Replacement of the axial histidine ligand with imidazole in cytochrome c peroxidase. 1. Effects on structure

Replacement of the axial histidine ligand with exogenous imidazole has been accomplished in a number of heme protein mutants, where it often serves to complement the functional properties of the protein. In this paper, we describe the effects of pH and buffer ion on the crystal structure of the H175G mutant of cytochrome c peroxidase, in which the histidine tether between the heme and the protein backbone is replaced by bound imidazole. The structures show that imidazole can occupy the proximal H175G cavity under a number of experimental conditions, but that the details of the interaction with the protein and the coordination to the heme are markedly dependent on conditions. Replacement of the tethered histidine ligand with imidazole permits the heme to shift slightly in its pocket, allowing it to adopt either a planar or distally domed conformation. H175G crystallized from both high phosphate and imidazole concentrations exists as a novel, 5-coordinate phosphate bound state, in which the proximal imidazole is dissociated and the distal phosphate is coordinated to the iron. To accommodate this bound phosphate, the side chains of His-52 and Asn-82 alter their positions and a significant conformational change in the surrounding protein backbone occurs. In the absence of phosphate, imidazole binds to the proximal H175G cavity in a pH-dependent fashion. At pH 7, imidazole is directly coordinated to the heme (d(Fe--Im) = 2.0 A) with a nearby distal water (d(Fe--HOH) = 2.4 A). This is similar to the structure of WT CCP except that the iron lies closer in the heme plane, and the hydrogen bond between imidazole and Asp-235 (d(Im--Asp) = 3.1 A) is longer than for WT CCP (d(His--Asp) = 2.9 A). As the pH is dropped to 5, imidazole dissociates from the heme (d(Fe--Im) = 2.9 A), but remains in the proximal cavity where it is strongly hydrogen bonded to Asp-235 (d(Im--Asp) = 2.8 A). In addition, the heme is significantly domed toward the distal pocket where it may coordinate a water molecule. Finally, the structure of H175G/Im, pH 6, at low temperature (100 K) is very similar to that at room temperature, except that the water above the distal heme face is not present. This study concludes that steric restrictions imposed by the covalently tethered histidine restrain the heme and its ligand coordination from distortions that would arise in the absence of the restricted tether. Coupled with the functional and spectroscopic properties described in the following paper in this issue, these structures help to illustrate how the delicate and critical interactions between protein, ligand, and metal modulate the function of heme enzymes.     

Comparative proton NMR analysis of wild-type cytochrome c peroxidase from yeast, the recombinant enzyme from Escherichia coli, and an Asp-235----Asn-235 mutant

Proton NMR spectra of cytochrome c peroxidase (CcP) isolated from yeast (wild type) and two Escherichia coli expressed proteins, the parent expressed protein [CcP(MI)] and the site-directed mutant CcP(MI,D235N) (Asp-235----Asn-235), have been examined. At neutral pH and in the presence of only potassium phosphate buffer and potassium nitrate, wild-type Ccp and CcP(MI) demonstrate nearly identical spectra corresponding to normal (i.e., "unaged") high-spin ferric peroxidase. In contrast, the mutant protein displays a spectrum characteristic of a low-spin form, probably a result of hydroxide ligation. Asp-235 is hydrogen-bonded to the proximal heme ligand, His-175. Changing Asp-235 to Asn results in alteration of the pK for formation of the basic form of CcP. Thus, changes in proximal side structure mediate the chemistry of the distal ligand binding site. All three proteins bind F-, N3-, and CN- ions, although the affinity of the mutant protein (D235N) for fluoride ion appears to be much higher than that of the other two proteins. Analysis of proton NMR spectra of the cyanide ligated forms leads to the conclusion that the mutant protein (D235N) possesses a more neutral proximal histidine imidazole ring than does either wild-type CcP or CcP(MI). It confirms that an important feature of the cytochrome c peroxidase structure is at least partial, and probably full, imidazolate character for the proximal histidine (His-175).     

