Novel heme ligand displacement by CO in the soluble hemophore HasA and its proximal ligand mutants: implications for heme uptake and release

HasASM, a hemophore secreted by the Gram-negative bacteria Serratia marcescens, extracts heme from host hemoproteins and shuttles it to HasRSM, a specific hemophore outer membrane receptor. Heme iron in HasASM is in a six-coordinate ferric state. It is linked to the protein by the heretofore uncommon axial ligand set, His32 and Tyr75. A third residue of the heme pocket, His83, plays a crucial role in heme ligation through hydrogen bonding to Tyr75. The vibrational frequencies of coordinated carbon monoxide constitute a sensitive probe of trans ligand field, FeCO structure, and electrostatic landscape of the distal heme pockets of heme proteins. In this study, carbonyl complexes of wild-type (WT) HasASM and its heme pocket mutants His32Ala, Tyr75Ala, and His83Ala were characterized by resonance Raman spectroscopy. The CO complexes of WT HasASM, HasASM(His32Ala), and HasASM(His83Ala) exhibit similar spectral features and fall above the line that correlates nuFe-CO and nuC-O for proteins having a proximal imidazole ligand. This suggests that the proximal ligand field in these CO adducts is weaker than that for heme-CO proteins bearing a histidine axial ligand. In contrast, the CO complex of HasASM(Tyr75Ala) has resonance Raman signatures consistent with ImH-Fe-CO ligation. These results reveal that in WT HasASM, the axial ImH side chain of His32 is displaced by CO. This is in contrast to other heme proteins known to have the His/Tyr axial ligand set, wherein the phenolic side chain of the Tyr ligand dissociates upon CO addition. The displacement of His32 and its stabilization in an unbound state is postulated to be relevant to heme uptake and/or release.     

Alteration of sperm whale myoglobin heme axial ligation by site-directed mutagenesis

Three mutant proteins of sperm whale myoglobin (Mb) that exhibit altered axial ligations were constructed by site-directed mutagenesis of a synthetic gene for sperm whale myoglobin. Substitution of distal pocket residues, histidine E7 and valine E11, with tyrosine and glutamic acid generated His(E7)Tyr Mb and Val(E11)Glu Mb. The normal axial ligand residue, histidine F8, was also replaced with tyrosine, resulting in His(F8)Tyr Mb. These proteins are analogous in their substitutions to the naturally occurring hemoglobin M mutants (HbM). Tyrosine coordination to the ferric heme iron of His(E7)Tyr Mb and His(F8)Tyr Mb is suggested by optical absorption and EPR spectra and is verified by similarities to resonance Raman spectral bands assigned for iron-tyrosine proteins. His(E7)Tyr Mb is high-spin, six-coordinate with the ferric heme iron coordinated to the distal tyrosine and the proximal histidine, resembling Hb M Saskatoon [His(beta E7)Tyr], while the ferrous iron of this Mb mutant is high-spin, five-coordinate with ligation provided by the proximal histidine. His(F8)Tyr Mb is high-spin, five-coordinate in both the oxidized and reduced states, with the ferric heme iron liganded to the proximal tyrosine, resembling Hb M Iwate [His(alpha F8)Tyr] and Hb M Hyde Park [His(beta F8)Tyr]. Val(E11)Glu Mb is high-spin, six-coordinate with the ferric heme iron liganded to the F8 histidine. Glutamate coordination to the ferric iron of this mutant is strongly suggested by the optical and EPR spectral features, which are consistent with those observed for Hb M Milwaukee [Val(beta E11)Glu]. The ferrous iron of Val(E11)Glu Mb exhibits a five-coordinate structure with the F8 histidine-iron bond intact.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural insights into the molecular mechanism of H‐NOX activation

