High pressure, a tool for exploring heme protein active sites

High pressure is an interesting and suitable parameter in the study of the dynamics and stability of proteins. The effects of pressure on proteins delineates its volumic (deltaV degrees ) and energetic (deltaG degrees ) parameters. An enormous amount of effort has been invested by several laboratories in developing basic theory and high pressure techniques that allow the determination of barotropic parameters. Cytochrome P450s, one of the largest super families of heme proteins, are good models for high pressure studies. Two distinct pressure-induced spin transitions of the heme iron in the active site and a P450 to P420 inactivation process have been characterized. The obtained reaction volumes of these two processes for a series of analog-bound cytochrome P450s are compared. We have shown that both the spin volume and the inactivation volume are dependent on the substrate analogs which are known to modulate the polarity and hydration of the heme pocket. Several linear correlations were found between these reaction volumes and the physico-chemical properties of the heme protein such as the polarity-induced exposure of tyrosines, the hydration of the cytochrome CYP101 heme pocket, and the mobility and binding of the substrates indicate that they constitute the main contribution to the complex thermodynamic reaction volume parameters. This interpretation allows us to conclude that cytochrome CYP101, CYP2B4 and CYP102 possess a similar mechanism of substrate binding. Interestingly the barotropic behaviors of monomeric cytochrome P450s are quite different from those of oligomeric and hetorooligomeric cytochrome P450s. The interactions of heterooligomeric subunits influence the stability of individual cytochrome P450s and the asymmetric organization of subunits which can control and modulate the activity and the recognition with NADPH-cytochrome P450 reductase.     

Resonance Raman study on the structure of the active sites of microsomal cytochrome P-450 isozymes LM2 and LM4

The isozymes 2 and 4 of rabbit microsomal cytochrome P-450 (LM2, LM4) have been studied by resonance Raman spectroscopy. Based on high quality spectra, a vibrational assignment of the porphyrin modes in the frequency range between 100-1700 cm-1 is presented for different ferric states of cytochrome P-450 LM2 and LM4. The resonance Raman spectra are interpreted in terms of the spin and ligation state of the heme iron and of heme-protein interactions. While in cytochrome P-450 LM2 the six-coordinated low-spin configuration is predominantly occupied, in the isozyme LM4 the five-coordinated high-spin form is the most stable state. The different stability of these two spin configurations in LM2 and LM4 can be attributed to the structures of the active sites. In the low-spin form of the isozymes LM4 the protein matrix forces the heme into a more rigid conformation than in LM2. These steric constraints are removed upon dissociation of the sixth ligand leading to a more flexible structure of the active site in the high-spin form of the isozyme LM4. The vibrational modes of the vinyl groups were found to be characteristic markers for the specific structures of the heme pockets in both isozymes. They also respond sensitively to type-I substrate binding. While in cytochrome P-450 LM4 the occupation of the substrate-binding pocket induces conformational changes of the vinyl groups, as reflected by frequency shifts of the vinyl modes, in the LM2 isozyme the ground-state conformation of these substituents remain unaffected, suggesting that the more flexible heme pocket can accommodate substrates without imposing steric constraints on the porphyrin. The resonance Raman technique makes structural changes visible which are induced by substrate binding in addition and independent of the changes associated with the shift of the spin state equilibrium: the high-spin states in the substrate-bound and substrate-free enzyme are structurally different. The formation of the inactive form, P-420, involves a severe structural rearrangement in the heme binding pocket leading to drastic changes of the vinyl group conformations. The conformational differences of the active sites in cytochromes P-450 LM2 and LM4 observed in this work contribute to the understanding of the structural basis accounting for substrate and product specificity of cytochrome P-450 isozymes.     

The catalytic mechanism of cytochrome P-450. Spin-trapping evidence for one-electron substrate oxidation

