Studies on Cytochrome c Peroxidase

Utility of fluorescent heme analogue ZnPPIX to monitor conformational heterogeneity in vertebrate hexa-coordinated globins

Here, we report the preparation and photo-physical characterization of hexa-coordinated vertebrate globins, human neuroglobin (hNgb) and cytoglobin (hCygb), with the native iron protoporphyrin IX (FePPIX) cofactor replaced by a fluorescent isostructural analogue, zinc protoporphyrin IX (ZnPPIX). To facilitate insertion of ZnPPIX into hexa-coordinated globins, apoproteins prepared via butanone extraction were unfolded by the addition of GuHCl and subsequently slowly refolded in the presence of ZnPPIX. The absorption/emission spectra of ZnPPIX reconstituted hCygb are similar to those observed for ZnPPIX reconstituted myoglobin whereas the absorption and emission spectra of ZnPPIX reconstituted hNgb are blue shifted by ∼2 nm. Different steady state absorption and emission properties of ZnPPIX incorporated in hCygb and hNgb are consistent with distinct hydrogen bonding interactions between ZnPPIX and the globin matrix. The fluorescence lifetime of ZnPPIX in hexa-coordinated globins is bimodal pointing towards increased heterogeneity of the heme binding cavity in hCygb and hNgb. ZnPPIX reconstituted Ngb binds to cytochrome c with the same affinity as reported for the native protein, suggesting that fluorescent analogues of Cygb and Ngb can be readily employed to monitor interactions between vertebrate hexa-coordinated globins and other proteins.

The contribution of heme propionate groups to the conformational dynamics associated with CO photodissociation from horse heart myoglobin

Photoacoustic calorimetry and transient absorption spectroscopy were used to study conformational dynamics associated with CO photodissociation from horse heart myoglobin (Mb) reconstituted with either Fe protoporphyrin IX dimethylester (FePPDME), Fe octaethylporphyrin (FeOEP), or with native Fe protoporphyrin IX (FePPIX). The volume and enthalpy changes associated with the Fe-CO bond dissociation and formation of a transient deoxyMb intermediate for the reconstituted Mbs were found to be similar to those determined for native Mb (DeltaV1 = -2.5+/-0.6 ml mol(-1) and DeltaH1 = 8.1+/-3.0 kcal mol(-1)). The replacement of FePPIX by FeOEP significantly alters the conformational dynamics associated with CO release from protein. Ligand escape from FeOEP reconstituted Mb was determined to be roughly a factor of two faster (tau=330 ns) relative to native protein (tau=700 ns) and accompanying reaction volume and enthalpy changes were also found to be smaller (DeltaV2 = 5.4+/-2.5 ml mol(-1) and DeltaH2 = 0.7+/-2.2 kcal mol(-1)) than those for native Mb (DeltaV2 = 14.3+/-0.8 ml mol(-1) and DeltaH2 = 7.8+/-3.5 kcal mol(-1)). On the other hand, volume and enthalpy changes for CO release from FePPIX or FePPDME reconstituted Mb were nearly identical to those of the native protein. These results suggest that the hydrogen bonding network between heme propionate groups and nearby amino acid residues likely play an important role in regulating ligand diffusion through protein matrix. Disruption of this network leads to a partially open conformation of protein with less restricted ligand access to the heme binding pocket.