The role of aspartate-235 in the binding of cations to an artificial cavity at the radical site of cytochrome c peroxidase.

The activated state of cytochrome c peroxidase, compound ES, contains a cation radical on the Trp-191 side chain. We recently reported that replacing this tryptophan with glycine creates a buried cavity at the active site that contains ordered solvent and that will specifically bind substituted imidazoles in their protonated cationic forms (Fitzgerald MM, Churchill MJ, McRee DE, Goodin DB, 1994, Biochemistry 33:3807-3818). Proposals that a nearby carboxylate, Asp-235, and competing monovalent cations should modulate the affinity of the W191G cavity for ligand binding are addressed in this study. Competitive binding titrations of the imidazolium ion to W191G as a function of [K+] show that potassium competes weakly with the binding of imidazoles. The dissociation constant observed for potassium binding (18 mM) is more than 3,000-fold higher than that for 1,2-dimethylimidazole (5.5 microM) in the absence of competing cations. Significantly, the W191G-D235N double mutant shows no evidence for binding imidazoles in their cationic or neutral forms, even though the structure of the cavity remains largely unperturbed by replacement of the carboxylate. Refined crystallographic B-values of solvent positions indicate that the weakly bound potassium in W191G is significantly depopulated in the double mutant. These results demonstrate that the buried negative charge of Asp-235 is an essential feature of the cation binding determinant and indicate that this carboxylate plays a critical role in stabilizing the formation of the Trp-191 radical cation.     

Heme pocket interactions in cytochrome c peroxidase studied by site-directed mutagenesis and resonance Raman spectroscopy

Resonance Raman spectra are reported for FeII and FeIII forms of cytochrome c peroxidase (CCP) mutants prepared by site-directed mutagenesis and cloning in Escherichia coli. These include the bacterial "wild type", CCP(MI), and mutations involving groups on the proximal (Asp-235----Asn, Trp-191----Phe) and distal (Trp-51----Phe, Arg-48----Leu and Lys) side of the heme. These spectra are used to assess the spin and ligation states of the heme, via the porphyrin marker band frequencies, especially v3, near 1500 cm-1, and, for the FeII forms, the status of the Fe-proximal histidine bond via its stretching frequency. The FeII-His frequency is elevated to approximately 240 cm-1 in CCP(MI) and in all of the distal mutants, due to hydrogen-bonding interactions between the proximal His-175 N delta and the carboxylate acceptor group on Asp-235. The FeII-His RR band has two components, at 233 and 246 cm-1, which are suggested to arise from populations having H-bonded and deprotonated imidazole; these can be viewed in terms of a double-well potential involving proton transfer coupled to protein conformation. The populations shift with changing pH, possibly reflecting structure changes associated with protonation of key histidine residues, and are influenced by the Leu-48 and Phe-191 mutations. A low-spin FeII form is seen at high pH for the Lys-48, Leu-48, Phe-191, and Phe-51 mutants; for the last three species, coordination of the distal His-52 is suggested by a approximately 200-cm-1 RR band assignable to Fe(imidazole)2 stretching.(ABSTRACT TRUNCATED AT 250 WORDS)     