Nitric oxide (NO) signaling in mammals controls important processes such as smooth muscle relaxation and neurotransmission by the activation of soluble guanylate cyclase (sGC). NO binding to the heme domain of sGC leads to dissociation of the iron–histidine (Fe–His) bond, which is required for enzyme activity. The heme domain of sGC belongs to a larger class of proteins called H‐NOX (Heme‐Nitric oxide/OXygen) binding domains. Previous crystallographic studies on H‐NOX domains demonstrate a correlation between heme bending and protein conformation. It was unclear, however, whether these structural changes were important for signal transduction. Subsequent NMR solution structures of H‐NOX proteins show a conformational change upon disconnection of the heme and proximal helix, similar to those observed in the crystallographic studies. The atomic details of these conformational changes, however, are lacking in the NMR structures especially at the heme pocket. Here, a high‐resolution crystal structure of an H‐NOX mutant mimicking a broken Fe–His bond is reported. This mutant exhibits specific changes in heme conformation and major N‐terminal displacements relative to the wild‐type H‐NOX protein. Fe–His ligation is ubiquitous in all H‐NOX domains, and therefore, the heme and protein conformational changes observed in this study are likely to occur throughout the H‐NOX family when NO binding leads to rupture of the Fe–His bond.     

Thermodynamics of heme binding to the HasA(SM) hemophore: effect of mutations at three key residues for heme uptake

HasA(SM) secreted by the Gram-negative bacterium Serratia marcescens belongs to the hemophore family. Its role is to take up heme from host heme carriers and to shuttle it to specific receptors. Heme is linked to the HasA(SM) protein by an unusual axial ligand pair: His32 and Tyr75. The nucleophilic nature of the tyrosine is enhanced by the hydrogen bonding of the tyrosinate to a neighboring histidine in the binding site: His83. We used isothermal titration microcalorimetry to examine the thermodynamics of heme binding to HasA(SM) and showed that binding is strongly exothermic and enthalpy driven: DeltaH = -105.4 kJ x mol(-1) and TDeltaS = -44.3 kJ x mol(-1). We used displacement experiments to determine the affinity constant of HasA(SM) for heme (K(a) = 5.3 x 10(10) M(-1)). This is the first time that this has been reported for a hemophore. We also analyzed the thermodynamics of the interaction between heme and a panel of single, double, and triple mutants of the two axial ligands His32 and Tyr75 and of His83 to assess the implication of each of these three residues in heme binding. We demonstrated that, in contrast to His32, His83 is essential for the binding of heme to HasA(SM), even though it is not directly coordinated to iron, and that the Tyr75/His83 pair plays a key role in the interaction.     

Histidine pK(a) shifts and changes of tautomeric states induced by the binding of gallium-protoporphyrin IX in the hemophore HasA(SM)

The HasA(SM) hemophore, secreted by Serratia marcescens, binds free or hemoprotein bound heme with high affinity and delivers it to a specific outer membrane receptor, HasR. In HasA(SM), heme is held by two loops and coordinated to iron by two residues, His 32 and Tyr 75. A third residue His 83 was shown recently to play a crucial role in heme ligation. To address the mechanistic issues of the heme capture and release processes, the histidine protonation states were studied in both apo- and holo-forms of HasA(SM) in solution. Holo-HasA(SM) was formed with gallium-protoporphyrin IX (GaPPIX), giving rise to a diamagnetic protein. By use of heteronuclear correlation NMR spectroscopy, the imidazole side-chain (15)N and (1)H resonances of the six HasA(SM) histidines were assigned and their pKa values and predominant tautomeric states according to pH were determined. We show that protonation states of the heme pocket histidines can modulate the nucleophilic character of the two axial ligands and, consequently, control the heme binding. In particular, the essential role of the His 83 is emphasized according to its direct interaction with Tyr 75.     

