Your search keyword '"CYTOCHROME-C PEROXIDASE"' showing total 270 results

1. Magnetic circular dichroism studies on the heme and tryptophan components of cytochrome c peroxidase.

Author

Myers D and Palmer G

Subjects

Cyanides, Fluorides, Horseradish Peroxidase, Cytochrome-c Peroxidase, Heme, Peroxidases, Tryptophan

Abstract

We have measured the magnetic circular dichroism of cytochrome c peroxidase and some of its derivatives from 250-350 nm. Comparison of the changes observed on conversion to the catalytic intermediate (cytochrome c peroxidase-I) with spectra obtained from horseradish peroxidase and its derivatives and model compounds of protoheme leads us to the conclusion that the observed changes in the magnetic circular dichroism spectra reflect conversion of the heme to the ferryl state. No evidence was found for modification of tryptophan in cytochrome c peroxidase-I.

Published

1985

2. Resonance Raman study on cytochrome c peroxidase and its intermediate. Presence of the Fe(IV) = O bond in compound ES and heme-linked ionization.

Author

Hashimoto S, Teraoka J, Inubushi T, Yonetani T, and Kitagawa T

Subjects

Computers, Histidine, Hydrogen-Ion Concentration, Saccharomyces cerevisiae enzymology, Spectrum Analysis, Raman, Cytochrome-c Peroxidase, Heme, Peroxidases

Abstract

Resonance Raman spectra of ferrous and ferric cytochrome c peroxidase and Compound ES and their pH dependences were investigated in resonance with Soret band. The Fe(IV) = O stretching Raman line of Compound ES was assigned to a broad band around 767 cm-1, which was shifted to 727 cm-1 upon 18O substitution. The 18O-isotopic frequency shift was recognized for Compound ES derived in H218O, but not in H216O. This clearly indicated occurrence of an oxygen exchange between the Fe(IV) = O heme and bulk water. The Fe(IV) = O stretching Raman band was definitely more intense and of higher frequency in D2O than in H2O as in Compound II of horseradish peroxidase, but in contrast with this its frequency was unaltered between pH 4 and 11. The Fe(II)-histidine stretching Raman line was assigned on the basis of the frequency shift observed for 54Fe isotopic substitution. From the intensity analysis of this band, the pKa of the heme-linked ionization of ferrocytochrome c peroxidase was determined to be 7.3. The Raman spectrum of ferricytochrome c peroxidase strongly suggested that the heme is placed under an equilibrium between the 5- and 6-coordinate high-spin structures. At neutral pH it is biased to the 5-coordinate structure, but at the acidic side of the transition of pKa = 5.5 the 6-coordinate heme becomes dominant. F- was bound to the heme iron at pH 6, but Cl- was bound only at acidic pH. Acidification by HNO3, H2SO4, CH3COOH, HBr, or HI resulted in somewhat different populations of the 5- and 6-coordinate forms when they were compared at pH 4.3. Accordingly, it is inferred that a water molecule which is suggested to occupy the sixth coordination position of the heme iron is not coordinated to the heme iron at pH 6 but that protonation of the pKa = 5.5 residue induces an appreciable structural change, allowing the coordination of the water molecule to the heme iron.

Published

1986

3. Comparison of heme environments and proximal ligands in peroxidases and other hemoproteins through carbon-13 nuclear magnetic resonance spectroscopy of carbon monoxide complexes.

Author

Behere DV, Gonzalez-Vergara E, and Goff HM

Subjects

Chloride Peroxidase, Cysteine, Cytochrome-c Peroxidase, Histidine, Horseradish Peroxidase, Imidazoles, Isoenzymes, Lactoperoxidase, Magnetic Resonance Spectroscopy, Myoglobin, Carbon Monoxide, Heme, Hemeproteins, Peroxidases

Abstract

Carbon-13 nuclear magnetic resonance signals for the carbon monoxide ligand in ferrous complexes of horseradish peroxidase, lactoperoxidase, and chloroperoxidase are located respectively at 209.1, 208.3, and 200.8 parts per million from the tetramethylsilane reference. On the basis of previous hemoprotein and model compound studies these resonance positions are consistent with coordination of a proximal histidine ligand in horseradish peroxidase and lactoperoxidase, and coordination of a cysteinyl mercaptide ligand in chloroperoxidase. Carbonyl chemical shift values for acidic and basic horseradish peroxidase isoenzymes are very similar.

Published

1985

4. Raman difference spectroscopy of heme-linked ionizations in cytochrome c peroxidase.

Author

Shelnutt JA, Satterlee JD, and Erman JE

Subjects

Hydrogen-Ion Concentration, Spectrum Analysis, Raman, Cytochrome-c Peroxidase, Heme, Peroxidases

Abstract

The pH dependence of the oxidation-state marker line of hemoproteins is investigated in cytochrome c peroxidase with Raman difference spectroscopy. The frequency is sensitive to ionization of a group on the protein that regulates catalytic activity of the resting ferriheme enzyme. The oxidation-state marker line shows a transition with pK of 5.5 in good agreement with other spectroscopic measurements and kinetic measurements of binding of peroxide, and other ligands to the native enzyme. The shift of 0.8 cm-1 to higher frequency at pH 4.5 relative to the pH 6.4 value is interpreted in terms of a substantial decrease in pi-electron density in the porphyrin ring. Charge density in the pi-system is highest at maximal activity, as would be expected if donor-acceptor interactions with residues of the protein stabilize the oxidized Fe(IV) reaction intermediate. Evidence of additional heme-linked ionizations with pK values near 7.5 is found; this alkaline transition involves deprotonation of several groups of the protein, conversion of iron from high to low spin, and, possibly, denaturation of the protein.

Published

1983

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

Author

Smulevich G, Mauro JM, Fishel LA, English AM, Kraut J, and Spiro TG

Subjects

DNA Mutational Analysis, Ferric Compounds, Ferrous Compounds, Hydrogen-Ion Concentration, Hydroxides, Models, Molecular, Saccharomyces cerevisiae enzymology, Spectrophotometry, Infrared, Spectrum Analysis, Raman, Structure-Activity Relationship, Water, Cytochrome-c Peroxidase, Heme, Peroxidases

Abstract

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)

Published

1988

6. Resonance Raman spectra of bovine liver catalase compound II. Similarity of the heme environment to horseradish peroxidase compound II.

Author

Chuang WJ, Heldt J, and Van Wart HE

Subjects

Animals, Cattle, Cytochrome-c Peroxidase, Hydrogen-Ion Concentration, Myoglobin, Oxidation-Reduction, Spectrum Analysis, Raman, Structure-Activity Relationship, Catalase, Heme, Horseradish Peroxidase, Liver enzymology, Peroxidases

Abstract

Resonance Raman spectroscopy has been used to investigate the structure and environment of the heme group in bovine liver catalase compound II. Both Soret- and Q-band excitation have been employed to observe and assign the skeletal stretching frequencies of the porphyrin ring. The oxidation state marker band v4 increases in frequency from 1373 cm-1 in ferricatalase to 1375 cm-1 in compound II, consistent with oxidation of the iron atom to the Fe(IV) state. Oxidation of five-coordinate, high-spin ferricatalase to compound II is accompanied by a marked increase of the porphyrin core marker frequencies that is consistent with a six-coordinate low-spin state with a contracted core. An Fe(IV) = O stretching band is observed at 775 cm-1 for compound II at neutral pH, indicating that there is an oxo ligand at the sixth site. At alkaline pH, the Fe(IV) = O stretching band shifts to 786 cm-1 in response to a heme-linked ionization that is attributed to the distal His-74 residue. Experiments carried out in H218O show that the oxo ligand of compound II exchanges with bulk water at neutral pH, but not at alkaline pH. This is essentially the same behavior exhibited by horseradish peroxidase compound II and the exchange reaction at neutral pH for both enzymes is attributed to acid/base catalysis by a distal His residue that is believed to be hydrogen-bonded to the oxo ligand. Thus, the structure and environment of the heme group of the compound II species of catalase and horseradish peroxidase are very similar. This indicates that the marked differences in their reactivities as oxidants are probably due to the manner in which the protein controls access of substrates to the heme group.

Published

1989

7. Crystallographic determination of the heme orientation and location of the cyanide binding site in yeast cytochrome c peroxidase.

Author

Poulos TL, Freer ST, Alden RA, Xuong NH, Edwards SL, Hamlin RC, and Kraut J

Subjects

Binding Sites, Fourier Analysis, Models, Molecular, Protein Binding, Protein Conformation, X-Ray Diffraction, Cyanides, Cytochrome-c Peroxidase, Heme, Peroxidases, Saccharomyces cerevisiae enzymology

Published

1978

8. Cytochrome c peroxidase mutant active site structures probed by resonance Raman and infrared signatures of the CO adducts.

Author

Smulevich G, Mauro JM, Fishel LA, English AM, Kraut J, and Spiro TG

Subjects

Arginine, Binding Sites, DNA Mutational Analysis, Histidine, Hydrogen Bonding, Protein Conformation, Recombinant Proteins, Saccharomyces cerevisiae enzymology, Spectrophotometry, Infrared, Spectrum Analysis, Raman, Carbon Monoxide, Cytochrome-c Peroxidase, Heme, Peroxidases

Abstract

Vibrational frequencies associated with FeC and CO stretching and FeCO bending modes have been determined via resonance Raman (RR) and infrared (IR) spectroscopy for cytochrome c peroxidase (CCP) mutants prepared by site-directed mutagenesis. 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. The data were analyzed with the aid of a recently established correlation between nu FeC and nu CO, which can be used to distinguish between back-bonding and axial ligand donor effects. At high pH all adducts showed essentially the same vibrational pattern (form I') with nu FeC approximately 505 cm-1, nu CO approximately 1948 cm-1, and delta FeCO (weak RR band) approximately 576 cm-1. These frequencies are very similar to those shown by the myoglobin CO adduct and imply a "normal" H-bond of the proximal histidine. At pH 7 (pH 6 for Asn-235 and Leu-48), different forms are seen for different proteins: form I (nu FeC approximately 500 cm-1, nu CO = 1922-1941 cm-1, and delta FeCO approximately 580 cm-1, very weak) in the case of CCP(MI) and Phe-191, as well as bakers' yeast CCP, or form II (nu FeC approximately 530 cm-1, nu CO = 1922-1933 cm-1, and delta FeCO = 585 cm-1, moderately strong) for Asn-235 and Phe-51.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1988

9. Heme-linked properties of Pseudomonas cytochrome c peroxidase. Evidence for non-equivalence of the hemes.

Author

Rönnberg M and Ellfolk N

Subjects

Carbon Monoxide, Ferrocyanides, Hydrogen Peroxide, Kinetics, Ligands, Oxidation-Reduction, Protein Conformation, Spectrophotometry, Cytochrome-c Peroxidase, Heme, Peroxidases, Pseudomonas aeruginosa enzymology

Abstract

Pseudomonas cytochrome c peroxidase contains two hemes, one of which is shown to be in low-spin and one in high-spin state. The ferric enzyme reveals absorption maxima at 640 and 705 nm. The alkaline transition of these bands indicates the sixth iron-binding ligand of the low-spin and high-spin heme to be, respectively, a methionyl residue and a water molecule. The high-spin heme reacts with hydrogen peroxide to form a ferryl structure, which is the reactive intermediate in the peroxidatic reaction. The ferrous enzyme binds carbon monoxide in a 1:1 molar ratio, whereas the ferric form is unreactive towards small anionic ligands like F- and CN-. On this basis the peroxidase may also be classified as a cytochrome cc'.

