How Modification of Accessible Lysines to Phenylalanine Modulates the Structural and Functional Properties of Horseradish Peroxidase: A Simulation Study

Horseradish Peroxidase (HRP) is one of the most studied peroxidases and a great number of chemical modifications and genetic manipulations have been carried out on its surface accessible residues to improve its stability and catalytic efficiency necessary for biotechnological applications. Most of the stabilized derivatives of HRP reported to date have involved chemical or genetic modifications of three surface-exposed lysines (K174, K232 and K241). In this computational study, we altered these lysines to phenylalanine residues to model those chemical modifications or genetic manipulations in which these positively charged lysines are converted to aromatic hydrophobic residues. Simulation results implied that upon these substitutions, the protein structure becomes less flexible. Stability gains are likely to be achieved due to the increased number of stable hydrogen bonds, improved heme-protein interactions and more integrated proximal Ca²⁺ binding pocket. We also found a new persistent hydrogen bond between the protein moiety (F174) and the heme prosthetic group as well as two stitching hydrogen bonds between the connecting loops GH and F′F″ in mutated HRP. However, detailed analysis of functionally related structural properties and dynamical features suggests reduced reactivity of the enzyme toward its substrates. Molecular dynamics simulations showed that substitutions narrow the bottle neck entry of peroxide substrate access channel and reduce the surface accessibility of the distal histidine (H42) and heme prosthetic group to the peroxide and aromatic substrates, respectively. Results also demonstrated that the area and volume of the aromatic-substrate binding pocket are significantly decreased upon modifications. Moreover, the hydrophobic patch functioning as a binding site or trap for reducing aromatic substrates is shrunk in mutated enzyme. Together, the results of this simulation study could provide possible structural clues to explain those experimental observations in which the protein stability achieved concurrent with a decrease in enzyme activity, upon manipulation of charge/hydrophobicity balance at the protein surface.     

Activity, stability, and unfolding of reconstituted horseradish peroxidase with modified heme

Heme-propionates of horseradish peroxidase (HRP) were esterified by p-nitrophenol, phenol and p-methylphenol to change its electron character and to increase its hydrophobicity. These synthetic hemes were inserted apo-HRP to give a novel HRP, respectively. Of the three reconstituted HRPs, reconstituted HRP with p-nitrophenol-modified heme derivative had a larger initial rate, affinity, catalytic efficiency and substrate-binding efficiency than native HRP in aqueous buffer and some solvents. The reconstituted HRPs showed higher thermostability and tolerance of DMF because of the increase of the hydrophobicity of the active site. Changing the electron character of the aromatic moieties linked at each terminal of the two heme-propionates can control activity and stability of HRP. The initial rate, affinity, catalytic efficiency and substrate-binding efficiency increased with the increases of electron-withdrawing efficiency of substituents at 4-position of the phenolic used to synthesize the heme derivatives, contrariwise, the stability decreased. The modifications resulted in the increase in the temperature (T_m) at the midpoint of thermal denaturation and the decreases in both enthalpy and entropy change at T_m. The changes of catalytic properties and stabilities are related to the changes of the conformation of HRP. The modification changed the environment of heme and tryptophan, increased α-helix content of HRP. The present work demonstrates that enhancement of the hydrophobicity and the electron-withdrawing efficiency of heme improves the activity and stability of HRP.     

Modification of glutamate dehydrogenase by pyridoxal-5'-phosphate. Study of the structural organisation of the hexamer and its possible role in the realization of GTP action

The catalytic and regulator properties of glutamate dehydrogenase by modification of Lys-126 residue by puridoxal-5'-phosphate was studied. The phosphopyridoxyl derivative of the enzyme with blocked NADH-induced binding site of GTP not capable of being polymerized was taken as a model. It was shown that: blocking the epsilon-amino group of Lys-126 residue brings to a simultaneous inactivation of the enzyme and desensibilization of its residual activity to GTP action; the modification of Lys-126 residue and resulting inactivation of the enzyme and desensibilization to GTP action were non-cooperative processes, with equal values of pseudofirst order rate constants; modification of Lys-126 residue of any of hexamer's protomer results in the desensibilization to GTP action on one of the contacting, catalytically active protomers. The experimental dependence of the inhibition degree of the enzyme by GTP upon the average number of modified residues of Lys-126 is explained by the model of the hexamer of glutamate dehydrogenase with identical interlocation of any of the protomers in relation to the one in contact.     

