Proton NMR investigation into the basis for the relatively high redox potential of lignin peroxidase

Increase of Redox Potential during the Evolution of Enzymes Degrading Recalcitrant Lignin

To investigate how ligninolytic peroxidases acquired the uniquely high redox potential they show today, their ancestors were resurrected and characterized. Unfortunately, the transient Compounds I (CI) and II (CII) from peroxide activation of the enzyme resting state (RS) are unstable. Therefore, the reduction potentials (E°') of the three redox couples (CI/RS, CI/CII and CII/RS) were estimated (for the first time in a ligninolytic peroxidase) from equilibrium concentrations analyzed by stopped-flow UV/Vis spectroscopy. Interestingly, the E°' of rate-limiting CII reduction to RS increased 70 mV from the common peroxidase ancestor to extant lignin peroxidase (LiP), and the same boost was observed for CI/RS and CI/CII, albeit with higher E°' values. A straightforward correlation was found between the E°' value and the progressive displacement of the proximal histidine Hϵ1 chemical shift in the NMR spectra, due to the higher paramagnetic effect of the heme Fe3+ . More interestingly, the E°' and NMR data also correlated with the evolutionary time, revealing that ancestral peroxidases increased their reduction potential in the evolution to LiP thanks to molecular rearrangements in their heme pocket during the last 400 million years.

Experimental recreation of the evolution of lignin-degrading enzymes from the Jurassic to date

BACKGROUND

Floudas et al. (Science 336: 1715) established that lignin-degrading fungi appeared at the end of Carboniferous period associated with the production of the first ligninolytic peroxidases. Here, the subsequent evolution of these enzymes in Polyporales, where most wood-rotting fungi are included, is experimentally recreated using genomic information.

RESULTS

With this purpose, we analyzed the evolutionary pathway leading to the most efficient lignin-degrading peroxidases characterizing Polyporales species. After sequence reconstruction from 113 genes of ten sequenced genomes, the main enzyme intermediates were resurrected and characterized. Biochemical changes were analyzed together with predicted sequences and structures, to understand how these enzymes acquired the ability to degrade lignin and how this ability changed with time. The most probable first peroxidase in Polyporales would be a manganese peroxidase (Mn³⁺ oxidizing phenolic lignin) that did not change substantially until the appearance of an exposed tryptophan (oxidizing nonphenolic lignin) originating an ancestral versatile peroxidase. Later, a quick evolution, with loss of the Mn²⁺-binding site, generated the first lignin peroxidase that evolved to the extant form by improving the catalytic efficiency. Increased stability at acidic pH, which strongly increases the oxidizing power of these enzymes, was observed paralleling the appearance of the exposed catalytic tryptophan.

CONCLUSIONS

We show how the change in peroxidase catalytic activities meant an evolutionary exploration for more efficient ways of lignin degradation by fungi, a key step for carbon recycling in land ecosystems. The study provides ancestral enzymes with a potential biotechnological interest for the sustainable production of fuels and chemicals in a biomass-based economy.

Immobilized Lignin Peroxidase-Like Metalloporphyrins as Reusable Catalysts in Oxidative Bleaching of Industrial Dyes

Synthetic and bioinspired metalloporphyrins are a class of redox-active catalysts able to emulate several enzymes such as cytochromes P450, ligninolytic peroxidases, and peroxygenases. Their ability to perform oxidation and degradation of recalcitrant compounds, including aliphatic hydrocarbons, phenolic and non-phenolic aromatic compounds, sulfides, and nitroso-compounds, has been deeply investigated. Such a broad substrate specificity has suggested their use also in the bleaching of textile plant wastewaters. In fact, industrial dyes belong to very different chemical classes, being their effective and inexpensive oxidation an important challenge from both economic and environmental perspective. Accordingly, we review here the most widespread synthetic metalloporphyrins, and the most promising formulations for large-scale applications. In particular, we focus on the most convenient approaches for immobilization to conceive economical affordable processes. Then, the molecular routes of catalysis and the reported substrate specificity on the treatment of the most diffused textile dyes are encompassed, including the use of redox mediators and the comparison with the most common biological and enzymatic alternative, in order to depict an updated picture of a very promising field for large-scale applications.

Unveiling the basis of alkaline stability of an evolved versatile peroxidase

A variant of high biotechnological interest (called 2-1B) was obtained by directed evolution of the Pleurotus eryngii VP (versatile peroxidase) expressed in Saccharomyces cerevisiae [García-Ruiz, González-Pérez, Ruiz-Dueñas, Martínez and Alcalde (2012) Biochem. J. 441, 487–498]. 2-1B shows seven mutations in the mature protein that resulted in improved functional expression, activity and thermostability, along with a remarkable stronger alkaline stability (it retains 60% of the initial activity after 120 h of incubation at pH 9 compared with complete inactivation of the native enzyme after only 1 h). The latter is highly demanded for biorefinery applications. In the present study we investigate the structural basis behind the enhanced alkaline stabilization of this evolved enzyme. In order to do this, several VP variants containing one or several of the mutations present in 2-1B were expressed in Escherichia coli, and their alkaline stability and biochemical properties were determined. In addition, the crystal structures of 2-1B and one of the intermediate variants were solved and carefully analysed, and molecular dynamics simulations were carried out. We concluded that the introduction of three basic residues in VP (Lys-37, Arg-39 and Arg-330) led to new connections between haem and helix B (where the distal histidine residue is located), and formation of new electrostatic interactions, that avoided the hexa-co-ordination of the haem iron. These new structural determinants stabilized the haem and its environment, helping to maintain the structural enzyme integrity (with penta-co-ordinated haem iron) under alkaline conditions. Moreover, the reinforcement of the solvent-exposed area around Gln-305 in the proximal side, prompted by the Q202L mutation, further enhanced the stability.

