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).     

High-pressure nuclear magnetic resonance studies of hemoproteins. Pressure-induced structural changes in the heme environments of ferric low-spin metmyoglobin complexes

In order to gain an insight into nonbonded interactions in the heme microenvironments of hemoproteins, proton NMR spectra of the cyanide and methylamine complexes of metmyoglobin and its derivatives reconstituted with deutero- and meso-hemins in H2O were studied under high pressures. The exchangeable NH proton of distal histidyl imidazole exhibits substantial pressure-induced shift while the proximal histidyl NH proton shows no pressure effect for the cyanide complexes. The heme peripheral proton signals, especially 5- and 8-methyl and vinyl C alpha H resonances, were also affected by pressure. These observations are interpreted as arising from pressure-induced structural changes in the heme crevice in which the pressure effects are localized to the distal side rather than the proximal side and from possible changes in the van der Waals contacts at the heme periphery with nearby amino acid residues.     

1H NMR studies of heme pocket conformation in zinc-substituted leghemoglobin, a diamagnetic analog of deoxyleghemoglobin

Reconstitution of apoleghemoglobin with zinc protoporphyrin IX is reported. NMR spectra show that the reconstitution is orientation specific and that there is no detectable heme isomerism or conformational heterogeneity. Resonances of heme substituents and distal and proximal amino acid protons have been assigned. Only minor differences in porphyrin-protein packing occur between zinc leghemoglobin and the CO complex of ferrous leghemoglobin. The zinc is five-coordinate and is ligated by the proximal histidine. Comparisons with diamagnetic six-coordinate complexes show that the distal His-61 and Leu-65 side chains move away from the binding site upon coordination of exogenous ligands. Conformational changes are minimal when the ligand is O2.     

Assignment of proton resonances in the NMR spectrum of carbonmonoxy hemoglobin beta subunit tetramers

Isolated beta chains from human adult hemoglobin at millimolar concentration are mainly associated to form beta 4 tetramers. We were able to obtain relevant two-dimensional proton nuclear magnetic resonance (NMR) spectra of such supermolecular complexes (Mr approximately 66,000) in the carboxylated state. Analysis of the spectra enabled us to assign the major part of the proton resonances corresponding to the heme substituents. We also report assignments of proton resonances originating from 12 amino acid side chains mainly situated in the heme pocket. These results provide a basis for a comparative analysis of the tertiary heme structure in isolated beta(CO) chains in solution and in beta(CO) subunits of hemoglobin crystals. The two structures are generally similar. A significantly different position, closer to the heme center, is predicted by the NMR for Leu-141 (H19) in isolated beta chains. Comparison of the assigned resonances of conserved amino acids in alpha chains, beta chains and sperm whale myoglobin indicates a close similarity of the tertiary heme pocket structure in the three homologous proteins. Significant differences were noted on the distal heme side, at the position of Val-E11, and on Leu-H19 and Phe-G5 position on the proximal side.     

Ligand binding and structural perturbations in cytochrome c peroxidase. A crystallographic study

Crystal structures of the complexes formed between cytochrome c peroxidase and cyanide, nitric oxide, carbon monoxide, and fluoride have been determined and refined to 1.85 A. In all four complexes significant changes occur in the distal heme pocket due to movement of Arg-48, His-52, and a rearrangement of active site water molecules. In the cyanide, nitric oxide, and carbon monoxide complexes, Arg-48 moves away from the ligand while in the fluoride complex Arg-48 moves in toward the ligand to form a hydrogen bond or ion pair with the fluoride. More subtle changes occur on the proximal side of the heme. In an earlier study at lower resolution (Edwards, S. L., Kraut, J., and Poulos, T. L. (1988) Biochemistry 27, 8074-8081), we found that nitric oxide binding causes perturbations in the proximal domain involving Trp-191 which has been confirmed by the present study. Trp-191 is stacked parallel to and in contact with the proximal ligand, His-175. Nitric oxide binding results in a slight movement of Trp-191 away from His-175 and a large increase in crystallographic temperature factors indicating increased mobility of these residues on the proximal side of the heme. These proximal-side changes are unique to nitric oxide and are not related strictly to spin-state or oxidation state of the iron atom since similar changes were not observed in the cyanide (low-spin ferric), carbon monoxide (low-spin ferrous), or fluoride (high-spin ferric) complexes.     