Published

1979

10. Computational analysis of the tryptophan cation radical energetics in peroxidase Compound I

Author

Poulos, Thomas L, Kim, Jenny S, and Murarka, Vidhi C

Subjects

Chemical Sciences, Physical Chemistry, Bioengineering, Cations, Cytochrome-c Peroxidase, Electron Spin Resonance Spectroscopy, Heme, Hydrogen Peroxide, Oxidation-Reduction, Peroxidase, Peroxidases, Tryptophan, Heme peroxidases, Computational biology, Crystallography, Inorganic Chemistry, Medicinal and Biomolecular Chemistry, Biochemistry and Cell Biology, Biophysics, Biochemistry and cell biology, Inorganic chemistry

Abstract

Three well-characterized heme peroxidases (cytochrome c peroxidase = CCP, ascorbate peroxidase = APX, and Leishmania major peroxidase = LMP) all have a Trp residue tucked under the heme stacked against the proximal His heme ligand. The reaction of peroxidases with H2O2 to give Compound I results in the oxidation of this Trp to a cationic radical in CCP and LMP but not in APX. Considerable experimental data indicate that the local electrostatic environment controls whether this Trp or the porphyrin is oxidized in Compound I. Attempts have been made to place the differences between these peroxidases on a quantitative basis using computational methods. These efforts have been somewhat limited by the approximations required owing to the computational cost of using fully solvated atomistic models with well-developed forcefields. This now has changed with available GPU computing power and the associated development of software. Here we employ thermodynamic integration and multistate Bennett acceptance ratio methods to help fine-tune our understanding on the energetic differences in Trp radical stabilization in all three peroxidases. These results indicate that the local solvent structure near the redox active Trp plays a significant role in stabilization of the cationic Trp radical.

Published

2022

11. Insights into the Dynamics and Dissociation Mechanism of a Protein Redox Complex Using Molecular Dynamics

Author

Hollingsworth, Scott A, Nguyen, Brian D, Chreifi, Georges, Arce, Anton P, and Poulos, Thomas L

Subjects

Medicinal and Biomolecular Chemistry, Chemical Sciences, Theoretical and Computational Chemistry, Generic health relevance, Cytochrome-c Peroxidase, Heme, Leishmania major, Molecular Dynamics Simulation, Mutation, Oxidation-Reduction, Peroxidase, Protein Conformation, Computation Theory and Mathematics, Medicinal & Biomolecular Chemistry, Medicinal and biomolecular chemistry, Theoretical and computational chemistry

Abstract

Leishmania major peroxidase (LmP) is structurally and functionally similar to the well-studied yeast Cytochrome c peroxidase (CCP). A recent Brownian dynamics study showed that L. major Cytochrome c (LmCytc) associates with LmP by forming an initial complex with the N-terminal helix A of LmP, followed by a movement toward the electron transfer (ET) site observed in the LmP-LmCytc crystal structure. Critical to forming the active electron transfer complex is an intermolecular Arg-Asp ion pair at the center of the interface. If the dissociation reaction is effectively the reverse of the association reaction, then rupture of the Asp-Arg ion pair should be followed by movement of LmCytc back toward LmP helix A. To test this possibility, we have performed multiple molecular dynamics (MD) simulations of the LmP-LmCytc complex. In five separate simulations, LmCytc is observed to indeed move toward helix A, and in two of the simulations, the Asp-Arg ion pair breaks, which frees LmCytc to fully associate with the LmP helix A secondary binding site. These results support the "bind and crawl" or "velcro" mechanism of association, wherein LmCytc forms a nonspecific electrostatic complex with LmP helix A, followed by a "crawl" toward the ET-active site, where the Asp-Arg ion pair holds the LmCytc in position for rapid ET. These simulations also point to Tyr134LmP as being important in the association/dissociation reactions. Experimentally mutating Tyr134 to Phe was found to decrease Km by 3.6-fold, which is consistent with its predicted role in complex formation by MD simulations.

Published

2017

12. A Stable Ferryl Porphyrin at the Active Site of Y463M BthA

Author

Steven E. Cohen, Catherine L. Drennan, Andrew C. Weitz, Michael P. Hendrich, Sean Elliott, and Kimberly Rizzolo

Subjects

Models, Molecular, Porphyrins, Stereochemistry, Iron, Oxidative phosphorylation, 010402 general chemistry, 01 natural sciences, Biochemistry, Article, Catalysis, chemistry.chemical_compound, Electron transfer, Colloid and Surface Chemistry, Bacterial Proteins, Oxidation state, Heme, Binding Sites, biology, Cytochrome c peroxidase, Ligand, Active site, General Chemistry, Cytochrome-c Peroxidase, Porphyrin, 0104 chemical sciences, chemistry, Mutation, biology.protein

Abstract

BthA is a diheme enzyme that is a member of the bacterial cytochrome c peroxidase superfamily, capable of generating a highly unusual Fe(IV)Fe(IV)=O oxidation state, known to be responsible for long-range oxidative chemistry in the enzyme MauG. Here we show that installing a canonical Met ligand in lieu of the Tyr found at the heme of MauG associated with electron transfer, results in a construct that yields an unusually stable Fe(IV)=O porphyrin at the peroxidatic heme. This state is spontaneously formed at ambient conditions using either molecular O(2) or H(2)O(2). The resulting data illustrate how a ferryl iron, with unforeseen stability, may be achieved in biology.

Published

2020

13. Crystal structure of Trypanosoma cruzi heme peroxidase and characterization of its substrate specificity and compound I intermediate

Author

Samuel L. Freeman, Vera Skafar, Hanna Kwon, Alistair J. Fielding, Peter C.E. Moody, Alejandra Martínez, Federico M. Issoglio, Lucas Inchausti, Pablo Smircich, Ari Zeida, Lucía Piacenza, Rafael Radi, and Emma L. Raven

Subjects

RM, Trypanosoma cruzi, Cytochromes c, Cell Biology, Ascorbic Acid, Heme, Cytochrome-c Peroxidase, Biochemistry, Antioxidants, Substrate Specificity, QH301, Ascorbate Peroxidases, Peroxidases, Humans, QD, Chagas Disease, Molecular Biology, Peroxidase

Abstract

The protozoan parasite Trypanosoma cruzi is the causative agent of American trypanosomiasis, otherwise known as Chagas disease. To survive in the host, the T. cruzi parasite needs antioxidant defense systems. One of these is a hybrid heme peroxidase, the T. cruzi ascorbate peroxidase-cytochrome c peroxidase enzyme (TcAPx-CcP). TcAPx-CcP has high sequence identity to members of the class I peroxidase family, notably ascorbate peroxidase (APX) and cytochrome c peroxidase (CcP), as well as a mitochondrial peroxidase from Leishmania major (LmP). The aim of this work was to solve the structure and examine the reactivity of the TcAPx-CcP enzyme. Low temperature electron paramagnetic resonance spectra support the formation of an exchange-coupled [Fe(IV)=O Trp233•+] compound I radical species, analogous to that used in CcP and LmP. We demonstrate that TcAPx-CcP is similar in overall structure to APX and CcP, but there are differences in the substrate-binding regions. Furthermore, the electron transfer pathway from cytochrome c to the heme in CcP and LmP is preserved in the TcAPx-CcP structure. Integration of steady state kinetic experiments, molecular dynamic simulations, and bioinformatic analyses indicates that TcAPx-CcP preferentially oxidizes cytochrome c but is still competent for oxidization of ascorbate. The results reveal that TcAPx-CcP is a credible cytochrome c peroxidase, which can also bind and use ascorbate in host cells, where concentrations are in the millimolar range. Thus, kinetically and functionally TcAPx-CcP can be considered a hybrid peroxidase.

Published

2022

14. Computational analysis of the tryptophan cation radical energetics in peroxidase Compound I

Author

Thomas L. Poulos, Jenny S. Kim, and Vidhi C. Murarka

Subjects

Inorganic Chemistry, Peroxidases, Cations, Electron Spin Resonance Spectroscopy, Tryptophan, Heme, Hydrogen Peroxide, Cytochrome-c Peroxidase, Biochemistry, Oxidation-Reduction, Peroxidase

Abstract

Three well-characterized heme peroxidases (cytochrome c peroxidase = CCP, ascorbate peroxidase = APX, and Leishmania major peroxidase = LMP) all have a Trp residue tucked under the heme stacked against the proximal His heme ligand. The reaction of peroxidases with H2O2 to give Compound I results in the oxidation of this Trp to a cationic radical in CCP and LMP but not in APX. Considerable experimental data indicate that the local electrostatic environment controls whether this Trp or the porphyrin is oxidized in Compound I. Attempts have been made to place the differences between these peroxidases on a quantitative basis using computational methods. These efforts have been somewhat limited by the approximations required owing to the computational cost of using fully solvated atomistic models with well-developed forcefields. This now has changed with available GPU computing power and the associated development of software. Here we employ thermodynamic integration and multistate Bennett acceptance ratio methods to help fine-tune our understanding on the energetic differences in Trp radical stabilization in all three peroxidases. These results indicate that the local solvent structure near the redox active Trp plays a significant role in stabilization of the cationic Trp radical. Graphical abstract

Published

2021

15. The redox potential of a heme cofactor in

Author

Elizabeth A, Karnaukh and Ksenia B, Bravaya

Subjects

Nitrosomonas europaea, Quantum Theory, Heme, Cytochrome-c Peroxidase, Molecular Dynamics Simulation, Oxidation-Reduction

Abstract

Redox reactions are crucial to biological processes that protect organisms against oxidative stress. Metalloenzymes, such as peroxidases which reduce excess reactive oxygen species into water, play a key role in detoxification mechanisms. Here we present the results of a polarizable QM/MM study of the reduction potential of the electron transfer heme in the cytochrome c peroxidase of Nitrosomonas europaea. We have found that environment polarization does not substantially affect the computed value of the redox potential. Particular attention has been given to analyzing the role of electrostatic interactions within the protein environment and the solvent on tuning the redox potential of the heme co-factor. We have found that the electrostatic interactions predominantly explain the fluctuations of the vertical ionization/attachment energies of the heme for the sampled configurations, and that the long range electrostatic interactions (up to 40 Å) contribute substantially to the absolute values of the vertical energy gaps.

Published

2021

16. Exploring the structure function relationship of heme peroxidases: Molecular dynamics study on cytochrome c peroxidase variants

Author

Mohamed M. Aboelnga

Subjects

Structure-Activity Relationship, Peroxidases, Health Informatics, Heme, Hydrogen Peroxide, Cytochrome-c Peroxidase, Molecular Dynamics Simulation, Peroxidase, Computer Science Applications

Abstract

Cytochrome c peroxidase (Ccp1) is a mitochondrial heme-containing enzyme that has served for decades as a chemical model to explore the structure function relationship of heme enzymes. Unveiling the impact of its heme pocket residues on the structural behavior, the non-covalent interactions and consequently its peroxidase activity has been a matter of increasing interest. To further probe these roles, we conducted intensive all-atom molecular dynamics simulations on WT and nineteen in-silico generated Ccp1 variants followed by a detailed structural and energetic analysis of H

Published

2022

17. How Does Replacement of the Axial Histidine Ligand in Cytochrome c Peroxidase by Nδ-Methyl Histidine Affect Its Properties and Functions? A Computational Study

Author

Calvin W. Z. Lee, M. Qadri E. Mubarak, Sam P. de Visser, and Anthony P. Green

Subjects

Ligands, Protein Engineering, 01 natural sciences, Ferric Compounds, hydroxylation, lcsh:Chemistry, chemistry.chemical_compound, Catalytic Domain, Heme, lcsh:QH301-705.5, Spectroscopy, Horseradish Peroxidase, biology, Cytochrome c peroxidase, enzyme models, Cytochrome c, General Medicine, Methylhistidines, Computer Science Applications, Oxidation-Reduction, Peroxidase, Stereochemistry, Iron, 010402 general chemistry, Article, Catalysis, Inorganic Chemistry, Electron transfer, epoxidation, Physical and Theoretical Chemistry, Molecular Biology, Histidine, density functional theory, 010405 organic chemistry, Organic Chemistry, Active site, Computational Biology, Hydrogen Bonding, Hydrogen Peroxide, Cytochrome-c Peroxidase, heme enzymes, 0104 chemical sciences, enzyme engineering, chemistry, Catalytic cycle, lcsh:Biology (General), lcsh:QD1-999, biology.protein, peroxidases

Abstract

Heme peroxidases have important functions in nature related to the detoxification of H2O2. They generally undergo a catalytic cycle where, in the first stage, the iron(III)&ndash, heme&ndash, H2O2 complex is converted into an iron(IV)&ndash, oxo&ndash, heme cation radical species called Compound I. Cytochrome c peroxidase Compound I has a unique electronic configuration among heme enzymes where a metal-based biradical is coupled to a protein radical on a nearby Trp residue. Recent work using the engineered N&delta, methyl histidine-ligated cytochrome c peroxidase highlighted changes in spectroscopic and catalytic properties upon axial ligand substitution. To understand the axial ligand effect on structure and reactivity of peroxidases and their axially N&delta, methyl histidine engineered forms, we did a computational study. We created active site cluster models of various sizes as mimics of horseradish peroxidase and cytochrome c peroxidase Compound I. Subsequently, we performed density functional theory studies on the structure and reactivity of these complexes with a model substrate (styrene). Thus, the work shows that the N&delta, methyl histidine group has little effect on the electronic configuration and structure of Compound I and little changes in bond lengths and the same orbital occupation is obtained. However, the N&delta, methyl histidine modification impacts electron transfer processes due to a change in the reduction potential and thereby influences reactivity patterns for oxygen atom transfer. As such, the substitution of the axial histidine by N&delta, methyl histidine in peroxidases slows down oxygen atom transfer to substrates and makes Compound I a weaker oxidant. These studies are in line with experimental work on N&delta, methyl histidine-ligated cytochrome c peroxidases and highlight how the hydrogen bonding network in the second coordination sphere has a major impact on the function and properties of the enzyme.