Horseradish peroxidase thermostabilization: The combinatorial effects of the surface modification and the polyols

Horseradish peroxidase is an important heme-containing plant enzyme with enormous medical diagnostic, biosensing, bioremediation and biotechnological applications. Any improvement in the stability of the enzyme will greatly enhance its application in mentioned areas. In the present study, the stabilizing effects of certain additives and chemical modification by citraconic anhydride on the thermal behavior of HRP were investigated. Both strategies brought about dramatic enhancement of the thermostability of the enzyme. Results obtained on T_m, changes in the circular dichroism (CD) spectra and kinetic parameters of HRP and its modified form are discussed in terms of contributions to the mechanism of the thermal stability and the activity enhancement. Polyols were very effective in providing protection against the irreversible thermoinactivation of the native and the modified forms of the enzyme. Our results reveal that a combination of medium change and surface modification may provide an effective strategy for the enhancement of the thermodynamic and the kinetic stability of the enzyme.     

Interaction of aromatic donor molecules with horseradish peroxidase: identification of the binding site and role of heme iron in the binding and activity

The interaction of aromatic substrates with horseradish peroxidase (HRP) was studied. Chemical modification of HRP was performed using diethylpyrocarbonate (DEPC) and for the first time the amino acid involved in binding with these substrates has been identified. The kinetic parameters for this interaction have been calculated and the role of heme iron in the oxidation of aromatic substrates by HRP has been discussed.     

The cloning of a new peroxidase found in lignocellulose cultures of Pleurotus eryngii and sequence comparison with other fungal peroxidases

We report cloning and sequencing of gene ps1 encoding a versatile peroxidase combining catalytic properties of lignin peroxidase (LiP) and manganese peroxidase (MnP) isolated from lignocellulose cultures of the white-rot fungus Pleurotus eryngii. The gene contains 15 putative introns, and the deduced amino acid sequence consists of a 339-residue mature protein with a 31-residue signal peptide. Several putative response elements were identified in the promoter region. Amino acid residues involved in oxidation of Mn(2+) and aromatic substrates by direct electron transfer to heme and long-range electron transfer from superficial residues as predicted by analogy with Phanerochaete chrysosporium MnP and LiP, respectively. A dendrogram is presented illustrating sequence relationships between 29 fungal peroxidases.     

Site-directed mutagenesis of cytochrome c(6) from Anabaena species PCC 7119. Identification of surface residues of the hemeprotein involved in photosystem I reduction

A number of surface residues of cytochrome c(6) from the cyanobacterium Anabaena sp. PCC 7119 have been modified by site-directed mutagenesis. Changes were made in six amino acids, two near the heme group (Val-25 and Lys-29) and four in the positively charged patch (Lys-62, Arg-64, Lys-66, and Asp-72). The reactivity of mutants toward the membrane-anchored complex photosystem I was analyzed by laser flash absorption spectroscopy. The experimental results indicate that cytochrome c(6) possesses two areas involved in the redox interaction with photosystem I: 1) a positively charged patch that may drive its electrostatic attractive movement toward photosystem I to form a transient complex and 2) a hydrophobic region at the edge of the heme pocket that may provide the contact surface for the transfer of electrons to P(700). The isofunctionality of these two areas with those found in plastocyanin (which acts as an alternative electron carrier playing the same role as cytochrome c(6)) are evident.     