Assignment of heme and distal amino acid resonances in the 1H-NMR spectra of the carbon monoxide and oxygen complexes of sperm whale myoglobin

Assignments of resonances of the heme and distal amino acid protons in spectra of the CO and O2 complexes of sperm whale myoglobin are reported. These resonances provide information on the conformation of the heme pocket. For oxymyoglobin, the assignments of the heme meso protons disagree with those proposed previously on the basis of partial deuteration experiments. Rapid ring flips about the C beta-C gamma bond are detected for Phe-CD1. Recent claims for two conformational substates of valine-E11 in carbonmonoxymyoglobin (Bradbury, J.H. and Carver, J.A. (1984) Biochemistry 23, 4905-4913) are shown to be in error. The pK of His-97 (FG3) in carbonmonoxymyoglobin has been determined (pK = 5.9). This residue appears to influence many spectroscopic properties of myoglobin. The distal His-E7 in carbonmonoxymyoglobin has pK less than 5.0. Differences in the heme pocket conformation in the CO complexes of myoglobin and leghemoglobin are discussed. These differences may be influential in O2 and CO association reactions.     

NMR studies of the conformations of leghemoglobins from soybean and lupin

Phase-sensitive two-dimensional NMR methods have been used to obtain extensive proton resonance assignments for the carbon monoxide complexes of lupin leghemoglobins I and II and soybean leghemoglobin a. The assigned resonances provide information on the solution conformations of the proteins, particularly in the vicinity of the heme. The structure of the CO complex of lupin leghemoglobin II in solution is compared with the X-ray crystal structure of the cyanide complex by comparison of observed and calculated ring current shifts. The structures are generally very similar but significant differences are observed for the ligand contact residues, Phe30, His63 and Val67, and for the proximal His97 ligand. Certain residues are disordered and adopt two interconverting conformations in lupin leghemoglobin II in solution. The proximal heme pocket structure is closely conserved in the lupin leghemoglobins I and II but small differences in conformation in the distal heme pocket are apparent. Larger conformational differences are observed when comparisons are made with the CO complex of soybean leghemoglobin. Altered protein-heme packing is indicated on the proximal side of the heme and some conformational differences are evident in the distal heme pocket. The small conformational differences between the three leghemoglobins probably contribute to the known differences in their O2 and CO association and dissociation kinetics. The heme pocket conformations of the three leghemoglobins are more closely related to each other than to sperm whale myoglobin. The most notable differences between the leghemoglobins and myoglobin are: (a) reduced steric crowding of the ligand binding site in the leghemoglobins, (b) different orientations of the distal histidine, and (c) small but significant differences in proximal histidine coordination geometry. These changes probably contribute to the large differences in ligand binding kinetics between the leghemoglobins and myoglobin.     

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)     

A 1H NMR comparison of the met-cyano complexes of elephant and sperm whale myoglobin. Assignment of labile proton resonances in the heme cavity and determination of the distal glutamine orientation from relaxation data

The met-cyano complex of elephant myoglobin has been investigated by high field 1H NMR spectroscopy, with special emphasis on the use of exchangeable proton resonances in the heme cavity to obtain structural information on the distal glutamine. Analysis of the distance dependence of relaxation rates and the exchange behavior of the four hyperfine shifted labile proton resonances has led to the assignment of the proximal His-F8 ring and peptide NHs and the His-FG3 ring NH and the distal Gln-E7 amide NH. The similar hyperfine shift patterns for both the apparent heme resonances as well as the labile proton peaks of conserved resonances in elephant and sperm whale met-cyano myoglobins support very similar electronic/molecular structures for their heme cavities. The essentially identical dipolar shifts and dipolar relaxation times for the distal Gln-E7 side chain NH and the distal His-E7 ring NH in sperm whale myoglobin indicate that those labile protons occupy the same geometrical position relative to the iron and heme plane. This geometry is consistent with the distal residue hydrogen bonding to the coordinated ligand. The similar rates and identical mechanisms of exchange with bulk water of the labile protons for the three conserved residues in the elephant and sperm whale heme cavity indicate that the dynamic stability of the proximal side of the heme pocket is unaltered upon the substitution (His----Gln). The much slower exchange rate (by greater than 10(4] of the distal NH in elephant relative to sperm whale myoglobin supports the assignment of the resonance to the intrinsically less labile amide side chain.     

