A single point mutation enhances hydroxynitrile synthesis by halohydrin dehalogenase

The cyanide-mediated ring opening of epoxides catalyzed by halohydrin dehalogenases yields β-hydroxynitriles that are of high interest for synthetic chemistry. The best studied halohydrin dehalogenase to date is the enzyme from Agrobacterium radiobacter, but this enzyme (HheC) exhibits only low cyanolysis activities. Sequence comparison between a pair of related halohydrin dehalogenases from Corynebacterium and Mycobacterium suggested that substitution of a threonine that interacts with the active site might be responsible for the higher cyanolytic activity of the former enzyme. Here we report that a variant of HheC in which this substitution (T134A) is adopted displays an up to 11-fold higher activity in cyanide-mediated epoxide ring-opening. The mutation causes removal of the hydrogen bond between residue 134 and the side chain O of the active site serine 132, which donates a hydrogen bond to the substrate oxygen. The mutation also increases dehalogenase rates with various substrates. Structural analysis revealed that the anion-binding site of the mutant enzyme remained unaltered, showing that the enhanced activity is due to altered interactions with the substrate oxygen rather than changes in the nucleophile binding site.     

Defining the involvement of HOCl or Cl2 as enzyme-generated intermediates in chloroperoxidase-catalyzed reactions.

Peroxidatic substrates, catechol (CAT) and 2,4,6-trimethylphenol (TMP) were used as probes of thechloride dependent reactions catalyzed by chloroperoxidase (CPO). TMP is consumed only in the presence of chloride. TMP is a competitive inhibitor versus CAT, but CAT is a noncompetitive inhibitor versus TMP in chloride-dependent CPO-catalyzed peroxidation reactions. The ratio of TMP versus CAT consumed by the chloride-dependent CPO reaction in direct competition studies increases as the chloride concentration is increased from 1.0 to 400 mM. Ratios of non-enzymatic HOCl reactions under conditions otherwise similar to those of the CPO reactions are relatively insensitive to changes in chloride concentration and are experimentally indistinguishable from the values attained by the enzyme system at high chloride concentrations. Comparison of enzymatic ratios with those of the HOCl reactions indicate that the proportion of the enzymatic reaction involving a freely dissociable, enzyme-generated, oxidized halogen species varies from 10% at low chloride concentrations to essentially 100% at high chloride concentrations. All data are consistent with a mechanism in which chloride competes with CAT for binding to both CPO compound I and the CPO chlorinating intermediate (EOCl). Chloride binding to CPO compound I leads to the formation of EOCl and initiates the CPO chloride-dependent pathway. When CAT binds to either compound I or EOCl, it is directly oxidized to product. When chloride binds to EOCl, it either induces release of HOCl or reacts with EOCl to produce Cl2, which is released from the enzyme. TMP and CAT compete for reaction with the free oxidized halogen species. This is the first direct evidence for kinetically significant involvement of a free oxidized halogen species as an intermediate in any CPO-catalyzed reaction.     

Effect of organic solvents on a chloroperoxidase biotransformation

The effect of organic solvents on the chlorination activity of chloroperoxidase (CPO) was identified for use in biotransformations with CPO. CPO was found to chlorinate monochlorodimedon (MCD) in the presence of organic solvents with log P values less than 0. The relative rates of chlorination with chloride ion in the presence of H₂O₂, buffer and 2.5–20% of either dimethyl sulfoxide, N,N-dimethyl formamide, methanol or acetonitrile, were in the range of 10–58% of that in buffer (pH 2.8) at the same reactant concentrations. The presence of such organic solvents was found to alter CPO catalysis by altering the protein conformation and the local environment at the active site. CPO did not display chlorination activity in the presence of organic solvents which had log P values greater than 0.     

Chloroperoxidase-catalyzed enantioselective oxidations in hydrophobic organic media.