Published

2020

18. A designed heme-[4Fe-4S] metalloenzyme catalyzes sulfite reduction like the native enzyme

Author

Parisa Hosseinzadeh, Evan N. Mirts, Yi Lu, Igor D. Petrik, and Mark J. Nilges

Subjects

Iron-Sulfur Proteins, Coenzymes, Protein Engineering, 010402 general chemistry, 01 natural sciences, Redox, Cofactor, Sulfite reductase, chemistry.chemical_compound, Sulfite, Sulfites, Heme, chemistry.chemical_classification, Binding Sites, Multidisciplinary, biology, 010405 organic chemistry, Cytochrome c peroxidase, Cytochrome-c Peroxidase, Combinatorial chemistry, 0104 chemical sciences, Enzyme, chemistry, Biocatalysis, biology.protein, Oxidation-Reduction

Abstract

Metals brought together do more Enzymatic reduction of oxyanions such as sulfite (SO 3 2− ) requires the delivery of multiple electrons and protons, a feat accomplished by cofactors tailored for catalysis and electron transport. Replicating this strategy in protein scaffolds may expand the range of enzymes that can be designed de novo. Mirts et al. selected a scaffold protein containing a natural heme cofactor and then engineered a cavity suitable for binding a second cofactor—an iron-sulfur cluster (see the Perspective by Lancaster). The resulting designed enzyme was optimized through rational mutation into a catalyst with spectral characteristics and activity similar to that of natural sulfite reductases. Science , this issue p. 1098 ; see also p. 1071

Published

2018

19. Interaction betweenNeisseria gonorrhoeaebacterial peroxidase and its electron donor, the lipid‐modified azurin

Author

Sofia R. Pauleta, Cláudia S. Nóbrega, UCIBIO - Applied Molecular Biosciences Unit, and DQ - Departamento de Química

Subjects

0301 basic medicine, Stereochemistry, Copper protein, 030106 microbiology, Biophysics, Electron donor, Biochemistry, Protein–protein interaction, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, Protein Domains, Azurin, Structural Biology, lipid-modified azurin, Genetics, Molecular Biology, Heme, electron transfer pathway, biology, Cytochrome c peroxidase, molecular docking, Cell Biology, Cytochrome-c Peroxidase, Lipids, Neisseria gonorrhoeae, Molecular Docking Simulation, protein–protein interaction, 030104 developmental biology, Solubility, chemistry, biology.protein, bacterial cytochrome c peroxidase, Protein Binding, Peroxidase

Abstract

cofinanced by the ERDF under the PT2020 Partnership Agreement (POCI-01-0145-FEDER-007728). The Neisseria gonorrhoeae bacterial cytochrome c peroxidase plays a key role in detoxifying the cells from H2O2 by reducing it to water using the lipid-modified azurin, LAz, a small type 1 copper protein, as electron donor. Here, the interaction between these two proteins was characterized by steady-state kinetics, two-dimensional NMR and molecular docking simulations. LAz is an efficient electron donor capable of activating this enzyme. This electron transfer complex is weak with a hydrophobic character, with LAz binding close to the electron transferring heme of the enzyme. The high catalytic rate (39 ± 0.03 s−1) is explained by the LAz pre-orientation, due to a positive dipole moment, and by the fast-dynamic ensemble of orientations, suggested by the small chemical shifts. publishersversion published

Published

2018

20. The proportion of Met80-sulfoxide dictates peroxidase activity of human cytochromec

Author

Torsten Kleffmann, Elizabeth C. Ledgerwood, Rinky Parakra, and Guy N. L. Jameson

Subjects

0301 basic medicine, Cardiolipins, Iron, Glycine, Apoptosis, Heme, 010402 general chemistry, 01 natural sciences, Inorganic Chemistry, 03 medical and health sciences, chemistry.chemical_compound, Methionine, Safrole, Cardiolipin, Humans, Sulfones, Inner mitochondrial membrane, 030102 biochemistry & molecular biology, biology, Cytochrome c peroxidase, Chemistry, Cytochrome c, Lactoperoxidase, Sulfoxide, Hydrogen Peroxide, Cytochrome-c Peroxidase, Hydrogen-Ion Concentration, 0104 chemical sciences, Enzyme Activation, Kinetics, Biochemistry, Mutation, biology.protein, Peroxidase

Abstract

The peroxidase activity of cytochrome c is proposed to contribute to apoptosis by peroxidation of cardiolipin in the mitochondrial inner membrane. However, cytochrome c heme is hexa-coordinate with a methionine (Met80) on the distal side, stopping it from acting as an efficient peroxidase. The first naturally occurring variant of cytochrome c discovered, G41S, has higher peroxidase activity than wild-type. To understand the basis for this increase and gain insight into the peroxidase activity of wild-type, we have studied wild-type, G41S and the unnatural variant G41T. Through a combined kinetic and mass spectrometric analysis, we have shown that hydrogen peroxide specifically oxidizes Met80 to the sulfoxide. In the absence of substrate this can be further oxidized to the sulfone, leading to a decrease in peroxidase activity. Peroxidase activity can be correlated with the proportion of sulfoxide present and if fully in that form, all variants have the same activity without a lag phase caused by activation of the protein.

Published

2018

21. Structure elaboration of isoniazid: synthesis, in silico molecular docking and antimycobacterial activity of isoniazid-pyrimidine conjugates

Author

Hardeep Kaur, Kelly Chibale, Lovepreet Singh, and Kamaljit Singh

Subjects

medicine.drug_class, In silico, Antitubercular Agents, 010402 general chemistry, Antimycobacterial, 01 natural sciences, Catalysis, Inorganic Chemistry, Small Molecule Libraries, chemistry.chemical_compound, Catalytic Domain, Drug Discovery, medicine, Isoniazid, Animals, Lactoperoxidase, Physical and Theoretical Chemistry, Molecular Biology, Heme, Catalase-peroxidase, Peroxidase, biology, 010405 organic chemistry, Cytochrome c peroxidase, Organic Chemistry, Active site, General Medicine, Mycobacterium tuberculosis, Cytochrome-c Peroxidase, 0104 chemical sciences, Molecular Docking Simulation, Pyrimidines, chemistry, Biochemistry, biology.protein, Cattle, Information Systems, medicine.drug

Abstract

Designing small molecule-based new drug candidates through structure modulation of the existing drugs has drawn considerable attention in view of inevitable emergence of resistance. A new series of isoniazid–pyrimidine conjugates were synthesized in good yields and evaluated for antitubercular activity against the H37Rv strain of Mycobacterium tuberculosis using the microplate Alamar Blue assay. Structure–anti-TB relationship profile revealed that conjugates 8a and 8c bearing a phenyl group at C-6 of pyrimidine scaffold were most active (MIC99 10 µM) and least cytotoxic members of the series. In silico docking of 8a in the active site of bovine lactoperoxidase as well as a cytochrome C peroxidase mutant N184R Y36A revealed favorable interactions similar to the heme enzyme catalase peroxidase (KatG) that activates isoniazid. This investigation suggests a rationale for further work on this promising series of antitubercular agents.

Published

2019

22. Reduction of hydrogen peroxide in gram-negative bacteria - bacterial peroxidases

Author

Cláudia S, Nóbrega and Sofia R, Pauleta

Subjects

Electron Transport, Oxidative Stress, Bacterial Proteins, Peroxidases, Gram-Negative Bacteria, Biocatalysis, Gene Expression Regulation, Bacterial, Heme, Hydrogen Peroxide, Cytochrome-c Peroxidase, Models, Theoretical, Hydroquinones

Abstract

Bacteria display an array of enzymes to detoxify reactive oxygen species that cause damage to DNA and to other biomolecules leading to cell death. Hydrogen peroxide is one of these species, with endogenous and exogenous sources, such as lactic acid bacteria, oxidative burst of the immune system or chemical reactions at oxic-anoxic interfaces. The enzymes that detoxify hydrogen peroxide will be the focus of this review, with special emphasis on bacterial peroxidases that reduce hydrogen peroxide to water. Bacterial peroxidases are periplasmic cytochromes with either two or three c-type haems, which have been classified as classical and non-classical bacterial peroxidases, respectively. Most of the studies have been focus on the classical bacterial peroxidases, showing the presence of a reductive activation in the presence of calcium ions. Mutagenesis studies have clarified the catalytic mechanism of this enzyme and were used to propose an intramolecular electron transfer pathway, with far less being known about the intermolecular electron transfer that occurs between reduced electron donors and the enzyme. The physiological function of these enzymes was not very clear until it was shown, for the non-classical bacterial peroxidase, that this enzyme is required for the bacteria to use hydrogen peroxide as terminal electron acceptor under anoxic conditions. These non-classical bacterial peroxidases are quinol peroxidases that do not require reductive activation but need calcium ions to attain maximum activity and share similar catalytic intermediates with the classical bacterial peroxidases.

Published

2019

23. The unusual redox properties of C-type oxidases

Author

Hartmut Michel, Frederic Melin, Petra Hellwig, Thomas J. Meyer, Hao Xie, Young O. Ahn, Robert B. Gennis, Chimie de la matière complexe (CMC), Université de Strasbourg (UNISTRA)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS), Institut de Chimie de Strasbourg, and Centre National de la Recherche Scientifique (CNRS)-Université Louis Pasteur - Strasbourg I-Institut de Chimie du CNRS (INC)

Subjects

0301 basic medicine, Cytochrome, Protein Conformation, Électrochimie, Biophysics, Respiratory chain, Spectroscopie, Heme, Rhodobacter sphaeroides, Ligands, Biochemistry, Membrane Potentials, Electron Transport, Electron Transport Complex IV, Structure-Activity Relationship, 03 medical and health sciences, chemistry.chemical_compound, Bacterial Proteins, Spectroscopy, Fourier Transform Infrared, Vibrio cholerae, Pseudomonas stutzeri, 030102 biochemistry & molecular biology, biology, Cytochrome c peroxidase, Hydrogen Bonding, Spectroélectrochimie, Cell Biology, Cytochrome-c Peroxidase, Electron transport chain, Chimie Physique, Oxygen, [CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistry, Heme B, 030104 developmental biology, chemistry, Potentiometry, biology.protein, Spectrophotometry, Ultraviolet, Protons, Cytochrome aa3, Oxidoreductases, Oxidation-Reduction, Protein Binding

Abstract

PMID: 27664317; Cytochrome cbb3 (also known as C-type) oxidases belong to the family of heme-copper terminal oxidases which couple at the end of the respiratory chain the reduction of molecular oxygen into water and the pumping of protons across the membrane. They are expressed most often at low pressure of O2 and they exhibit a low homology of sequence with the cytochrome aa3 (A-type) oxidases found in mitochondria. Their binuclear active site comprises a high-spin heme b3 associated with a CuB center. The protein also contains one low-spin heme b and 3 hemes c. We address here the redox properties of cbb3 oxidases from three organisms, Rhodobacter sphaeroides, Vibrio cholerae and Pseudomonas stutzeri by means of electrochemical and spectroscopic techniques. We show that the redox potential of the heme b3 exhibits a relatively low midpoint potential, as in related cytochrome c-dependent nitric oxide reductases. Potential implications for the coupled electron transfer and proton uptake mechanism of C-type oxidases are discussed.