Iron ligand recognition by monomeric hemoglobins

Binding affinities of monomeric Glycera dibranchiata hemoglobin for some anions and heterocyclic amines, including imidazoles, pyrazole, triazole and tetrazole have been evaluated and compared with those of sperm whale and horse heart myoglobin. The proteins' affinities for substituted heterocyclic amines are strongly influenced by the steric bulk and flexibility of the aromatic ring. The ligand coordination mode depends on the heme oxidation state, iron(III) amine adducts being more stable than the iron(II) adducts, the higher affinities of stronger Brønsted-Lowry bases reflecting their essentially sigma-donor character. The bifunctional molecule morpholinoethylisocyanide acts as a redox-state-dependent ambidentate ligand, binding as an N-donor to iron(III), but as a C-donor to iron(II). pH-Dependences of the ESR and optical spectra of the azole adducts reveal iron-linked ionisations and spin-equilibria in the heme pocket. Enthalpy and entropy changes for the binding process were estimated for several ligands, and mutually compensatory behaviour is observed globally for delta H degree and delta S degree. At the compensation temperature theta, the binding affinities of monomeric Glycera dibranchiata hemoglobin and sperm whale myoglobin are similar and associated with free energy changes delta G degree (theta) approximately -9 +/- 1 kJ mol-1 for the heterocyclic and anionic ligands.

Kinetic studies on CO binding to reconstituted myoglobins with four synthetic hemes; structural control in ligand binding to myoglobin

Examination was made of CO binding reactions to four kinds of modified sperm whale myoglobin (Mb), whose heme was reconstituted by iron complexes of synthetic porphyrins such as porphine (Por), meso-tetramethylporphyrin (TMeP), meso-tetraethylporphyrin (TEtP) and meso-tetra(n-propyl)porphyrin (TnPrP), using flash photolysis and stopped-flow methods. The CO association rate was found to be 5- to 20-times and dissociation rate 10- to 36-times accelerated by replacement with synthetic hemes. These features could be explained based on characteristic structures of modified Mbs indicated by X-ray crystallography. The side chain of Arg-45 protruded from the heme vicinity into the solvent region and heme was tilted by interactions of meso-alkyl side chains with surrounding peptides, resulting in the formation of widely opened channels and pockets for ligand passage. These structural features indicate the CO ligand to more easily enter or exit from heme pockets of reconstituted myoglobins, compared to native Mb.

1H-NMR study of the mechanism of assembly and equilibrium heme orientation of sperm whale myoglobin reconstituted with protohemin type-isomers

The products of the incorporation of various protohemin type-isomers into the heme pocket of sperm whale myoglobin were investigated by 1H-NMR in the met-cyano complexes, both immediately after reconstitution as well as at equilibrium. The type-isomers studied include those involving all possible interchanges of the two substituents on a given pyrrole. The protohemin-III and -XIII isomers, with true 2-fold symmetry, yielded only homogeneous products. Protohemins-XI, -XIV both exhibited two species after reconstitution, with one disappearing with time. Protohemin-I was the only asymmetric hemin that failed to exhibit two isomers initially. The orientation of the hemin within the pocket was established by nuclear Overhauser detected dipolar connectivities among heme substituents and between heme substituents and assigned heme pocket residues. At equilibrium, the heme orientations were dominated by the asymmetric propionate rather than vinyl dispositions on the hemin, with a clear preference for placing a propionate at the 8- vs. 5-methyl position of native myoglobin. For protohemin-XI, the propionates were found in the unexpected positions of the 7-propionate and 2-vinyl groups of native myoglobin, indicating that propionates can occupy positions well within the hydrophobic interior. The alternate heme orientation for the metastable intermediates detected for protohemin-XI and -XIV involved rotational isomerism about the alpha,gamma-meso axes bisecting the vinyl positions, but these two axes are at right angles to each other in the protein matrix. The fact that protohemin-XIV, but not protohemin-I, exhibits a reversed orientation as a reconstitution intermediate provides direct evidence that vinyl contacts, as well as propionate links, modulate the relative stabilities of the initial encounter complexes between hemin and apomyoglobin. The heme cavity molecular/electronic structure was found largely unperturbed for the complexes of the various protohemin type-isomers.

