Resonance Raman spectra of Pseudomonas cytochrome c peroxidase

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

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.

Resonance Raman spectroscopy of cytochrome c peroxidase variants that mimic manganese peroxidase

Cytochrome c peroxidase (C cP) variants with an engineered Mn(II) binding site, including MnC cP [C cP(MI, G41E, V45E, H181D)], MnC cP(W191F), and MnC cP(W191F, W51F), that mimic manganese peroxidase (MnP), have been characterized by resonance Raman (RR) spectroscopy. Analysis of the Raman bands in the 200-700 cm(-1) and 1300-1650 cm(-1) regions indicates that both the coordination and spin state of the heme iron in the variants differ from that of C cP(MI), the recombinant yeast C cP containing additional Met-Ile residues at the N-terminus. At neutral pH the frequencies of the nu(3) mode indicate that a pure five-coordinate heme iron exists in C cP(MI) whereas a six-coordinate low-spin iron is the dominant species in the C cP variants with the engineered Mn(II) binding site. The H181D mutation, which weakens the proximal linkage to the heme iron, may be responsible for these spectral and structural changes. Raman spectra of the variants C cP(MI, W191F) and C cP(MI, W191F, W51F) were also obtained to clarify the structural and functional roles of mutations at two tryptophan sites. The W51F mutation was found to disrupt H-bonding to the distal water molecules and the resulting variants tended to form transitional or mixed coordination states that possess spectral and structural features similar to that of MnP. Such structural features, with a loosened distal water, may facilitate the binding of H(2)O(2) and increase the rate constant for compound I formation. This effect, in addition to the elimination of an H-bond to ferryl oxygen by the same mutation, accounts for the increased MnP specific activity of MnC cP(W191F, W51F).

Calcium-dependent conformation of a heme and fingerprint peptide of the diheme cytochrome c peroxidase from Paracoccus pantotrophus

The structural changes in the heme macrocycle and substituents caused by binding of Ca(2+) to the diheme cytochrome c peroxidase from Paracoccus pantotrophus were clarified by resonance Raman spectroscopy of the inactive fully oxidized form of the enzyme. The changes in the macrocycle vibrational modes are consistent with a Ca(2+)-dependent increase in the out-of-plane distortion of the low-potential heme, the proposed peroxidatic heme. Most of the increase in out-of-plane distortion occurs when the high-affinity site I is occupied, but a small further increase in distortion occurs when site II is also occupied by Ca(2+) or Mg(2+). This increase in the heme distortion explains the red shift in the Soret absorption band that occurs upon Ca(2+) binding. Changes also occur in the low-frequency substituent modes of the heme, indicating that a structural change in the covalently attached fingerprint pentapeptide of the LP heme occurs upon Ca(2+) binding to site I. These structural changes may lead to loss of the sixth ligand at the peroxidatic heme in the semireduced form of the enzyme and activation.

Mössbauer characterization of Paracoccus denitrificans cytochrome c peroxidase. Further evidence for redox and calcium binding-induced heme-heme interaction

Mössbauer and electron paramagnetic resonance (EPR) spectroscopies were used to characterize the diheme cytochrome c peroxidase from Paracoccus denitrificans (L.M.D. 52.44). The spectra of the oxidized enzyme show two distinct spectral components characteristic of low spin ferric hemes (S = 1/2), revealing different heme environments for the two heme groups. The Paracoccus peroxidase can be non-physiologically reduced by ascorbate. Mössbauer investigation of the ascorbate-reduced peroxidase shows that only one heme (the high potential heme) is reduced and that the reduced heme is diamagnetic (S = 0). The other heme (the low potential heme) remains oxidized, indicating that the enzyme is in a mixed valence, half-reduced state. The EPR spectrum of the half-reduced peroxidase, however, shows two low spin ferric species with gmax = 2.89 (species I) and gmax = 2.78 (species II). This EPR observation, together with the Mössbauer result, suggests that both species are arising from the low potential heme. More interestingly, the spectroscopic properties of these two species are distinct from that of the low potential heme in the oxidized enzyme, providing evidence for heme-heme interaction induced by the reduction of the high potential heme. Addition of calcium ions to the half-reduced enzyme converts species II to species I. Since calcium has been found to promote peroxidase activity, species I may represent the active form of the peroxidatic heme.