Interaction of heme with variants of the heme chaperone CcmE carrying active site mutations and a cleavable N-terminal His tag

Cytochrome c maturation in the periplasms of many bacteria requires the heme chaperone CcmE, which binds heme covalently both in vivo and in vitro via a histidine residue before transferring the heme to apocytochromes c. To investigate the mechanism and specificity of heme attachment to CcmE, we have mutated the conserved histidine 130 of a soluble C-terminally His-tagged version of CcmE (CcmEsol-C-His6) from Escherichia coli to alanine or cysteine. Remarkably, covalent bond formation with heme occurs with the protein carrying the cysteine mutation, and the process occurs both in vivo and in vitro. The yield of holo-H130C CcmEsol-C-His6 produced in vivo is low compared with the wild type. In vitro heme attachment occurs only under reducing conditions. We demonstrate the involvement of one of the heme vinyl groups and a side chain at residue 130 in the bond formation by showing that in vitro attachment does not occur either with the heme analogue mesoheme or when alanine is present at residue 130. These results have implications for the mechanism of heme attachment to the histidine of CcmE. In vitro, CcmEsol lacking a His tag binds 8-anilino-1-naphthalenesulphonate and heme, the latter both noncovalently and via a covalent bond from the histidine side chain, similarly to the tagged proteins, thus countering a recent proposal that the His tag causes the heme binding. However, the His tag does appear to enhance the rate of in vitro covalent heme binding and to affect the heme ligation in the ferric b-type cytochrome form.     

Biophysical and structural analysis of a novel heme B iron ligation in the flavocytochrome cellobiose dehydrogenase

The fungal extracellular flavocytochrome cellobiose dehydrogenase (CDH) participates in lignocellulose degradation. The enzyme has a cytochrome domain connected to a flavin-binding domain by a peptide linker. The cytochrome domain contains a 6-coordinate low spin b-type heme with unusual iron ligands and coordination geometry. Wild type CDH is only the second example of a b-type heme with Met-His ligation, and it is the first example of a Met-His ligation of heme b where the ligands are arranged in a nearly perpendicular orientation. To investigate the ligation further, Met65 was replaced with a histidine to create a bis-histidyl ligated iron typical of b-type cytochromes. The variant is expressed as a stable 90-kDa protein that retains the flavin domain catalytic reactivity. However, the ability of the mutant to reduce external one-electron acceptors such as cytochrome c is impaired. Electrochemical measurements demonstrate a decrease in the redox midpoint potential of the heme by 210 mV. In contrast to the wild type enzyme, the ferric state of the protoheme displays a mixed low spin/high spin state at room temperature and low spin character at 90 K, as determined by resonance Raman spectroscopy. The wild type cytochrome does not bind CO, but the ferrous state of the variant forms a CO complex, although the association rate is very low. The crystal structure of the M65H cytochrome domain has been determined at 1.9 A resolution. The variant structure confirms a bis-histidyl ligation but reveals unusual features. As for the wild type enzyme, the ligands have a nearly perpendicular arrangement. Furthermore, the iron is bound by imidazole N delta 1 and N epsilon 2 nitrogen atoms, rather than the typical N epsilon 2/N epsilon 2 coordination encountered in bis-histidyl ligated heme proteins. To our knowledge, this is the first example of a bis-histidyl N delta 1/N epsilon 2-coordinated protoporphyrin IX iron.     

Rapid intrachain binding of histidine-26 and histidine-33 to heme in unfolded ferrocytochrome C.

Time-resolved spectroscopic studies of unfolded horse iron(II) cytochrome c have suggested that the imidazole side chains of His26 and His33 bind transiently to the heme iron on microsecond time scales, after photodissociation of a carbon monoxide ligand from the heme. Our studies of four variants of cytochrome c (horse wild type, horse H33N, horse H33N/H26Q, and tuna wild type), unfolded in guanidine hydrochloride at pH 6.5, demonstrate that these side chains are responsible for the observed microsecond spectral changes. As His33 and then His26 are eliminated from the horse wild-type sequence, transient optical absorption spectra show systematic suppression of a rapid (approximately 10-100 micros) Soret absorbance change that follows photolysis of CO. Transient binding of these histidine side chains to the heme therefore generates one of the fast kinetic phases observed in previous photochemically triggered spectroscopic studies of dynamics in unfolded iron(II) cytochrome c. Furthermore, both His33 and His26 appear to contribute to a similar extent in these early kinetics. Thus, the stiffness of the polypeptide chain creates a deviation from Gaussian chain behavior by impeding, although not preventing, the formation of short (<10 peptide bonds) intrachain loops around the heme group.     