High-resolution three-dimensional structure of horse heart cytochrome c

The 1.94 A resolution three-dimensional structure of oxidized horse heart cytochrome c has been elucidated and refined to a final R-factor of 0.17. This has allowed for a detailed assessment of the structural features of this protein, including the presence of secondary structure, hydrogen-bonding patterns and heme geometry. A comprehensive analysis of the structural differences between horse heart cytochrome c and those other eukaryotic cytochromes c for which high-resolution structures are available (yeast iso-1, tuna, rice) has also been completed. Significant conformational differences between these proteins occur in three regions and primarily involve residues 22 to 27, 41 to 43 and 56 to 57. The first of these variable regions is part of a surface beta-loop, whilst the latter two are located together adjacent to the heme group. This study also demonstrates that, in horse cytochrome c, the side-chain of Phe82 is positioned in a co-planar fashion next to the heme in a conformation comparable to that found in other cytochromes c. The positioning of this residue does not therefore appear to be oxidation-state-dependent. In total, five water molecules occupy conserved positions in the structures of horse heart, yeast iso-1, tuna and rice cytochromes c. Three of these are on the surface of the protein, serving to stabilize local polypeptide chain conformations. The remaining two are internally located. One of these mediates a charged interaction between the invariant residue Arg38 and a nearby heme propionate. The other is more centrally buried near the heme iron atom and is hydrogen bonded to the conserved residues Asn52, Tyr67 and Thr78. It is shown that this latter water molecule shifts in a consistent manner upon change in oxidation state if cytochrome c structures from various sources are compared. The conservation of this structural feature and its close proximity to the heme iron atom strongly implicate this internal water molecule as having a functional role in the mechanism of action of cytochrome c.     

Refined crystal structure of cytoplasmic malate dehydrogenase at 2.5-A resolution

The molecular structure of cytoplasmic malate dehydrogenase from pig heart has been refined by alternating rounds of restrained least-squares methods and model readjustment on an interactive graphics system. The resulting structure contains 333 amino acids in each of the two subunits, 2 NAD molecules, 471 solvent molecules, and 2 large noncovalently bound molecules that are assumed to be sulfate ions. The crystallographic study was done on one entire dimer without symmetry restraints. Analysis of the relative position of the two subunits shows that the dimer does not obey exact 2-fold rotational symmetry; instead, the subunits are related by a 173 degrees rotation. The structure results in a R factor of 16.7% for diffraction data between 6.0 and 2.5 A, and the rms deviations from ideal bond lengths and angles are 0.017 A and 2.57 degrees, respectively. The bound coenzyme in addition to hydrophobic interactions makes numerous hydrogen bonds that either are directly between NAD and the enzyme or are with solvent molecules, some of which in turn are hydrogen bonded to the enzyme. The carboxamide group of NAD is hydrogen bonded to the side chain of Asn-130 and via a water molecule to the backbone nitrogens of Leu-157 and Asp-158 and to the carbonyl oxygen of Leu-154. Asn-130 is one of the corner residues in a beta-turn that contains the lone cis peptide bond in cytoplasmic malate dehydrogenase, situated between Asn-130 and Pro-131. The active site histidine, His-186, is hydrogen bonded from nitrogen ND1 to the carboxylate of Asp-158 and from its nitrogen NE2 to the sulfate ion bound in the putative substrate binding site. In addition to interacting with the active site histidine, this sulfate ion is also hydrogen bonded to the guanidinium group of Arg-161, to the carboxamide group of Asn-140, and to the hydroxyl group of Ser-241. It is speculated that the substrate, malate or oxaloacetate, is bound in the sulfate binding site with the substrate 1-carboxyl hydrogen bonded to the guanidinium group of Arg-161.     

The crystal structure of lignin peroxidase at 1.70 A resolution reveals a hydroxy group on the cbeta of tryptophan 171: a novel radical site formed during the redox cycle