Etiohemin as a prosthetic group of myoglobin

Sperm whale myoglobin was reconstituted with etioheme and the stoichiometric complex formation was confirmed. The proton NMR spectrum of the deoxy myoglobin exhibits an NH signal from the proximal histidine at 78.6 ppm, indicating heme incorporation into the heme pocket to form the Fe-N(His-F8) bond. The appearance of a single set of the heme-methyl NMR signals shows that etioheme without acid side-chains specifically interacts with the surrounding globin. The visible spectral data suggest retention of a normal iron coordination structure. The functional and NMR spectral properties of etioheme myoglobin are similar to those of mesoheme myoglobin, reflecting the absence of the electron-withdrawing heme vinyl groups.

Proton NMR study of the myoglobin reconstituted with meso-tetra(n-propyl)hemin

Spectrophotometric titration of meso-tetra(n-propyl)hemin with sperm-whale apomyoglobin revealed their 1:1 complex formation. The purified reconstituted metmyoglobin bound with an equal molar amount of CN- and the second CN- ligation was not evidenced, suggesting that the hemin is not loosely attached to the globin surface, but incorporated into the heme pocket. The hyperfine-shifted proton NMR spectrum of the deoxy myoglobin revealed the proximal imidazole NH resonance at 85.1 ppm to indicate the formation of the Fe-N(His-F8) bond. The eight pyrrole protons of the hemin of myoglobin in the absence of external ligand were observed as a single peak at -16 ppm. This indicates the electronic symmetry of the hemin and the low-spin configuration of the heme iron. The pyrrole-proton NMR patterns of the cyanide and deoxy myoglobins were found to be remarkably temperature-dependent, which was consistently explained in terms of the free rotation of the prosthetic group. The NMR results suggest that introduction of meso-tetra(n-propyl)hemin totally disrupts the highly stereospecific heme-globin contacts, making the prosthetic group mobile in the heme cavity.

Crystal structure of cytochrome c peroxidase compound I

We have compared the 2.5-A crystal structure of yeast cytochrome c peroxidase (CCP) with that of its semistable two-equivalent oxidized intermediate, compound I, by difference Fourier and least-squares refinement methods. Both structures were observed at -15 degrees C. The difference Fourier map reveals that formation of compound I causes only small positional adjustments of a few tenths of an angstrom. The map's most pronounced feature is a pair of positive and negative peaks bracketing the heme iron position. Least-squares refinement shows that the iron atom moves about 0.2 A toward the distal side of the heme. No significant difference density is evident near the side chains of Trp-51 or Met-172, each of which has been proposed to be the site of the electron paramagnetic resonance (EPR) active radical in compound I. However, the second most prominent feature of difference density is a negative peak near the side chain of Thr-180, which, according to the results of least-squares refinement, moves by 0.15 A in the direction of Met-230. These observations, together with the results of mutagenesis experiments [Fishel, L. A., Villafranca, J. E., Mauro, J. M., & Kraut, J. (1987) Biochemistry 26, 351-360; Goodin, D. B., Mauk, A. G., & Smith, M. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 1295-1299] in which Trp-51 and Met-172 have been replaced without loss of the EPR radical signal in compound I, lead us to consider the possibility that the radical site lies within a cluster composed of the side chains of Met-230, Met-231, and Trp-191.(ABSTRACT TRUNCATED AT 250 WORDS)

A kinetic study of the reaction between cytochrome c peroxidase and hydrogen peroxide. Dependence on pH and ionic strength

The rate of the reaction between cytochrome c peroxidase and hydrogen peroxide was investigated using the stopped-flow technique. The apparent bimolecular rate constant was determined between pH 3.3 and pH 11 as a function of ionic strength. The pH dependence of the apparent bimolecular rate constant can be explained by assuming that two ionizable groups on the enzyme strongly influence the rate of the reaction. At 0.1 M ionic strength, a group with a pKa of 5.5 must be unprotonated and a group with a pKa of 9.8 must be protonated for the enzyme to react rapidly with hydrogen peroxide. The apparent acid dissociation constants depend upon the ionic strength. The true bimolecular rate constant has a value of (4.5 +/- 0.3) X 10(7) M-1 sec-1 and is independent of ionic strength.