Effect of mutation at valine 61 on the three-dimensional structure, stability, and redox potential of cytochrome b5.

To elucidate the role played by Val61 of cytochrome b(5), this residue of the tryptic fragment of bovine liver cytochrome b(5) was chosen for replacement with tyrosine (Val61Tyr), histidine (Val61His), glutamic acid (Val61Glu), and lysine (Val61Lys) by means of site-directed mutagenesis. The mutants Val61Tyr, Val61Glu, Val61His, and Val61Lys exhibit electronic spectra identical to that of the wild type, suggesting that mutation at Val61 did not affect the overall protein structure significantly. The redox potentials determined by differential pulse voltammetry were -10 (wild type), -25 (Val61Glu), -33 (Val61Tyr), 12 (Val61His), and 17 mV (Val61Lys) versus NHE. The thermal stabilities and urea-mediated denaturation of wild-type cytochrome b(5) and its mutants were in the following order: wild type > Val61Glu > Val61Tyr > Val61His > Val61Lys. The kinetics of denaturation of cytochrome b(5) by urea was also analyzed. The first-order rate constants of heme transfer between cytochrome b(5) and apomyoglobin at 20 +/- 0.2 degrees C were 0.25 +/- 0.01 (wild type), 0.42 +/- 0.02 (Val61Tyr), 0.93 +/- 0.04 (Val61Glu), 2.88 +/- 0.01 (Val61His), and 3.88 +/- 0.02 h(-)(1) (Val61Lys). The crystal structure of Val61His was determined using the molecular replacement method and refined at 2.1 A resolution, showing that the imidazole side chain of His61 points away from the heme-binding pocket and extends into the solvent, the coordination distances from Fe to NE2 atoms of two axial ligands are approximately 0.6 A longer than the reported value, and the hydrogen bond network involving Val61, the heme propionates, and three water molecules no longer exists. We conclude that the conserved residue Val61 is located at one of the key positions, the "electrostatic potential" around the heme-exposed area and the hydrophobicity of the heme pocket are determinant factors modulating the redox potential of cytochrome b(5), and the hydrogen bond network around the exposed heme edge is also an important factor affecting the heme stability.     

Exploiting the conformational flexibility of leghemoglobin: a framework for examination of heme protein axial ligation

We have exploited the intrinsic conformational flexibility of leghemoglobin to reengineer the heme active site architecture of the molecule by replacement of the mobile His61 residue with tyrosine (H61Y variant). The electronic absorption spectrum of the ferric derivative of H61Y is similar to that observed for the phenolate derivative of the recombinant wild-type protein (rLb), consistent with coordination of Tyr61 to (high-spin) iron. EXAFS data clearly indicate a 6-coordinate heme geometry and a Fe-O bond length of 185pm. MCD and EPR spectroscopies are consistent with this assignment and support ligation by an anionic (tyrosinate) group. The alteration in heme ligation leads to a 148mV decrease in the reduction potential for H61Y (-127+/-5mV) compared to rLb and destabilisation of the functional oxy-derivative. The results are discussed in terms of our wider understanding of other heme proteins with His-Tyr ligation.     