The crystal structure of lignin peroxidase (LiP) from the white rot fungus Phanerochaete chrysosporium was refined to an R-factor of 16.2 % utilizing synchrotron data in the resolution range from 10 to 1.7 A. The final model comprises all 343 amino acid residues, 370 water molecules, the heme, four carbohydrates, and two calcium ions. Lignin peroxidase shows the typical peroxidase fold and the heme has a close environment as found in other peroxidases. During refinement of the LiP model an unprecedented modification of an amino acid was recognized. The surface residue tryptophan 171 in LiP is stereospecifically hydroxylated at the Cbeta atom due to an autocatalytic process. We propose that during the catalytic cycle of LiP a transient radical at Trp171 occurs that is different from those previously assumed for this type of peroxidase. Recently, the existence of a second substrate-binding site centered at Trp171 has been reported, by us which is different from the "classical heme edge" site found in other peroxidases. Here, we report evidence for a radical formation at Trp171 using spin trapping, which supports the concept of Trp171 being a redox active amino acid and being involved in the oxidation of veratryl alcohol. On the basis of our current model, an electron pathway from Trp171 to the heme is envisaged, relevant for the oxidation of veratryl alcohol and possibly lignin. Beside the opening leading to the heme edge, which can accommodate small aromatic substrate molecules, a smaller channel giving access to the distal heme pocket was identified that is large enough for molecules such as hydrogen peroxide. Furthermore, it was found that in LiP the bond between the heme iron and the Nepsilon2 atom of the proximal histidine residue is significantly longer than in cytochrome c peroxidase (CcP). The weaker Fe-N bond in LiP renders the heme more electron deficient and destabilizes high oxidation states, which could explain the higher redox potential of LiP as compared to CcP.     

Geometry of interaction of metal ions with histidine residues in protein structures

An analysis of the geometry and the orientation of metal ions bound to histidine residues in proteins is presented. Cations are found to lie in the imidazole plane along the lone pair on the nitrogen atom. Out of the two tautomeric forms of the imidazole ring, the NE2-protonated form is normally preferred. However, when bound to a metal ion the ND1-protonated form is predominant and NE2 is the ligand atom. When the metal coordination is through ND1, steric interactions shift the side chain torsional angle, chi 2 from its preferred value of 90 or 270 degrees. The orientation of histidine residues is usually stabilized through hydrogen bonding; ND1-protonated form of a helical residue can form a hydrogen bond with the carbonyl oxygen atom in the preceding turn of the helix. A considerable number of ligands are found in helices and beta-sheets. A helical residue bound to a heme group is usually found near the C-terminus of the helix. Two ligand groups four residues apart in a helix, or two residues apart in a beta-strand are used in many proteins to bind metal ions.     

The 2.6-A crystal structure of Pseudomonas putida cytochrome P-450

The crystal structure of Pseudomonas putida cytochrome P-450cam in the ferric, camphor bound form has been determined and partially refined to R = 0.23 at 2.6 A. The single 414 amino acid polypeptide chain (Mr = 45,000) approximates a triangular prism with a maximum dimension of approximately 60 A and a minimum of approximately 30 A. Twelve helical segments (A through L) account for approximately 40% of the structure while antiparallel beta pairs account for only approximately 10%. The unexposed iron protoporphyrin IX is sandwiched between two parallel helices designated the proximal and distal helices. The heme iron atom is pentacoordinate with the axial sulfur ligand provided by Cys 357 which extends from the N-terminal end of the proximal (L) helix. A substrate molecule, 2-bornanone (camphor), is buried in an internal pocket just above the heme distal surface adjacent to the oxygen binding site. The substrate molecule is held in place by a hydrogen bond between the side chain hydroxyl group of Tyr 96 and the camphor carbonyl oxygen atom in addition to complementary hydrophobic contacts between the camphor molecule and neighboring aliphatic and aromatic residues. The camphor is oriented such that the exo-surface of C5 would contact an iron bound, "activated" oxygen atom for stereoselective hydroxylation.     

Refined structure of cytochrome c3 at 1.8 A resolution

The structure of cytochrome c3 from the sulfate-reducing bacterium Desulfovibrio vulgaris Miyazaki has been successfully refined at 1.8 A resolution. The crystallographic R factor is 0.176 for 9907 significant reflections. The isotropic temperature factors of individual atoms were refined and a total of 47 water molecules located on the difference map were incorporated in the refinement. The four heme groups are closely packed, with adjacent pairs of heme planes being nearly perpendicular to each other. The fifth and the sixth ligands of the heme iron atoms are histidine residues with N epsilon 2-Fe distances ranging from 1.88 A to 2.12 A. The histidine co-ordination to the heme iron is different for each heme group. The heme groups are all highly exposed to solvent, although the actual regions exposed differ among the hemes. The four heme groups are located in different environments, and the heme planes are deformed from planarity. The differences in the heme structures and their environments indicate that the four heme groups are non-equivalent. The chemical as well as the physical properties of cytochrome c3 should be interpreted in terms of the structural non-equivalence of the heme groups. The characteristic secondary structural non-equivalence of the heme groups. The characteristic secondary structures of the polypeptide chain of this molecule are three short alpha-helices, two short beta-strands and ten reverse turns.     