Insights into the alkaline transformation of ferricytochrome c from (1)H NMR studies in 30% acetonitrile-water

Recently, we found that ferricytochrome c (ferricyt c) undergoes significant structural changes in mixed aqueous-nonaqueous media, resulting in the formation of a mixture of alkaline-like species. The equilibrium composition of this mixture of species is dependent on the dielectric constant of the mixed solvent medium. One-dimensional (1D) and two-dimensional (2D) (1)H nuclear magnetic resonance (NMR) methods have now been used to study these alkaline-like forms in 30% acetonitrile-water solution. A native-like (M80-ligated) III* form, two lysine-ligated forms (IVa* and IVb*), and a hydroxide-ligated form (V*) were observed. Heme proton resonance assignments for these forms were accomplished using 1D (1)H NMR and 2D nuclear Overhauser effect spectroscopy methods at 20 degrees C and 35 degrees C. The chemical exchange between the alkaline forms in 30% acetonitrile solution facilitated heme proton resonance assignments. Based on examination of the heme proton chemical shifts and several highly conserved amino acid residues, the electronic structure, secondary structure, and hydrogen bond network in the vicinity of the heme in the III* form were found to be intact. Similarly, the heme electronic structure of the IVa* form was found to be comparable to that of the IVa form. Differences in the order of the heme methyl resonances in the IVb* form, however, suggest that the heme active site in this form is somewhat different from that observed in aqueous alkaline solution. In addition, resonance assignments for the 8- and 3-methyl heme protons were made for the hydroxide-ligated V* form for the first time. The observation of chemical exchange peaks between all species except IVb* and IVa* or V* was used to propose an exchange pathway between the different forms of ferricyt c in 30% acetonitrile solution. This pathway may be biologically significant because ferricyt c, which resides in the intermembrane space of mitochondria, is exposed to medium of relatively low dielectric constant when it interacts with the mitochondrial membrane.     

Probing the Q-proton pathway of ba3-cytochrome c oxidase by time-resolved Fourier transform infrared spectroscopy

In cytochrome c oxidase, the terminal respiratory enzyme, electron transfers are strongly coupled to proton movements within the enzyme. Two proton pathways (K and D) containing water molecules and hydrophobic amino acids have been identified and suggested to be involved in the proton translocation from the mitochondrial matrix or the bacterial cytoplasm into the active site. In addition to the K and D proton pathways, a third proton pathway (Q) has been identified only in ba3-cytochrome c oxidase from Thermus thermophilus, and consists of residues that are highly conserved in all structurally known heme-copper oxidases. The Q pathway starts from the cytoplasmic side of the membrane and leads through the axial heme a3 ligand His-384 to the propionate of the heme a3 pyrrol ring A, and then via Asn-366 and Asp-372 to the water pool. We have applied FTIR and time-resolved step-scan Fourier transform infrared (TRS2-FTIR) spectroscopies to investigate the protonation/deprotonation events in the Q-proton pathway at ambient temperature. The photolysis of CO from heme a3 and its transient binding to CuB is dynamically linked to structural changes that can be tentatively attributed to ring A propionate of heme a3 (1695/1708 cm(-1)) and to deprotonation of Asp-372 (1726 cm(-1)). The implications of these results with respect to the role of the ring A propionate of heme a3-Asp372-H2O site as a proton carrier to the exit/output proton channel (H2O pool) that is conserved among all structurally known heme-copper oxidases, and is part of the Q-proton pathway in ba3-cytochrome c oxidase, are discussed.     