Design and fine-tuning redox potentials of metalloproteins involved in electron transfer in bioenergetics

Redox potentials are a major contributor in controlling the electron transfer (ET) rates and thus regulating the ET processes in the bioenergetics. To maximize the efficiency of the ET process, one needs to master the art of tuning the redox potential, especially in metalloproteins, as they represent major classes of ET proteins. In this review, we first describe the importance of tuning the redox potential of ET centers and its role in regulating the ET in bioenergetic processes including photosynthesis and respiration. The main focus of this review is to summarize recent work in designing the ET centers, namely cupredoxins, cytochromes, and iron-sulfur proteins, and examples in design of protein networks involved these ET centers. We then discuss the factors that affect redox potentials of these ET centers including metal ion, the ligands to metal center and interactions beyond the primary ligand, especially non-covalent secondary coordination sphere interactions. We provide examples of strategies to fine-tune the redox potential using both natural and unnatural amino acids and native and nonnative cofactors. Several case studies are used to illustrate recent successes in this area. Outlooks for future endeavors are also provided. This article is part of a Special Issue entitled Biodesign for Bioenergetics--the design and engineering of electronic transfer cofactors, proteins and protein networks, edited by Ronald L. Koder and J.L. Ross Anderson.

Modulating the cobalt redox potential through imidazole hydrogen bonding interactions in a supramolecular biomimetic protein-cofactor model

This paper describes a supramolecular biomimetic model of the “His-on” configuration and the charge relay system present in certain types of B₁₂-dependent enzymes.

A realistic model for the active site of histidine-on cobalamin@protein complexes is reported and studied under homogeneous and immobilized conditions. Analysis of lower ligand modulation and its influence on the properties of the biomimetic compound are presented. The cofactor attachment by a protein's histidine residue was imitated by covalently linking an artificial imidazole-containing linker to cobyric acid. The resulting intramolecular coordination complex is an excellent structural model of its natural archetype, according to 2D ¹H-NMR studies and molecular modeling. The effect of deprotonation of the axially coordinating imidazole ligand – as proposed for natural cofactor complexes – tunes significantly the position of the cathodic peak (ΔV = –203 mV) and stabilizes thereby the Co^III form. Partial deprotonation of the imidazole moiety through hydrogen bonding interactions was then achieved by immobilizing the biomimetic model on hydrophobic C18 silica, which yielded an unprecedented insight on how this class of Cbl-dependent proteins may fine-tune their properties in biological systems.

Improving the pH-stability of Versatile Peroxidase by Comparative Structural Analysis with a Naturally-Stable Manganese Peroxidase

Versatile peroxidase (VP) from the white-rot fungus Pleurotus eryngii is a high redox potential peroxidase of biotechnological interest able to oxidize a wide range of recalcitrant substrates including lignin, phenolic and non-phenolic aromatic compounds and dyes. However, the relatively low stability towards pH of this and other fungal peroxidases is a drawback for their industrial application. A strategy based on the comparative analysis of the crystal structures of VP and the highly pH-stable manganese peroxidase (MnP4) from Pleurotus ostreatus was followed to improve the VP pH stability. Several interactions, including hydrogen bonds and salt bridges, and charged residues exposed to the solvent were identified as putatively contributing to the pH stability of MnP4. The eight amino acid residues responsible for these interactions and seven surface basic residues were introduced into VP by directed mutagenesis. Furthermore, two cysteines were also included to explore the effect of an extra disulfide bond stabilizing the distal Ca²⁺ region. Three of the four designed variants were crystallized and new interactions were confirmed, being correlated with the observed improvement in pH stability. The extra hydrogen bonds and salt bridges stabilized the heme pocket at acidic and neutral pH as revealed by UV-visible spectroscopy. They led to a VP variant that retained a significant percentage of the initial activity at both pH 3.5 (61% after 24 h) and pH 7 (55% after 120 h) compared with the native enzyme, which was almost completely inactivated. The introduction of extra solvent-exposed basic residues and an additional disulfide bond into the above variant further improved the stability at acidic pH (85% residual activity at pH 3.5 after 24 h when introduced separately, and 64% at pH 3 when introduced together). The analysis of the results provides a rational explanation to the pH stability improvement achieved.

The influence of heme ruffling on spin densities in ferricytochromes c probed by heme core 13C NMR

The heme in cytochromes c undergoes a conserved out-of-plane distortion known as ruffling. For cytochromes c from the bacteria Hydrogenobacter thermophilus and Pseudomonas aeruginosa , NMR and EPR spectra have been shown to be sensitive to the extent of heme ruffling and to provide insights into the effect of ruffling on the electronic structure. Through the use of mutants of each of these cytochromes that differ in the amount of heme ruffling, NMR characterization of the low-spin (S = ½) ferric proteins has confirmed and refined the developing understanding of how ruffling influences the spin distribution on heme. The chemical shifts of the core heme carbons were obtained through site-specific labeling of the heme via biosynthetic incorporation of (13)C-labeled 5-aminolevulinic acid derivatives. Analysis of the contact shifts of these core heme carbons allowed Fermi contact spin densities to be estimated and changes upon ruffling to be evaluated. The results allow a deconvolution of the contributions to heme hyperfine shifts and a test of the influence of heme ruffling on the electronic structure and hyperfine shifts. The data indicate that as heme ruffling increases, the spin densities on the β-pyrrole carbons decrease while the spin densities on the α-pyrrole carbons and meso carbons increase. Furthermore, increased ruffling is associated with stronger bonding to the heme axial His ligand.