The molecular basis of inhibitor resistance in a mammalian mitochondrial cytochrome b mutant

The mitochondrial gene for the cytochrome b of Complex III has been cloned from a mouse L-cell mutant with increased resistance to 2-n-heptyl-4-hydroxyquinoline-N-oxide and other inhibitors which block reactions at the b562 heme group. Nucleotide sequencing revealed that this gene contained a G:A transition on the coding strand at position 14,830. At the amino acid level, this mutation results in the substitution of an aspartic acid residue for a conserved glycine at position 231 of cytochrome b. Based upon current models for the secondary structure of cytochrome b, the altered amino acid lies in close proximity to one of the invariant histidine residues involved in binding the heme groups. Combining this result with the previous biochemical studies of this mutant, we hypothesize that the insertion of this highly charged side chain alters the conformation around the b562 heme group such that 2-n-heptyl-4-hydroxyquinoline-N-oxide and the other inhibitors of this group have reduced access to the inhibitor binding domain.     

Effect of Asp-235-->Asn substitution on the absorption spectrum and hydrogen peroxide reactivity of cytochrome c peroxidase.

The spectroscopic properties of a mutant cytochrome c peroxidase, in which Asp-235 has been replaced by an asparagine residue, were examined in both nitrate and phosphate buffers between pH 4 and 10.5. The spin state of the enzyme is pH dependent, and four distinct spectroscopic species are observed in each buffer system: a predominantly high-spin Fe(III) species at pH 4, two distinct low-spin forms between pH 5 and 9, and the denatured enzyme above pH 9.3. The spectrum of the mutant enzyme at pH 4 is dependent upon specific ion effects. Increasing the pH above 5 converts the mutant enzyme to a predominantly low-spin hydroxy complex. Subsequent conversion to a second low-spin form is essentially complete at pH 7.5. The second low-spin form has the distal histidine, His-52, coordinated to the heme iron. To evaluate the effect of the changes in coordination state upon the reactivity of the enzyme, the reaction between hydrogen peroxide and the mutant enzyme was also examined as a function of pH. The reaction of CcP(MI,D235N) with peroxide is biphasic. At pH 6, the rapid phase of the reaction can be attributed to the bimolecular reaction between hydrogen peroxide and the hydroxy-ligated form of the mutant enzyme. Despite the hexacoordination of the heme iron in this form, the bimolecular rate constant is approximately 22% that of pentacoordinate wild-type yeast cytochrome c peroxidase. The bimolecular reaction of the mutant enzyme with peroxide exhibits the same pH dependence in nitrate-containing buffers that has been described for the wild-type enzyme, indicating a loss of reactivity with the protonation of a group with an apparent pKa of 5.4. This observation eliminates Asp-235 as the source for this heme-linked ionization and strengthens the hypothesis that the pKa of 5.4 is associated with His-52. The slower phase of the reaction between peroxide and the mutant enzyme saturates at high peroxide concentration and is attributed to conversion of unreactive to reactive forms of the enzyme. The fraction of enzyme which reacts via the slow phase is dependent upon both pH and specific ion effects.     