Nucleotide sequence encoding the di-haem cytochrome c551 peroxidase from Pseudomonas aeruginosa

The nucleotide sequence of the gene encoding cytochrome c551 peroxidase from Pseudomonas aeruginosa is reported. The translated amino acid sequence differs from the sequence reported earlier by peptide mapping most significantly by the presence of a section containing an additional 20 residues. A number of minor differences are also evident. The new sequence translates to a protein containing 346 amino acids, the first 23 being typical of a hydrophobic leader peptide with a characteristic protease cleavage site.

Spectroscopic characterization of cytochrome c peroxidase from Paracoccus denitrificans

The cytochrome c peroxidase of Paracoccus denitrificans is similar to the well-studied enzyme from Pseudomonas aeruginosa. Like the Pseudomonas enzyme, the Paracoccus peroxidase contains two haem c groups, one high potential and one low potential. The high-potential haem acts as a source of the second electron for H2O2 reduction, and the low-potential haem acts as a peroxidatic centre. Reduction with ascorbate of the high-potential haem of the Paracoccus enzyme results in a switch of the low-potential haem to a high-spin state, as shown by visible and n.m.r. spectroscopy. This high-spin haem of the mixed-valence enzyme is accessible to ligands and binds CN- with a KD of 5 microM. The Paracoccus enzyme is significantly different from that from Pseudomonas in the time course of high-spin formation after reduction of the high-potential haem, and in the requirement for bivalent cations. Reduction with 1 mM ascorbate at pH 6 is complete within 2 min, and this is followed by a slow appearance of the high-spin state with a half-time of 10 min. Thus the process of reduction and spin state change can be easily separated in time and the intermediate form obtained. This separation is also evident in e.p.r. spectra, although the slow change involves an alteration in the low-spin ligation at this temperature rather than a change in spin state. The separation is even more striking at pH 7.5, where no high-spin form is obtained until 1 mM Ca2+ is added to the mixed-valence enzyme. The spin-state switch of the low-potential haem shifts the midpoint redox potential of the high-potential haem by 50 mV, a further indication of haem-haem interaction.

A quantitative model for the mechanism of action of the cytochrome c peroxidase of Pseudomonas aeruginosa

Each of the elementary reaction steps in both the activation process and catalytic cycle of the cytochrome c peroxidase of Pseudomonas aeruginosa was characterized using stopped-flow methods. A synthesis of these data led to the establishment of a quantitative model for the action of this enzyme. Comparisons were made between experimental data and calculations over a wide range of enzyme, reductant and H2O2 concentrations. Close agreement was found between empirical and simulated reaction time courses from millisecond to tens of seconds time ranges, giving us confidence in the validity of the quantitative model of this enzyme's actions.

Structural and functional features of Pseudomonas cytochrome c peroxidase

The secondary structure of Pseudomonas cytochrome c peroxidase (ferrocytochrome c: hydrogen-peroxide oxidoreductase, EC 1.11.1.5) has been predicted from the established amino acid sequence of the enzyme using a Chou-Fasman-type algorithm. The amount of alpha-helicity thus obtained is in agreement with previously obtained results based on circular dichroic measurements at far UV. The two heme c moieties of the enzyme have earlier been shown to have widely different characteristics, e.g., the redox potentials of the hemes differ with about 600 mV, and carry out different functions in the enzyme molecule. The structural comparisons made in this study enlighten the observed functional differences. The first heme in the polypeptide chain, heme 1, has in its environment a folding pattern generally encountered in cytochromes. In the region of the sixth ligand, however, profound differences are noted. The cytochromal methionine has been replaced by a lysine with a concomitant lowering of redox-potential thus making peroxidatic activity possible. Around heme 2, extra amino acid residues have been added to the peroxidase as compared with Rhodospirillum molischianum cytochrome c2 core structure in the 20's loop. After completion of the cytochromal fold around heme 2 an additional tail consisting of 25 residues is linked. This tail shows no stabilizing elements of secondary structure, but contains a strongly hydrophobic segment which suggests a possible membrane contact site of this extrinsic membrane protein. Heme 2 is concluded to have a cytochromal function in the molecule. To further elucidate the functional properties of the enzyme, a noncovalent two-fragment complex was produced by specific cleavage of the peroxidase by Pseudomonas elastase. The complex was studied with respect to its properties to the native enzyme. The two-fragment complex of Pseudomonas peroxidase retains the overall conformation of the native enzyme showing, however, no heme-heme interaction. Thus, a comparison of the properties of the native enzyme with those of the two-fragment complex permitted some conclusions to be drawn on the structure of the enzyme as well as the mechanism of heme-heme interaction. From the present results we conclude that the two distal heme surfaces in the peroxidase are oriented toward each other. This structural arrangement allows an inter-heme communication in the enzyme molecule and it also forms the structural basis for the enzyme mechanism. The structural comparisons also give insight into the evolution of an ancestral cytochrome c into an efficient peroxidase that has a versatile control mechanism in heme-heme interaction.

