Proximal Iron Ligand Research Articles

Covalent heme attachment to the protein in human heme oxygenase-1 with selenocysteine replacing the His25 proximal iron ligand

To characterize heme oxygenase with a selenocysteine (SeCys) as the proximal iron ligand, we have expressed truncated human heme oxygenase-1 (hHO-1) His25Cys, in which Cys-25 is the only cysteine, in the Escherichia coli cysteine auxotroph strain BL21(DE3)cys. Selenocysteine incorporation into the protein was demonstrated by both intact protein mass measurement and mass spectrometric identification of the selenocysteine-containing tryptic peptide. One selenocysteine was incorporated into approximately 95% of the expressed protein. Formation of an adduct with Ellman's reagent (DTNB) indicated that the selenocysteine in the expressed protein was in the reduced state. The heme-His25SeCys hHO-1 complex could be prepared by either (a) supplementing the overexpression medium with heme, or (b) reconstituting the purified apoprotein with heme. Under reducing conditions in the presence of imidazole, a covalent bond is formed by addition of the selenocysteine residue to one of the heme vinyl groups. No covalent bond is formed when the heme is replaced by mesoheme, in which the vinyls are replaced by ethyl groups. These results, together with our earlier demonstration that external selenolate ligands can transfer an electron to the iron [Y. Jiang, P.R. Ortiz de Montellano, Inorg. Chem. 47 (2008) 3480-3482 ], indicate that a selenyl radical is formed in the hHO-1 His25SeCys mutant that adds to a heme vinyl group.

Replacement of the proximal histidine iron ligand by a cysteine or tyrosine converts heme oxygenase to an oxidase.

The H25C and H25Y mutants of human heme oxygenase-1 (hHO-1), in which the proximal iron ligand is replaced by a cysteine or tyrosine, have been expressed and characterized. Resonance Raman studies indicate that the ferric heme complexes of these proteins, like the complex of the H25A mutant but unlike that of the wild type, are 5-coordinate high-spin. Labeling of the iron with 54Fe confirms that the proximal ligand in the ferric H25C protein is a cysteine thiolate. Resonance-enhanced tyrosinate modes in the resonance Raman spectrum of the H25Y.heme complex provide direct evidence for tyrosinate ligation in this protein. The H25C and H25Y heme complexes are reduced to the ferrous state by cytochrome P450 reductase but do not catalyze alpha-meso-hydroxylation of the heme or its conversion to biliverdin. Exposure of the ferrous heme complexes to O2 does not give detectable ferrous-dioxy complexes and leads to the uncoupled reduction of O2 to H2O2. Resonance Raman studies show that the ferrous H25C and H25Y heme complexes are present in both 5-coordinate high-spin and 4-coordinate intermediate-spin configurations. This finding indicates that the proximal cysteine and tyrosine ligand in the ferric H25C and H25Y complexes, respectively, dissociates upon reduction to the ferrous state. This is confirmed by the spectroscopic properties of the ferrous-CO complexes. Reduction potential measurements establish that reduction of the mutants by NADPH-cytochrome P450 reductase, as observed, is thermodynamically allowed. The two proximal ligand mutations thus destabilize the ferrous-dioxy complex and uncouple the reduction of O2 from oxidation of the heme group. The proximal histidine ligand, for geometric or electronic reasons, is specifically required for normal heme oxygenase catalysis.

Heme oxygenase active-site residues identified by heme-protein cross-linking during reduction of CBrCl3.

The reduction of CBrCl3 by the heme-heme oxygenase complex forms dissociable and covalently bound heme products. No such products are formed with mesoheme in which the heme vinyl substituents are replaced by ethyl groups. The dissociable heme products are chromatographically similar but not identical to those obtained in the analogous reaction with myoglobin. Tryptic digestion of the heme-protein adduct and Edman sequencing and mass spectrometric analysis of the heme-linked peptide identify His-25, the proximal iron ligand, as the alkylated residue. Reaction of CBrCl3 with the heme complexes of the T135V mutant and a Delta221 C-terminal truncated protein yields heme-linked peptides in addition to that from the wild-type reaction. The sequence of the principal labeled peptide from the T135V reaction, 205TAFLLNIQLFEELQELLTHDTK226 , and the lability of the adduct suggest the heme is attached to one of the carboxylic acid residues. A carboxylic acid residue is probably also labeled in the modified peptide 49LVMASLYHIYVALEEEIER67 from the Delta221 truncated protein. Thus, addition of the reductively generated trichloromethyl radical to a heme vinyl group produces a species that alkylates active-site residues. The changes in the alkylated residue caused by the Thr-135 mutation or truncation of the protein places residues in the sequences 49-67 and 205-226 within the active site. Furthermore, this is the first demonstration that heme oxygenase, like cytochrome P450, may catalyze the reductive metabolism of halocarbons and thus contribute to the toxicity of these agents.