Heme orientation modulates histidine dissociation and ligand binding kinetics in the hexacoordinated human neuroglobin

Neuroglobin (Ngb) is a globin present in the brain and retina of mammals. This hexacoordinated hemoprotein binds small diatomic molecules, albeit with lower affinity compared with other globins. Another distinctive feature of most mammalian Ngb is their ability to form an internal disulfide bridge that increases ligand affinity. As often seen for prosthetic heme b containing proteins, human Ngb exhibits heme heterogeneity with two alternative heme orientations within the heme pocket. To date, no details are available on the impact of heme orientation on the binding properties of human Ngb and its interplay with the cysteine oxidation state. In this work, we used ¹H NMR spectroscopy to probe the cyanide binding properties of different Ngb species in solution, including wild-type Ngb and the single (C120S) and triple (C46G/C55S/C120S) mutants. We demonstrate that in the disulfide-containing wild-type protein cyanide ligation is fivefold faster for one of the two heme orientations (the A isomer) compared with the other isomer, which is attributed to the lower stability of the distal His64–iron bond and reduced steric hindrance at the bottom of the cavity for heme sliding in the A conformer. We also attribute the slower cyanide reactivity in the absence of a disulfide bridge to the tighter histidine–iron bond. More generally, enhanced internal mobility in the CD loop bearing the disulfide bridge hinders access of the ligand to heme iron by stabilizing the histidine–iron bond. The functional impact of heme disorder and cysteine oxidation state on the properties of the Ngb ligand is discussed.     

Structural propensities in the heme binding region of apocytochrome b5. II. Heme conjugates

In the absence of heme cofactor, the water-soluble domain of rat microsomal cytochrome b5 (cyt b5) contains a long flexible region within its 42-residue heme-binding loop. Heme capture induces this region to fold into a well-defined structure containing helices H3-H5, each separated by a turn, with His39 and His63 serving as axial ligands to the heme iron. We have shown that the H4 region of the apoprotein has the greatest tendency for disorder within the isolated binding loop. Here, the effect of the His63-iron bond and proximity of heme plane on the population of helical conformation in H4 and H5 was investigated by synthesis and characterization of a peptide-sandwiched mesoheme construct in which two H4-H5 peptides were covalently attached to a single cofactor. Spectroscopic data indicated that a holoprotein-like bis-histidine coordination state was achieved over a pH range from 7 to 9. Trifluoroethanol titrations of the construct and the analogous free peptide under these pH conditions revealed that heme proximity and iron ligation were insufficient to promote helix formation in H4 and H5. These observations were used to assess the role of disordered regions in heme capture and the loop-scaffold interface in holoprotein folding and stability.     

A novel heme and peroxide-dependent tryptophan-tyrosine cross-link in a mutant of cytochrome c peroxidase

The crystal structure of a cytochrome c peroxidase mutant where the distal catalytic His52 is converted to Tyr reveals that the tyrosine side-chain forms a covalent bond with the indole ring nitrogen atom of Trp51. We hypothesize that this novel bond results from peroxide activation by the heme iron followed by oxidation of Trp51 and Tyr52. This hypothesis has been tested by incorporation of a redox-inactive Zn-protoporphyrin into the protein, and the resulting crystal structure shows the absence of a Trp51-Tyr52 cross-link. Instead, the Tyr52 side-chain orients away from the heme active-site pocket, which requires a substantial rearrangement of residues 72-80 and 134-144. Additional experiments where heme-containing crystals of the mutant were treated with peroxide support our hypothesis that this novel Trp-Tyr cross-link is a peroxide-dependent process mediated by the heme iron.     