The biological effects of vanadyl curcumin and vanadyl diacetylcurcumin complexes: the effect on structure,function and oxidative stability of the peroxidase enzyme,antibacterial activity and cytotoxic effect

Curcumin has multiple pharmacological effects, but it has poor stability. Complexation of curcumin with metals improves its stability. Here, the effects of vanadyl curcumin and vanadyl diacetylcurcumin on the function and structure of horseradish peroxidase enzyme were evaluated by spectroscopic techniques. Cytotoxic effect of the complexes was also assessed on MCF-7 breast cancer, bladder and LNCaP prostate carcinoma cell line. The results showed that the complexes improve catalytic activity of HRP, and also increase its tolerance against the oxidative condition. The result also indicated that the affinity of HRP for hydrogen peroxide substrate decreases, while the affinity increases for phenol substrate. Circular dichroism and fluorescence spectroscopies showed that compactness of the enzyme structure around the catalytic heme group and the distance between the heme group and tryptophan residue decreases after the binding. The antibacterial and cytotoxic results indicated that the complexes have anticancer potential, but they have no considerable antibacterial activity.     

Horseradish peroxidase: Modulation of properties by chemical modification of protein and heme

Horseradish peroxidase (HRP) is one of the most studied enzymes of the plant peroxidase superfamily. HRP is also widely used in different bioanalytical applications and diagnostic kits. The methods of genetic engineering and protein design are now widely used to study the catalytic mechanism and to improve properties of the enzyme. Here we review the results of another approach to HRP modification—through the chemical modification of amino acids or prosthetic group of the enzyme. Computer models of HRPs with modified hemes are in good agreement with the experimental data.     

Enzymatic characterization and molecular modeling of an evolutionarily interesting fungal β-N-acetylhexosaminidase

Fungal β-N-acetylhexosaminidases are inducible extracellular enzymes with many biotechnological applications. The enzyme from Penicillium oxalicum has unique enzymatic properties despite its close evolutionary relationship with other fungal hexosaminidases. It has high GalNAcase activity, tolerates substrates with the modified N-acyl group better and has some other unusual catalytic properties. In order to understand these features, we performed isolation, biochemical and enzymological characterization, molecular cloning and molecular modelling. The native enzyme is composed of two catalytic units (65 kDa each) and two propeptides (15 kDa each), yielding a molecular weight of 160 kDa. Enzyme deglycosylated by endoglycosidase H had comparable activity, but reduced stability. We have cloned and sequenced the gene coding for the entire hexosaminidase from P. oxalicum. Sufficient sequence identity of this hexosaminidase with the structurally solved enzymes from bacteria and humans with complete conservation of all catalytic residues allowed us to construct a molecular model of the enzyme. Results from molecular dynamics simulations and substrate docking supported the experimental kinetic and substrate specificity data and provided a molecular explanation for why the hexosaminidase from P. oxalicum is unique among the family of fungal hexosaminidases.     

Direct voltammetry and electrochemical catalysis with horseradish peroxidase in polyacrylamide hydrogel films

This paper reports the direct voltammetry of horseradish peroxidase (HRP) incorporated in amphiphilic polyacrylamide (PAM) films modified on pyrolytic graphite (PG) electrodes. Cyclic voltammetry of HRP-PAM films showed a pair of well-defined, nearly reversible peaks at approximately -0.33 V vs. SCE in pH 7.0 buffers, characteristic of HRP heme Fe(III)/Fe(II) redox couple. The PAM films in solution contained large amounts of water and formed a hydrogel, and provided a favorable microenvironment for HRP and facilitated its direct electron transfer with underlying PG electrodes. The apparent heterogeneous electron transfer rate constant (k(s)) and formal potential (E*') were estimated by fitting the data of square wave voltammetry (SWV) with the non-linear regression analysis. UV-vis absorption spectra demonstrated that HRP in PAM films retained its secondary structure similar to its native state. The embedded HRP in PAM films showed the electrocatalytic activity to various substrates such as nitrite, oxygen and hydrogen peroxide. The possible mechanism of catalytic reaction of H(2)O(2) with HRP-PAM films was proposed.     