Chloroperoxidase from Caldariomyces fumago, a peroxidase that performs P450-like chemistry, was immobilized via covalent attachment into polyurethane foam as well as conjugated with a surfactant or polymer via colyophilization. The resulting preparations catalyzed enantio- and regioselective oxidations in hydrophobic organic media with tert-butyl hydroperoxide as the oxidant.Dried PUR-foam immobilized CPO mediated the selective oxidation of indole to 2-oxindole (regioselectivity: 99%) in water-saturated isooctane or 1-octanol. Thioanisole was converted into the corresponding (R)-sulfoxide (ee > 99%) in isooctane medium.The complexes of CPO with sodium octadecylsulphate or ethyl cellulose mediated the oxidation of thioanisole in water-immiscible organic media with variable enantioselectivity due to radical side-reactions. In the presence of alpha-tocopherol, acting as radical scavenger, the (R)-sulfoxide was formed with ee > 90%. The effect of the water activity on the catalytic activity of the complexes was investigated.The CPO complexes likewise mediated the regioselective oxidation of indole into 2-oxindole in water-saturated isooctane or 1-octanol and its kinetics were investigated. The reaction suffered from substrate inhibition when carried out in isooctane.     

Identification of halohydrin dehalogenase mutants that resist COBE inhibition

The biocatalytic cascade conversion of ethyl 4-chloroacetoacetate (COBE) to ethyl (R)-4-cyano-3-hydroxybutyrate ((R)-HN) for the preparation of atorvastatin represents significant economic and environmental benefits, and is catalyzed by alcohol dehydrogenase and halohydrin dehalogenase (HHDH). However, as the activity of HHDH is inhibited by COBE, the cascade reaction is an inefficient one-pot reaction. In this study, substrate inhibition kinetics analysis was performed and the inhibition by COBE was found to be competitive reversible inhibition. Molecular simulation analysis was used to determine the inhibition mechanism by COBE. The results showed that COBE bound to the active center of HHDH via the formation of hydrogen bonds with the OH groups of S132 and Y145. Site saturation mutagenesis of residues around the active site and at the entrance of the access tunnel was performed, and two target mutant residues were identified, F136 and W249. Small focused mutagenesis on these two residues was performed and the F136V/W249F mutant was successfully found to relieve the activity inhibition of HHDH by COBE. The half inhibiting concentration of mutant F136V/W249F was found to be 20-fold higher than wild-type HHDH. The efficiency of the multi-enzymatic one-pot system for the synthesis of (R)-HN from COBE using mutant F136V/W249F was improved significantly.     

Expanding the Halohydrin Dehalogenase Enzyme Family: Identification of Novel Enzymes by Database Mining

Halohydrin dehalogenases are very rare enzymes that are naturally involved in the mineralization of halogenated xenobiotics. Due to their catalytic potential and promiscuity, many biocatalytic reactions have been described that have led to several interesting and industrially important applications. Nevertheless, only a few of these enzymes have been made available through recombinant techniques; hence, it is of general interest to expand the repertoire of these enzymes so as to enable novel biocatalytic applications. After the identification of specific sequence motifs, 37 novel enzyme sequences were readily identified in public sequence databases. All enzymes that could be heterologously expressed also catalyzed typical halohydrin dehalogenase reactions. Phylogenetic inference for enzymes of the halohydrin dehalogenase enzyme family confirmed that all enzymes form a distinct monophyletic clade within the short-chain dehydrogenase/reductase superfamily. In addition, the majority of novel enzymes are substantially different from previously known phylogenetic subtypes. Consequently, four additional phylogenetic subtypes were defined, greatly expanding the halohydrin dehalogenase enzyme family. We show that the enormous wealth of environmental and genome sequences present in public databases can be tapped for in silico identification of very rare but biotechnologically important biocatalysts. Our findings help to readily identify halohydrin dehalogenases in ever-growing sequence databases and, as a consequence, make even more members of this interesting enzyme family available to the scientific and industrial community.     