Variation and analysis of second-sphere interactions and axial histidinate character in c-type cytochromes

The electron-donating properties of the axial His ligand to heme iron in cytochromes c (cyts c) are found to be correlated with the midpoint reduction potential (E(m)) in variants of Hydrogenobacter thermophilus cytochrome c(552) (Ht cyt c(552)) in which mutations have been made in and near the Cys-X-X-Cys-His (CXXCH) heme-binding motif. To probe the strength of the His-Fe(III) interaction, we have measured (13)C nuclear magnetic resonance (NMR) chemical shifts for (13)CN(-) bound to heme iron trans to the axial His in Ht Fe(III) cyt c(552) variants. We observe a linear relationship between these (13)C chemical shifts and E(m), indicating that the His-Fe(III) bond strength correlates with E(m). To probe a conserved hydrogen bonding interaction between the axial His Hdelta1 and the backbone carbonyl of a Pro residue, we measured the pK(a) of the axial His Hdelta1 proton (pK(a(2))), which we propose to relate to the His-Fe(III) interaction, reduction potential, and local electrostatic effects. The observed linear relationship between the axial His (13)Cbeta chemical shift and E(m) is proposed to reflect histidinate (anionic) character of the ligand. A linear relationship also is seen between the average heme methyl (1)H chemical shift and E(m) which may reflect variation in axial His electron-donating properties or in the ruffling distortion of the heme plane. In summary, chemical shifts of the axial His and exogenous CN(-) bound trans to His are shown to be sensitive probes of the His-Fe(III) interaction in variants of Ht cyt c(552) and display trends that correlate with E(m).

Extracellular Enzyme Production and Synthetic Lignin Mineralization by Ceriporiopsis subvermispora

The ability of the white rot fungus Ceriporiopsis subvermispora to mineralize C-synthetic lignin was studied under different culture conditions, and the levels of two extracellular enzymes were monitored. The highest mineralization rates (28% after 28 days) were obtained in cultures containing a growth-limiting amount of nitrogen source (1.0 mM ammonium tartrate); under this condition, the levels of manganese peroxidase (MnP) and laccase present in the culture supernatant solutions were very low compared with cultures containing 10 mM of the nitrogen source. In contrast, cultures containing a limiting concentration of the carbon source (0.1% glucose) showed low levels of both enzymes and also very low mineralization rates compared with cultures containing 1% glucose. Cultures containing 11 ppm of Mn(II) showed a higher rate of mineralization than those containing 0.3 or 40 ppm of this cation. Levels of MnP and laccase were higher when 40 ppm of Mn(II) was used. Mineralization rates were slightly higher in cultures flushed daily with oxygen, whereas laccase levels were lower and MnP levels were approximately the same as in cultures maintained under an air atmosphere. The presence of 0.4 mM veratryl alcohol reduced both mineralization rates and MnP levels, without affecting laccase levels. Lignin peroxidase activity was not detected under any condition. Addition of purified lignin peroxidase to the cultures in the presence or absence of veratryl alcohol did not enhance mineralization rates significantly.

Redox properties of heme peroxidases

Peroxidases are heme enzymes found in bacteria, fungi, plants and animals, which exploit the reduction of hydrogen peroxide to catalyze a number of oxidative reactions, involving a wide variety of organic and inorganic substrates. The catalytic cycle of heme peroxidases is based on three consecutive redox steps, involving two high-valent intermediates (Compound I and Compound II), which perform the oxidation of the substrates. Therefore, the thermodynamics and the kinetics of the catalytic cycle are influenced by the reduction potentials of three redox couples, namely Compound I/Fe3+, Compound I/Compound II and Compound II/Fe3+. In particular, the oxidative power of heme peroxidases is controlled by the (high) reduction potential of the latter two couples. Moreover, the rapid H2O2-mediated two-electron oxidation of peroxidases to Compound I requires a stable ferric state in physiological conditions, which depends on the reduction potential of the Fe3+/Fe2+ couple. The understanding of the molecular determinants of the reduction potentials of the above redox couples is crucial for the comprehension of the molecular determinants of the catalytic properties of heme peroxidases. This review provides an overview of the data available on the redox properties of Fe3+/Fe2+, Compound I/Fe3+, Compound I/Compound II and Compound II/Fe3+ couples in native and mutated heme peroxidases. The influence of the electron donor properties of the axial histidine and of the polarity of the heme environment is analyzed and the correlation between the redox properties of the heme group with the catalytic activity of this important class of metallo-enzymes is discussed.

