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.

A kinetic epoxidation assay for chloroperoxidase.

Chloroperoxidase exhibits a wide variety of enantioselective epoxidation reactions. Until now, the epoxidation activities have been mainly evaluated using elaborate gas chromatographic methods. This paper reports a rapid and convenient spectrophotometric assay for CPO. The disappearance of indene by catalytic epoxidation is monitored at 250 nm and this is used as an index of enzyme activity. This method will prove to be highly useful in large-scale screening of mutants.

Replacement of the proximal heme thiolate ligand in chloroperoxidase with a histidine residue.

Chloroperoxidase is a versatile heme enzyme which can cross over the catalytic boundaries of other oxidative hemoproteins and perform multiple functions. Chloroperoxidase, in addition to catalyzing classical peroxidative reactions, also acts as a P450 cytochrome and a potent catalase. The multiple functions of chloroperoxidase must be derived from its unique active site structure. Chloroperoxidase possesses a proximal cysteine thiolate heme iron ligand analogous to the P450 cytochromes; however, unlike the P450 enzymes, chloroperoxidase possesses a very polar environment distal to its heme prosthetic group and contains a glutamic acid residue in close proximity to the heme iron. The presence of a thiolate ligand in chloroperoxidase has long been thought to play an essential role in its chlorination and epoxidation activities; however, the research reported in this paper proves that hypothesis to be invalid. To explore the role of Cys-29, the amino acid residue supplying the thiolate ligand in chloroperoxidase, Cys-29 has been replaced with a histidine residue. Mutant clones of the chloroperoxidase genome have been expressed in a Caldariomyces fumago expression system by using gene replacement rather than gene insertion technology. C. fumago produces wild-type chloroperoxidase, thus requiring gene replacement of the wild type by the mutant gene. To the best of our knowledge, this is the first time that gene replacement has been reported for this type of fungus. The recombinant histidine mutants retain most of their chlorination, peroxidation, epoxidation, and catalase activities. These results downplay the importance of a thiolate ligand in chloroperoxidase and suggest that the distal environment of the heme active site plays the major role in maintaining the diverse activities of this enzyme.

Expression of Batis maritima methyl chloride transferase in Escherichia coli.

Methyl chloride transferase, a novel enzyme found in several fungi, marine algae, and halophytic plants, is a biological catalyst responsible for the production of atmospheric methyl chloride. A previous paper reports the purification of this methylase from Batis maritima and the isolation of a cDNA clone of the gene for this enzyme. In this paper, we describe the isolation of a genomic clone of the methylase gene and the expression of recombinant methyl chloride transferase in Escherichia coli and compare the kinetic behavior of the wild-type and recombinant enzyme. The recombinant enzyme is active and promotes the production of methyl chloride by E. coli under in vivo conditions. The kinetic data indicate that the recombinant and wild-type enzymes have similar halide (Cl-, Br-, and I-)-binding capacities. Both the recombinant and wild-type enzymes were found to function well in high NaCl concentrations. This high salt tolerance resembles the activity of halobacterial enzymes rather than halophytic plant enzymes. These findings support the hypothesis that this enzyme functions in the control and regulation of the internal concentration of chloride ions in halophytic plant cells.

cDNA cloning of Batis maritima methyl chloride transferase and purification of the enzyme.

Methyl chloride transferase catalyzes the synthesis of methyl chloride from S-adenosine-L-methionine and chloride ion. This enzyme has been purified 2,700-fold to homogeneity from Batis maritima, a halophytic plant that grows abundantly in salt marshes. The purification of the enzyme was accomplished by a combination of ammonium sulfate fractionation, column chromatography on Sephadex G100 and adenosine-agarose, and TSK-250 size-exclusion HPLC. The purified enzyme exhibits a single band on SDS/PAGE with a molecular mass of approximately 22.5 kDa. The molecular mass of the purified enzyme was 22,474 Da as determined by matrix-associated laser desorption ionization mass spectrometry. The methylase can function in either a monomeric or oligomeric form. A 32-aa sequence of an internal fragment of the methylase was determined (GLVPGCGGGYDVVAMANPER FMVGLDIXENAL, where X represents unknown residue) by Edman degradation, and a full-length cDNA of the enzyme was obtained by rapid amplification of cDNA ends-PCR amplification of cDNA oligonucleotides. The cDNA gene contains an ORF of 690 bp encoding an enzyme of 230 aa residues having a predicted molecular mass of 25,761 Da. The disparity between the observed and calculated molecular mass suggests that the methylase undergoes posttranslational cleavage, possibly during purification. Sequence homologies suggest that the B. maritima methylase defines a new family of plant methyl transferases. A possible function for this novel methylase in halophytic plants is discussed.