Solution and Crystal Structures of the H175G Mutant of Cytochrome c Peroxidase: A Resonance Raman Study

Site-directed mutagenesis offers a powerful probe of heme proteins. Recent attention has focused on mutants whose proximal iron ligand is replaced by smaller, noncoordinating amino acids. These mutants form artificial cavities where the native proximal ligand resided and which are capable of binding exogenous ligands such as imidazoles. Such reconstituted systems permit detailed studies of the electronic and stereochemical influences of the proximal ligand on catalysis and activity.1-6 The paradigm of these mutants is H175G cytochrome c peroxidase (CCP). Its X-ray crystal structure revealed that the iron is close to two water molecules.1 In heme oxygenase, the H25A mutant has been proposed to contain a single water ligand on the heme iron.4 The iron in the H170A mutant of horseradish peroxidase is probably bound by a water molecule at pH 4 and an additional sixth ligand (possibly a distal histidine) at pH 5-7.6 The crystal structure of the imidazole adduct of H93G myoglobin has been reported,2 but structural and spectroscopic data for the H93G mutant in the absence of imidazole are not yet available. Interestingly, UV-vis spectra of wild-type metmyoglobin and ferric Coprinus cinereus peroxidase in acidic buffer7,8 bear resemblance to those of the proximal ligand-deficient heme proteins; the native proximal ligation may well be disrupted under such conditions. Among these proximal-ligand mutants, H175G CCP is unique in that its crystal structure indicates two water molecules axial to the heme. However, it is not certain whether one or both of these waters is strongly coordinated, what the water protonation states are, and whether the axial coordination of two water molecules can be maintained in solution. In this study, we have examined the crystal and solution structures of the H175G mutant by UVvis, resonance Raman (RR), and EPR spectroscopy. Ferric H175G CCP9 undergoes a transition from a “red form” near pH 6 to a “green form” near pH 7 (Figure 1). The absorbance at 408 nm (λmax of the red form) changes with pH to give an apparent pKa of ∼6.5 (inset, Figure 1). A fit to these data indicates that the transition involves a cooperative twoproton process. One proton is proposed to be from the ironbound water molecule, but the source of the second proton is unknown. The UV-vis and RR spectra of H175G at pH 10.0 are almost identical to those at pH 7.2 (not shown). FeIII(TMP)s [TMP ) 5,10,15,20-tetrakis(1-methylpyridinium)porphines] exhibit similar ligand ionization in aqueous solution where the five-coordinate iron is ligated by a water at pH 11.10,11 Resonance Raman spectra of heme proteins are dominated by porphyrin skeletal vibrations, i.e., totally symmetric ν2, ν3, and ν4 with Soret excitation, nonsymmetric modes ν10, ν11, and ν19 with Q-band excitation, and ν2 and ν10 with near-UV (∼350 nm) excitation.12-15 The frequencies of these modes are determined by the iron coordination and spin states. The RR spectra of H175G16 are shown in Figure 2. The well-defined ν3 and ν10 frequencies at 1494 and 1630 cm-1, respectively, of the red solution (pH 5.9) are clearly characteristic of a fivecoordinate high-spin (5cHS) ferric heme.15,17-20 The RR spectra of the green solution (pH 7.2) also indicate a dominant 5cHS

Rescue of the horseradish peroxidase His-170-->Ala mutant activity by imidazole: importance of proximal ligand tethering.