Effects of phthalic anhydride modification on horseradish peroxidase stability and activity

Phthalic anhydride (PA) modification stabilizes horseradish peroxidase (HRP) by reversal of the positive charge on two of HRP's six lysine residues. Native and PA-HRP had half-inactivation temperatures of 51 and 65 degrees C and half-lives at 65 degrees C of 4 and 17 min, respectively. PA-HRP was more resistant to dimethylformamide at room temperature and tetrahydrofuran at 60 degrees C and to unfolding by heat, guanidine chloride, EDTA, and the reducing agent tris(2-carboxyethyl)phosphine hydrochloride. Binding of the hydrophobic probe Nile Red to the native enzyme and to PA-HRP was similar. The kinetics of both HRPs with the substrates ABTS, ferrocyanide, ferulic acid, and indole-3-propionic acid were measured, as was binding of the inhibitor benzhydroxamic acid. Small improvements in the catalytic properties were detected.     

Enzyme-mediated hydrogel encapsulation of single cells for high-throughput screening and directed evolution of oxidoreductases

Directed evolution of oxidoreductases to improve their catalytic properties is being ardently pursued in the industrial, biotechnological, and biopharma sectors. Hampering this pursuit are current enzyme screening methods that are limited in terms of throughput, cost, time, and complexity. We present a directed evolution strategy that allows for large-scale one-pot screening of glucose oxidase (GOx) enzyme libraries in well-mixed homogeneous solution. We used GOx variants displayed on the outer cell wall of yeasts to initiate a cascade reaction with horseradish peroxidase (HRP), resulting in peroxidase-mediated phenol cross-coupling and encapsulation of individual cells in well-defined fluorescent alginate hydrogel shells within ~10 min in mixed cell suspensions. Following application of denaturing stress to whole-cell GOx libraries, only cells displaying GOx variants with enhanced stability or catalytic activity were able to carry out the hydrogel encapsulation reaction. Fluorescence-activated cell sorting was then used to isolate the enhanced variants. We characterized three of the newly evolved Aspergillus niger GOx enzyme sequences and found up to ~5-fold higher specific activity, enhanced thermal stability, and differentiable glycosylation patterns. By coupling intracellular gene expression with the rapid formation of an extracellular hydrogel capsule, our system improves high-throughput screening for directed evolution of H ₂O ₂-producing enzymes many folds.     

Dicyclohexylcarbodiimide cross-links two conserved residues, Asp-184 and Lys-72, at the active site of the catalytic subunit of cAMP-dependent protein kinase

In the absence of MgATP, the catalytic subunit of cAMP-dependent protein kinase is irreversibly inhibited by the hydrophobic carbodiimide dicyclohexylcarbodiimide, and this inhibition is most likely due to the formation of a cross-link between a carboxyl group and a lysine residue in the active site (Toner-Webb & Taylor, 1987). In order to identify these cross-linked residues, the catalytic subunit was modified by dicyclohexylcarbodiimide and then treated with acetic anhydride and digested with trypsin. The resulting peptides were resolved by high-performance liquid chromatography. One major absorbing tryptic peptide and one smaller peptide consistently and reproducibly showed a decrease in absorbance after the catalytic subunit had been treated with DCCD. These peptides correspond to residues 166-190 and 57-93, respectively. A unique peptide was isolated from the modified catalytic subunit, and the sequence of this peptide established that the cross-linking occurred between Asp-184 and Lys-72. The cross-linking of these two residues, which were both identified previously as essential residues, confirms the likelihood that each plays a role in the functioning of this enzyme. The fact that Asp-184 and Lys-72 appear to be invariant in all protein kinases further supports the hypothesis that these two residues, located close to one another at the active site of the enzyme, play essential roles in catalysis.     

Chemical and kinetic evidence for an essential histidine in horseradish peroxidase for iodide oxidation.