Heme ligation and conformational plasticity in the isolated c domain of cytochrome cd1 nitrite reductase

The heme ligation in the isolated c domain of Paracoccus pantotrophus cytochrome cd(1) nitrite reductase has been characterized in both oxidation states in solution by NMR spectroscopy. In the reduced form, the heme ligands are His69-Met106, and the tertiary structure around the c heme is similar to that found in reduced crystals of intact cytochrome cd1 nitrite reductase. In the oxidized state, however, the structure of the isolated c domain is different from the structure seen in oxidized crystals of intact cytochrome cd1, where the c heme ligands are His69-His17. An equilibrium mixture of heme ligands is present in isolated oxidized c domain. Two-dimensional exchange NMR spectroscopy shows that the dominant species has His69-Met106 ligation, similar to reduced c domains. This form is in equilibrium with a high-spin form in which Met106 has left the heme iron. Melting studies show that the midpoint of unfolding of the isolated c domain is 320.9 +/- 1.2 K in the oxidized and 357.7 +/- 0.6 K in the reduced form. The thermally denatured forms are high-spin in both oxidation states. The results reveal how redox changes modulate conformational plasticity around the c heme and show the first key steps in the mechanism that lead to ligand switching in the holoenzyme. This process is not solely a function of the properties of the c domain. The role of the d1 heme in guiding His17 to the c heme in the oxidized holoenzyme is discussed.     

X-ray crystallographic study of cyanide binding provides insights into the structure-function relationship for cytochrome cd1 nitrite reductase from Paracoccus pantotrophus

We present a 1.59-A resolution crystal structure of reduced Paracoccus pantotrophus cytochrome cd(1) with cyanide bound to the d(1) heme and His/Met coordination of the c heme. Fe-C-N bond angles are 146 degrees for the A subunit and 164 degrees for the B subunit of the dimer. The nitrogen atom of bound cyanide is within hydrogen bonding distance of His(345) and His(388) and either a water molecule in subunit A or Tyr(25) in subunit B. The ferrous heme-cyanide complex is unusually stable (K(d) approximately 10(-6) m); we propose that this reflects both the design of the specialized d(1) heme ring and a general feature of anion reductases with active site heme. Oxidation of crystals of reduced, cyanide-bound, cytochrome cd(1) results in loss of cyanide and return to the native structure with Tyr(25) as a ligand to the d(1) heme iron and switching to His/His coordination at the c-type heme. No reason for unusually weak binding of cyanide to the ferric state can be identified; rather it is argued that the protein is designed such that a chelate-based effect drives displacement by tyrosine of cyanide or a weaker ligand, like reaction product nitric oxide, from the ferric d(1) heme.     

Conversion of the Escherichia coli cytochrome b562 to an archetype cytochrome b: a mutant with bis-histidine ligation of heme iron

A mutant of the Escherichia coli cytochrome b(562) has been created in which the heme-ligating methionine (Met) at position 7 has been replaced with a histidine (His) (M7H). This protein is a double mutant that also has the His 63 to asparagine (H63N) mutation, which removes a solvent-exposed His. While the H63N mutation has no measurable effect on the cytochrome, the M7H mutation converts the atypical His/Met heme ligation in cytochrome b(562) to the classic cytochrome b-type bis-His ligation. This mutation has little effect on the K(d) of heme binding but significantly reduces the chemical and thermal stability of the mutant cytochrome relative to the wild type (wt). Both proteins have similar absorbance (Abs) and electron paramagnetic resonance (EPR) properties characteristic of 6-coordinate low-spin heme. The Abs spectra of the oxidized and reduced bis-His cytochrome are slightly blue-shifted relative to the wt, and the alpha Abs band of ferrous M7H mutant is unusually split. The M7H mutation decreases the midpoint potential of the bound heme by 260 mV at pH 7 and considerably alters the pH dependence of the E(m), which becomes dominated by a single pK(red) = 6.8.     