The proximal iron ligand in horseradish peroxidase (HRP) is His-170. The H170A mutant of polyhistidine-tagged HRP (hHRP) has been expressed in a baculovirus system and has been purified and characterized. At pH 7, the Soret maximum of the mutant is at 414 nm rather than 403 nm. Resonance Raman spectra indicate that the protein is primarily 6-coordinate low-spin in the ferric state with a band in the ferrous state at 212 cm-1 indicative of distal histidine coordination to the iron. Exogenous imidazole (Im) binds to the enzyme with Kd = 22 +/- 4 mM. Reaction of H170A hHRP with H2O2 does not give spectroscopically detectable compound I or compound II intermediates but results in gradual degradation of the heme group. Nevertheless, H170A hHRP is catalytically active, and its guaiacol and ABTS peroxidase activities are improved 260- and 125-fold, respectively, in the presence of saturating concentrations of Im. The Km for the stimulatory effect of Im is 24 mM for both guaiacol and ABTS. The pH profile of H170A hHRP differs from that of wild-type hHRP, but the differences are essentially eliminated by Im. The rate of formation of "compound I" for H170A hHRP, determined by steady state kinetic methods, is k1 = 16 M-1 s-1 without Im and k1 = 2.4 x 10(4) M-1 s-1 with Im. The corresponding rate for wild-type hHRP is k1 = 4.4 x 10(6) M-1 s-1. The results indicate that Im binds in the cavity created by the H170A mutation, coordinates to the heme iron atom, and restores a large part of the catalytic activity by rescuing the rate of compound I formation. However, this rescue of the catalytic activity by Im is possibly limited by coordination of the heme to the distal histidine (His-42) in the H170A mutant. Thus, a primary function of the proximal histidine is to tether the iron atom to disfavor sixth ligand binding, particularly coordination of the iron to the distal histidine. In addition, strong hydrogen bonding of the proximal ligand may be critical for facilitating O-O bond cleavage in the formation of compound I.

Expression in yeast and purification of functional macrophage nitric oxide synthase. Evidence for cysteine-194 as iron proximal ligand.

Mouse macrophage NO-synthase (mNOS) was expressed in a unique yeast-based system by using a three-step procedure which allows yeast growth and NOS expression to be uncoupled. Despite cytotoxic effects related to mNOS expression, levels of catalytically active enzyme up to 0.5 mg of protein per 5 L of culture was obtained after purification. Its electrophoretic, spectroscopic [lambda max = 446 nm for its Fe(II)-CO complex], and catalytic properties were similar to those previously reported for mNOS purified from macrophages. Recombinant mNOS catalyzed the NADPH-dependent oxidation of L-arginine to citrulline (Km = 7 +/- 3 microM) as well as the reduction of cytochrome C by NADPH [Km = 34 +/- 8 microM and Vm = 25 +/- 5 mumol min-1 (mg of protein-1)]. Two mutants of mNOS in which Cys 194 was replaced with either serine or histidine were constructed and expressed in the same yeast strain at a level higher than that of the wild type protein, as they appear less toxic for the host. Both mutants exhibited electrophoretic properties and activities toward cytochrome C reduction identical to those of wild type NOS. However, they were unable to catalyze the oxidation of L-arginine to citrulline and did not appear to bind heme (no appearance of peaks around 400 and 446 nm for the resting enzyme and its CO complex, respectively, in visible spectroscopy). These data provide the first experimental evidence in favor of previous suggestions that Cys 194 was the proximal iron ligand of mouse mNOS.

Heme oxygenase (HO-1): His-132 stabilizes a distal water ligand and assists catalysis.

His-25 and His-132 are the primary candidates for the proximal heme iron ligand in heme oxygenase isozyme-1 (HO-1). The unambiguous spectroscopic demonstration that His-25 is the proximal iron ligand leaves the role of His-132 uncertain. Absorption and resonance Raman spectroscopy are used here to establish that mutation of His-132 to an alanine, glycine, or serine does not alter the histidine-iron bond, but results in the loss of the water molecule coordinated to the distal side of the iron in the wild-type enzyme-substrate complex. The His-132 mutations also (a) destabilize the ferrous-O2 complex with respect to autoxidation, which should result in partial uncoupling of NADPH consumption from heme oxidation, and (b) decrease the affinity of the enzyme for heme. The catalytic activity of the protein is decreased but not suppressed by these mutations: the H132G and H132A mutants retain 40-50% and the H132S mutant 20% of the activity of the wild-type protein. His-132, however, is required for catalytic turnover of the protein with H2O2. These results place His-132 close to the iron on the distal side of the heme pocket and indicate that His-132 facilitates, but is not absolutely required for, the catalytic turnover of HO-1.