Molecular characterisation of coproporphyrinogen oxidase from Glycine max and Arabidopsis thaliana

Coproporphyrinogen III oxidase (CPO; E.C. 1.3.3.3 ) is an enzyme of haem and chlorophyll synthesis. Biochemical studies have indicated that the majority of CPO activity is present in plastids, with no detectable levels in mitochondria. However, this approach cannot rule out low (less than 5%) activity in the mitochondria, nor the possible presence of CPO in the cytosol, where it is found in yeast (Saccharomyces cerevisiae). We have studied this question further using molecular techniques. A cDNA encoding the mature protein of soybean (Glycine max L.) CPO was used to overexpress the enzyme 200-fold in Escherichia coli. The recombinant enzyme, purified to homogeneity in three steps, is a dimer, with a K_m for coproporphyrinogen III of 0.25 ± 0.03 μM and a V_max of 1.48 pkat. Antibodies raised against the purified soybean CPO were used in western blots to show that the enzyme is present in etioplasts but not in mitochondria. In the completely sequenced genome of Arabidopsis thaliana, we identified two genes encoding CPO, but only one of them (AtCPO-I ) was able to complement a yeast mutant defective in the enzyme; the other is likely to be a pseudogene. A construct encoding the first 92 residues of AtCPO-I fused to green fluorescent protein (GFP) was introduced into Arabidopsis plants by Agrobacterium-mediated transformation. Confocal microscopy demonstrated that the CPO–GFP fusion protein was confined exclusively to plastids in leaves and roots, with no GFP seen in the mitochondria or cytosol.     

Low temperature photo-oxidation of chloroperoxidase Compound II

Oxidation of the heme-thiolate enzyme chloroperoxidase (CPO) from Caldariomyces fumago with peroxynitrite (PN) gave the Compound II intermediate, which was photo-oxidized with 365 nm light to give a reactive oxidizing species. Cryo-solvents at pH ≈ 6 were employed, and reactions were conducted at temperatures as low as − 50 °C. The activity of CPO as evaluated by the chlorodimedone assay was unaltered by treatment with PN or by production of the oxidizing transient and subsequent reaction with styrene. EPR spectra at 77 K gave the amount of ferric protein at each stage in the reaction sequence. The PN oxidation step gave a 6:1 mixture of Compound II and ferric CPO, the photolysis step gave an approximate 1:1 mixture of active oxidant and ferric CPO, and the final mixture after reaction with excess styrene contained ferric CPO in 80% yield. In single turnover reactions at − 50 °C, styrene was oxidized to styrene oxide in high yield. Kinetic studies of styrene oxidation at − 50 °C displayed saturation kinetics with an equilibrium constant for formation of the complex of K_bind = 3.8 × 10⁴ M^− 1 and an oxidation rate constant of k_ox = 0.30 s^− 1. UV-Visible spectra of mixtures formed in the photo-oxidation sequence at ca. − 50 °C did not contain the signature Q-band absorbance at 690 nm ascribed to CPO Compound I prepared by chemical oxidation of the enzyme, indicating that different species were formed in the chemical oxidation and the photo-oxidation sequence.     

Chloroperoxidase-catalyzed Epoxidation of Styrene in Aqueous and Nonaqueous Media

To overcome poor product yields and stability in aqueous solution, we have examined the chloroperoxidase (CPO from Caldariomyces fumago ) catalyzed oxidation of styrene in organic media using tert -butyl hydroperoxide as external oxidant. CPO's intrinsic catalytic activity in tert -butanol, as reflected in its k cat value, was ca. one-fourth of that in aqueous buffer, indicating that the enzyme remains highly active in the organic solvent. Styrene epoxidation reactions were modeled in both aqueous and nonaqueous media to provide global kinetic information, which dominates non-initial rate conditions and is heavily influenced by continuous deactivation of the CPO. Deactivation studies revealed that the enzyme is deactivated quickly by the combination of the tert -butyl hydroperoxide and styrene, possibly due to the styrenic free radicals generated during the enzymatic reaction. These results may enable catalyst-engineering strategies to be initiated to improve the prospects of using CPO in nonaqueous media for large-scale epoxidation reactions.     