Activation of the cytochrome c peroxidase of Pseudomonas aeruginosa. The role of a heme-linked protein loop: a mutagenesis study

Mutagenesis studies have been used to investigate the role of a heme ligand containing protein loop (67-79) in the activation of di-heme peroxidases. Two mutant forms of the cytochrome c peroxidase of Pseudomonas aeruginosa have been produced. One mutant (loop mutant) is devoid of the protein loop and the other (H71G) contains a non-ligating Gly at the normal histidine ligand site. Spectroscopic data show that in both mutants the distal histidine ligand of the peroxidatic heme in the un-activated enzyme is lost or is exchangeable. The un-activated H71G and loop mutants show, respectively, 75% and 10% of turnover activity of the wild-type enzyme in the activated form, in the presence of hydrogen peroxide and the physiological electron donor cytochrome c(551). Both mutant proteins show the presence of constitutive reactivity with peroxide in the normally inactive, fully oxidised, form of the enzyme and produce a radical intermediate. The radical product of the constitutive peroxide reaction appears to be located at different sites in the two mutant proteins. These results show that the loss of the histidine ligand from the peroxidatic heme is, in itself, sufficient to produce peroxidatic activity by providing a peroxide binding site and that the formation of radical intermediates is very sensitive to changes in protein structure. Overall, these data are consistent with a major role for the protein loop 67-79 in the activation of di-heme peroxidases and suggest a "charge hopping" mechanism may be operative in the process of intra-molecular electron transfer.     

Identification and functional and spectral characterization of a globin-coupled histidine kinase from Anaeromyxobacter sp. Fw109-5

Two-component signal transduction systems regulate numerous important physiological functions in bacteria. In this study we have identified, cloned, overexpressed, and characterized a dimeric full-length heme-bound (heme:protein, 1:1 stoichiometry) globin-coupled histidine kinase (AfGcHK) from Anaeromyxobacter sp. strain Fw109-5 for the first time. The Fe(III), Fe(II)-O(2), and Fe(II)-CO complexes of the protein displayed autophosphorylation activity, whereas the Fe(II) complex had no significant activity. A H99A mutant lost heme binding ability, suggesting that this residue is the heme proximal ligand. Moreover, His-183 was proposed as the autophosphorylation site based on the finding that the H183A mutant protein was not phosphorylated. The phosphate group of autophosphorylated AfGcHK was transferred to Asp-52 and Asp-169 of a response regulator, as confirmed from site-directed mutagenesis experiments. Based on the amino acid sequences and crystal structures of other globin-coupled oxygen sensor enzymes, Tyr-45 was assumed to be the O(2) binding site at the heme distal side. The O(2) dissociation rate constant, 0.10 s(-1), was substantially increased up to 8.0 s(-1) upon Y45L mutation. The resonance Raman frequencies representing ν(Fe-O2) (559 cm(-1)) and ν(O-O) (1149 cm(-1)) of the Fe(II)-O(2) complex of Y45F mutant AfGcHK were distinct from those of the wild-type protein (ν(Fe-O2), 557 cm(-1); ν(O-O), 1141 cm(-1)), supporting the proposal that Tyr-45 is located at the distal side and forms hydrogen bonds with the oxygen molecule bound to the Fe(II) complex. Thus, we have successfully identified and characterized a novel heme-based globin-coupled oxygen sensor histidine kinase, AfGcHK, in this study.     

Factors determining the orientation of axially coordinated imidazoles in heme proteins.