Cytochrome P-450 is destroyed during catalytic oxidation of several 4-substituted 3,5-bis(ethoxycarbonyl)-2,6-dimethyl-1,4-dihydropyridine substrates. A qualitative correlation has been found between the ability to destroy cytochrome P-450 and the stability of the 4-substituent as a radical. Destruction of the enzyme by the 4-ethyl (DDEP), 4-propyl, and 4-isobutyl analogues is due to transfer of the 4-alkyl group from the substrate to a nitrogen of the prosthetic heme, a process which gives rise to isolable N-alkylprotoporphyrin IX derivatives. Little enzyme destruction is observed when the 4-alkyl group is of low radical stability (methyl, phenyl) and good destruction, but no isolable heme adducts when the 4-substituent is of very high radical stability (isopropyl, benzyl). Spin-trapping studies have established that the 4-ethyl group in DDEP is lost as a radical as a result of oxidation by cytochrome P-450. Of three commonly used spin traps, only alpha-(4-pyridyl-1-oxide) N-tert-butylnitrone was found suitable for such studies. The other spin traps, 5,5-dimethyl-1-pyrroline-N-oxide and alpha-phenyl N-tert-butylnitrone, were found to be ineffective, the latter because it strongly inhibits cytochrome P-450. Hydrogen peroxide formed in situ can support a part of the cytochrome P-450-catalyzed ethyl radical formation and DDEP-dependent self-inactivation. The results provide persuasive evidence that oxidation of the nitrogen in DDEP by cytochrome P-450 proceeds in one-electron steps. Cytochrome P-450 may thus function, at least with certain substrates, as a one-electron oxidant.     

Heme-pocket-hydration change during the inactivation of cytochrome P-450camphor by hydrostatic pressure.

Hydrostatic pressure has been used to convert cytochrome P-450camphor to cytochrome P-420. The latter is an inactivated but soluble and undenaturated form of cytochrome P-450camphor. Using camphor analogues as probes of the active site we show that the inactivation volume change is directly correlated to the initial degree of hydration of the heme pocket. The values range between -73 ml/mol and -197 ml/mol [Di Primo, C., Hui Bon Hoa, G., Douzou, P. & Sligar, S. G. (1990) Eur. J. Biochem. 193, 383-386] for a totally hydrated (substrate-free, low-spin, six coordinated heme iron) and a non-hydrated (camphor-bound, high-spin, five coordinated heme iron) heme pocket. These results suggest that the larger value, -197 ml/mol, for the inactivation volume change is due to a hydration change of the heme pocket resulting from the displacement of the substrate during the compression and the subsequent entrance of water molecules. Similarly, the stability of the protein against compression is correlated with water accessibility to the active site. Increase in substrate mobility by loss of specific interactions with both regions of well defined secondary structure of cytochrome P-450camphor results in an increase of water accessibility and decrease of stability. Thus for camphor and adamantanone which strongly interact with the protein and exclude water from the active site [Poulos, T. L., Finzel, B. C. & Howard, A. J. (1987) J. Mol. Biol. 195, 687-700; Raag, R. & Poulos, T. L. (1989) Biochemistry 28, 917-922] the increase in stability compared to the free protein is roughly 30 kJ/mol at 20 degrees C. With smaller substrates such as norcamphor, which loosely fits into the active site and does not completely exclude water [Raag, R. & Poulos, T. L. (1989) Biochemistry 28, 917-922], the increase in stability is only 7 kJ/mol. Finally these results suggest that cytochrome P-420 induced by hydrostatic pressure is a unique form where the active site is hydrated and camphor is displaced from its binding site.     

Destruction of cytochrome P-450 by vinyl fluoride, fluroxene, and acetylene. Evidence for a radical intermediate in olefin oxidation

Vinyl fluoride, vinyl bromide, fluroxene (2,2,2-trifluoroethyl vinyl ether), and acetylene alkylate the prosthetic heme group of cytochrome P-450 enzymes which catalyze their metabolism. The alkylated heme moiety has been identified in all four cases, after carboxyl group methylation and demetalation, as the dimethyl easier of N-(2-oxoethyl)protoporphyrin IX. The dimethyl acetal derivative of the aldehyde group in this structure is also isolated. The formation of the same prosthetic heme adduct with the four substrates requires introduction of an oxygen at the trifluoroethoxy or halide-substituted terminus of the pi bond and reaction of the unsubstituted terminus with a heme nitrogen atom. This reaction orientation is consistent with a radical intermediate, possibly formed by way of an initial pi-bond radical cation, but is difficult to reconcile with a cationic intermediate. The occurrence of a radical intermediate in the oxidation of olefins by cytochrome P-450 is thus suggested.     