Proton NMR studies of human hemoglobin variants modified in the proximal side of beta heme pocket. Implications for the affinity control and cooperative mechanism

Using high resolution proton NMR spectroscopy, we have investigated 10 human hemoglobin variants modified in the proximal side of the heme pocket in beta subunits. Comparative observation of several resonances in the spectra of liganded and unliganded hemoglobins allowed us to characterize the localization and nature of the structural perturbations induced by amino acid substitutions or chemical modification. The present data indicate that the structural perturbations are localized in the beta subunits, mainly in the tertiary domain surrounding the modification site. Analysis of the aromatic region of the liganded hemoglobin spectra gives substantial information for the assignment of the His-beta 97 C-2H resonance. Correlation of the spectroscopic observations with the functional characteristics of the studied hemoglobins demonstrates that structural factors localized in the proximal side of the heme pocket can control the ligand-iron interaction taking place on the other heme side. The structural perturbations induced by the modifications in the F or FG segments of the beta subunits do not extend to the distal side but rather to the alpha 1 beta 2 interface. This argues the existence of a gradient of tertiary structural stability, indicating a possible structural pattern of heme-heme interaction in the cooperativity control.     

A nuclear Overhauser effect study of the heme crevice in the resting state and compound I of horseradish peroxidase: evidence for cation radical delocalization to the proximal histidine

The assignment of resolved hyperfine-shifted resonances in high-spin resting state horseradish peroxidase (HRP) and its double-oxidized reactive form, compound I (HRP-I), has been carried out by using the nuclear Overhauser effect (NOE) starting with the known heme methyl assignments in each species. In spite of the efficient spin-lattice relaxation and very broad resonances, significant NOEs were observed for all neighboring pyrrole substituents, which allowed the assignment of the elusive propionate alpha-methylene protons. In the resting state HRP, this leads directly to the identity of the proximal His-170 H beta peaks. The determination that one of the most strongly contact-shifted single proton resonances in HRP-I does not arise from the porphyrin dictates that the cation radical must be delocalized to some amino acid residue. The relaxation properties of the non-heme contact-shifted signal in HRP-I support the identity of this contributing residue as the proximal His-170. Detailed analysis of changes in both contact shift pattern and NOEs indicates that compound I formation is accompanied by a approximately 5 degree rotation of the 6-propionate group. The implication of a porphyrin cation radical delocalized over the proximal histidine for the proposed location of the solely amino acid centered radical in compound I of related cytochrome c peroxidase is discussed.     

19F NMR of trifluoroacetyl-labeled cysteine mutants of myoglobin: structural probes of nitric oxide bound to the H93G cavity mutant.

Nitric oxide (NO) binds to the myoglobin (Mb) cavity mutant, H93G, forming either a 5- or 6-coordinate Fe--NO heme complex. The H93G mutation replaces the proximal histidine of Mb with glycine, allowing exogenous ligands to occupy the proximal binding site. In the absence of the covalently attached proximal ligand, NO could bind to H93G from the proximal side of the heme rather than the typical diatomic binding pocket on the distal side when the 5-coordinate complex forms. The question of whether NO binds on the distal or proximal side was addressed by (19)F NMR. Site-directed mutagenesis was used to introduce unique cysteine residues at the protein surface on either the distal (S58C) or proximal (L149C) side, approximately equidistant from and perpendicular to the heme plane of both wild-type and H93G Mb. The cysteine thiols were alkylated with 3-bromo-1,1,1-trifluoroacetone to attach a trifluoroacetyl group at the mutation site. (19)F NMR spectra of 5-coordinate, NO bound S58C/H93G and L149C/H93G double mutants depict peaks with line widths of 100 and 23 Hz, respectively. As fluorine peaks broaden with increasing proximity to paramagnetic centers, such as 5-coordinate Fe--NO, the (19)F NMR data are consistent with NO binding in the distal heme pocket of H93G, even in the absence of a sixth axial ligand. Additionally, (19)F NMR spectra are reported for deoxy, oxy, CO, met CN, and met H(2)O forms of the labeled cysteine mutants. These results demonstrate that the fluorine probes are sensitive to subtle conformational changes in the protein structure due to ligation and oxidation state changes of the heme iron in Mb.     