Published

2016

24. Constraints on the Radical Cation Center of Cytochrome c Peroxidase for Electron Transfer from Cytochrome c

Author

Brian R. Crane, Boris Dzikovski, Thomas M. Payne, and Estella F. Yee

Subjects

Models, Molecular, 0301 basic medicine, Free Radicals, Protein Conformation, Stereochemistry, Crystallography, X-Ray, Ligands, 010402 general chemistry, Photochemistry, 01 natural sciences, Biochemistry, Article, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, Cations, Binding site, Heme, Binding Sites, biology, Cytochrome c peroxidase, Cytochrome c, Cytochromes c, Cytochrome-c Peroxidase, Photochemical Processes, Electron transport chain, Porphyrin, Recombinant Proteins, 0104 chemical sciences, Kinetics, 030104 developmental biology, Amino Acid Substitution, Radical ion, chemistry, Mutagenesis, Site-Directed, biology.protein

Abstract

The tryptophan 191 cation radical of cytochrome c peroxidase (CcP) compound I (Cpd I) mediates long-range electron transfer (ET) to cytochrome c (Cc). Here we test the effects of chemical substitution at position 191. CcP W191Y forms a stable tyrosyl radical upon reaction with peroxide and produces spectral properties similar to those of Cpd I but has low reactivity toward reduced Cc. CcP W191G and W191F variants also have low activity, as do redox ligands that bind within the W191G cavity. Crystal structures of complexes between Cc and CcP W191X (X = Y, F, or G), as well as W191G with four bound ligands reveal similar 1:1 association modes and heme pocket conformations. The ligands display structural disorder in the pocket and do not hydrogen bond to Asp235, as does Trp191. Well-ordered Tyr191 directs its hydroxyl group toward the porphyrin ring, with no basic residue in the range of interaction. CcP W191X (X = Y, F, or G) variants substituted with zinc-porphyrin (ZnP) undergo photoinduced ET with Cc(III). Their slow charge recombination kinetics that result from loss of the radical center allow resolution of difference spectra for the charge-separated state [ZnP(+), Cc(II)]. The change from a phenyl moiety at position 191 in W191F to a water-filled cavity in W191G produces effects on ET rates much weaker than the effects of the change from Trp to Phe. Low net reactivity of W191Y toward Cc(II) derives either from the inability of ZnP(+) or the Fe-CcP ferryl to oxidize Tyr or from the low potential of the resulting neutral Tyr radical.

Published

2016

25. Cytochrome c peroxidase facilitates the beneficial use of H 2 O 2 in prokaryotes

Author

Vadim N. Gladyshev, Marco Mariotti, and Alaattin Kaya

Subjects

0301 basic medicine, chemistry.chemical_classification, Reactive oxygen species, Multidisciplinary, Cytochrome c peroxidase, Cellular respiration, Superoxide, Heme, Hydrogen Peroxide, Cytochrome-c Peroxidase, Mitochondrion, medicine.disease_cause, Respiratory enzyme, Cell biology, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, Peroxidases, PNAS Plus, chemistry, Commentaries, Second messenger system, medicine, Oxidation-Reduction, Oxidative stress

Abstract

A new exciting study reports the discovery of a beneficial function of H2O2 in bacteria (1). Khademian and Imlay show that Escherichia coli can use cytochrome c peroxidase (Ccp) as a respiratory enzyme, wherein H2O2 acts as an electron acceptor under anoxic conditions (Fig. 1 A ). This finding may impact our understanding of microbial metabolism and the role of H2O2 in prokaryotes. The use of molecular oxygen by organisms is often associated with the phenomenon known as oxidative stress, a deleterious state counteracted by an arsenal of specialized enzymes that ensure that this threat is contained and the intracellular milieu is protected (2). This function is supported by oxidation and reduction reactions that alleviate the deleterious effects of partially reduced species of molecular oxygen, also known as reactive oxygen species (ROS). We also know that, in eukaryotes, ROS may not only induce “collateral damage,” but also have fundamental roles in cellular physiology, supporting such processes as the immune response, signal transduction, and cell proliferation (3). Organisms tightly control the levels of ROS and their spatiotemporal characteristics, so that they could be used as second messengers or agents for bacterial killing, yet would not significantly damage cellular components. Mitochondria are considered as a major intracellular source of H2O2, an abundant and physiologically relevant form of ROS in cells that originates from the superoxide anion (O2.−) during aerobic respiration (4). Cells use several types of enzymes to fine-tune the rate of H2O2 release from this compartment to cytoplasm. H2O2 is also a product of various enzymes that use molecular oxygen for two-electron oxidation reactions (5), further supporting the physiological relevance of H2O2 for cellular life. However, because the purposeful … [↵][1]1To whom correspondence should be addressed. Email: vgladyshev{at}rics.bwh.harvard.edu. [1]: #xref-corresp-1-1

Published

2017

26. Resonance Raman, EPR and MCD Spectroscopic Investigation of Diheme Cytochrome c Peroxidases from Nitrosomonas europaea and Shewanella oneidensis

Author

Wolf, Matthew W., Rizzolo, Kimberly, Elliott, Sean J., and Lehnert, Nicolai

Subjects

Models, Molecular, Shewanella, Protein Conformation, Circular Dichroism, Electron Spin Resonance Spectroscopy, Nitrosomonas europaea, Heme, Cytochrome-c Peroxidase, Spectrum Analysis, Raman, Article, Catalysis, Catalytic Domain, Oxidoreductases, Oxidation-Reduction

Abstract

Cytochrome c peroxidases (bCcPs) are diheme enzymes required for the reduction of H2O2 to water in bacteria. There are two classes of bCcPs: one class of enzymes is active in the diferric form (constitutively active), and the other class of enzymes requires the reduction of the high-potential heme (H-heme) before catalysis commences (reductively activated) at the low-potential heme (L-heme). In order to better understand the mechanisms and heme electronic structures of these different bCcPs, a constitutively active bCcP from Nitrosomonas europaea (NeCcP) and a reductively activated bCcP from Shewanella oneidensis (SoCcP) were characterized in both the diferric and semi-reduced states by electron paramagnetic resonance (EPR), resonance Raman (rRaman), and magnetic circular dichroism (MCD) spectroscopy. In contrast to some previous crystallographic studies, EPR and rRaman spectra do not indicate the presence of significant amounts of a five-coordinate, high-spin ferric heme in NeCcP or SoCcP in either the diferric or semi-reduced states in solution. This points towards a mechanism of activation where the active site L-heme is not in a static, five-coordinate state, but where the activation is more subtle and likely involves formation of a six-coordinate hydroxo complex, which could then react with hydrogen peroxide in an acid-base type reaction to create Compound 0, the ferric hydroperoxo complex. This mechanism lies in stark contrast to the diheme enzyme MauG that exhibits a static, five-coordinate open heme site at the peroxidatic heme, and that forms a more stable Fe(IV)=O intermediate.

Published

2018

27. LC-MS/MS Proteoform Profiling Exposes Cytochrome c Peroxidase Self-Oxidation in Mitochondria and Functionally Important Hole Hopping from Its Heme

Author

Ann M. English and Meena Kathiresan

Subjects

0301 basic medicine, Antioxidant, medicine.medical_treatment, Oxidative phosphorylation, Heme, Saccharomyces cerevisiae, Mitochondrion, 010402 general chemistry, 01 natural sciences, Biochemistry, Redox, Catalysis, law.invention, 03 medical and health sciences, chemistry.chemical_compound, Colloid and Surface Chemistry, law, Tandem Mass Spectrometry, medicine, Histidine, Proteogenomics, Cytochrome c peroxidase, General Chemistry, Glutathione, Hydrogen Peroxide, Cytochrome-c Peroxidase, 0104 chemical sciences, Mitochondria, 030104 developmental biology, chemistry, Recombinant DNA, Tyrosine, Oxidation-Reduction, Chromatography, Liquid

Abstract

LC-MS/MS profiling reveals that the proteoforms of cytochrome c peroxidase (Ccp1) isolated from respiring yeast mitochondria are oxidized at numerous Met, Trp, and Tyr residues. In vitro oxidation of recombinant Ccp1 by H2O2 in the absence of its reducing substrate, ferrocytochrome c, gives rise to similar proteoforms, indicating uncoupling of Ccp1 oxidation and reduction in mitochondria. The oxidative modifications found in the Ccp1 proteoforms are consistent with radical transfer (hole hopping) from the heme along several chains of redox-active residues (Trp, Met, Tyr). These modifications delineate likely hole-hopping pathways to novel substrate-binding sites. Moreover, a decrease in recombinant Ccp1 oxidation by H2O2 in vitro in the presence of glutathione supports a protective role for hole hopping to this antioxidant. Isolation and characterization of extramitochondrial Ccp1 proteoforms reveals that hole hopping from the heme in these proteoforms results in selective oxidation of the proximal heme l...

Published

2018

28. YhjA - An Escherichia coli trihemic enzyme with quinol peroxidase activity

Author

Cláudia S. Nóbrega, Bart Devreese, Sofia R. Pauleta, UCIBIO - Applied Molecular Biosciences Unit, and DQ - Departamento de Química

Subjects

0301 basic medicine, Heme binding, Stereochemistry, Genetic Vectors, Heme enzyme, Respiratory chain, Biophysics, Gene Expression, Heme, Quinol peroxidase activity, Biochemistry, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Escherichia coli, Trihemic bacterial peroxidase, Cloning, Molecular, Binding Sites, 030102 biochemistry & molecular biology, biology, Hydroquinone, Cytochrome c peroxidase, Escherichia coli Proteins, Active site, Hydrogen Peroxide, Cell Biology, Cytochrome-c Peroxidase, Hydrogen-Ion Concentration, Recombinant Proteins, Hydroquinones, Kinetics, 030104 developmental biology, chemistry, Peroxidases, Oxidative stress, Menadiol, biology.protein, Biocatalysis, Oxidation-Reduction, Peroxidase, Protein Binding

Abstract

Belgian Federal Science Policy Office (Belspo) (grant to BD, IAP7/44, iPROS project). co-financed by the ERDF under the PT2020 Partnership Agreement (POCI-01-0145-FEDER-007728). The trihemic bacterial cytochrome c peroxidase from Escherichia coli, YhjA, is a membrane-anchored protein with a C-terminal domain homologous to the classical bacterial peroxidases and an additional N-terminal (NT) heme binding domain. Recombinant YhjA is a 50 kDa monomer in solution with three c-type hemes covalently bound. Here is reported the first biochemical and spectroscopic characterization of YhjA and of the NT domain demonstrating that NT heme is His63/Met125 coordinated. The reduction potentials of P (active site), NT and E hemes were established to be −170 mV, +133 mV and +210 mV, respectively, at pH 7.5. YhjA has quinol peroxidase activity in vitro with optimum activity at pH 7.0 and millimolar range KM values using hydroquinone and menadiol (a menaquinol analogue) as electron donors (KM = 0.6 ± 0.2 and 1.8 ± 0.5 mM H2O2, respectively), with similar turnover numbers (kcat = 19 ± 2 and 13 ± 2 s−1, respectively). YhjA does not require reductive activation for maximum activity, in opposition to classical bacterial peroxidases, as P heme is always high-spin 6-coordinated with a water-derived molecule as distal axial ligand but shares the need for the presence of calcium ions in the kinetic assays. Formation of a ferryl Fe(IV) = O species was observed upon incubation of fully oxidized YhjA with H2O2. The data reported improve our understanding of the biochemical properties and catalytic mechanism of YhjA, a three-heme peroxidase that uses the quinol pool to defend the cells against hydrogen peroxide during transient exposure to oxygenated environments. publishersversion published