Horseradish peroxidase (HRP), when incubated with diethylpyrocarbonate (DEPC), shows a time-dependent loss of iodide oxidation activity. The inactivation follows pseudo-first order kinetics with a second order rate constant of 0.43 min-1 M-1 at 30 degrees C and is reversed by neutralized hydroxylamine. The difference absorption spectrum of the modified versus native enzyme shows a peak at 244 nm, characteristic of N-carbethoxyhistidine, which is diminished by treatment with hydroxylamine. Correlation between the stoichiometry of histidine modification and the extent of inactivation indicates that out of 2 histidine residues modified, one is responsible for inactivation. A plot of the log of the reciprocal half-time of inactivation against log DEPC concentration further suggests that only 1 histidine is involved in catalysis. The rate of inactivation shows a pH dependence with an inflection point at 6.2, indicating histidine derivatization by DEPC. Inactivation due to modification of tyrosine, lysine, or cysteine has been excluded. CD studies reveal no significant change in the protein or heme conformation following DEPC modification. We suggest that a unique histidine residue is required for maximal catalytic activity of HRP for iodide oxidation.     

Selective alteration of substrate specificity by replacement of aspartic acid-189 with lysine in the binding pocket of trypsin

To test the role of Asp-189 which is located at the base of the substrate binding pocket in determining the specificity of trypsin toward basic substrates, this residue was replaced with a lysine residue by site-directed mutagenesis. Both rat trypsinogen and Lys-189 trypsinogen were expressed and secreted into the periplasmic space of Escherichia coli. The proteins were purified to homogeneity and activated by porcine enterokinase, and their catalytic activities were determined on natural and synthetic substrates. Lys-189 trypsin displayed no catalytic activity toward arginyl and lysyl substrates. Further, there was no compensatory change in specificity toward acidic substrates; no cleavage of aspartyl or glutamyl bonds was detected. Additional studies of substrate specificity involving gas-phase sequence analyses of digested natural substrates revealed an inherent but low chymotrypsin-like activity of trypsin. This activity was retained but modified by the Asp to Lys change at position 189. In addition to hydrolyzing phenylalanyl and tyrosyl peptide bonds, the mutant enzyme has the unique property of cleaving leucyl bonds. On the basis of computer graphic modeling studies of the Lys-189 side chain, it appears that the positively charged NH2 group is directed outside the substrate binding pocket. The resulting hydrophobic cavity may explain the altered substrate specificity of the mutant enzyme. The relatively low chymotrypsin-like activity of both recombinant enzymes may be due to distorted positioning of the scissile bond with respect to the catalytic triad rather than to the lack of sufficient interaction between the hydrophobic side chains and the substrate binding pocket of the enzyme.     

Covalently modified microperoxidases as heme-peptide models for peroxidases

Microperoxidase-8 (MP8) and microperoxidase-9 (MP9) have been covalently modified by attachment of proline-containing residues to the amino terminal peptide chain in order to obtain new peroxidase model systems. The catalytic activities of these derivatives in the oxidation of p-cresol by hydrogen peroxide have been compared to that of MP8. The presence of steric hindrance above the heme reduces the formation rate of the catalytically active species, while the reactivity is increased when the amino group of a proline residue is close to the iron. The modification of the catalyst affects the rate of degradation processes undergone by the heme group during catalysis. A bulky aromatic group on the distal side decreases the stability of the complex because it reduces the mobility of a phenoxy radical species formed during catalysis, while the presence of proline residues increases the number of turnovers of the heme catalysts before degradation. The complex Pro2-MP8 obtained by addition of two proline residues to MP8 exhibits the best catalytic performance in terms of activity and chemical stability.     