Hypersensitive radical probe studies of chloroperoxidase-catalyzed hydroxylation reactions.

The oxidation of hypersensitive radical probes by chloroperoxidase from Caldariomyces fumago (CPO) was studied in an attempt to "time" a putative radical intermediate. Oxidation of (trans-2-phenylcyclopropyl)methane, previously studied by Zaks and Dodds [Zaks, A., and Dodds, D. R. (1995) J. Am. Chem. Soc. 115, 10419-10424] was reinvestigated. Unrearranged oxidation products were found as previously reported, and control experiments demonstrated that the cyclic alcohol from oxidation at the cyclopropylcarbinyl position, while subject to further oxidation, survives CPO oxidation as detectable species. However, in contrast to the report by Zaks and Dodds, the rearranged alcohol product expected from ring opening of a cyclopropylcarbinyl radical intermediate was shown to be unstable toward the enzyme oxidation reaction. Because of this instability, two new hypersensitive radical probes, (trans-2-phenylcyclopropyl)ethane and 2-(trans-2-phenylcyclopropyl)propane, and their potential cyclic and acyclic products from oxidation at the cyclopropylcarbinyl position were synthesized and tested. Oxidation of both of these probes at the cyclopropylcarbinyl position by CPO gave unrearranged alcohol products only, but control experiments again demonstrated that the rearranged alcohol products were unstable toward CPO oxidation conditions. From the combination of the probe and control studies, the lifetime of a putative radical intermediate must be less than 3 ps. Whereas the results are consistent with an insertion mechanism for production of alcohol product, they do not exclude a very short-lived intermediate.

Unusual propargylic oxidations catalyzed by chloroperoxidase.

This paper describes a new chloroperoxidase oxidative activity, namely, propargylic oxidations. Under appropriate conditions, chloroperoxidase catalyzes the oxidation of a variety of 2-alkynes to aldehydes via alcohol intermediates. Both hydrogen peroxide and t-butyl hydroperoxide can serve as terminal oxidants. The triple bond in the substrate is usually untouched. A free radical mechanism is proposed for the initial hydroxylation step in the overall reaction.

Mössbauer and electron paramagnetic resonance studies of chloroperoxidase following mechanism-based inactivation with allylbenzene.

We have used Mössbauer and electron paramagnetic resonance (EPR) spectroscopy to study a heme-N-alkylated derivative of chloroperoxidase (CPO) prepared by mechanism-based inactivation with allylbenzene and hydrogen peroxide. The freshly prepared inactivated enzyme ("green CPO") displayed a nearly pure low-spin ferric EPR signal with g = 1.94, 2.15, 2.31. The Mössbauer spectrum of the same species recorded at 4.2 K showed magnetic hyperfine splittings, which could be simulated in terms of a spin Hamiltonian with a complete set of hyperfine parameters in the slow spin fluctuation limit. The EPR spectrum of green CPO was simulated using a three-term crystal field model including g-strain. The best-fit parameters implied a very strong octahedral field in which the three 2T2 levels of the (3d)5 configuration in green CPO were lowest in energy, followed by a quartet. In native CPO, the 6A1 states follow the 2T2 ground state doublet. The alkene-mediated inactivation of CPO is spontaneously reversible. Warming of a sample of green CPO to 22 degrees C for increasing times before freezing revealed slow conversion of the novel EPR species to two further spin S = 1/2 ferric species. One of these species displayed g = 1.82, 2.25, 2.60 indistinguishable from native CPO. By subtracting spectral components due to native and green CPO, a third species with g = 1.86, 2.24, 2.50 could be generated. The EPR spectrum of this "quasi-native CPO," which appears at intermediate times during the reactivation, was simulated using best-fit parameters similar to those used for native CPO.

Probing the heme iron coordination structure of pressure-induced cytochrome P420cam.