The cellular location and specificity of bacterial cytochrome c peroxidases

The locations of cytochrome c peroxidase and catalase activities in the two Gram-negative bacteria Pseudomonas stutzeri (N.C.I.B. 9721) and Paracoccus denitrificans (N.C.I.B. 8944) were investigated by the production of spheroplasts. In both species the cytochrome c peroxidase was predominantly periplasmic: 92% of total activity in Ps. stutzeri and 98% of nonmembrane-bound activity in Pa. denitrificans were found in this cellular compartment. In contrast, the catalase was mostly in the cytoplasmic fraction. Purification of the Pa. denitrificans cytochrome c peroxidase showed it to be the haem c-containing polypeptide of Mr 42,000 that has already been described by Bosma, Braster, Stouthamer & Van Versefeld [(1987) Eur. J. Biochem. 165, 665-670] but was not identified by them as a peroxidase. The visible-absorption spectra of the enzyme closely resemble those of cytochrome c peroxidase from Pseudomonas aeruginosa but the donor specificity is different, with the Pa. denitrificans enzyme preferring the basic mitochondrial cytochromes c to the acidic cytochromes c-551 and reacting well with the Pa. denitrificans cytochrome c-550.

The primary structure of Pseudomonas cytochrome c peroxidase

The primary structure of Pseudomonas cytochrome c peroxidase is presented. The intact protein was fragmented with cyanogen bromide into five fragments; partial cleavage was observed at a Met-His bond of the protein. The primary structure was established partly by automatic Edman degradations, partly by manual sequencing of peptides obtained with trypsin, thermolysin, chymotrypsin, pepsin, subtilisin and Staphylococcus aureus V8 endopeptidase. The order of the cyanogen bromide fragments was further confirmed by overlapping peptides obtained by specific cleavage of the whole protein. Pseudomonas cytochrome c peroxidase consists of 302 amino acid residues giving a calculated Mr of 33690.

Specific cleavage of Pseudomonas cytochrome-c peroxidase by elastase from Pseudomonas aeruginosa

The occasional cleavage of the Pseudomonas cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) molecule into two well-defined fragments during the preparation of the enzyme is shown to be identical to that caused by elastase isolated from the culture solution of Pseudomonas aeruginosa. A cyanogen bromide fragmentation of proteolytically cleaved and of intact enzyme shows the cleaved peptide bond to be situated in cyanogen bromide fragment II. The amino-acid sequence of this fragment was established by sequencing peptides obtained with trypsin, thermolysin, chymotrypsin and o-iodosobenzoate. It is concluded from the sequence homology that the polypeptide chain of Pseudomonas peroxidase is wrapped around the high-potential heme in a similar manner as in high-potential cytochromes c in general. The specific proteolytic cleavage occurs at a Ser-Val (Leu-Pro) region which is assumed to be the site of attachment between enzyme and membrane. The cleavage of the Ser-Val bond renders the peroxidase molecule enzymatically inactive by impeding the conformational changes essential for the function of the native enzyme.

Redox-linked spin-state changes in the di-haem cytochrome c-551 peroxidase from Pseudomonas aeruginosa

Magnetic-c.d., e.p.r. and optical-absorption spectra are reported for the half-reduced form of Pseudomonas aeruginosa cytochrome c-551 peroxidase, a di-haem protein, and its fluoride derivative. Comparison of this enzyme species with oxidized peroxidase shows the occurrence of spin-state changes at both haem sites. The high-potential haem changes its state from partially high-spin to low-spin upon reduction. This is linked to a structural alteration at the ferric low-potential haem group, causing it to change from low-spin to high-spin. Low-temperature spectra demonstrate photolysis of an endogenous ligand of the high-potential haem. In addition, an inactive form of enzyme is examined in which the structural change at the ferric low-potential haem does not occur on reduction of the high-potential haem.