Crystal structure of chlorite dismutase, a detoxifying enzyme producing molecular oxygen

Chlorite dismutase (Cld) is a key enzyme of perchlorate and chlorate respiration. This heme-based protein reduces the toxic compound chlorite into the innocuous chloride anion in a very efficient way while producing molecular oxygen. A sequence comparison between Cld homologues shows a highly conserved family. The crystal structure of Azospira oryzae strain GR-1 Cld is reported to 2.1 A resolution. The structure reveals a hexameric organization of the Cld, while each monomer exhibits a ferredoxin-like fold. The six subunits are organized in a ring structure with a maximal diameter of 9 nm and an inner diameter of 2 nm. The heme active-site pocket is solvent accessible both from the inside and the outside of the ring. Moreover, a second anion binding site that could accommodate the assumed reaction intermediate ClO(-) for further transformation has been identified near the active site. The environment of the heme cofactor was investigated with electron paramagnetic resonance spectroscopy. Apart from the high-spin ferric signal of the five-coordinate resting-state enzyme, two low-spin signals were found corresponding to six-coordinate species. The current crystal structure confirms and complements a recently proposed catalytic mechanism that proceeds via a ferryl species and a ClO(-) anion. Our structural data exclude cooperativity between the iron centers.

Microbial degradation of lignin: how a bulky recalcitrant polymer is efficiently recycled in nature and how we can take advantage of this

Lignin is the second most abundant constituent of the cell wall of vascular plants, where it protects cellulose towards hydrolytic attack by saprophytic and pathogenic microbes. Its removal represents a key step for carbon recycling in land ecosystems, as well as a central issue for industrial utilization of plant biomass. The lignin polymer is highly recalcitrant towards chemical and biological degradation due to its molecular architecture, where different non-phenolic phenylpropanoid units form a complex three-dimensional network linked by a variety of ether and carbon-carbon bonds. Ligninolytic microbes have developed a unique strategy to handle lignin degradation based on unspecific one-electron oxidation of the benzenic rings in the different lignin substructures by extracellular haemperoxidases acting synergistically with peroxide-generating oxidases. These peroxidases poses two outstanding characteristics: (i) they have unusually high redox potential due to haem pocket architecture that enables oxidation of non-phenolic aromatic rings, and (ii) they are able to generate a protein oxidizer by electron transfer to the haem cofactor forming a catalytic tryptophanyl-free radical at the protein surface, where it can interact with the bulky lignin polymer. The structure-function information currently available is being used to build tailor-made peroxidases and other oxidoreductases as industrial biocatalysts.

Heme attachment motif mobility tunes cytochrome c redox potential

Hydrogen exchange (HX) rates and midpoint potentials (Em) of variants of cytochrome c from Pseudomonas aeruginosa (Pa cyt c551) and Hydrogenobacter thermophilus (Ht cyt c552) have been characterized in an effort to develop an understanding of the impact of properties of the Cys-X-X-Cys-His pentapeptide c-heme attachment (CXXCH) motif on heme redox potential. Despite structural conservation of the CXXCH motif, Ht cyt c552 exhibits a low level of protection from HX for amide protons within this motif relative to Pa cyt c551. Site-directed mutants have been prepared to determine the structural basis for and functional implications of these variations on HX behavior. The double mutant Ht-M13V/K22M displays suppressed HX within the CXXCH motif as well as a decreased Em (by 81 mV), whereas the corresponding double mutant of Pa cyt c551 (V13M/M22K) exhibits enhanced HX within the CXXCH pentapeptide and a modest increase in Em (by 30 mV). The changes in Em correlate with changes in axial His chemical shifts in the ferric proteins reflecting the extent of histidinate character. Thus, the mobility of the CXXCH pentapeptide is found to impact the His-Fe(III) interaction and therefore the heme redox potential.

Mechanism of versatile peroxidase inactivation by Ca(2+) depletion

Versatile peroxidase (VP) from Bjerkandera adusta, as other class II peroxidases, is inactivated by Ca(2+) depletion. In this work, the spectroscopic characterizations of Ca(2+)-depleted VP at pH 4.5 (optimum for activity) and pH 7.5 are presented. Previous works on other ligninolytic peroxidases, such as lignin peroxidase and manganese peroxidase, have been performed at pH 7.5; nevertheless, at this pH these enzymes are inactive independently of their Ca(2+) content. At pH 7.5, UV-Vis spectra indicate a heme-Fe(3+) transition from 5-coordinated high-spin configuration in native peroxidase to 6-coordinated low-spin state in the inactive Ca(2+)-depleted form. This Fe(3+) hexa-coordination has been proposed as the origin of inactivation. However, our results at pH 4.5 show that Ca(2+)-depleted enzyme has a high spin Fe(3+). EPR measurements on VP confirm the differences in the Fe(3+) spin states at pH 4.5 and at 7.5 for both, native and Ca(2+)-depleted enzymes. In addition, EPR spectra recorded after the addition of H(2)O(2) to Ca(2+)-depleted VP show the formation of compound I with the radical species delocalized on the porphyrin ring. The lack of radical delocalization on an amino acid residue exposed to solvent, W170, as determined in native enzyme at pH 4.5, explains the inability of Ca(2+)-depleted VP to oxidize veratryl alcohol. These observations, in addition to a notorious redox potential decrease, suggest that Ca(2+)-depleted versatile peroxidase is able to form the active intermediate compound I but its long range electron transfer has been disrupted.

NMR study of manganese(II) binding by a new versatile peroxidase from the white-rot fungus Pleurotus eryngii

Nuclear magnetic resonance spectroscopy has been used to characterize the versatile peroxidase from Pleurotus eryngii, both in the resting state and in the cyanide-inhibited form. The assignment of most of the hyperfine-shifted resonances has been achieved by two-dimensional NMR, allowing the comparison of the present system with other ligninolytic peroxidases. This information has enabled a detailed analysis of the interaction of the enzyme with one of its reducing substrates, Mn(II). Furthermore, comparison with the data collected on a mutant in the putative Mn(II) binding site, and an analysis of the enzyme kinetic properties, shed light on the factors affecting the function of this novel peroxidase.