Atypical kinetic behavior of chloroperoxidase-mediated oxidative halogenation of polycyclic aromatic hydrocarbons

We have identified an atypical kinetic behavior for the oxidative halogenation of several polycyclic aromatic hydrocarbons (PAHs) by chloroperoxidase (CPO) from Caldariomyces fumago. This behavior resembles the capacity of some members of the P450 family to simultaneously recognize several substrate molecules at their active sites. Indeed, fluorometric studies showed that PAHs exist in solution as monomers and π-π dimers that interact to different extents with CPO. The dissociation constants of dimerization were evaluated for every single PAH by spectrofluorometry. Furthermore, docking studies also suggest that CPO might recognize either one or two substrate molecules in its active site. The atypical sigmoidal kinetic behavior of CPO in the oxidative halogenation of PAHs is explained in terms of different kinetic models for non-heteroatomic PAHs (naphthalene, anthracene and pyrene). The results suggest that the actual substrate for CPO in this study was the π-π dimer for all evaluated PAHs.     

Selective oxidations with molecular oxygen,catalyzed by chloroperoxidase in the presence of a reductant

Chloroperoxidase (CPO) catalyzes the oxidation of various substrates with molecular oxygen as the primary oxidant, in the presence of dihydroxyfumaric acid (DHF) as a sacrificial reductant. For example, indole is oxidized to 2-oxindole with up to 77% selectivity and thioanisole to the corresponding R-sulfoxide (e.e. >99%). To our knowledge, these are the first examples of (enantio)selective aerobic oxidations catalyzed by peroxidases. A mechanism is proposed which involves initial formation of hydrogen peroxide via autoxidation of DHF. CPO subsequently uses the hydrogen peroxide for the selective oxidation of the substrate, via an oxygen transfer mechanism. In contrast, horseradish proxidase (HRP) primarily catalyzes the oxidation of DHF via a classical peroxidase mechanism and oxidations of added substrates are aselective.     

Chloroperoxidase-catalyzed Epoxidation of Styrene in Aqueous and Nonaqueous Media

To overcome poor product yields and stability in aqueous solution, we have examined the chloroperoxidase (CPO from Caldariomyces fumago ) catalyzed oxidation of styrene in organic media using tert -butyl hydroperoxide as external oxidant. CPO's intrinsic catalytic activity in tert -butanol , as reflected in its k cat value, was ca. one-fourth of that in aqueous buffer, indicating that the enzyme remains highly active in the organic solvent. Styrene epoxidation reactions were modeled in both aqueous and nonaqueous media to provide global kinetic information, which dominates non-initial rate conditions and is heavily influenced by continuous deactivation of the CPO. Deactivation studies revealed that the enzyme is deactivated quickly by the combination of the tert -butyl hydroperoxide and styrene, possibly due to the styrenic free radicals generated during the enzymatic reaction. These results may enable catalyst-engineering strategies to be initiated to improve the prospects of using CPO in nonaqueous media for large-scale epoxidation reactions.     

Enantioselective epoxidation and carbon-carbon bond cleavage catalyzed by Coprinus cinereus peroxidase and myeloperoxidase