A rapid-scan spectrometric and stopped-flow study of compound I and compound II of Pseudomonas cytochrome c peroxidase

A quantitative yield of half-reduced (ferrous-ferric) cytochrome c peroxidase from Pseudomonas aeruginosa has been obtained by using either ascorbate or NADH as reductant of the resting (ferric-ferric) enzyme along with phenazine methosulfate as mediator. The formation of Compounds I and II from the half-reduced enzyme and hydrogen peroxide has been studied at 25 degrees C using rapid-scan spectrometry and stopped-flow measurements. The spectra of Compound I in the Soret and visible regions were recorded within 5 ms after mixing the half-reduced enzyme with H2O2. The spectrum of the primary compound at the Soret region had a maximum at 414 nm, and in the visible region at 528 and 556 nm. The spectrum of Compound I showed no bands in the 650-nm region, excluding the possibility of a pi-cation radical being part of the catalytic mechanism. Compound I was stable for at least 12 s when no reducing equivalents were present. In the presence of reduced azurin, half-reduced enzyme reacted with H2O2 to form Compound II within 50 ms. The spectrum of Compound II had a Soret maximum at 411 nm. In the visible region the Compound II spectrum was close to that of the totally oxidized, resting enzyme form. In the presence of excess azurin, Compound II was converted rapidly to the half-reduced enzyme form. The kinetics of Compound I formation was also followed with peracetic acid, ethylhydroperoxide, and m-chloroperbenzoic acid as electron acceptors. The rate constants of these reactions are diminished compared to that of hydrogen peroxide, indicating a closed structure for the heme pocket of the enzyme.

A study of the oxidized form of Pseudomonas aeruginosa cytochrome c-551 peroxidase with the use of magnetic circular dichroism

The magnetic properties at different temperatures of oxidized Pseudomonas aeruginosa cytochrome c-551 peroxidase were studied, with the use of the technique of magnetic-circular-dichroism spectroscopy. At 4.2K, both constituent haems were found to be low-spin, and the axial ligand pairs were identified as histidine-histidine and histidine-methionine. At room temperature high-spin signals were observed, amounting to less than 25% of the total haem present. These signals are concluded to arise mainly from a temperature-dependent spin-state equilibrium in the methionine-ligated haem.

The nature of species prepared by photolysis of half-reduced, fully reduced and fully reduced carbonmonoxy-cytochrome c-551 peroxidase from Pseudomonas aeruginosa

The half-reduced, fully reduced and fully reduced CO-bound forms of the enzyme cytochrome c-551 peroxidase isolated from Pseudomonas aeruginosa were examined by a combination of low-temperature absorption and magnetic-circular-dichroism spectroscopy. Deliberate low-temperature (4.2K) photolysis of these forms of the enzyme, in all of which the high-potential haem is in the ferrous state, revealed that this haem group, assigned to have a histidine-methionine ligand set, is photosensitive. The photolabile ligand is most likely to be the methionine residue, and the product of photolysis, namely the high-spin (S = 2) ferrous form, is stable at low temperature (4.2K). Warming to approx. 20K allows thermal recombination to occur, restoring the low-spin (S = 0) state. The low-potential haem (bis-histidine ligation) is photoinert in both ferric and ferrous states; however, the photosensitive CO adduct of this centre cannot be maintained as the photolysed (S = 2) product at 4.2K. This surprising observation may be due to quantum-mechanical tunnelling of the CO through the activation barrier even at 4.2K, implying that the activation barrier to thermal recombination is both narrow and low. Low-temperature absorption spectroscopy reveals that the high-potential haem has a very characteristic low-spin ferrous spectrum with intense highly structured beta- and split alpha-bands, whereas the spectrum of the low-potential ferrous haem contains alpha- and beta-bands devoid of fine structure.