Published

2018

29. Functionally Distinct Bacterial Cytochrome c Peroxidases Proceed through a Common (Electro)catalytic Intermediate

Author

Kelly A. Walsh, Katherine E. Frato, and Sean Elliott

Subjects

Models, Molecular, 0301 basic medicine, Shewanella, Stereochemistry, Inorganic chemistry, Nitrosomonas europaea, Biochemistry, Catalysis, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, Shewanella oneidensis, Heme, 030102 biochemistry & molecular biology, biology, Chemistry, Cytochrome c peroxidase, Cytochrome c, Active site, Hydrogen Peroxide, Cytochrome-c Peroxidase, Hydrogen-Ion Concentration, biology.organism_classification, Electron transport chain, biology.protein, Oxidation-Reduction, Peroxidase

Abstract

The diheme cytochrome c peroxidase from Shewanella oneidensis (So CcP) requires a single electron reduction to convert the oxidized, as-isolated enzyme to an active conformation. We employ protein film voltammetry to investigate the mechanism of hydrogen peroxide turnover by So CcP. When the enzyme is poised in the active state by incubation with sodium l-ascorbate, the graphite electrode specifically captures a highly active state that turns over peroxide in a high potential regime. This is the first example of an on-pathway catalytic intermediate observed for a bacterial diheme cytochrome c peroxidase that requires reductive activation, consistent with the observed voltammetric response from the diheme cytochrome c peroxidase from Nitrosomonas europaea (Ne), which is constitutively active and does not require the same one electron activation. Mutational analysis at the active site of So CcP confirms that the rate-limiting step involves a proton-coupled single electron reduction of a high valent iron species centered on the low-potential heme, consistent with the same mutation in Ne CcP. The pH dependence of catalysis for wild-type So CcP suggests that reduction shifts the pK(a)'s of at least two amino acids. Mutation of His81 in "loop 1", a surface exposed loop thought to shift conformation during the reductive activation process, eliminated one of the pH dependent features, confirming that the loop 1 shifts, changing the environment of His81 during the rate-limiting step. The observed catalytic intermediate has the same electron stoichiometry and similar pH dependence to that previously reported for Ne CcP, which is constitutively active and therefore hypothesized to follow a different catalytic mechanism. The prominent similarities between the rate-limiting steps of differing mechanistic classes of bCcPs suggest unexpected similarities in the intermediates formed.

Published

2015

30. Apolar distal pocket mutants of yeast cytochrome c peroxidase: Binding of imidazole, 1-methylimidazole and 4-nitroimidazole to the triAla, triVal, and triLeu variants

Author

Anil K. Bidwai, Lidia B. Vitello, James E. Erman, and Caitlan E Ayala

Subjects

musculoskeletal diseases, Saccharomyces cerevisiae Proteins, Cytochrome, Stereochemistry, Biophysics, Saccharomyces cerevisiae, Plasma protein binding, Biochemistry, Article, Analytical Chemistry, chemistry.chemical_compound, immune system diseases, Catalytic Domain, Imidazole, skin and connective tissue diseases, Molecular Biology, Heme, 1-Methylimidazole, Alanine, Nitroimidazole, biology, Cytochrome c peroxidase, Imidazoles, Cytochrome-c Peroxidase, Hydrogen-Ion Concentration, Amino Acid Substitution, chemistry, Nitroimidazoles, Mutation, biology.protein, Protein Binding

Abstract

Imidazole binding to three apolar distal heme pocket mutants of yeast cytochrome c peroxidase (CcP) has been investigated between pH4 and 8. The three CcP variants have Arg-48, Trp-51, and His-52 mutated to either all alanine, CcP(triAla), all valine, CcP(triVal), or all leucine residues, CcP(triLeu). The imidazole binding curves for all three mutants are biphasic indicating that each of the mutants exists in at least two conformational states with different affinities for imidazole. At pH7, the high-affinity conformations of the three CcP mutants bind imidazole between 3.8 and 4.7 orders of magnitude stronger than that of wild-type CcP while the low-affinity conformations have binding affinities about 2.5 orders of magnitude larger than wild-type CcP. Imidazole binding to the three CcP mutants is pH dependent with the strongest binding observed at high pH. Apparent pK(a) values for the transition in binding vary between 5.6 and 7.5 for the high-affinity conformations and between 6.2 and 6.8 for the low-affinity conformations of the CcP triple mutants. The kinetics of imidazole binding are also biphasic. The fast phase of imidazole binding to CcP(triAla) and CcP(triLeu) is linearly dependent on the imidazole concentration while the slow phase is independent of imidazole concentration. Both phases of imidazole binding to CcP(triVal) have a hyperbolic dependence on the imidazole concentration. The apparent association rate constants vary between 30 and 170 M(-1)s(-1) while the apparent dissociation rate constants vary between 0.05 and 0.43 s(-1). The CcP triple mutants have higher binding affinities for 1-methylimidazole and 4-nitroimidazole than does wild-type CcP.

Published

2015

31. Enzymatic Mechanism of Leishmania major Peroxidase and the Critical Role of Specific Ionic Interactions

Author

Sarvind Tripathi, Thomas L. Poulos, Anton P. Arce, Georges Chreifi, Scott A. Hollingsworth, Huiying Li, and Hugo I. Magaña-Garcia

Subjects

Models, Molecular, Cytochrome, Stereochemistry, Static Electricity, Leishmaniasis, Cutaneous, Saccharomyces cerevisiae, Crystallography, X-Ray, Ferric Compounds, Biochemistry, Article, Electron Transport, chemistry.chemical_compound, Oxidoreductase, Humans, Enzyme kinetics, Heme, Leishmania major, Peroxidase, Ions, chemistry.chemical_classification, biology, Chemistry, Cytochrome c peroxidase, Cytochrome c, Cytochrome-c Peroxidase, stomatognathic diseases, Ionic strength, biology.protein, Oxidation-Reduction

Abstract

Leishmania major peroxidase (LmP) is very similar to the well-known yeast cytochrome c peroxidase (CcP). Both enzymes catalyze the peroxidation of cytochrome c. Like CcP, LmP reacts with H2O2 to form Compound I, which consists of a ferryl heme and a Trp radical, Fe(IV)═O;Trp(•+). Cytochrome c (Cytc) reduces the Trp radical to give Compound II, Fe(IV)═O;Trp, which is followed by an intramolecular electron transfer to give Fe(III)-OH;Trp(•+), and in the last step, Cytc reduces the Trp radical. In this study, we have used steady-state and single-turnover kinetics to improve our understanding of the overall mechanism of LmP catalysis. While the activity of CcP greatly increases with ionic strength, the kcat for LmP remains relatively constant at all ionic strengths tested. Therefore, unlike CcP, where dissociation of oxidized Cytc is limiting at low ionic strengths, association/dissociation reactions are not limiting at any ionic strength in LmP. We conclude that in LmP, the intramolecular electron transfer reaction, Fe(IV)═O;Trp to Fe(III)-OH;Trp(•+), is limiting at all ionic strengths. Unlike CcP, LmP depends on key intermolecular ion pairs to form the electron transfer competent complex. Mutating these sites causes the initial rate of association to decrease by 2 orders of magnitude and a substantial decrease in kcat. The drop in kcat is due to a switch in the rate-limiting step of the mutants from intramolecular electron transfer to the rate of association in forming the LmP-LmCytc complex. These studies show that while LmP and CcP form very similar complexes and exhibit similar activities, they substantially differ in how their activity changes as a function of ionic strength. This difference is primarily due to the heavy reliance of LmP on highly specific intermolecular ion pairs, while CcP relies mainly on nonpolar interactions.

Published

2015

32. Insights into the Dynamics and Dissociation Mechanism of a Protein Redox Complex Using Molecular Dynamics

Author

Georges Chreifi, Anton P. Arce, Brian Nguyen, Scott A. Hollingsworth, and Thomas L. Poulos

Subjects

0301 basic medicine, Protein Conformation, General Chemical Engineering, Heme, Library and Information Sciences, Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Dissociation (chemistry), Article, 03 medical and health sciences, Molecular dynamics, Electron transfer, Protein structure, Leishmania major, Peroxidase, 030102 biochemistry & molecular biology, biology, Chemistry, Cytochrome c peroxidase, Cytochrome c, General Chemistry, Cytochrome-c Peroxidase, 0104 chemical sciences, Computer Science Applications, stomatognathic diseases, Crystallography, Mutation, biology.protein, Brownian dynamics, Oxidation-Reduction

Abstract

Leishmania major peroxidase (LmP) is structurally and functionally similar to the well-studied yeast cytochrome c peroxidase (CCP). A recent Brownian dynamics study showed that L. major cytochrome c (LmCytc) associates with LmP by forming an initial complex with the N-terminal helix A of LmP, followed by a movement toward the electron transfer (ET) site observed in the LmP-LmCytc crystal structure. Critical to forming the active electron transfer complex is an intermolecular Arg-Asp ion pair at the center of the interface. If the dissociation reaction is effectively the reverse of the association reaction, then rupture of the Asp-Arg ion pair should be followed by movement of LmCytc back toward LmP helix A. To test this possibility we have carried out multiple molecular dynamics simulations of LmP-LmCytc complex. In 5 separate simulations LmCytc is observed to indeed move toward helix A and in two of the simulations, the Asp-Arg ion pair breaks, which frees LmCytc to fully associate with the LmP helix A secondary binding site. These results support the “bind and crawl” or “velcro” mechanism of association wherein LmCytc forms a non-specific electrostatic complex with LmP helix A followed by a “crawl” toward the ET active site where the Asp-Arg ion pair holds the LmCytc in position for rapid ET. These simulations also point to Tyr134LmP as being important in the association/dissociation reactions. Experimentally mutating Tyr134 to Phe was found to decrease Km by 3.6 fold, consistent with its predicted role in complex formation by molecular dynamics simulations.

Published

2017

33. Using an artificial tryptophan 'wire' in cytochrome c peroxidase for oxidation of organic substrates

Author

Rajneesh K. Bains, Jeffrey J. Warren, and Mackenzie J. Field

Subjects

0301 basic medicine, Models, Molecular, Stereochemistry, Protein Conformation, 010402 general chemistry, Photochemistry, 01 natural sciences, Redox, Inorganic Chemistry, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, Aromatic amino acids, Organic Chemicals, Coloring Agents, Heme, chemistry.chemical_classification, biology, Chemistry, Cytochrome c peroxidase, Tryptophan, Cytochrome-c Peroxidase, 0104 chemical sciences, Amino acid, 030104 developmental biology, Alcohols, Mutation, biology.protein, Mutagenesis, Site-Directed, Oxidation-Reduction, Peroxidase

Abstract

Lignolytic peroxidases use an electron transfer (ET) pathway that involves amino acid-mediated substrate oxidation at the surface of the protein rather than at an embedded heme site. In many of these peroxidases, redox catalysis takes place at a substrate accessible tyrosine or tryptophan (Trp) amino acid. Here, we describe new mutants of cytochrome c peroxidase (CcP) that were designed to incorporate a Trp-based “wire” that can move oxidizing equivalents from the heme to the protein surface. Three mutant CcP proteins were expressed and characterized: A193W, Y229W, and A193W/Y229W. These mutants can oxidize veratryl alcohol substrate with turnover numbers greater than wild type CcP using H2O2 as an oxidant. The A193W/Y229W mutant is the most active. However, the reactivity is still less than typical lignin peroxidases at pH 8. The redox reactivity of these proteins is analysed using semiclassical electron transfer theory. An electron hopping mechanism is possible for A193W/Y229W mutant. These data suggest that artificial chains of aromatic amino acids can support hole transfer from embedded sites to protein surfaces for catalytic redox reactions.