Cytochrome P450cam was subjected to high pressures of 2.2 kbar, converting the enzyme to its inactive form P420cam. The resultant protein was characterized by electron paramagnetic resonance, magnetic circular dichroism, circular dichroism, and electronic absorption spectroscopy. A range of exogenous ligands has been employed to probe the coordination structure of P420cam. The results suggest that conversion to P420cam involves a conformational change which restricts the substrate binding site and/or alters the ligand access channel. The reduction potential of P420cam is essentially the same in the presence or absence of camphor (-211 +/- 10 and -210 +/- 15 mV, respectively). Thus, the well-documented thermodynamic regulation of enzymatic activity for P450cam in which the reduction potential is coupled to camphor binding is not found with P420cam. Further, cyanide binds more tightly to P420cam (Kd = 1.1 +/- 0.1 mM) than to P450cam (Kd = 4.6 +/- 0.2 mM), reflecting a weakened iron-sulfur ligation. Spectral evidence reported herein for P420cam as well as results from a parallel investigation of the spectroscopically related inactive form of chloroperoxidase lead to the conclusion that a sulfur-derived proximal ligand is coordinated to the heme of ferric cytochrome P420cam.

Probing the heme iron coordination structure of alkaline chloroperoxidase.

The mechanism by which the heme-containing peroxidase, chloroperoxidase, is able to chlorinate substrates is poorly understood. One approach to advance our understanding of the mechanism of the enzyme is to determine those factors which contribute to its stability. In particular, under alkaline conditions, chloroperoxidase undergoes a transition to a new, spectrally distinct form, with accompanying loss of enzymatic activity. In the present investigation, ferric and ferrous alkaline chloroperoxidase (C420) have been characterized by electronic absorption, magnetic circular dichroism, and electron paramagnetic resonance spectroscopy. The heme iron oxidation state influences the transition to C420; the pKa for the alkaline transition is 7.5 for the ferric protein and 9.5 for the ferrous protein. The five-coordinate, high-spin ferric native protein converts to a six-coordinate low-spin species (C420) as the pH is raised above 7.5. The inability of ferric C420 to bind exogenous ligands, as well as the dramatically increased reactivity of the proximal Cys29 heme ligand toward modification by the sulfhydryl reagent p-mercuribenzoate, suggests that a conformational change has occurred during conversion to C420 that restricts access to the peroxide binding site while increasing the accessibility of Cys29. However, it does appear that Cys29-derived ligation is at least partially retained by ferric C420, potentially in a thiolate/imidazole coordination sphere. Ferrous C420, on the other hand, appears not to possess a thiolate ligand but instead likely has a bis-imidazole (histidine) coordination structure. The axial ligand trans to carbon monoxide in ferrous-CO C420 may be a histidine imidazole. Since chloroperoxidase functions normally through the ferric and higher oxidation states, the fact that the proximal thiolate ligand is largely retained in ferric C420 clearly indicates that additional factors such as the absence of a vacant sixth coordination site sufficiently accessible for peroxide binding may be the cause of catalytic inactivity.

High-pressure-assisted reconstitution of recombinant chloroperoxidase.

An expression vector containing a T7 promoter and an OmpA signal sequence followed by the DNA sequence of mature chloroperoxidase from the fungus Caldariomyces fumago has been transformed into Escherichia coli. This construct gave high-level expression of apochloroperoxidase when induced with isopropyl thiogalactopyranoside. The nonglycosylated apoenzyme was secreted into periplasmic space. The recombinant apochloroperoxidase was expressed at a level representing about 2% of the total cellular protein. Before conversion to holoenzyme, the apochloroperoxidase was denatured in 8 M urea and partially purified by DEAE chromatography. Maximum yields of holoenzyme were obtained when the denatured apochloroperoxidase, dissolved in a refolding buffer containing iron protoporphyrin IX, calcium ions, and oxidized glutathione, was subjected to high pressure (207 MPa) at -12 degrees C and then allowed to refold at atmospheric pressure and room temperature. The recombinant holoenzyme was characterized by absorption and CD spectroscopy and tested for halogenation and peroxidation activity. The yield of active holochloroperoxidase was about 5% when high-pressure treatment was used as part of the reconstitution process. In the absence of pressure treatment, holoenzyme was formed at about the 1% level. The holochloroperoxidase preparations which resulted from high-pressure treatment showed, upon return to atmospheric pressure, a considerably higher content of native-like secondary structure compared to the nonpressurized preparations. These experiments show that active recombinant chloroperoxidase molecules can be produced, and prove that glycosylation is not a mandatory requirement for chloroperoxidase refolding.