Expression, purification, and characterization of recombinant forms of membrane-bound cytochrome c-550nm from Bacillus subtilis

Bacillus subtilis expresses a cytochrome c-550nm that participates in respiratory electron transfer and is an integral membrane protein. Analysis of the B. subtilis cytochrome c-550nm amino acid sequence predicts a single N-terminal transmembrane helix attached to a water-soluble heme binding domain [C. von Wachenfeldt and L. Hederstedt (1990) J. Biol. Chem. 265, 13939-13948]. We have purified cytochrome c-550nm from wild-type B. subtilis and B. subtilis transformed with the shuttle vector pHP13 containing the gene for B. subtilis cytochrome c-550nm (cccA). In B. subtilis transformed with pHP13/cccA there is better than eightfold more membrane-bound cytochrome c-550nm than in wild-type B. subtilis. The overexpressed cytochrome c-550nm can be purified by chromatography on hydroxylapatite and Q-Sepharose media. A six-histidine tag has been added to the C-terminus of cytochrome c-550nm from B. subtilis as a further aid for purification. This strain produces cytochrome c-550nm to a level fourfold greater than wild type and allows for one-step purification using metal affinity chromatography. UV-Vis spectroscopy detects no change in the heme C spectrum due to the addition of six histidines. Neither form of B. subtilis cytochrome c-550nm is stable in its reduced state in aerated buffer, unless EDTA is added. The two forms, wild-type and his-tagged, of cytochromes c have similar midpoint redox potentials of 195 and 185 mV, respectively, and are equally good substrates for B. subtilis cytochrome c oxidase. We conclude that the addition of the histidine tag eases the purification of cytochrome c-550nm from B. subtilis plasma membranes and that the additional metal binding site does not compromise the stability or functional properties of the protein.     

Protein-protein interactions in microsomal cytochrome P-450 isozyme LM2 and their effect on substrate binding

The effects of protein-protein interactions and substrate binding on the structure of the active site of rabbit liver microsomal cytochrome P-450 LM2 have been analyzed by resonance Raman spectroscopy of the monomeric and oligomeric protein in solution. Also H2O2-dependent catalytic activities of the two states have been compared. The two vinyl substituents of the heme exhibit different orientations, as indicated by the frequencies and intensities of their stretching vibrations. One group lies in the plane of the heme and remains unchanged in the two states of cytochrome P-450 LM2, the other is tilted out of the plane. The tilting angle in oligomers was smaller than in monomers. These vinyl stretching modes together with some porphyrin modes, were found to be sensitive indicators of the quaternary structure and of substrate binding. In both the oligomer and the monomer, substrate binding causes changes of the relative intensities of some porphyrin modes and the vinyl stretching vibrations which may reflect modifications of the electronic transitions due to hydrophobic interactions between the bound substrate and the heme. In contrast to the monomeric cytochrome P-450 LM2, benzphetamine binding to the oligomers of this isozyme additionally produces a shift of the spin-state equilibrium. This indicates that in the oligomer the substrate-binding pocket is converted by protein-protein interaction to a structure that forces substrates to interfere with the sixth ligands, inducing an increase of the five-coordinated high-spin configuration. In the monomer the substrate-binding pocket can accommodate benzphetamine without affecting the spin state. Binding of imidazole to the monomeric and oligomeric cytochrome P-450 LM2 produces essentially the same resonance Raman spectra. Apparently the replacement of the native sixth ligand by imidazole disturbs the structure of the active site in such a way that it becomes insensitive to protein-protein interactions. H2O2-dependent N-demethylation of benzphetamine and aniline p-hydroxylation by cytochrome P-450 LM2 did not depend on its state of aggregation.     

Comparison of substrate metabolism by cytochromes P450 2B1, 2B4, and 2B6: relationship of heme spin state,catalysis, and the effects of cytochrome b5

The metabolism of selected substrates by cytochromes P450 (P450) 2B1, 2B4, and 2B6 was compared, and the effects of cytochrome b(5) (b(5)) on these reactions were assessed. There did not appear to be any trends regarding the effects of b(5) when the metabolism of a given substrate by the different P450 enzymes was compared. The changes in spin states of the P450 enzymes as a result of interactions with substrates and cytochrome b(5) were also determined. Only P450 2B4 demonstrated a relationship between spin state, reaction coupling and b(5) effects. The rates of benzphetamine and 7-ethoxy-4-trifluoromethylcoumarin metabolism by the three enzymes could be correlated with the proportions of high spin heme. Similarly, the proportion of reaction coupling during the metabolism of selected substrates was approximately equal to the proportion of high spin P450. The data are interpreted to indicate that a P450 conformational equilibrium coordinately regulates catalysis and spin state changes.     