Molecular dynamics simulations of lignin peroxidase in solution

The dynamical and structural properties of lignin peroxidase and its Trp171Ala mutant have been investigated in aqueous solution using molecular dynamics (MD) simulations. In both cases, the enzyme retained its overall backbone structure and all its noncovalent interactions in the course of the MD simulations. Very interestingly, the analysis of the MD trajectories showed the presence of large fluctuations in correspondence of the residues forming the heme access channel; these movements enlarge the opening and facilitate the access of substrates to the enzyme active site. Moreover, steered molecular dynamics docking simulations have shown that lignin peroxidase natural substrate (veratryl alcohol) can easily approach the heme edge through the access channel.

Two-dimensional NMR study of the heme active site structure of chloroperoxidase

The heme active site structure of chloroperoxidase (CPO), a glycoprotein that displays versatile catalytic activities isolated from the marine mold Caldariomyces fumago, has been characterized by two-dimensional NMR spectroscopic studies. All hyperfine shifted resonances from the heme pocket as well as resonances from catalytically relevant amino acid residues including the heme iron ligand (Cys(29)) attributable to the unique catalytic properties of CPO have been firmly assigned through (a) measurement of nuclear Overhauser effect connectivities, (b) prediction of the Curie intercepts from both one- and two-dimensional variable temperature studies, (c) comparison with assignments made for cyanide derivatives of several well characterized heme proteins such as cytochrome c peroxidase, horseradish peroxidase, and manganese peroxidase, and (d) examination of the crystal structural parameters of CPO. The location of protein modification that differentiates the signatures of the two isozymes of CPO has been postulated. The function of the distal histidine (His(105)) in modulating the catalytic activities of CPO is proposed based on the unique arrangement of this residue within the heme cavity. Contrary to the crystal state, the high affinity Mn(II) binding site in CPO (in solution) is not accessible to externally added Mn(II). The results presented here provide a reasonable explanation for the discrepancies in the literature between spectroscopists and crystallographers concerning the manganese binding site in this unique protein. Our study indicates that results from NMR investigations of the protein in solution can complement the results revealed by x-ray diffraction studies of the crystal form and thus provide a complete and better understanding of the actual structure of the protein.

Spectroscopic characterization and ligand-binding properties of chlorite dismutase from the chlorate respiring bacterial strain GR-1

Chlorite dismutase (EC 1.13.11.49), an enzyme capable of reducing chlorite to chloride while producing molecular oxygen, has been characterized using EPR and optical spectroscopy. The EPR spectrum of GR-1 chlorite dismutase shows two different high-spin ferric heme species, which we have designated 'narrow' (gx,y,z = 6.24, 5.42, 2.00) and 'broad' (gz,y,x = 6.70, 5.02, 2.00). Spectroscopic evidence is presented for a proximal histidine co-ordinating the heme iron center of the enzyme. The UV/visible spectrum of the ferrous enzyme and EPR spectra of the ferric hydroxide and imidazole adducts are characteristic of a heme protein with an axial histidine co-ordinating the iron. Furthermore, the substrate analogs nitrite and hydrogen peroxide have been found to bind to ferric chlorite dismutase. EPR spectroscopy of the hydrogen peroxide adduct shows the loss of both high-spin and low-spin ferric signals and the appearance of a sharp radical signal. The NO adduct of the ferrous enzyme exhibits a low-spin EPR signal typical of a five-co-ordinate heme iron nitrosyl adduct. It seems that the bond between the proximal histidine and the iron is weak and can be broken upon binding of NO. The midpoint potential, Em(Fe3+/2+) = -23 mV, of chlorite dismutase is higher than for most heme enzymes. The spectroscopic features and redox properties of chlorite dismutase are more similar to the gas-sensing hemoproteins, such as guanylate cyclase and the globins, than to the heme enzymes.

Fungal peroxidases: molecular aspects and applications

Peroxidases are oxidoreductases that utilize hydrogen peroxide to catalyze oxidative reactions. A large number of peroxidases have been identified in fungal species and are being characterized at the molecular level. In this manuscript we review the current knowledge on the molecular aspects of this type of enzymes. We present an overview of the research efforts undertaken in deciphering the structural basis of the catalytic properties of fungal peroxidases and discuss molecular genetics and protein homology aspects of this enzyme class. Finally, we summarize the potential biotechnological applications of these enzymes and evaluate recent advances on their expression in heterologous systems for production purposes.

Redox equilibria of manganese peroxidase from Phanerochaetes chrysosporium: functional role of residues on the proximal side of the haem pocket

Redox potentials of recombinant manganese peroxidase from Phanerochaetes chrysosporium have been measured by cyclic voltammetry as a function of pH, between pH 4.5 and pH 10.5. They display a bimodal behaviour (characterized by an 'alkaline' and an 'acid' transition), which indicates that (at least) two protonating groups change their pK(b) values upon reduction (and/or oxidation) of the iron atom in haem. Analogous measurements have been carried out on four site-directed mutants involving residues in close proximity to the proximal ligand, His(173), in order to investigate the role played by residues of the proximal haem pocket on the redox properties of this enzyme. Results obtained suggest that the protonation state of N(delta) of the proximal imidazole group is redox-linked and that it is crucial in regulating the 'alkaline' transition. On the other hand, none of the proximal mutants alters the 'acid' transition, suggesting that it is modulated by groups located in a different portion of the protein.