X-ray absorption near edge studies of cytochrome P-450-CAM, chloroperoxidase, and myoglobin. Direct evidence for the electron releasing character of a cysteine thiolate proximal ligand.

The low spin ferric and low and high spin ferrous forms of myoglobin, bacterial cytochrome P-450-CAM, and chloroperoxidase have been examined by Fe-K x-ray absorption edge spectroscopy. The positions of the absorption edge and the shapes of preedge and edge regions of imidazole adducts of ferric P-450-CAM and chloroperoxidase are essentially the same when compared with thiolate-ligated ferric myoglobin. As these three protein derivatives all have six-coordinate, low spin, ferric hemes with axial imidazole and thiolate ligands, the superposition of x-ray absorption edge spectral properties demonstrates that the protein environment does not effect the spectra, provided one compares heme iron centers with identical coordination numbers, spin and oxidation states, and ligand sets. In contrast, a 0.96 eV difference is observed in the energy of the absorption edge for imidazole- and thiolate-ligated ferric myoglobin with the latter shifted to lower energy as observed for ferrous myoglobin states. Similarly, in the low spin ferric-imidazole and ferrous-CO states, the energies of the absorption edge for chloroperoxidase and P-450-CAM are shifted in the direction of the ferrous state (to lower energy) when compared with those for analogous myoglobin derivatives. In the deoxyferrous high spin state, comparison of the edge spectra of chloroperoxidase with analogous data for cytochrome P-450-CAM suggests that the electron density at the iron is similar for these two protein states. The shifts observed in the energies of the x-ray absorption edge for the thiolate-ligated states of these proteins relative to derivatives lacking a thiolate ligand provide a direct measure of the electron releasing character of a thiolate axial ligand. These results therefore support the suggested role of the cysteinate proximal ligand of P-450 as a strong internal electron donor to promote O-O bond cleavage in the putative ferric-peroxide intermediate to generate the proposed ferryl-oxo "active oxygen" state of the reaction cycle.

Role of flavin in acetoin production by two bacterial pyruvate oxidases.

Escherichia coli pyruvate oxidase (POXEC) requires FAD both for the oxidative decarboxylation of pyruvate to acetate and CO2 and for the formation of acetoin from pyruvate and acetaldehyde. Prior work has shown that the catalytic activity (kcat/Km) for POXEC in the oxidative reaction is stimulated approximately 450-fold by amphiphilic activators. This paper shows that the acetoin reaction does not respond to activation. The FAD requirement for acetoin formation can be replaced by 5-deaza-FAD and 6-hydroxy-FAD, FAD analogs which form kinetically stable oxidized and reduced enzyme species, respectively. As would be expected, the 5-deaza- and 6-hydroxy-FAD enzymes are not active in the oxidative reaction. A second flavin pyruvate oxidase from Pediococcus pseudomonas (POXPP), which catalyzes the oxidative decarboxylation of pyruvate to CO2 and acetyl phosphate, also requires FAD for acetoin formation. POXPP has an oxidative rate comparable to that of POXEC, but in comparison to POXEC, POXPP catalyzes acetoin formation at a much reduced rate. Again, as was found with the POXEC, an FAD analog incapable of undergoing facile oxidation-reduction reactions also could replace the FAD requirement in the POXPP acetoin reaction. The results indicate that the role for FAD in acetoin formation with both enzymes is based on a structural requirement and that FAD does not participate in a redox function in the acetoin reaction.

Chemical and transient state kinetic studies on the formation and decomposition of horseradish peroxidase compounds XI and XII.