Published

2017

34. NMR studies of the interaction between inner membrane-associated and periplasmic cytochromes from Geobacter sulfurreducens

Author

Oliver Einsle, Joana M. Dantas, Anton Brausemann, and Carlos A. Salgueiro

Subjects

0301 basic medicine, Models, Molecular, Cytochrome, Protein Conformation, 030106 microbiology, Biophysics, Heme, Crystallography, X-Ray, Biochemistry, Protein–protein interaction, Electron Transport, 03 medical and health sciences, chemistry.chemical_compound, Electron transfer, Bacterial Proteins, Structural Biology, Genetics, Inner membrane, Protein Interaction Domains and Motifs, Databases, Protein, Molecular Biology, Geobacter sulfurreducens, Nuclear Magnetic Resonance, Biomolecular, Binding Sites, biology, Nitrogen Isotopes, Cytochromes c, Membrane Proteins, Cell Biology, Periplasmic space, Cytochrome-c Peroxidase, biology.organism_classification, Recombinant Proteins, Molecular Docking Simulation, Kinetics, chemistry, biology.protein, Periplasmic Proteins, Protein Multimerization, Geobacter, Oxidation-Reduction, Algorithms

Abstract

Geobacter sulfurreducens is a dissimilatory metal reducing bacterium with notable properties and significance in biotechnological applications. Biochemical studies suggest that the inner membrane-associated diheme cytochrome MacA and the periplasmic triheme cytochrome PpcA from G. sulfurreducens can exchange electrons. In this work, NMR chemical shift perturbation measurements were used to map the interface region and to measure the binding affinity between PpcA and MacA. The results show that MacA binds to PpcA in a cleft defined by hemes I and IV, favoring the contact between PpcA heme IV and the MacA high potential heme. The dissociation constant values indicate the formation of a low affinity complex between the proteins, which is consistent with the transient interaction observed in electron transfer complexes. This article is protected by copyright. All rights reserved.

Published

2017

35. Identifying the Elusive Sites of Tyrosyl Radicals in Cytochrome c Peroxidase: Implications for Oxidation of Substrates Bound at a Site Remote from the Heme

Author

Anabella Ivancich, Lynda J. Donald, Nadime Karaduman, Parisa Hosseinzadeh, Yi Lu, Peter C. Loewen, Thomas D. Pfister, Kyle D. Miner, University of Illinois at Urbana-Champaign [Urbana], University of Illinois System, Systèmes membranaires, photobiologie, stress et détoxification (SMPSD - UMR 8221), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), University of Manitoba [Winnipeg], Bioénergétique et Ingénierie des Protéines (BIP ), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), University of Illinois at Urbana Champaign (UIUC), and University of Illinois System-University of Illinois System

Subjects

Models, Molecular, Saccharomyces cerevisiae Proteins, Protein Conformation, Surface Properties, Stereochemistry, Recombinant Fusion Proteins, Radical, Reactive intermediate, Heme, 010402 general chemistry, Photochemistry, 01 natural sciences, Biochemistry, Article, law.invention, Electron Transport, Electron transfer, chemistry.chemical_compound, law, Electron paramagnetic resonance, Expectorants, Binding Sites, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], biology, 010405 organic chemistry, Chemistry, Cytochrome c peroxidase, Guaiacol, Electron Spin Resonance Spectroscopy, Tryptophan, [SDV.BBM.BM]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Molecular biology, [CHIM.CATA]Chemical Sciences/Catalysis, Cytochrome-c Peroxidase, 0104 chemical sciences, [SDV.BBM.BP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Biophysics, Kinetics, [SPI.ELEC]Engineering Sciences [physics]/Electromagnetism, A-site, Amino Acid Substitution, Biocatalysis, Mutagenesis, Site-Directed, biology.protein, Tyrosine, Mutant Proteins, Oxidation-Reduction, Peroxidase

Abstract

International audience; The location of the Trp radical and the catalytic function of the [Fe(IV)═O Trp191•+] intermediate in cytochrome c peroxidase (CcP) are well-established; however, the unambiguous identification of the site(s) for the formation of tyrosyl radical(s) and their possible biological roles remain elusive. We have now performed a systematic investigation of the location and reactivity of the Tyr radical(s) using multifrequency Electron Paramagnetic Resonance (EPR) spectroscopy combined with multiple-site Trp/Tyr mutations in CcP. Two tyrosines, Tyr71 and Tyr236, were identified as those contributing primarily to the EPR spectrum of the tyrosyl radical, recorded at 9 and 285 GHz. The EPR characterization also showed that the heme distal-side Trp51 is involved in the intramolecular electron transfer between Tyr71 and the heme and that formation of Tyr71• and Tyr236• is independent of the [Fe(IV)═O Trp191•+] intermediate. Tyr71 is located in an optimal position to mediate the oxidation of substrates binding at a site, more than 20 Å from the heme, which has been reported recently in the crystal structures of CcP with bound guaicol and phenol [Murphy, E. J., et al. (2012) FEBS J. 279, 1632–1639]. The possibility of discriminating the radical intermediates by their EPR spectra allowed us to identify Tyr71• as the reactive species with the guaiacol substrate. Our assignment of the surface-exposed Tyr236 as the other radical site agrees well with previous studies based on MNP labeling and protein cross-linking [Tsaprailis, G., and English, A. M. (2003) JBIC, J. Biol. Inorg. Chem. 8, 248–255] and on its covalent modification upon reaction of W191G CcP with 2-aminotriazole [Musah, R. A., and Goodin, D. B. (1997) Biochemistry 36, 11665–11674]. Accordingly, while Tyr71 acts as a true reactive intermediate for the oxidation of certain small substrates that bind at a site remote from the heme, the surface-exposed Tyr236 would be more likely related to oxidative stress signaling, as previously proposed. Our findings reinforce the view that CcP is the monofunctional peroxidase that most closely resembles its ancestor enzymes, the catalase-peroxidases, in terms of the higher complexity of the peroxidase reaction [Colin, J., et al. (2009) J. Am. Chem. Soc. 131, 8557–8563]. The strategy used to identify the elusive Tyr radical sites in CcP may be applied to other heme enzymes containing a large number of Tyr and Trp residues and for which Tyr (or Trp) radicals have been proposed to be involved in their peroxidase or peroxidase-like reaction.

Published

2014

36. Paramagnetic properties of the low- and high-spin states of yeast cytochrome c peroxidase

Author

Alexander N. Volkov, Sophie Vanwetswinkel, and Nico A. J. van Nuland

Subjects

Hemeproteins, Quantitative Biology::Biomolecules, Hemeprotein, Chemistry, Ligand, Cytochrome c peroxidase, Chemical shift, Electron Spin Resonance Spectroscopy, Hexacoordinate, Cytochrome-c Peroxidase, Zero field splitting, Biochemistry, Mitochondria, NMR spectra database, Crystallography, chemistry.chemical_compound, Nuclear magnetic resonance, Yeasts, Condensed Matter::Strongly Correlated Electrons, Nuclear Magnetic Resonance, Biomolecular, Heme, Spectroscopy

Abstract

Here we describe paramagnetic NMR analysis of the low- and high-spin forms of yeast cytochrome c peroxidase (CcP), a 34 kDa heme enzyme involved in hydroperoxide reduction in mitochondria. Starting from the assigned NMR spectra of a low-spin CN-bound CcP and using a strategy based on paramagnetic pseudocontact shifts, we have obtained backbone resonance assignments for the diamagnetic, iron-free protein and the high-spin, resting-state enzyme. The derived chemical shifts were further used to determine low- and high-spin magnetic susceptibility tensors and the zero-field splitting constant (D) for the high-spin CcP. The D value indicates that the latter contains a hexacoordinate heme species with a weak field ligand, such as water, in the axial position. Being one of the very few high-spin heme proteins analyzed in this fashion, the resting state CcP expands our knowledge of the heme coordination chemistry in biological systems.

Published

2013

37. The tuberculosis prodrug isoniazid bound to activating peroxidases

Author

Isabel K. Macdonald, Emma J. Murphy, Peter C. E. Moody, Emma Lloyd Raven, Katherine A. Brown, and Clive Metcalfe

Subjects

Stereochemistry, Antitubercular Agents, Heme, Crystallography, X-Ray, Biochemistry, chemistry.chemical_compound, Ascorbate Peroxidases, Bacterial Proteins, Drug Resistance, Bacterial, Isoniazid, medicine, Tuberculosis, Prodrugs, Binding site, Molecular Biology, Binding Sites, biology, Chemistry, Cytochrome c peroxidase, Active site, food and beverages, Mycobacterium tuberculosis, Cell Biology, Cytochrome-c Peroxidase, Catalase, APX, bacterial infections and mycoses, Protein Structure, Tertiary, Peroxidases, Structural Homology, Protein, Mutation, biology.protein, Protein Binding, Peroxidase, medicine.drug

Abstract

Isoniazid (INH, isonicotinic acid hydrazine) is one of only two therapeutic agents effective in treating tuberculosis. This prodrug is activated by the heme enzyme catalase peroxidase (KatG) endogenous to Mycobacterium tuberculosis but the mechanism of activation is poorly understood, in part because the binding interaction has not been properly established. The class I peroxidases ascorbate peroxidase (APX) and cytochrome c peroxidase (CcP) have active site structures very similar to KatG and are also capable of activating isoniazid. We report here the first crystal structures of complexes of isoniazid bound to APX and CcP. These are the first structures of isoniazid bound to any activating enzymes. The structures show that isoniazid binds close to the delta-heme edge in both APX and CcP, although the precise binding orientation varies slightly in the two cases. A second binding site for INH is found in APX at the gamma-heme edge close to the established ascorbate binding site, indicating that the gamma-heme edge can also support the binding of aromatic substrates. We also show that in an active site mutant of soybean APX (W41A) INH can bind directly to the heme iron to become an inhibitor and in a different mode when the distal histidine is replaced by alanine (H42A). These structures provide the first unambiguous evidence for the location of the isoniazid binding site in the class I peroxidases and provide rationalization of isoniazid resistance in naturally occurring KatG mutant strains of M. tuberculosis.

Published

2016

38. Peroxide-dependent formation of a covalent link between Trp51 and the heme in cytochrome c peroxidase

Author

Andrew R. Bottrill, Victor Guallar, Clive Metcalfe, Jaswir Basran, Sharad Mistry, Emma J. Murphy, Zoi Pipirou, and Emma Lloyd Raven

Subjects

biology, Molecular Structure, Cytochrome c peroxidase, Stereochemistry, Tryptophan, Active site, Heme, Cytochrome-c Peroxidase, Oxidants, Biochemistry, Porphyrin, Peroxide, Peroxides, chemistry.chemical_compound, chemistry, Covalent bond, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, biology.protein, Chromatography, High Pressure Liquid, Peroxidase

Abstract

Ascorbate peroxidase (APX), cytochrome c peroxidase (CcP), and the catalase-peroxidases (KatG) share very similar active site structures and are distinguished from other peroxidases by the presence of a distal tryptophan residue. In KatG, this distal tryptophan forms a covalent link to an adjacent tyrosine residue, which in turn links to a methionine residue. We have previously shown [ Pipirou, Z. et al. ( 2007 ) Biochemistry 46 , 2174 - 2180 ] that reaction of APX with peroxide leads, over long time scales, to formation of a covalent link with the distal tryptophan (Trp41) in a mechanism that proceeds through initial formation of a compound I species bearing a porphyrin pi-cation radical followed by radical formation on Trp41, as implicated in the KatG enzymes. Formation of such a covalent link in CcP has never been reported, and we proposed that this could be because compound I in CcP uses Trp191 instead of a porphyrin pi-cation radical. To test this, we have examined the reactivity of the W191F variant of CcP with H(2)O(2), in which formation of a porphyrin pi-cation radical occurs. We show, using electronic spectroscopy, HPLC, and mass spectroscopy, that in W191F partial formation of a covalent link from Trp51 to the heme is observed, as in APX. Radical formation on Trp51, as seen for KatG and APX, is implicated; this is supported by QM/MM calculations. Collectively, the data show that all three members of the class I heme peroxidases can support radical formation on the distal tryptophan and that the reactivity of this radical can be controlled either by the protein structure or by the nature of the compound I intermediate.