We demonstrate that myeloperoxidase (MPO) and Coprinus cinereus peroxidase (CiP) catalyze the enantioselective epoxidation of styrene and a number of substituted derivatives with a reasonable enantiomeric excess (up to 80%) and in a moderate yield. Three major differences with respect to the chloroperoxidase from Caldariomyces fumago (CPO) are observed in the reactivity of MPO and CiP toward styrene derivatives. First, in contrast to CPO, MPO and CiP produced the (S)-isomers of the epoxides in enantiomeric excess. Second, for MPO and CiP the H(2)O(2) had to be added very slowly (10 eq in 16 h) to prevent accumulation of catalytically inactive enzyme intermediates. Under these conditions, CPO hardly showed any epoxidizing activity; only with a high influx of H(2)O(2) (300 eq in 1.6 h) was epoxidation observed. Third, both MPO and CiP formed significant amounts of (substituted) benzaldehydes as side products as a consequence of C-alpha-C-beta bond cleavage of the styrene derivatives, whereas for CPO and cytochrome c peroxidase this activity is not observed. C-alpha-C-beta cleavage was the most prominent reaction catalyzed by CiP, whereas with MPO the relative amount of epoxide formed was higher. This is the first report of peroxidases catalyzing both epoxidation reactions and carbon-carbon bond cleavage. The results are discussed in terms of mechanisms involving ferryl oxygen transfer and electron transfer, respectively.     

Inactivation of chloroperoxidase by arginine

Inactivation of chloroperoxidase (CPO) from Caldariomyces fumago by arginine was investigated. It was found that the red native CPO solution was turned into a stable green species with a concomitant shift of the Soret band from 398 to 425 nm in the presence of arginine. The green CPO lost almost all of its catalytic activity, and this inactivation was irreversible.Differential UV–vis spectrophotometry was used to examine the binding properties of arginine to CPO. The formation of CPO-arginine (1:1) complex was highly pH-dependent. Fluorescence investigation revealed the exposure degree of prosthetic group increased. Kinetic analysis indicated that CPO has both a high affinity and specificity to arginine.This inactivation may be caused mainly by the binding of guanidinium group in arginine to the acid–base catalytic group Glu183 in CPO. The change of surrounding environment around heme induced by the interaction of heme propionates with arginine and the occupying of the sixth axial ligand position of heme iron by hydroxyl are also reasons bringing on this inactivation.     

Chemical modification of chloroperoxidase for enhanced stability and activity

Chloroperoxidase from Caldariomyces fumago (CPO, EC 1.11.1.10) is one of the most interesting enzymes from the group of heme peroxidases and has been extensively applied in synthetic processes. Nevertheless, the practical application of CPO is limited due to its very low operational stability, especially in the presence of peroxidative compounds. For this reason, effect of chemical modifications of CPO in the stability of the enzyme was studied. Side-chain selective modifications of amino groups of Lys residues, and carboxyl groups of Asp and Glu residues, as well as crosslinking and periodate oxidation of sugar moiety were carried out. The stability of modified CPOs was evaluated at elevated pH and temperature, and in the presence of tert-butyl hydroperoxide. Effect of modification of CPO on the performance of the reaction of Cbz-ethanolamine oxidation was studied as well. Those modifications that involved carboxyl groups via carbodiimide coupled method and the periodate oxidation of the sugar moiety produced better catalysts than native CPO in terms of stability and activity at elevated pH values and temperatures.     

Identification and characterization of a highly S-enantioselective halohydrin dehalogenase from Tsukamurella sp. 1534 for kinetic resolution of halohydrins

Halohydrin dehalogenases are remarkable enzymes which possess promiscuous catalytic activity and serve as potential biocatalysts for the synthesis of chiral halohydrins, epoxides and β-substituted alcohols. The enzyme HheC exhibits a highly R enantioselectivity in the processes of dehalogenation of vicinal halohydrins and ring-opening of epoxides, which attracts more attentions in organic synthesis. Recently dozens of novel potential halohydrin dehalogenases have been identified by gene mining, however, most of the characterized enzymes showed low stereoselectivity. In this study, a novel halohydrin dehalogenase of HheA10 from Tsukamurella sp. 1534 has been heterologously expressed, purified and characterized. Substrate spectrum and kinetic resolution studies indicated the HheA10 was a highly S enantioselective enzyme toward several halohydrins, which produced the corresponding epoxides with the ee (enantiomeric excess) and E values up to >99% and >200 respectively. Our results revealed the HheA10 was a promising biocatalyst for the synthesis of enantiopure aromatic halohydrins and epoxides via enzymatic kinetic resolution of racemic halohydrins. What’s more important, the HheA10 as the first individual halohydrin dehalogenase with the highly S enantioselectivity provides a complementary enantioselectivity to the HheC.     