Allosteric mechanisms in cytochrome P450 3A4 studied by high-pressure spectroscopy: pivotal role of substrate-induced changes in the accessibility and degree of hydration of the heme pocket

Allosteric mechanisms in human cytochrome P450 3A4 (CYP3A4) in oligomers in solution or monomeric enzyme incorporated into Nanodiscs (CYP3A4ND) were studied by high-pressure spectroscopy. The allosteric substrates 1-pyrenebutanol (1-PB) and testosterone were compared with bromocriptine (BCT), which shows no cooperativity. In both CYP3A4 in solution and CYP3A4ND, we observed a complete pressure-induced high-to-low spin shift at pressures of <3 kbar either in the substrate-free enzyme or in the presence of BCT. In addition, both substrate-free and BCT-bound enzyme revealed a pressure-dependent equilibrium between two states with different barotropic parameters designated R for relaxed and P for pressure-promoted conformations. This pressure-induced conformational transition was also observed in the studies with 1-PB and testosterone. In CYP3A4 oligomers, the transition was accompanied by an important increase in homotropic cooperativity with both substrates. Surprisingly, at high concentrations of allosteric substrates, the amplitude of the spin shift in both CYP3A4 in solution and Nanodiscs was very low, demonstrating that hydrostatic pressure induces neither substrate dissociation nor an increase in the heme pocket hydration in the complexes of the pressure-promoted conformation of CYP3A4 with 1-PB or testosterone. These findings suggest that the mechanisms of interactions of CYP3A4 with 1-PB and testosterone involve an effector-induced transition that displaces a system of conformational equilibria in the enzyme toward the state(s) with decreased solvent accessibility of the active site so that the flux of water into the heme pocket is impeded and the high-spin state of the heme iron is stabilized.     

Raman evidence for specific substrate-induced structural changes in the heme pocket of human cytochrome P450 aromatase during the three consecutive oxygen activation steps

Specific substrate-induced structural changes in the heme pocket are proposed for human cytochrome P450 aromatase (P450arom) which undergoes three consecutive oxygen activation steps. We have experimentally investigated this heme environment by resonance Raman spectra of both substrate-free and substrate-bound forms of the purified enzyme. The Fe-CO stretching mode (nu(Fe)(-)(CO)) of the CO complex and Fe(3+)-S stretching mode (nu(Fe)(-)(S)) of the oxidized form were monitored as a structural marker of the distal and proximal sides of the heme, respectively. The nu(Fe)(-)(CO) mode was upshifted from 477 to 485 and to 490 cm(-)(1) by the binding of androstenedione and 19-aldehyde-androstenedione, substrates for the first and third steps, respectively, whereas nu(Fe)(-)(CO) was not observed for P450arom with 19-hydroxyandrostenedione, a substrate for the second step, indicating that the heme distal site is very flexible and changes its structure depending on the substrate. The 19-aldehyde-androstenedione binding could reduce the electron donation from the axial thiolate, which was evident from the low-frequency shift of nu(Fe)(-)(S) by 5 cm(-)(1) compared to that of androstenedione-bound P450arom. Changes in the environment in the heme distal site and the reduced electron donation from the axial thiolate upon 19-aldehyde-androstenedione binding might stabilize the ferric peroxo species, an active intermediate for the third step, with the suppression of the formation of compound I (Fe(4+)=O porphyrin(+)(*)) that is the active species for the first and second steps. We, therefore, propose that the substrates can regulate the formation of alternative reaction intermediates by modulating the structure on both the heme distal and proximal sites in P450arom.     

Regioselectivity of CYP2B6: homology modeling,molecular dynamics simulation,docking

Human cytochrome P450 (CYP) 2B6 activates the anticancer prodrug cyclophosphamide (CPA) by 4-hydroxylation. In contrast, the same enzyme catalyzes N-deethylation of a structural isomer, the prodrug ifosfamide (IFA), thus causing severe adverse drug effects. To model the molecular interactions leading to a switch in regioselectivity, the structure of CYP2B6 was modeled based on the structure of rabbit CYP2C5. We modeled the missing 22-residue loop in CYP2C5 between helices F and G (the F-G loop), which is not resolved in the X-ray structure, by molecular dynamics (MD) simulations using a simulated annealing protocol. The modeled conformation of the loop was validated by unconstrained MD simulations of the complete enzymes (CYP2C5 and CYP2B6) in water for 70 and 120 ps, respectively. The simulations were stable and led to a backbone r.m.s. deviation of 1.7 A between the two CYPs.The shape of the substrate binding site of CYP2B6 was further analyzed. It consists of three well-defined hydrophobic binding pockets adjacent to the catalytic heme. Size, shape and hydrophobicity of these pockets were compared to the shapes of the two structurally isomeric substrates. In their preferred orientation in the binding site, both substrates fill all three binding pockets without repulsive interactions. The distance to the heme iron is short enough for 4-hydroxylation and N-deethylation to occur for CPA and IFA, respectively. However, if the substrates are docked in the non-preferred orientation (such that 4-hydroxylation and N-deethylation would occur for IFA and CPA, respectively), one pocket is left empty, and clashes were observed between the substrates and the enzyme.     