Biotechnological applications of peroxidases

Peroxidases are widely distributed in nature. Reduction of peroxides at the expense of electron donating substrates, make peroxidases useful in a number of biotechnological applications. Enzymes such as lignin peroxidase and manganese peroxidase, both associated with lignin degradation, may be successfully used for biopulping and biobleaching in the paper industry, and can produce oxidative breakdown of synthetic azo dyes. Oxidative polymerization of phenols and aromatic amines conducted by horseradish peroxidase (HRP) in water and water-miscible organic solvents, may lead to new types of aromatic polymers. Site directed mutagenesis of HRP has been used to improve the enantioselectivity of arylmethylsulfide oxidations. Peroxidase has a potential for soil detoxification, while HRP as well as soybean and turnip peroxidases have been applied for the bioremediation of wastewater contaminated with phenols, cresols, and chlorinated phenols. Peroxidase based biosensors have found use in analytical systems for determination of hydrogen peroxide and organic hydroperoxides, while co-immobilized with a hydrogen peroxide producing enzyme, they can be used for determination of glucose, alcohols, glutamate and choline. Peroxidase has also been used for practical analytical applications in diagnostic kits, such as quantitation of uric acid, glucose, cholesterol, lactose, and so on. Enzyme linked immunorbent assay (ELISA) tests on which peroxidase is probably the most common enzyme used for labeling an antibody, are a simple and reliable way of detecting toxins, pathogens, cancer risk in bladder and prostate, and many other analytes. Directed evolution methods, appear to be a valuable alternative to engineer new catalyst forms of plant peroxidases from different sources to overcome problems of stability and to increase thermal resistance.     

Identification of critical lysyl residues in the pyrophosphate-dependent phosphofructo-1-kinase of Propionibacterium freudenreichii.

Pyrophosphate-dependent 6-phosphofructo-1-kinase (PPi-PFK) from Propionibacterium freudenreichii was inactivated by low concentrations of the lysine-specific reagent pyridoxal phosphate (PLP) after sodium borohydride reduction. The substrates fructose 6-phosphate and fructose 1,6-bisphosphate protected against inactivation whereas inorganic pyrophosphate had little effect. An HPLC profile of a tryptic digest of PPi-PFK modified at low concentrations of PLP showed a single major peak with only a small number of minor peaks. The major peak peptide was isolated and sequenced to obtain IGAGXTMVQK, where X represents a modified lysine residue, corresponding to Lys-315. Lys-315 was protected from reaction with PLP by fructose 1,6-bisphosphate. As indicated by HPLC maps of PPi-PFK modified with varying concentrations of PLP, a direct correlation was observed between activity loss and the modification of Lys-315. Two of the minor peptide peaks were shown to contain Lys-80 and Lys-85, which were modified in a mutually exclusive manner. Partial protection against modification of these two residues was provided by MgPPi. The data were used to adjust the sequence alignment of the Propionibacterium enzyme with that of ATP-dependent PFK of Escherichia coli to identify homologous residues in the substrate binding site. It is suggested that Lys-315 interacts with the 6-phosphate of fructose 6-phosphate and that Lys-80 and -85 may be located near the pyrophosphate binding site.     

The Saccharomyces cerevisiae succinate dehydrogenase anchor subunit, Sdh4p: mutations at the C-terminal lys-132 perturb the hydrophobic domain

The yeast succinate dehydrogenase (SDH) is a tetramer of non-equivalent subunits, Sdh1p-Sdh4p, that couples the oxidation of succinate to the transfer of electrons to ubiquinone. One of the membrane anchor subunits, Sdh4p, has an unusual 30 amino acid extension at the C-terminus that is not present in SDH anchor subunits of other organisms. We identify Lys-132 in the Sdh4p C-terminal region as necessary for enzyme stability, ubiquinone reduction, and cytochrome b562 assembly in SDH. Five Lys-132 substituted SDH4 genes were constructed by site-directed mutagenesis and introduced into an SDH4 knockout strain. The mutants, K132E, K132G, K132Q, K132R, and K132V were characterized in vivo for respiratory growth and in vitro for ubiquinone reduction, enzyme stability, and cytochrome b562 assembly. Only the K132R substitution, which conserves the positive charge of Lys-132, produces a wild-type enzyme. The remaining four mutants do not affect the ability of SDH to oxidize succinate in the presence of the artificial electron acceptor, phenazine methosulfate, but impair quinone reductase activity, enzyme stability, and heme insertion. Our results suggest that the presence of a positive charge on residue 132 in the C-terminus of Sdh4p is critical for establishing a stable conformation in the SDH hydrophobic domain that is compatible with ubiquinone reduction and cytochrome b562 assembly. In addition, our data suggest that heme does not play an essential role in quinone reduction.