Factors determining conformations of imidazole axially coordinated to heme in heme proteins were investigated by analyzing 693 hemes in 432 different crystal structures of heme proteins from the Protein Data Bank (PDB), where at least one histidine is ligated to heme. The results from a search of the PDB for protein structures were interpreted with molecular force field computations. Analysis of data from these crystal structures indicated that there are two main factors that determine the orientations of imidazole ligated to heme. These are the interactions of imidazole with the propionic acid side chains of heme and with the histidine backbone. From the analysis of the crystal structures of heme proteins, it turned out that the hydrogen bonding pattern is often not decisive, though it is probably used by nature to fine-tune the orientation of imidazole axially ligated to heme. We found that in many heme proteins the NdeltaH group of imidazole ligated to heme can assume a number of different hydrogen bonds and that in mutant structures the orientation of the ligated imidazole often does not change significantly, although the mutant altered the hydrogen bonding scheme involving the imidazole. Data from crystal structures of heme proteins show that there are preferred orientations of imidazoles with respect to heme. Generally, the NdeltaH group of imidazole is oriented toward the propionic acid groups of the heme. In some cases, the NdeltaH group of imidazole is close to only one of the propionic acid groups, but it is practically never oriented in the opposite direction. The imidazole also adopts a preferred orientation with respect to its histidine backbone such that the plane of the imidazole ring is practically never parallel to the Calpha-Cbeta bond of its histidine backbone. For a given conformation of histidine backbone with respect to heme, as well as imidazole with respect to histidine backbone, the orientation of the imidazole with respect to heme is uniquely determined, since the three orientations depend on each other. Hence, the interaction of the imidazole with the backbone also influences the orientation of the imidazole with respect to the heme. Force field computations are in agreement with experimental data. With this method, we showed that there is an energy minimum when the NdeltaH group of the imidazole is oriented toward the propionic acid groups and that there are minima of energy for orientations where the imidazole ring is orthogonal to the plane defined by the Calpha-Cbeta and Cbeta-Cgamma bonds of the histidine. The computations also demonstrated that these interactions are mainly of electrostatic origin. By taking into account these two major factors, we were able to understand the orientations of axially coordinated imidazoles for all groups of heme proteins, except for the group of cytochrome c peroxidase. In this group, the orientation of the imidazole is determined by a strong hydrogen bond of the NdeltaH group with Asp235.     

The degradation of cytochrome c by hydrogen peroxide

Cytochrome c is degraded by a large excess of hydrogen peroxide, leading to opening of the heme porphyrin ring and loss of the Soret absorption bands. The kinetic parameters of this reaction have been determined, and it is shown that a small concentration of oxygen is liberated at the same rate as degradation. Low-level chemiluminescence and release of a hydroxylating species also accompany heme destruction. It is proposed that heme iron activates hydrogen peroxide to a more powerful oxidant, perhaps the hydroxyl radical, which remains bound to the heme iron and initiates attack on the porphyrin ring. Chemiluminescence appears to result from a side reaction involving singlet oxygen attack on the alpha-methene bridge, yielding a dioxetane. The in vivo degradation of cytochrome c by excess hydrogen peroxide may interfere with respiration, accelerate aging, and enhance the metabolism of carcinogens.     

The active center of catalase

The refined structure of beef liver catalase (I. Fita, A. M. Silva, M. R. N. Murthy & M. G. Rossmann, unpublished results) is here examined with regard to possible catalytic mechanisms. The distal side of the deeply buried heme pocket is connected with the surface of the molecule by one (or possibly two) channel. The electron density representing the heme group, in each of the two crystallographically independent subunits, is consistent with degradation of the porphyrin rings. The heme group appears to be buckled, reflecting the high content of bile pigment in liver catalase. The spatial organization on the proximal side (where the fifth ligand of the iron is located) shows an elaborate network of interactions. The distal side contains the substrate pocket. The limited space in this region severely constrains possible substrate positions and orientations. The N delta atom of the essential His74 residue hydrogen bonds with O gamma of Ser113, which in turn hydrogen bonds to a water molecule associated with the propionic carbonylic group of pyrrole III. These interactions are also visible in the refined structure of Penicillium vitale catalase (B. K. Vainshtein, W. R. Melik-Adamyan, V. V. Barynin, A. A. Vagin, A. I. Grebenko, V. V. Borisov, K. S. Bartels, I. Fita, & M. G. Rossmann, unpublished results). Model building suggests a pathway for a catalase mechanism (compound I formation, as well as catalatic and peroxidatic reactions). There are some similarities in compound I formation of catalase and cytochrome c peroxidase.     