Essential histidines of prostaglandin endoperoxide synthase. His-309 is involved in heme binding

Prostaglandin endoperoxide (PGH) synthase has a single iron protoporphyrin IX which is required for both the cyclooxygenase and peroxidase activities of the enzyme. At room temperature, the heme iron is coordinated at the axial position by an imidazole, and about 20% of the heme iron is coordinated at the distal position by an imidazole. We have used site-directed mutagenesis to investigate which histidine residues are involved in PGH synthase catalysis and heme binding. Individual mutant cDNAs for ovine PGH synthases were prepared with amino acid substitutions at each of 13 conserved histidines. cos-1 cells were transfected with each of these cDNAs, and the cyclooxygenase and peroxidase activities of the resulting microsomal PGH synthases were measured. Mutant PGH synthases in which His-207, His-309, or His-388 was replaced with either glutamine or alanine lacked both activities. Gln-386 and Ala-386 PGH synthase mutants exhibited cyclooxygenase but not peroxidase activities. Other mutants exhibited both activities at varying levels. Because binding of heme renders native PGh synthase resistant to cleavage by trypsin, we examined the effects of heme on the relative sensitivities of native, Ala-204, Ala-207, Ala-309, Ala-386, and Ala-388 mutant PGH synthases to trypsin as a measure of the heme-protein interaction. The Ala-309 PGh synthase mutant was notably hypersensitive to tryptic cleavage, even in the presence of exogenous heme; in contrast, the native enzyme and the other alanine mutants exhibited similar, lower sensitivities toward trypsin and, except for the Ala-386 mutant, were partially protected from trypsin cleavage by heme. Preincubation of the native and each of the alanine mutant PGH synthases, including the Ala-309 mutant, with indomethacin protected the proteins from trypsin cleavage. Thus, all the mutant proteins retain sufficient three-dimensional structure to bind cyclooxygenase inhibitors. Our results suggest that His-309 is one of the heme ligands, probably the axial ligand, of PGH synthase. Two other histidines, His-207 and His-388, are essential for both PGH synthase activities suggesting that either His-207 or His-388 can serve as the distal heme ligand; however, the trypsin cleavage measurements imply that neither His-207 nor His-388 is required for heme binding. This is consistent with the fact that only 20% of the distal coordination position of the heme iron of PGH synthase is occupied by an imidazole side chain.     

Structural studies of cytochrome b5: complete sequence-specific resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from pig and calf

We report complete sequence-specific proton resonance assignments for the trypsin-solubilized microsomal ferrocytochrome b5 obtained from calf liver. In addition, sequence-specific resonance assignments for the main-chain amino acid protons (i.e., C alpha, C beta, and amide protons) are also reported for the porcine cytochrome b5. Assignment of the majority of the main-chain resonances was rapidly accomplished by automated procedures that used COSY and HOHAHA peak coordinates as input. Long side chain amino acid spin system identification was facilitated by long-range coherence-transfer experiments (HOHAHA). Problems with resonance overlap were resolved by examining differences between the two-dimensional 500-MHz NMR spectra of rabbit, pig, and calf proteins and by examining the temperature-dependent variation of amide proton resonances. Calculations of the aromatic ring-current shifts for protons that the X-ray crystal structure indicated were proximal to aromatic residues were found to be useful in corroborating assignments, especially those due to the large shifts induced by the heme. Assignment of NOESY cross peaks was greatly facilitated by a prediction of intensities using a complete relaxation matrix analysis based on the crystal structure. These results suggest that the single-crystal X-ray structure closely resembles that of the solution structure although there is evidence that the solution structure has a more dynamic character.     

Proton NMR investigation of the heme active site structure of an engineered cytochrome c peroxidase that mimics manganese peroxidase.