Anion binding to resting and half-reduced Pseudomonas cytochrome c peroxidase

The anion-binding characteristics of resting and half-reduced Pseudomonas cytochrome c peroxidase (ferrocytochrome c-551: hydrogen peroxide oxidoreductase, EC 1.11.1.5) have been examined by EPR and optical spectroscopy with cyanide, azide and fluoride as ligands. The resting enzyme was found to be essentially inaccessible for ligation, which indicates that it has a closed conformation. In contrast, the half-reduced enzyme has a conformation in which the low-potential heme is easily accessible for ligands, a behavior parallel to that towards the substrate hydrogen peroxide (Rönnberg, M., Araiso, T., Ellfolk, N. and Dunford, H.B. (1981) Arch. Biochem. Biophys. 207, 197-204). Cyanide and azide caused distinct changes in the low-potential heme c moiety, and the gz values of the two low-spin derivatives were 3.14 and 3.22, respectively. Fluoride binds to the same heme, giving rise to a high-spin signal at g = 6. The dissociation constants of the anions differ widely from each other, the values for the cyanide, azide and fluoride being 23 microM, 2.5 mM and 0.13 M, respectively. In addition, a partial shift of the low-spin peak at g = 2.84 of the half-reduced species to 3.24 was observed even at low concentrations of fluoride.

Pseudomonas cytochrome C-551 peroxidase. A purification procedure and study of CO-binding kinetics

A procedure is described for the purification of cytochrome c peroxidase from Pseudomonas aeruginosa involving extraction by sonication, followed by acid precipitation and chromatography on only two types of gel. The final preparation had a purity ratio A407/A280 of 4.2, and was found to be essentially pure by isoelectric focusing. The enzyme was shown to be unstable during degassing under vacuum except in the presence of detergent. The kinetics of CO binding to dithionite-reduced peroxidase were studied with stopped-flow and flash-photolysis techniques, and the results obtained between pH 5 and 7 suggest the existence of two forms of dithionite-reduced enzyme in slow equilibrium.

Properties and function of the two hemes in Pseudomonas cytochrome c peroxidase

The oxidation-reduction potentials of the two c-type hemes of Pseudomonas aeruginosa cytochrome c peroxidase (ferrocytochrome c:hydrogen-peroxide oxidoreductase EC 1.11.1.5) have been determined and found to be widely different, about +320 and -330 mV, respectively. The EPR spectrum at temperatures below 77 K reveals only low-spin signals (gz 3.24 and 2.93), whereas optical spectra at room temperature indicate the presence of one high-spin and one low-spin heme in the enzyme. Optical absorption spectra of both resting and half-reduced enzyme at 77 K lack features of a high-spin compound. It is concluded that the heme ligand arrangement changes on cooling from 298 to 77 K with a concomitant change in the spin state. The active form of the peroxidase is the half-reduced enzyme, in which one heme is in the ferrous and the other in the ferric state (low-spin below 77 K with gz 2.84). Reaction of the half-reduced enzyme with hydrogen peroxide forms Compound I with the hemes predominantly in the ferric (gz 3.15) and the ferryl states. Compound I has a half-life of several seconds and is converted into Compound II apparently having a ferric-ferric structure, characterized by an EPR peak at g 3.6 with unusual temperature and relaxation behavior. Rapid-freeze experiments showed that Compound II is formed in a one-electron reduction of Compound I. The rates of formation of both compounds are consistent with the notion that they are involved in the catalytic cycle.

Electron paramagnetic resonance studies of Pseudomonas cytochrome c peroxidase

The EPR spectrum at 15 K of Pseudomonas cytochrome c peroxidase, which contains two hemes per molecule, is in the totally ferric form characteristic of low-spin heme giving two sets of g-values with gz 3.26 and 2.94. These values indicate an imidazole-nitrogen : heme-iron : methionine-sulfur and an imidazole-nitrogen : heme-iron : imidazole-nitrogen hemochrome structure, respectively. The spectrum is essentially identical at pH 6.0 and 4.6 and shows only a very small amount of high-spin heme iron (g 5--6) also at 77 K. Interaction between the two hemes is shown to exist by experiments in which one heme is reduced. This induces a change of the EPR signal of the other (to gz 2.83, gy 2.35 and gx 1.54), indicative of the removal of a histidine proton from that heme, which is axially coordinated to two histidine residues. If hydrogen peroxide is added to the partially reduced protein, its EPR signal is replaced by still other signals (gz 3.5 and 3.15). Only a very small free radical peak could be observed consistent with earlier mechanistic proposals. Contrary to the EPR spectra recorded at low temperature, the optical absorption spectra of both totally oxidized and partially reduced enzyme reveal the presence of high-spin heme at room temperature. It seems that a transition of one of the heme c moieties from an essentially high-spin to a low-spin form takes place on cooling the enzyme from 298 to 15 K.