The role of the conserved box E residues in the active site of the Escherichia coli type I signal peptidase

Type I signal peptidases are integral membrane proteins that function to remove signal peptides from secreted and membrane proteins. These enzymes carry out catalysis using a serine/lysine dyad instead of the prototypical serine/histidine/aspartic acid triad found in most serine proteases. Site-directed scanning mutagenesis was used to obtain a qualitative assessment of which residues in the fifth conserved region, Box E, of the Escherichia coli signal peptidase I are critical for maintaining a functional enzyme. First, we find that there is no requirement for activity for a salt bridge between the invariant Asp-273 and the Arg-146 residues. In addition, we show that the conserved Ser-278 is required for optimal activity as well as conserved salt bridge partners Asp-280 and Arg-282. Finally, Gly-272 is essential for signal peptidase I activity, consistent with it being located within van der Waals proximity to Ser-278 and general base Lys-145 side-chain atoms. We propose that replacement of the hydrogen side chain of Gly-272 with a methyl group results in steric crowding, perturbation of the active site conformation, and specifically, disruption of the Ser-90/Lys-145 hydrogen bond. A refined model is proposed for the catalytic dyad mechanism of signal peptidase I in which the general base Lys-145 is positioned by Ser-278, which in turn is held in place by Asp-280.     

Evidence for an essential histidine residue in the ascorbate-binding site of cytochrome b561

Cytochrome b(561) mediates equilibration of the ascorbate/semidehydroascorbate redox couple across the membranes of secretory vesicles. The cytochrome is reduced by ascorbic acid and oxidized by semidehydroascorbate on either side of the membrane. Treatment with diethyl pyrocarbonate (DEPC) inhibits reduction of the cytochrome by ascorbate, but this activity can be restored by subsequent treatment with hydroxylamine, suggesting the involvement of an essential histidine residue. Moreover, DEPC inactivates cytochrome b(561) more rapidly at alkaline pH, consistent with modification of a histidine residue. DEPC does not affect the absorption spectrum of cytochrome b(561) nor does it change the midpoint reduction potential, confirming that histidine modification does not affect the heme. Ascorbate protects the cytochrome from inactivation by DEPC, indicating that the essential histidine is in the ascorbate-binding site. Further evidence for this is that DEPC treatment inhibits oxidation of the cytochrome by semidehydroascorbate but not by ferricyanide. This supports a reaction mechanism in which ascorbate loses a hydrogen atom by donating a proton to histidine and transferring an electron to the heme.     

Crystal structure of rat heme oxygenase-1 in complex with heme bound to azide. Implication for regiospecific hydroxylation of heme at the alpha-meso carbon

Heme oxygenase (HO) catalyzes physiological heme degradation consisting of three sequential oxidation steps that use dioxygen molecules and reducing equivalents. We determined the crystal structure of rat HO-1 in complex with heme and azide (HO-heme-N(3)(-)) at 1.9-A resolution. The azide, whose terminal nitrogen atom is coordinated to the ferric heme iron, is situated nearly parallel to the heme plane, and its other end is directed toward the alpha-meso position of the heme. Based on resonance Raman spectroscopic analysis of HO-heme bound to dioxygen, this parallel coordination mode suggests that the azide is an analog of dioxygen. The azide is surrounded by residues of the distal F-helix with only the direction to the alpha-meso carbon being open. This indicates that regiospecific oxygenation of the heme is primarily caused by the steric constraint between the dioxygen bound to heme and the F-helix. The azide interacts with Asp-140, Arg-136, and Thr-135 through a hydrogen bond network involving five water molecules on the distal side of the heme. This network, also present in HO-heme, may function in dioxygen activation in the first hydroxylation step. From the orientation of azide in HO-heme-N(3)(-), the dioxygen or hydroperoxide bound to HO-heme, the active oxygen species of the first reaction, is inferred to have a similar orientation suitable for a direct attack on the alpha-meso carbon.