Heme Peroxidases: Structure, Function, Mechanism and Involvement in Activation of Carcinogens. A Review

Peroxidases are enzymes playing an important role in large and diverse numbers of physiological processes in organisms including human. We have attempted in this article to summarize and review the important structural and catalytic properties of principal classes of heme peroxidases as well as their biological functions. Major reactions catalyzed by these enzymes (a conventional peroxidase cycle, reactions using O2and halogenations) and their mechanism are reviewed, too. Moreover, the reaction mechanisms by which peroxidases are implicated in bioactivation of xenobiotic chemicals are presented. Numerous chemicals including protoxicants and procarcinogens are metabolized by equally numerous chemical reactions catalyzed by peroxidases. The unifying theme is the radical nature of the oxidations. The direct conventional peroxidase reaction forming reactive species is generally responsible for the activation of procarcinogenic substrates of peroxidases. The subsequent formation of a superoxide anion radical and peroxy radicals is necessary for activation of chemicals that are poor substrates for peroxidases. The significance of studies concerning the reactions catalyzed by peroxidases is underlined in the present review article. A review with 166 references.

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

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

The tautomeric state of histidines in myoglobin

1H-15N HMQC spectra were collected on 15N-labeled sperm whale myoglobin (Mb) to determine the tautomeric state of its histidines in the neutral form. By analyzing metaquoMb and metcyanoMb data sets collected at various pH values, cross-peaks were assigned to the imidazole rings and their patterns interpreted. Of the nine histidines not interacting with the heme in sperm whale myoglobin, it was found that seven (His-12, His-48, His-81, His-82, His-113, His-116, and His-119) are predominantly in the N epsilon2H form with varying degrees of contribution from the Ndelta1 H form. The eighth, His-24, is in the Ndelta1H state as expected from the solid state structure. 13C correlation spectra were collected to probe the state of the ninth residue (His-36). Tentative interpretation of the data through comparison with horse Mb suggested that this ring is predominantly in the Ndelta1H state. In addition, signals were observed from the histidines associated with the heme (His-64, His-93, and His-97) in the 1H-15N HMQC spectra of the metcyano form. In several cases, the tautomeric state of the imidazole ring could not be derived from inspection of the solid state structure. It was noted that hydrogen bonding of the ring was not unambiguously reflected in the nitrogen chemical shift. With the experimentally determined tautomeric state composition in solution, it will be possible to broaden the scope of other studies focused on the electrostatic contribution of histidines to the thermodynamic properties of myoglobin.

Paramagnetic NMR shifts in cyanoferricytochrome c. Investigation of thermal stability and deviations from Curie law behaviour

The paramagnetic shifts of 13C nuclei positioned alpha to the haem in cyanoferricytochrome c are reported and analysed in terms of molecular orbitals based on D4h symmetry with a rhombic perturbation. The temperature dependence of the Fermi contact and dipolar shifts of the haem and axial histidine ligand show deviations from Curie Law behaviour which are explained by a Boltzmann distribution between partially filled 3e(pi) molecular orbitals and the ground and first excited state Kramers doublets. The comprehensive explanation of the temperature dependence of the paramagnetic shifts leads to the conclusion that there is no detectable temperature dependence of the haem orientation or that of the His ligand orientation. This work also provides evidence for the role of the axial His ligand in determining the orientation of the magnetic z-axis.

Structural properties of peroxidases

Peroxidases are heme proteins which are able to catalyze the oxidation of a large variety of substrates through the reaction with hydrogen peroxide. The specific biological function, the reduction potential of the iron and the nature of the substrates which can be oxidized, are strongly determined by the structural features of the protein matrix around the prosthetic group. In particular, two main features are considered to be responsible of the specificity of the biological function: the strong anionic character of the fifth, proximal ligand to the iron, which is able to stabilize high oxidation states, and the hydrophilic nature of the residues in the distal pocket. Beside the correct reduction potential for the oxidation reaction, the specificity towards different substrates also depends on the protein structural arrangement which can determine specific binding sites for substrates and mediators. Particularly, in the case of MnP,the Mn2+ binding site has been individuated in the X-ray structure. NMR studies were previously reported which provided an iron-manganese distance consistent with that from the X-ray structure. This information can help in defining the possible pathway for the electron transfer from the Mn2+ ion to the iron. On the contrary, in the case of LiP no information is available on the possible binding site of veratryl alcohol as well as of other aromatic substrates. This article reviews these structural properties of peroxidases with particular emphasis to their implications in the catalytic process. Finally, the calcium ions have been located in the structure of LiP and the MnP: their structural relevance will be discussed on the light of the possible role in determining the optimal arrangement of residues in the distal cavity for the enzymatic reaction.