Published

2016

39. Autocatalytic formation of a covalent link between tryptophan 41 and the heme in ascorbate peroxidase

Author

Zoi Pipirou, Clive M. Metcalfe, Emma Lloyd Raven, Andrew R. Bottrill, Sandip K. Badyal, Sharad Mistry, and Bernard J. Rawlings

Subjects

Heme, Biochemistry, chemistry.chemical_compound, Ascorbate Peroxidases, Bacterial Proteins, Tandem Mass Spectrometry, Catalase-peroxidase, Chromatography, High Pressure Liquid, biology, Chemistry, Cytochrome c peroxidase, Spectrum Analysis, Tryptophan, Hydrogen Peroxide, Cytochrome-c Peroxidase, APX, Catalase, Recombinant Proteins, Peroxidases, Covalent bond, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, biology.protein, Soybeans, Oxidation-Reduction, Peroxidase, Deuteroporphyrins

Abstract

Electronic spectroscopy, HPLC analyses, and mass spectrometry (MALDI-TOF and MS/MS) have been used to show that a covalent link from the heme to the distal Trp41 can occur on exposure of ascorbate peroxidase (APX) to H2O2 under noncatalytic conditions. Parallel analyses with the W41A variant and with APX reconstituted with deuteroheme clearly indicate that the covalent link does not form in the absence of either Trp41 or the heme vinyl groups. The presence of substrate also precludes formation of the link. Formation of a protein radical at Trp41 is implicated, in a reaction mechanism that is analogous to that proposed [Ghiladi, R. A., et al. (2005) Biochemistry 44, 15093−15105] for formation of a covalent Trp-Tyr-Met link in the closely related catalase peroxidase (KatG) enzymes. Collectively, the data suggest that radical formation at the distal tryptophan position is not an exclusive feature of the KatG enzymes and may be used more widely across other members of the class I heme peroxidase family.

Published

2016

40. Challenging Density Functional Theory Calculations with Hemes and Porphyrins

Author

Sam P. de Visser and Martin J. Stillman

Subjects

Hemeproteins, Models, Molecular, chlorophylls, Porphyrins, Metalloporphyrins, Protein Conformation, Complex system, Electrons, Review, Heme, 010402 general chemistry, 01 natural sciences, DFT, Catalysis, Electron Transport Complex IV, Inorganic Chemistry, lcsh:Chemistry, Cytochrome P-450 Enzyme System, Computational chemistry, Animals, Humans, enzyme mechanism, Physical and Theoretical Chemistry, Molecular Biology, lcsh:QH301-705.5, Spectroscopy, 010405 organic chemistry, Chemistry, Organic Chemistry, Hemoglobin A, General Medicine, Ga(III)PPIX, Cytochrome-c Peroxidase, 0104 chemical sciences, Computer Science Applications, lcsh:Biology (General), lcsh:QD1-999, Chemical physics, Natural processes, Quantum Theory, MCD spectroscopy, Density functional theory

Abstract

In this paper we review recent advances in computational chemistry and specifically focus on the chemical description of heme proteins and synthetic porphyrins that act as both mimics of natural processes and technological uses. These are challenging biochemical systems involved in electron transfer as well as biocatalysis processes. In recent years computational tools have improved considerably and now can reproduce experimental spectroscopic and reactivity studies within a reasonable error margin (several kcal·mol(-1)). This paper gives recent examples from our groups, where we investigated heme and synthetic metal-porphyrin systems. The four case studies highlight how computational modelling can correctly reproduce experimental product distributions, predicted reactivity trends and guide interpretation of electronic structures of complex systems. The case studies focus on the calculations of a variety of spectroscopic features of porphyrins and show how computational modelling gives important insight that explains the experimental spectra and can lead to the design of porphyrins with tuned properties.

Published

2016

41. Targeted proteomics identify metabolism-dependent interactors of yeast cytochrome c peroxidase: implications in stress response and heme trafficking

Author

Meena Kathiresan and Ann M. English

Subjects

0301 basic medicine, Proteomics, Silver Staining, Saccharomyces cerevisiae Proteins, Recombinant Fusion Proteins, Saccharomyces cerevisiae, Biophysics, Heme, Mitochondrion, Biochemistry, Interactome, Biomaterials, 03 medical and health sciences, chemistry.chemical_compound, Stress, Physiological, Protein Isoforms, Amino Acid Sequence, biology, Cytochrome c peroxidase, Metals and Alloys, Biological Transport, Cytochrome-c Peroxidase, biology.organism_classification, Yeast, Mitochondria, 030104 developmental biology, chemistry, Chemistry (miscellaneous), biology.protein, Peroxiredoxin, Peroxidase, Protein Binding

Abstract

Recently we discovered that cytochrome c peroxidase (Ccp1) functions primarily as a mitochondrial H2O2 sensor and heme donor in yeast cells. When cells switch their metabolism from fermentation to respiration mitochondrial H2O2 levels spike, and overoxidation of its polypeptide labilizes Ccp1's heme. A large pool of heme-free Ccp1 exits the mitochondria and enters the nucleus and vacuole. To gain greater insight into the mechanisms of Ccp1's H2O2-sensing and heme-donor functions during the cell's different metabolic states, here we use glutathione-S-transferase (GST) pulldown assays, combined with 1D gel electrophoresis and mass spectrometry to probe for interactors of apo- and holoCcp1 in extracts from 1 d fermenting and 7 d stationary-phase respiring yeast. We identified Ccp1's peroxidase cosubstrate Cyc1 and 28 novel interactors of GST-apoCcp1 and GST-holoCcp1 including mitochondrial superoxide dismutase 2 (Sod2) and cytosolic Sod1, the mitochondrial transporter Pet9, the three yeast isoforms of glyceraldehyde-3-phosphate dehydrogenase (Tdh3/2/1), heat shock proteins including Hsp90 and Hsp70, and the main peroxiredoxin in yeast (Tsa1) as well as its cosubstrate, thioreoxin (Trx1). These new interactors expand the scope of Ccp1's possible roles in stress response and in heme trafficking and suggest several new lines of investigation. Furthermore, our targeted proteomics analysis underscores the limitations of large-scale interactome studies that found only 4 of the 30 Ccp1 interactors isolated here.

Published

2016

42. Cytochrome c peroxidase activity of heme bound amyloid β peptides

Author

Somdatta Ghosh Dey, Chandradeep Ghosh, Manas Seal, and Olivia Basu

Subjects

Stereochemistry, Peptide, Heme, 010402 general chemistry, Spectrum Analysis, Raman, environment and public health, 01 natural sciences, Biochemistry, Inorganic Chemistry, chemistry.chemical_compound, Hydrogen peroxide, chemistry.chemical_classification, Amyloid beta-Peptides, biology, 010405 organic chemistry, Cytochrome c peroxidase, Cytochrome c, Cytochrome-c peroxidase activity, Hydrogen Peroxide, Cytochrome-c Peroxidase, 0104 chemical sciences, enzymes and coenzymes (carbohydrates), Kinetics, Enzyme, chemistry, Ionic strength, embryonic structures, cardiovascular system, biology.protein

Abstract

Heme bound amyloid β (Aβ) peptides, which have been associated with Alzheimer's disease (AD), can catalytically oxidize ferrocytochrome c (Cyt c(II)) in the presence of hydrogen peroxide (H2O2). The rate of catalytic oxidation of Cyt(II) c has been found to be dependent on several factors, such as concentration of heme(III)-Aβ, Cyt(II) c, H2O2, pH, ionic strength of the solution, and peptide chain length of Aβ. The above features resemble the naturally occurring enzyme cytochrome c peroxidase (CCP) which is known to catalytically oxidize Cyt(II) c in the presence of H2O2. In the absence of heme(III)-Aβ, the oxidation of Cyt(II) c is not catalytic. Thus, heme-Aβ complex behaves as CCP.

Published

2016

43. Why do bacteria use so many enzymes to scavenge hydrogen peroxide?

Author

James A. Imlay and Surabhi Mishra

Subjects

Time Factors, Photochemistry, Molecular Sequence Data, Biophysics, Rubrerythrin, Heme, Biochemistry, Article, Catalysis, Escherichia coli, Amino Acid Sequence, Sulfhydryl Compounds, NADH peroxidase, Molecular Biology, chemistry.chemical_classification, Bacteria, Sequence Homology, Amino Acid, biology, Cytochrome c peroxidase, Rubredoxins, Glutathione peroxidase, Hydrogen Peroxide, Cytochrome-c Peroxidase, Catalase, biology.organism_classification, Hemerythrin, Oxidative Stress, Phenotype, Enzyme, Models, Chemical, Peroxidases, chemistry, Mutation, biology.protein, Peroxidase

Abstract

Hydrogen peroxide (H(2)O(2)) is continuously formed by the autoxidation of redox enzymes in aerobic cells, and it also enters from the environment, where it can be generated both by chemical processes and by the deliberate actions of competing organisms. Because H(2)O(2) is acutely toxic, bacteria elaborate scavenging enzymes to keep its intracellular concentration at nanomolar levels. Mutants that lack such enzymes grow poorly, suffer from high rates of mutagenesis, or even die. In order to understand how bacteria cope with oxidative stress, it is important to identify the key enzymes involved in H(2)O(2) degradation. Catalases and NADH peroxidase (Ahp) are primary scavengers in many bacteria, and their activities and physiological impacts have been unambiguously demonstrated through phenotypic analysis and through direct measurements of H(2)O(2) clearance in vivo. Yet a wide variety of additional enzymes have been proposed to serve similar roles: thiol peroxidase, bacterioferritin comigratory protein, glutathione peroxidase, cytochrome c peroxidase, and rubrerythrins. Each of these enzymes can degrade H(2)O(2) in vitro, but their contributions in vivo remain unclear. In this review we examine the genetic, genomic, regulatory, and biochemical evidence that each of these is a bonafide scavenger of H(2)O(2) in the cell. We also consider possible reasons that bacteria might require multiple enzymes to catalyze this process, including differences in substrate specificity, compartmentalization, cofactor requirements, kinetic optima, and enzyme stability. It is hoped that the resolution of these issues will lead to an understanding of stress resistance that is more accurate and perceptive.

Published

2012

44. Effect of alternative distal residues on the reactivity of cytochrome c peroxidase: Properties of CcP mutants H52D, H52E, H52N, and H52Q

Author

James E. Erman, Lidia B. Vitello, and Miriam C. Foshay

Subjects

musculoskeletal diseases, Cytochrome, Stereochemistry, Mutant, Biophysics, Biochemistry, Article, Analytical Chemistry, Structure-Activity Relationship, chemistry.chemical_compound, immune system diseases, Structure–activity relationship, Histidine, Reactivity (chemistry), Asparagine, skin and connective tissue diseases, Molecular Biology, Heme, biology, Chemistry, Cytochrome c peroxidase, Cytochromes c, Hydrogen Peroxide, Cytochrome-c Peroxidase, Kinetics, Mutagenesis, Site-Directed, biology.protein, Oxidation-Reduction

Abstract

To test the effect of alternative bases at the distal histidine position, four CcP variants have been constructed that substitute the two basic residues, aspartate and glutamate, and their amides, asparagine and glutamine, for histidine-52, i.e., CcP(H52D), CcP(H52E), CcP(H52N), and CcP(H52Q). All four mutants catalyze oxidation of ferrocytochrome c by H(2)O(2) with steady-state activities that are between 250 and 7700 times slower than wild-type CcP at pH 6.0, 0.10M ionic strength, 25°C. The rate of Compound I formation is decreased between 3.5 and 5.4 orders of magnitude for the mutants compared to wild-type CcP, with the rate of the reaction between CcP(H52Q) and H(2)O(2) the slowest yet observed for any CcP mutant. A correlation between the rate of Compound I formation and the rate of HCN binding for CcP and various CcP distal pocket mutants provides strong evidence that the rate-limiting step in CcP Compound I formation is deprotonation of H(2)O(2) within the distal heme pocket under the experimental conditions employed in this study. While CcP(H52E) reacts stoichiometrically with H(2)O(2) to form Compound I, only ~36% of CcP(H52D), ~21% of CcP(H52Q) and ~8% of CcP(H52N) appear to be converted to Compound I during their respective reactions with H(2)O(2). This is partially due to the slow rate of Compound I formation and the rapid endogenous decay of Compound I for these mutants. The pathways for the endogenous decay of Compound I for the four mutants used in this study are distinct from that of wild-type CcP Compound I.