Histidine 61: an important heme ligand in the soluble fumarate reductase from Shewanella frigidimarina

An examination of the X-ray structure of the soluble fumarate reductase from Shewanella frigidimarina [Taylor, P., Pealing, S. L., Reid, G. A., Chapman, S. K., and Walkinshaw, M. D. (1999) Nat. Struct. Biol. 6, 1108-1112] shows the presence of four, bis-His-ligated, c-type hemes and one flavin adenine dinucleotide, FAD. The heme groups provide a "molecular wire" for the delivery of electrons to the FAD. Heme IV is closest to the FAD (7.4 A from heme methyl to FAD C7), and His61, a ligand to heme IV, is also close (8.4 A to FAD C7). Electron delivery to the FAD from the heme groups must proceed via heme IV, as hemes I-III are too far from the FAD for feasible electron transfer. To examine the importance of heme IV and its ligation for enzyme function, we have substituted His61 with both methionine and alanine. Here we describe the crystallographic, kinetic, and electrochemical characterization of the H61M and H61A mutant forms of the Shewanella fumarate reductase. The crystal structures of these mutant forms of the enzyme have been determined to 2.1 and 2.2 A resolution, respectively. Substitution of His61 with alanine results in heme IV having only one protein ligand (His86), the sixth coordination position being occupied by an acetate ion derived from the crystal cryoprotectant solution. In the structure of the H61M enzyme, Met61 is found not to ligate the heme iron, a role that is taken by a water molecule. Apart from these features, there are no significant structural alterations as a result of either substitution. Both the H61M-Fcc(3) and H61A-Fcc(3) mutant enzymes are catalytically active but exhibit marked decreases in the value of k(cat) for fumarate reduction with respect to that of the wild type (5- and 10-fold lower, respectively). There is also a significant shift in the pK(a) values for the mutant enzymes, from 7.5 for the wild type to 8.26 for H61M and 9.29 for H61A. The fumarate reductase activity of both mutant enzymes can be recovered to approximately 80% of that seen for the wild type by the addition of exogenous imidazole. In the case of H61A, recovery of activity is also accompanied by a shift of the pK(a) from 9.29 to 7.46 (close, and within experimental error, to that for the wild type). Pre-steady-state kinetic measurements show clearly that rate constants for the fumarate dependent reoxidation of the heme groups are adversely affected by the mutations. The solvent isotope effect for fumarate reduction in the wild-type enzyme has a value of 8.0, indicating that proton delivery is substantially rate limiting. This value falls to 5.6 and 2.2 for the H61M and H61A mutants, respectively, indicating that electron transfer, rather than proton transfer, is becoming more rate-limiting in the mutant enzymes.     

Residue F4 plays a key role in modulating oxygen affinity and cooperativity in Scapharca dimeric hemoglobin

Residue F4 (Phe 97) undergoes the most dramatic ligand-linked transition in Scapharca dimeric hemoglobin, with its packing in the heme pocket in the unliganded (T) state suggested to be a primary determinant of its low affinity. Mutation of Phe 97 to Leu (previously reported), Val, and Tyr increases oxygen affinity from 8- to 100-fold over that of the wild type. The crystal structures of F97L and F97V show side chain packing in the heme pocket for both R and T state structures. In contrast, in the highest-affinity mutation, F97Y, the tyrosine side chain remains in the interface (high-affinity conformation) even in the unliganded state. Comparison of these mutations reveals a correlation between side chain packing in the heme pocket and oxygen affinity, indicating that greater mass in the heme pocket lowers oxygen affinity due to impaired movement of the heme iron into the heme plane. The results indicate that a key hydrogen bond, previously hypothesized to have a central role in regulation of oxygen affinity, plays at most only a small role in dictating ligand affinity. Equivalent mutations in sperm whale myoglobin alter ligand affinity by only 5-fold. The dramatically different responses to mutations at the F4 position result from subtle, but functionally critical, stereochemical differences. In myoglobin, an eclipsed orientation of the proximal His relative to the A and C pyrrole nitrogen atoms provides a significant barrier for high-affinity ligand binding. In contrast, the staggered orientation of the proximal histidine found in liganded HbI renders its ligand affinity much more susceptible to packing contacts between F4 and the heme group. These results highlight very different strategies used by cooperative hemoglobins in molluscs and mammals to control ligand affinity by modulation of the stereochemistry on the proximal side of the heme.     

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.