The heme active site structure of an engineered cytochrome c peroxidase [MnCcP; see Yeung, B. K., et al. (1997) Chem. Biol. 4, 215-221] that closely mimics manganese peroxidase (MnP) has been characterized by both one- and two-dimensional NMR spectroscopy. All hyperfine-shifted resonances from the heme pocket as well as resonances from catalytically relevant amino acid residues in the congested diamagnetic envelope have been assigned. From the NMR spectral assignment and the line broadening pattern of specific protons in NOESY spectra of MnCcP, the location of the engineered Mn(II) center is firmly identified. Furthermore, we found that the creation of the Mn(II)-binding site in CcP resulted in no detectable structural changes on the distal heme pocket of the protein. However, notable structural changes are observed at the proximal side of the heme cavity. Both CepsilonH shift of the proximal histidine and (15)N shift of the bound C(15)N(-) suggest a weaker heme Fe(III)-N(His) bond in MnCcP compared to WtCcP. Our results indicate that the engineered Mn(II)-binding site in CcP resulted in not only a similar Mn(II)-binding affinity and improved MnP activity, but also weakened the Fe(III)-N(His) bond strength of the template protein CcP so that its bond strength is similar to that of the target protein MnP. The results presented here help elucidate the impact of designing a metal-binding site on both the local and global structure of the enzyme, and provide a structural basis for engineering the next generation of MnCcP that mimics MnP more closely.     

Conformational change and histidine control of heme chemistry in cytochrome c peroxidase: resonance Raman evidence from Leu-52 and Gly-181 mutants of cytochrome c peroxidase.

Resonance Raman (RR) spectra are reported for Fe(III), Fe(II), and Fe(II)CO forms of site-directed mutants of the cytochrome c peroxidase variant CCP(MI), cloned in Escherichia coli. The Fe(II) form is five-coordinate (5-c) and high-spin at low pH, but it is six-coordinate (6-c) and low-spin at high pH except when the distal His-52 residue is replaced with Leu, showing the sixth ligand to be the His-52 imidazole. Although the Leu-52 mutant stays 5-c, it does undergo an alkaline transition, as revealed by upshifts and broadening of bands assigned to vinyl C = C stretching (1620 cm-1) and C beta-vinyl bending (402 cm-1). Similar changes are seen for CCP(MI) and other mutants. Thus the alkaline transition induces a conformational change that affects the vinyl groups, probably through changes in their orientation, and that permits the His-52 imidazole to bind the Fe. The RR band arising from the stretching of the proximal Fe(II)-imidazole bond contains components at ca. 235 and 245 cm-1 for CCP(MI), which are believed to reflect a double well potential for the H-bond between the proximal His-175 imidazole and the Asp-235 carboxylate group. Loss of this H-bond by mutation of Asp-235 to Asn results in the loss of these two bands and their replacement by a single band at 205 cm-1. Although the Fe(II)-imidazole stretching mode cannot be observed in the 6-c alkaline form of the enzyme, the sixth ligand in the alkaline form of CCP(MI) is photolabile, and the status of the Fe(II)-imidazole bond can be determined in the resulting 5-c-photoproduct. For CCP(MI) at alkaline pH, the conformation change induces an increase in the 235/245-cm-1 ratio, reflecting a perturbation of the H-bond potential. In the His-52----Leu mutant, a 205-cm-1 band appears along with the 235/245-cm-1 doublet at alkaline pH, indicating partial loss of the proximal H-bond due to the distal alteration. The effect of mutations that perturb the H-bonding network that extends from the distal to the proximal side of the heme is more dramatic: at alkaline pH, His-181----Gly, Arg-48----Leu, and Trp-51----Phe mutants show an Fe(II)-imidazole stretching mode at 205 cm-1 exclusively, indicating complete loss of the proximal Asp-235-His-175 H-bond.(ABSTRACT TRUNCATED AT 400 WORDS)     

Proton hyperfine resonance assignments in cyanide-ligated cytochrome c peroxidase using the nuclear Overhauser effect

The development of the proton nuclear Overhauser effect (NOE) for hyperfine shifted resonances of cyanide-ligated cytochrome c peroxidase (Saccharomyces cerevisiae) has been studied. In the pre-steady state regime, the major effects are due to primary NOEs to nearest neighbor protons. This has been used to advantage in making assignments of all of the remaining unassigned, resolved, downfield hyperfine shifted resonances. This work also determined the relative orientation of the heme pyrrole II substituents which is the cis configuration with the 4 alpha-vinyl proton pointing away from the 3CH3. In addition to heme protons, resonances of histidine 175, threonine 180, and histidine 52 have been assigned. These results indicate some structural rearrangement of the distal amino acids accompanying ligation.     

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.