild-type efficiency. The Ala-198-->Gly mutation had little influence on substrate specificity and caused a general decrease in enzyme efficiency. However, the Leu-230-->Ala mutation caused the selectivity for 2-hydroxyoctanoate over lactate to increase by a factor of 80.