Charge reversal of a critical active-site residue of cytochrome-c peroxidase: characterization of the Arg48-->Glu variant

A new variant of cytochrome-c peroxidase in which the positively charged Arg48 present in the distal heme-binding pocket has been replaced with a Glu residue has been prepared and characterized to explore, in part, the possibility that a negative charge close to the heme could contribute to stabilization of a porphyrin-centered pi-cation radical in the compound I derivative of the variant. Between pH 4 and 8, this variant forms three pH-linked spectroscopic species. The electronic absorption and 1H-NMR spectra of the predominant form at low pH (HS1) are indicative of a high-spin, pentacoordinate heme iron system. Near neutral pH, a second high-spin species (HS2) is dominant, in which the heme iron center is hexacoordinated, with a water molecule as the sixth axial ligand. At high pH, the third form (LS) exhibits the spectroscopic characteristics of a low-spin, hexacoordinate heme center with bishistidine axial ligation. The apparent pKa values for these transitions are 4.4 and 7.4, respectively, in phosphate buffers and 5.0 and 7.1, respectively, in phosphate/nitrate buffers. Replacement of Arg48 with Glu reduces the thermal stability of the enzyme and also decreases the Fe(III)/Fe(II) reduction potential of the enzyme by approximately 50 mV relative to that of the wild-type enzyme. The stability of compound I formed by the variant is decreased although the rate at which it forms is just one order of magnitude less than that of the wild-type enzyme, thus confirming previous results which indicate that the function of residue 48 in the wild-type peroxidase is more related to the stability of compound I than to its formation [Erman, J. E., Vitello, L. B., Miller, M. A. & Kraut, J. (1992) J. Am. Chem. Soc. 114, 6592-6593; Vitello, L. B., Erman, J. E., Miller, M. A., Wang, J. & Kraut, J. (1993) Biochemistry 32, 9807-9818]. Stopped-flow studies failed to detect even transient formation of a porphyrin-centered radical following addition of hydrogen peroxide to the Fe(III)-enzyme. The consequences of this drastic electrostatic modification of the active site on the steady-state kinetics of the variant are relatively minor.

Axial Imidazole Distortion Effects on the Catalytic and Binding Properties of Chelated Deuterohemin Complexes

The effect of strain in the axial coordination of imidazole to the heme has been studied in the chelate complexes deuterohemin-histidine (DH-His) and deuterohemin-alanylhistidine (DH-AlaHis). Molecular mechanics calculations indicate that three types of distortion of the axial ligand occur in DH-His, due to the relatively short length of the arm carrying the donor group: tilting off-axis, tipping, and inclination of the imidazole plane with respect to the axial Fe-N bond. The effects of tilting (Deltagamma approximately 10 degrees ) and inclination of the imidazole ring (Deltadelta approximately 17 degrees ) are dominant, while tipping is small and is probably of little importance here. By contrast, the axial imidazole coordination is normal in DH-AlaHis and other computed deuterohemin-dipeptide or -tripeptide complexes where histidine is the terminal residue, the only exception being DH-ProHis, where the rigidity of the proline ring reduces the flexibility of the chelating arm. The distortion in the axial iron-imidazole bond in DH-His has profound and negative influence on the binding and catalytic properties of this complex compared to DH-AlaHis. The former complex binds more weakly carbon monoxide, in its reduced form, and imidazole, in its oxidized form, than the latter. The catalytic efficiency in peroxidative oxidations is also reduced in DH-His with respect to DH-AlaHis. The activity of the latter complex is similar to that of microperoxidase-11, the peptide fragment incorporating the heme that results from hydrolytic cleavage of cytochrome c.

Crystal structures of cyanide- and triiodide-bound forms of Arthromyces ramosus peroxidase at different pH values. Perturbations of active site residues and their implication in enzyme catalysis

The structures of the cyanide and triiodide complexes of Arthromyces ramosus peroxidase (ARP) at different pH values were investigated by x-ray crystallography in order to examine the behavior of the invariant residues of arginine (Arg-52) and distal histidine (His-56) during the enzyme reaction as well as to provide the structural basis of the active site of peroxidase. The models of the cyanide complexes at pH 7.5, 5.0, and 4.0, respectively, were refined to the R-factors of 17.8, 17.8, and 18.5% using 7.0-1.6-A resolution data, and those of the triiodide complexes at pH 6.5 and 5.0 refined to 16.9 and 16.8% using 7.0-1.9-A resolution data. The structures of the cyanide complexes at pH 7.5, 5.0, and 4.0 are identical within experimental error. Cyanide ion bound to the heme in the bent conformation rather than in the tilt conformation. Upon cyanide ion binding, the N epsilon atom of His-56 moved toward the ion by rotation of the imidazole ring around the C beta-C gamma bond, but there was little conformational change in the remaining residues. The distance between the N epsilon atom of His-56 and the nitrogen atom of the cyanide suggests the presence of a hydrogen bond between them in the pH range investigated. In the triiodide complexes, one of the two triiodides bound to ARP was located at the distal side of the heme. When triiodide bound to ARP, unlike the rearrangement of the distal arginine of cytochrome c peroxidase that occurs on formation of the fluoride complex or compound I, the side chain of Arg-52 moved little. The conformation of the side chain of His-56, however, changed markedly. Conformational flexibility of His-56 appears to be a requisite for proton translocation from one oxygen atom to the other of HOO- by acid-base catalysis to produce compound I. The iron atom in each cyanide complex (low-spin ferric) is located in the heme plane, whereas in each triiodide complex (high-spin ferric) the iron atom is displaced from the plane about 0.2 A toward the proximal side.