Structural changes of horse heart ferricytochrome C induced by changes of ionic strength and anion binding

To test the validity of the notion that changes in ionic strength and ion binding do not cause any major functionally relevant structural changes in cytochrome c, we measured the absorption and electronic circular dichroism (ECD) of horse heart ferricytochrome c for the Soret and 695 nm charge-transfer band as a function of dihydrogen phosphate and sodium acetate concentrations. This band is known to probe the integrity of the functionally pivotal Fe3+-M80 linkage. Spectral changes indicate that an ionic strength increase (via an increasing acetate ion concentration) affects only a subset of conformational substates of the Fe-M80 interface, probed by the 695 nm charge-transfer band, without a substantial modification of the heme environment. This result suggests that the substates probed by the 695 nm band differ with respect to their capability to transduce changes of solvent-protein interactions to the active site. The binding of H2PO4- ions causes more significant structural changes, which give rise to a large increase of the oscillator strength of the 695 nm band. This reflects a strengthening of the Fe-M80 bond in all substates, which probably destabilizes the oxidized state but stabilizes the folded state of the protein. Additional structural variations are likely to involve aromatic side chains, such as F82 and W59, and the hydrogen-bonding network in the heme pocket. In contrast to the current belief that anion binding to the binding domain of the protein for cytochrome c oxidase does not cause any functionally relevant structural changes, our results show that the structural variations that occur in the heme pocket are most likely of functional significance.     

Structural studies of yeast iso-1 cytochrome c mutants by resonance Raman spectroscopy.

The Ser82 and Phe82 variants of yeast iso-1 cytochrome c were studied by resonance Raman spectroscopy. In both oxidation states, distinct spectral changes were observed for some of those bands in the low-frequency region, which sensitively respond to conformational perturbations of the protein environment of the heme. These bands can be assigned to modes which include strong contributions of vibrations largely localized in the propionate-carrying pyrrole rings A and D. This indicates structural differences in the deeper part of the heme crevice, remote from the mutation site. This conclusion is in line with previous results from X-ray crystallography and NMR spectroscopy. No differences in the resonance-Raman spectra were observed which can be directly correlated with conformational changes of the heme pocket in the vicinity of the mutation site. Temperature-dependent resonance Raman experiments of the oxidized mutants revealed spectral changes which are closely related to those observed for cytochrome c upon adsorption to charged silver surfaces by surface-enhanced resonance Raman spectroscopy. These spectral changes can be attributed to an opening of the heme crevice accompanied by a weakening of the iron-methionine ligand bond. The temperature-dependent conformational transition occurs at approximately 30 degrees C for the Ser82 variant and at about 45 degrees C for the Phe82 variant, implying that the Phe----Ser substitution significantly lowers the thermal stability of the heme pocket. The reduced forms of both mutants are stable up to 65 degrees C.     

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.     

Spin-labeling studies of rat liver NADPH-cytochrome p450 reductase: conformation and function relationship.

ESR spin-labeling studies designed to yield information regarding the relationship between function and conformation of rat liver NADPH-cytochrome P450 reductase (EC 1.6.4.2) were carried out. The purified enzyme was spin labeled by a nitroxide derivative of p-chloromercuribenzoate. Two conditions for spin labeling were employed: (i) the presence of NADP+, yielding an active site-protected spin-labeled reductase, and (ii) the absence of NADP+, yielding completely spin-labeled reductase. Reductase in which the active site was protected by binding NADP+ and then spin-labeled retains most of its enzymatic activity; on the other hand, completely spin-labeled reductase is devoid of any enzymatic activity. Completely spin-labeled reductase yields a two-component resolved ESR spectrum that reflects two classes of spin-labeled binding sites, a strongly immobilized (S) and a weakly immobilized (W) site. The ratio of W/S provides a valuable parameter for studying the relationship between function and conformation. Structural perturbants, such as urea, KCl, and pH, were employed to determine their effects on the activity of the enzyme and their relationship to changes in the conformational state of the reductase. It was further observed that the enzymatically active spin-labeled derivative generated superoxide radical in the presence of NADPH and cytochrome c, which in turn reduced completely the attached spin-label.     