Immobilization of Chloroperoxidase on Aminopropyl-Glass

Chloroperoxidase (CPO) purified from Caldariomyces fumago CMI 89362 was covalently bound to aminopropyl-glass by using a modification of an established method. Acid-washed glass was derivatized by using aminopropyltriethoxysilane, and the enzyme was ionically bound at low ionic strength. Further treatment with glutaraldehyde covalently linked the enzyme to the glass beads in an active form. No elution of bound activity from glass beads could be detected with a variety of washings. The loading of enzyme protein to the glass beads was highest, 100 mg of CPO per g of glass, at high reaction ratios of CPO to glass, but the specific activity of the immobilized enzyme was highest, 36% of theoretical, at low enzyme-to-carrier ratios. No differences in the properties of the soluble and immobilized enzymes could be detected by a number of criteria: their pH-activity and pH-stability profiles were similar, as were their thermal stabilities. After five uses, the immobilized enzyme retained full activity between pH 6.0 and 6.7.     

Utilization of peroxide and its relevance in oxygen insertion reactions catalyzed by chloroperoxidase.

Chloroperoxidase (CPO) catalyzed oxygen insertions are highly enantioselective and hence of immense biotechnological potential. A peroxide activation step is required to give rise to the compound I species that catalyzes this chiral reaction. A side reaction, a catalase type peroxide dismutation, is another feature of CPO's versatility. This work systematically investigates the utilization of different peroxides for the two reactions, i.e. the catalase type reaction and the oxygen insertion reaction. For the oxygen insertion reaction, indene and phenylethyl sulfide were chosen as substrate models for epoxidation and sulfoxidation respectively. The results clearly show that CPO is stable towards hydrogen peroxide and has a total number of turnovers near one million prior to deactivation. The epoxidation reactions terminate before completion because the enzyme functioning in its catalatic mode quickly removes all of the hydrogen peroxide from the reaction mixture. Sulfoxidation reactions are much faster than epoxidation reactions and thus are better able to compete with the catalase reaction for hydrogen peroxide utilization. A preliminary study towards optimizing the reaction system components for a laboratory scale synthetic epoxidation is reported.     

Monoterpenes as novel substrates for oxidation and halo-hydroxylation with chloroperoxidase from Caldariomyces fumago

Chloroperoxidase (CPO) from Caldariomyces fumago was analysed for its ability to oxidize ten different monoterpenes with hydrogen peroxide as oxidant. In the absence of halide ions geraniol and, to a lesser extent, citronellol and nerol were converted into the corresponding aldehydes, whereas terpene hydrocarbons did not serve as substrates under these conditions. In the presence of chloride, bromide and iodide ions, every terpene tested was converted into one or more products. (1S)-(+)-3-carene was chosen as a model substrate for the CPO-catalysed conversion of terpenes in the presence of sodium halides. With chloride, bromide and iodide, the reaction products were the respective (1S,3R,4R,6R)-4-halo-3,7,7-trimethyl-bicyclo[4.1.0]-heptane-3-ols, as identified by ¹H and ¹³C nuclear magnetic resonance. These product formations turned out to be strictly regio- and stereoselective and proceeded very rapidly and almost quantitatively. Initial specific activities of halohydrin formation increased from 4.22 U mg⁻¹ with chloride to 12.22 U mg⁻¹ with bromide and 37.11 U mg⁻¹ with iodide as the respective halide ion. These results represent the first examples of the application of CPO as a highly efficient biocatalyst for monoterpene functionalization. This is a promising strategy for ‘green’ terpene chemistry overcoming drawbacks usually associated with cofactor-dependent oxygenases, whole-cell biocatalysts and conventional chemical methods used for terpene conversions.