NMR studies of recombinant Coprinus peroxidase and three site-directed mutants. Implications for peroxidase substrate binding

Proton nuclear magnetic resonance spectroscopy has been used to characterise and compare wild-type fungal and recombinant Coprinus cinereus peroxidase (CIP) and three mutants in which Gly156 and/or Asn157 was replaced by Phe. Analysis of one- and two-dimensional NMR spectra of recombinant CIP was undertaken for comparison with the fungal enzyme and in order to establish a meaningful basis for solution studies of CIP mutants. Proton resonance assignments of haem and haem-linked residues obtained for the cyanide-ligated form of recombinant CIP revealed a high degree of spectral similarity with those of lignin and manganese-dependent peroxidases and extend previously reported NMR data for fungal CIP. The three mutants examined by NMR spectroscopy comprised site-specific substitutions made to a region of the structure believed to form part of the peroxidase haem group access channel for substrate and ligand molecules. Proton resonances of the aromatic side-chains of Phe156 and Phe157 were found to have similar spectral characteristics to those of two phenylalanine residues known to be involved in the binding of aromatic donor molecules to the plant peroxidase, horseradish peroxidase isoenzyme C. The results are discussed in the context of complementary reactivity studies on the mutants in order to develop a more detailed understanding of aromatic donor molecule binding to fungal and plant peroxidases.

NMR investigation of isotopically labeled cyanide derivatives of lignin peroxidase and manganese peroxidase

The 1H NMR spectroscopy was used to study lignin peroxidase (LiP) and manganese peroxidase (MnP) containing deuterated histidines. LiP and MnP were obtained from a histidine auxotroph of the fungus Phanerochaete chrysosporium grown in the presence of deuterated histidines. The derivatives with deuterated histidines have allowed a firm assignment of the protons of the distal and proximal histidines. We have also found that the LiP from this strain exhibits different orientations of the 2-vinyl group compared to the LiP from the strain previously studied. Mobility of the group has also been detected, thus explaining the apparent inconsistency between X-ray solid-state and NMR solution data. The 15N shift values of 15N-enriched CN- in the cyanide derivatives of LiP and MnP have also been measured. The shift patterns, both for 15N and for the proximal histidine protons of several peroxidases, are consistent with predominant contact shift contributions which reflect the bond strength of the metal-axial ligand. Finally, our results confirm a correlation between shift values of 15N and those of proximal histidine protons and the Fe3+/Fe2+ redox potentials.

Molecular biology of the lignin-degrading basidiomycete Phanerochaete chrysosporium

The white rot basidiomycete Phanerochaete chrysosporium completely degrades lignin and a variety of aromatic pollutants during the secondary metabolic phase of growth. Two families of secreted heme enzymes, lignin peroxidase (LiP) and manganese peroxidase (MnP), are major components of the extracellular lignin degradative system of this organism. MnP and LiP both are encoded by families of genes, and the lip genes appear to be clustered. The lip genes contain eight or nine short introns; the mnp genes contain six or seven short introns. The sequences surrounding active-site residues are conserved among LiP, MnP, cytochrome c peroxidase, and plant peroxidases. The eight LiP cysteine residues align with 8 of the 10 cysteines in MnP. LiPs are synthesized as preproenzymes with a 21-amino-acid signal sequence followed by a 6- or 7-amino-acid propeptide. MnPs have a 21- or 24-amino-acid signal sequence but apparently lack a propeptide. Both LiP and MnP are regulated at the mRNA level by nitrogen, and the various isozymes may be differentially regulated by carbon and nitrogen. MnP also is regulated at the level of gene transcription by Mn(II), the substrate for the enzyme, and by heat shock. The promoter regions of mnp genes contain multiple heat shock elements as well as sequences that are identical to the consensus metal regulatory elements found in mammalian metallothionein genes. DNA transformation systems have been developed for P. chrysosporium and are being used for studies on gene regulation and for gene replacement experiments.

Spectroscopic characterization of a newly isolated cytochrome P450 from Rhodococcus rhodochrous

Cytochrome P450 (P450) from Rhodococcus rhodochrous have been characterized through circular dichroism and nuclear magnetic resonance (NMR) spectroscopy, both in the substrate-free and substrate-bound forms. The data are compared with those of P450cam and indicate a close similarity of the structure of the active site in the two proteins. The substrate-free species contains low-spin iron(III), while the 2-ethoxyphenol bound species contains high-spin iron(III). The substrate is in slow exchange on the NMR time scale. The binding of CN- has been investigated and the final adduct characterized through NMR spectra. Nuclear relaxation times of the isotropically shifted signals turn out to be shorter than in other heme proteins, both in the high- and in the low-spin species. This is the result of longer electron relaxation times in P450s than in peroxidases and metmyoglobin. This property, as well as the electron paramagnetic resonance (EPR) spectrum of the substrate-free form, are discussed in terms of the presence of the cysteine as the fifth ligand of the iron ion instead of a histidine as it occurs in peroxidases and myoglobin.

One- and two-dimensional NMR characterization of oxidized and reduced cytochrome c' from Rhodocyclus gelatinosus

1D and 2D NMR spectra of both the reduced and oxidized forms of cytochrome c' from Rhodocyclus gelatinosus have been recorded. The analysis of the pH dependence of the 1H NMR spectrum of the ferric form has been performed, and two main ionizing groups have been identified. By comparison of the pH dependence of the available spectra of cytochromes c', an ambiguity remaining from previous studies on related cytochromes c' has been solved. By means of 2D spectra, an assignment of all the paramagnetically shifted signals is proposed both for the ferrous and for the ferric forms.