ESR-spectroscopy of cytochrome P-450 LM2 in the soluble and membrane-bound state

Influence of microenvironment on the structure of spin-labeled cytochrome P-450 LM2 was studied. The distance between the spin-label which is covalently bound to cysteine-152 and heme ferrum in soluble protein is 17 A and 23 A in the membrane-bound one. The spin-label was exposed in water solution in both cases. It was shown that solubilized cytochrome P-450 LM2 in water solution forms the aggregates consisting of 4-6 monomers.     

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

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

Resonance Raman evidence for an exchangeable protein hydrogen associated with the heme a group of cytochrome oxidase

When cytochrome-c oxidase is soaked in D2O, downshifts of the cytochrome a formyl C = O stretching mode are seen in the resonance Raman (RR) spectra (413.1 nm excitation) of both the resting and reduced forms. Other changes observed in the reduced protein RR spectra are consistent with involvement of the cytochrome a formyl group in the deuterium effect. The D2O-induced RR changes are fully developed during 3-5 days incubation, but are incomplete after 1 h. Extraction of the heme a chromophore in deuterated solvents eliminates these changes, implying that the exchangeable proton is on a protein group in the cytochrome a pocket which H-bonds to the heme formyl. The rate of the D2O exchange process is unaffected by enzyme turnover, thus reducing the likelihood that the cytochrome a formyl H-bond is directly involved in the redox-linked mechanism of proton pumping.     

Rational engineering of cytochromes P450 2B6 and 2B11 for enhanced stability: Insights into structural importance of residue 334

Rational mutagenesis was used to improve the thermal stability of human cytochrome P450 2B6 and canine P450 2B11. Comparison of the amino acid sequences revealed seven sites that are conserved between the stable 2B1 and 2B4 but different from those found in the less stable 2B6 and 2B11. P334S was the only mutant that showed increased heterologous expression levels and thermal stability in both 2B6 and 2B11. The mechanism of this effect was explored with pressure-perturbation spectroscopy. Compressibility of the heme pocket in variants of all four CYP2B enzymes containing proline at position 334 are characterized by lower compressibility than their more stable serine 334 counterpart. Therefore, the stabilizing effect of P334S is associated with increased conformational flexibility in the region of the heme pocket. Improved stability of P334S 2B6 and 2B11 may facilitate the studies of these enzymes by X-ray crystallography and biophysical techniques.     

Role of electrostatics and salt bridges in stabilizing the compound I radical in ascorbate peroxidase

Cytochrome c (CcP) and ascorbate peroxidase (APX) are heme peroxidases which have very similar active site structures yet differ substantially in the properties of compound I, the intermediate formed upon reaction with peroxides. Although both peroxidases have a tryptophan in the proximal heme pocket, Trp191 in CcP and Trp179 in APX, only Trp191 in CcP forms a stable cation radical while APX forms the more traditional porphyrin pi-cation radical. Previous work [Barrows, T. P., et al. (2004)Biochemistry 43, 8826-8834] has shown that converting three methionine residues in the cytochrome c peroxidase (CcP) proximal heme pocket to the corresponding residues in APX dramatically decreased the stability of the Trp191 radical in CcP compound I. On the basis of these results, we reasoned that replacing the analogous residues at positions 160, 203, and 204 in APX with methionine should stabilize a Trp179 radical in APX compound I. Steady- and transient-state kinetics of this mutant (designated APX3M) show a significant destabilization of the native porphyrin pi-radical, while electron paramagnetic resonance (EPR) studies show an increase in the intensity of the signal at g = 2.006 with characteristics consistent with formation of a Trp radical. This hypothesis was tested by replacing Trp179 with Phe in the APX3M background. The EPR spectrum of this mutant was very similar to that of the CcP W191G mutant which is known to form a tyrosine radical. Previously published theoretical studies [Guallar, V., et al. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 6998-7002] suggest that electrostatic shielding of the heme propionates also plays a role in the stability of the porphyrin radical. Arg172 in APX hydrogen bonds with one of the heme propionates. Replacing Arg172 with an asparagine residue in the APX3M background generates a mutant which no longer forms the full complement of the compound I porphyrin pi-radical. These results suggest that the electrostatics of the proximal pocket and the shielding of propionate groups by salt bridges are critical factors controlling the location of a stable compound I radical in heme peroxidases.