Previous studies on the chlorination reaction catalyzed by horseradish peroxidase using chlorite as the source of chlorine detected the formation of a chlorinating intermediate that was termed Compound X (Shahangian, S., and Hager, L.P. (1982) J. Biol. Chem. 257, 11529-11533). These studies indicated that at pH 10.7, the optical absorption spectrum of Compound X was similar to the spectrum of horseradish peroxidase Compound II. Compound X was shown to be quite stable at alkaline pH values. This study was undertaken to examine the relationship between the oxidation state of the iron protoporphyrin IX heme prosthetic group in Compound X and the chemistry of the halogenating intermediate. The experimental results show that the optical absorption properties and the oxidation state of the heme prosthetic group in horseradish peroxidase are not directly related to the presence of the activated chlorine atom in the intermediate. The oxyferryl porphyrin heme group in alkaline Compound X can be reduced to a ferric heme species that still retains the activated chlorine atom. Furthermore, the reaction of chlorite with horseradish peroxidase at acidic pH leads to the secondary formation of a green intermediate that has the spectral properties of horseradish peroxidase Compound I (Theorell, H. (1941) Enzymologia 10, 250-252). The green intermediate also retains the activated chlorine atom. By analogy to peroxidase Compound I chemistry, the heme prosthetic group in the green chlorinating intermediate must be an oxyferryl porphyrin pi-cation radical species (Roberts, J. E., Hoffman, B. M., Rutter, R. J., and Hager, L. P. (1981) J. Am. Chem. Soc. 103, 7654-7656). To be consistent with traditional peroxidase nomenclature, the red alkaline form of Compound X has been renamed Compound XII, and the green acidic form has been named Compound XI. The transfer of chlorine from the chlorinating intermediate to an acceptor molecule follows an electrophilic (rather than a free radical) path. A mechanism for the reaction is proposed in which the activated chlorine atom is bonded to a heteroatom on an active-site amino acid side chain. Transient state kinetic studies show that the initial intermediate, Compound XII, is formed in a very fast reaction. The second-order rate constant for the formation of Compound XII is approximately 1.1 x 10(7) M-1 s-1. The rate of formation of Compound XII is strongly pH-dependent. At pH 9, the second-order rate constant for the formation of Compound XII drops to 1.5 M-1 s-1. At acidic pH values, Compound XII undergoes a spontaneous first-order decay to yield Compound XI.(ABSTRACT TRUNCATED AT 400 WORDS)

Minimum requirements for protease activation of flavin pyruvate oxidase.

Previous investigations have shown that the catalytic efficiency (kcat/KM) of pyruvate oxidase can be enhanced 450-fold by chymotryptic cleavage of a 23-residue peptide (alpha-peptide) from the carboxy terminus of the enzyme. The minimum requirement for proteolytic activation has been investigated by exposing pyruvate oxidase to a variety of carboxypeptidases, either singly or in combination. The extent of carboxypeptidase hydrolysis was followed by analyzing the release of amino acids and by mass spectral analysis of the truncated alpha-peptides which were derived from the carboxypeptidase-treated preparations. The results indicate that the removal of 7 carboxy-terminal residues does not activate the enzyme whereas the removal of 10 or 11 residues produces activated pyruvate oxidase. Activation of pyruvate oxidase by endoproteinase Glu-C confirms the carboxypeptidase results. Endoproteinase Glu-C specificity predicts hydrolytic cleavage of the peptide bond between Glu-561 and Val-562 with the removal of 11 residues from the carboxy terminus of the enzyme.

Electron paramagnetic resonance investigations of exogenous ligand complexes of low-spin ferric chloroperoxidase: further support for endogenous thiolate ligation to the heme iron.

Previous spectroscopic studies of chloroperoxidase have provided evidence for endogenous thiolate sulfur donor ligation to the central heme iron of the enzyme. This conclusion is further supported by recent DNA sequence data which revealed the existence of a third cysteine residue (in addition to a disulfide pair detected earlier) in the protein available for coordination to the heme iron. Thus, chloroperoxidase shares many spectroscopic properties with cytochrome P-450, the only other known thiolate-ligated heme protein. Surprisingly, a previous electron paramagnetic resonance (EPR) study of low-spin ferric chloroperoxidase-ligand complexes (Hollenberg, P.F., Hager, L.P., Blumberg, W.E. and Peisach, J. (1980) J. Biol. Chem. 255, 4801-4807) was unable to provide clear support for the presence of a thiolate ligand, although sulfur coordination was implicated. This was, in part, because an insufficient number of complexes was examined. In this work, we have significantly expanded upon the previous EPR study by using an extensive variety of over twenty exogenous ligands including carbon, nitrogen, oxygen, phosphorus and sulfur donors. Crystal field analysis, using the procedure of Blumberg and Peisach, of the present data in comparison with data for analogous complexes of cytochrome P-450-CAM, thiolate-ligated heme model systems, and myoglobin, is clearly indicative of endogenous thiolate ligation for chloroperoxidase. In addition, the UV-visible absorption and EPR spectral data suggest that a carboxylate ligand is a possible candidate for the endogenous sixth ligand to the heme iron that is responsible for the reversible conversion of ferric chloroperoxidase from high-spin to low-spin at low temperatures (less than 200 K).