Published

2011

45. Ascorbate peroxidase activity of cytochromec

Author

Badri S. Rajagopal, Florina Deac, Radu Silaghi-Dumitrescu, Cristina Bischin, Jonathan A. R. Worrall, Chris E. Cooper, and Grigore Damian

Subjects

Free Radicals, Cardiolipins, Iron, Apoptosis, Ascorbic Acid, Heme, Methylation, Biochemistry, Mitochondria, Heart, chemistry.chemical_compound, Cytochrome C1, Yeasts, Animals, Cytochrome c oxidase, Horses, Guanidine, biology, Cytochrome c peroxidase, Chemistry, Spectrum Analysis, Cytochrome c, Cytochromes c, Cytochrome P450 reductase, Hydrogen Peroxide, General Medicine, Cytochrome-c Peroxidase, Kinetics, Coenzyme Q – cytochrome c reductase, biology.protein, Cattle, Signal Transduction, Peroxidase

Abstract

The peroxidase-type reactivity of cytochrome c is proposed to play a role in free radical production and/or apoptosis. This study describes cytochrome c catalysis of peroxide consumption by ascorbate. Under conditions where the sixth coordination position at the cytochrome c heme iron becomes more accessible for exogenous ligands (by carboxymethylation, cardiolipin addition or by partial denaturation with guanidinium hydrochloride) this peroxidase activity is enhanced. A reaction intermediate is detected by stopped-flow UV-vis spectroscopy upon reaction of guanidine-treated cytochrome c with peroxide, which resembles the spectrum of globin Compound II species and is thus proposed to be a ferryl species. The ability of physiological levels of ascorbate (10-60 µM) to interact with this species may have implications for mechanisms of cell signalling or damage that are based on cytochrome c/peroxide interactions.

Published

2010

46. Identification of a bacterial di-haem cytochrome c peroxidase from Methylomicrobium album BG8

Author

Harald B. Jensen, Odd André Karlsen, and Øivind Larsen

Subjects

Operon, Molecular Sequence Data, Heme, Microbiology, Bacterial Proteins, Amino Acid Sequence, Cloning, Molecular, Peptide sequence, Methylococcus capsulatus, Base Sequence, biology, Cytochrome c peroxidase, Cytochrome c, Nucleic acid sequence, Periplasmic space, Cytochrome-c Peroxidase, biology.organism_classification, Molecular biology, Protein Transport, Biochemistry, Methylococcaceae, biology.protein, Sequence Alignment, Peroxidase

Abstract

The nucleotide sequence of an open reading frame (corB) downstream of the copper-repressible CorA-encoding gene of the methanotrophic bacterium Methylomicrobium album BG8 was obtained by restriction enzyme digestion and inverse PCR. The amino acid sequence deduced from this gene showed significant sequence similarity to the surface-associated di-haem cytochrome c peroxidase (SACCP) previously isolated from Methylococcus capsulatus (Bath), including both c-type haem-binding motifs. Homology analysis placed this protein, phylogenetically, within the subfamily containing the M. capsulatus SACCP of the bacterial di-haem cytochrome c peroxidase (BCCP) family of proteins. Immunospecific recognition confirmed synthesis of the M. album CorB as a protein non-covalently associated with the outer membrane and exposed to the periplasm. corB expression is regulated by the availability of copper ions during growth and the protein is most abundant in M. album when grown at a low copper-to-biomass ratio, indicating an important physiological role of CorB under these growth conditions. corB was co-transcribed with the gene encoding CorA, constituting a copper-responding operon, which appears to be under the control of a σ 54-dependent promoter. M. album CorB is the second isolated member of the recently described subfamily of the BCCP family of proteins. So far, these proteins have only been described in methanotrophic bacteria.

Published

2010

47. Engineering the Substrate Specificity and Reactivity of a Heme Protein: Creation of an Ascorbate Binding Site in Cytochrome c Peroxidase

Author

Jaswir Basran, Peter C. E. Moody, Emma Lloyd Raven, Emma J. Murphy, and Clive Metcalfe

Subjects

Hemeproteins, Binding Sites, Hemeprotein, biology, Cytochrome c peroxidase, Stereochemistry, Substrate (chemistry), Ascorbic Acid, Cytochrome-c Peroxidase, Crystallography, X-Ray, Protein Engineering, Ascorbic acid, Biochemistry, Porphyrin, Substrate Specificity, chemistry.chemical_compound, Amino Acid Substitution, chemistry, biology.protein, Binding site, Oxidation-Reduction, Heme, Peroxidase

Abstract

The binding of substrates to heme enzymes has been widely assumed to occur at the so-called delta-heme edge. Recently, however, a number of examples have appeared in which substrate binding at an alternative site, the gamma-heme edge, is also possible. In previous work [Sharp et al. (2003) Nat. Struct. Biol. 10, 303-307], we showed that binding of ascorbate to ascorbate peroxidase occurred at the gamma-heme edge. Here, we show that the closely related cytochrome c peroxidase enzyme can duplicate the substrate binding properties of ascorbate peroxidase through the introduction of relatively modest structural changes at Tyr36 and Asn184. Hence, crystallographic data for the Y36A/N184R/W191F triple variant of cytochrome c peroxidase shows ascorbate bound to the gamma-heme edge, with hydrogen bonds to the heme propionate and Arg184. In parallel mechanistic studies in variants incorporating the W191F mutation, we show that a transient porphyrin pi-cation radical in Compound I of cytochrome c peroxidase, analogous to that observed in ascorbate peroxidase, is competent for ascorbate oxidation but that under steady state conditions this intermediate decays too rapidly to sustain efficient turnover of ascorbate. The results are discussed in terms of our more general understanding of substrate oxidation across other heme proteins, and the emerging role of the heme propionates at the gamma-heme edge.

Published

2008

48. Engineering Ascorbate Peroxidase Activity into Cytochrome c Peroxidase

Author

B. Bhaskar, Thomas L. Poulos, Patricia Oertel, and Yergalem T. Meharenna

Subjects

Models, Molecular, musculoskeletal diseases, Protein Conformation, Molecular Sequence Data, Ascorbic Acid, Arginine, Crystallography, X-Ray, Protein Engineering, Biochemistry, Article, chemistry.chemical_compound, Ascorbate Peroxidases, immune system diseases, Oxidoreductase, Binding site, skin and connective tissue diseases, Heme, chemistry.chemical_classification, Binding Sites, Base Sequence, biology, Cytochrome c peroxidase, food and beverages, Cytochrome-c Peroxidase, Ascorbic acid, APX, Peroxidases, chemistry, Mutagenesis, Site-Directed, biology.protein, Peroxidase

Abstract

Cytochrome c peroxidase (CCP) and ascorbate peroxidase (APX) have very similar structures, and yet neither CCP nor APX exhibits each other's activities with respect to reducing substrates. APX has a unique substrate binding site near the heme propionates where ascorbate H-bonds with a surface Arg and one heme propionate (Sharp et al. (2003) Nat. Struct. Biol. 10, 303-307). The corresponding region in CCP has a much longer surface loop, and the critical Arg residue that is required for ascorbate binding in APX is Asn in CCP. In order to convert CCP into an APX, the ascorbate-binding loop and critical arginine were engineered into CCP to give the CCP2APX mutant. The mutant crystal structure shows that the engineered site is nearly identical to that found in APX. While wild-type CCP shows no APX activity, CCP2APX catalyzes the peroxidation of ascorbate at a rate of approximately 12 min (-1), indicating that the engineered ascorbate-binding loop can bind ascorbate.

Published

2008

49. Calcium-Dependent Heme Structure in the Reduced Forms of the Bacterial Cytochrome c Peroxidase from Paracoccus pantotrophus

Author

John A. Shelnutt, Sofia R. Pauleta, Isabel Moura, Graham W. Pettigrew, Celia F. Goodhew, and Yi Lu

Subjects

Protein Conformation, Stereochemistry, Molecular Conformation, chemistry.chemical_element, Heme, Calcium, Spectrum Analysis, Raman, Biochemistry, Enzyme activator, chemistry.chemical_compound, Protein structure, Cations, medicine, Magnesium, Ions, chemistry.chemical_classification, Paracoccus pantotrophus, Chemistry, Cytochrome c peroxidase, Cytochrome-c Peroxidase, Enzyme Activation, Oxygen, Enzyme, Models, Chemical, Ferric, medicine.drug

Abstract

This work reports for the first time a resonance Raman study of the mixed-valence and fully reduced forms of Paracoccus pantotrophus bacterial cytochrome c peroxidase. The spectra of the active mixed-valence enzyme show changes in the structure of the ferric peroxidatic heme compared to the fully oxidized enzyme; these differences are observed upon reduction of the electron-transferring heme and upon full occupancy of the calcium site. For the mixed-valence form in the absence of Ca(2+), the peroxidatic heme is six-coordinate and low-spin on the basis of the frequencies of the structure-sensitive Raman lines: the enzyme is inactive. With added Ca(2+), the peroxidatic heme is five-coordinate high-spin and active. The calcium-dependent spectral differences indicate little change in the conformation of the ferrous electron-transferring heme, but substantial changes in the conformation of the ferric peroxidatic heme. Structural changes associated with Ca(2+) binding are indicated by spectral differences in the structure-sensitive marker lines, the out-of-plane low-frequency macrocyclic modes, and the vibrations associated with the heme substituents of that heme. The Ca(2+)-dependent appearance of a strong gamma 15 saddling-symmetry mode for the mixed-valence form is consistent with a strong saddling deformation in the active peroxidatic heme, a feature seen in the Raman spectra of other peroxidases. For the fully reduced form in the presence of Ca(2+), the resonance Raman spectra show that the peroxidatic heme remains high-spin.

Published

2008

50. Mapping protein electron transfer pathways with QM/MM methods

Author

Victor Guallar and Frank H. Wallrapp

Subjects

Models, Molecular, Camphor 5-Monooxygenase, Cytochrome, Stereochemistry, Biomedical Engineering, Biophysics, Electrons, Bioengineering, Heme, Biochemistry, Electron Transport, Biomaterials, QM/MM, Electron transfer, Ascorbate Peroxidases, Cytochrome C1, biology, Cytochrome c peroxidase, Chemistry, Cytochrome c, Cytochrome-c Peroxidase, Electron transport chain, Models, Chemical, Peroxidases, biology.protein, Quantum Theory, Research Article, Biotechnology, Peroxidase

Abstract

Mixed quantum mechanics/molecular mechanics (QM/MM) methods offer a valuable computational tool for understanding the electron transfer pathway in protein–substrate interactions and protein–protein complexes. These hybrid methods are capable of solving the Schrödinger equation on a small subset of the protein, the quantum region, describing its electronic structure under the polarization effects of the remainder of the protein. By selectively turning on and off different residues in the quantum region, we are able to obtain the electron pathway for short- and large-range interactions. Here, we summarize recent studies involving the protein–substrate interaction in cytochrome P450 camphor, ascorbate peroxidase and cytochrome c peroxidase, and propose a novel approach for the long-range protein–protein electron transfer. The results on ascorbate peroxidase and cytochrome c peroxidase reveal the importance of the propionate groups in the electron transfer pathway. The long-range protein–protein electron transfer has been studied on the cytochrome c peroxidase–cytochrome c complex. The results indicate the importance of Phe82 and Cys81 on cytochrome c , and of Asn196, Ala194, Ala176 and His175 on cytochrome c peroxidase.

Published

2008