Activation of Escherichia coli pyruvate oxidase enhances the oxidation of hydroxyethylthiamin pyrophosphate.

The catalytic efficiency (kcat/Km) of Escherichia coli flavin pyruvate oxidase can be stimulated 450-fold either by the addition of lipid activators or by limited proteolytic hydrolysis. Previous studies have shown that a functional lipid binding site is a mandatory prerequisite for the in vivo functioning of this enzyme (Grabau, C., and Cronan, J. E., Jr. (1986) Biochemistry 25, 3748-3751). The effect of activation on the transient state kinetics of partial reactions in the overall oxidative conversion of pyruvate to acetate and CO2 has now been examined. The rate of decarboxylation of pyruvate to form CO2 and hydroxyethylthiamin pyrophosphate for both activated and unactivated forms of the enzyme is identical within experimental error. The decarboxylation step was measured using substrate concentrations of the enzyme in the absence of an electron acceptor. The pseudo-first order rate constant for the decarboxylation step is 60-80 s-1. The rate of oxidation of hydroxyethylthiamin pyrophosphate and concomitant enzyme-bound flavin reduction was analyzed by stopped-flow methods utilizing synthetic hydroxyethylthiamin pyrophosphate. The pseudo-first order rate for this step with unactivated enzyme was 2.85 s-1 and increased 145-fold for lipid-activated enzyme to 413 s-1 and 61-fold for the proteolytically activated enzyme to 173 s-1. The analysis of a third reaction step, the reoxidation of enzyme-bound FADH, was also investigated by stopped-flow techniques utilizing ferricyanide as the electron acceptor. The rate of oxidation of enzyme.FADH is very fast for both unactivated (1041 s-1) and activated enzyme (645 s-1). The data indicate that the FAD reduction step is the rate-limiting step in the overall reaction for unactivated enzyme. Alternatively, the rate-limiting step in the overall reaction with the activated enzyme shifts to one of the partial steps in the decarboxylation reaction.

Chemical modification of chloroperoxidase with diethylpyrocarbonate. Evidence for the presence of an essential histidine residue.

Chloroperoxidase from Caldariomyces fumago is well documented as an extremely versatile catalyst, and studies are currently being conducted to delineate the fine structural features that allow the enzyme to possess chemical and physical similarities to the peroxidases, catalases, and P-450 cytochromes. Earlier investigations of ligand binding to the heme iron of chloroperoxidase, along with the presence of an invariant distal histidine residue in the active site of peroxidases and catalases, have led to the hypothesis that chloroperoxidase also possesses an essential histidine residue that may participate in catalysis. To address this in a more direct fashion, chemical modification studies were initiated with diethylpyrocarbonate. Incubation of chloroperoxidase with this reagent resulted in a time-dependent inactivation of enzyme. Kinetic analysis revealed that the inactivation was due to a simple bimolecular reaction. The rate of inactivation exhibited a pH dependence, indicating that modification of a titratable residue with a pKa value of 6.91 was responsible for inactivation; this data provided strong evidence for histidine derivatization by diethylpyrocarbonate. To further support these results, inactivation due to cysteine, tyrosine, or lysine modification was ruled out. The stoichiometry of histidine modification was estimated by the increase in absorption at 246 nm, and it was found that more than 1 histidine residue was derivatized when chloroperoxidase was inactivated with diethylpyrocarbonate. However, it was shown that the rates of modification and inactivation were not equivalent. This was interpreted to reflect that both essential and nonessential histidine residues were modified by diethylpyrocarbonate. Kinetic analysis indicated that modification of a single essential histidine residue was responsible for inactivation of the enzyme. Studies with [14C]diethylpyrocarbonate provided stoichiometric support that derivatization of a single histidine inactivated chloroperoxidase. Based on sequence homology with cytochrome c peroxidase, histidine 38 was identified as a likely candidate for the distal residue. Molecular modeling, based on secondary structure predictions, allows for the construction of an active site peptide, and implicates a number of other residues that may participate in catalysis.

Methyl chloride transferase: a carbocation route for biosynthesis of halometabolites.

Enzymatic synthesis of methyl halides through an S-adenosyl methionine transfer mechanism has been detected in cell extracts of Phellinus promaceus (a white rot fungus), Endocladia muricata (a marine red algae), and Mesembryanthemum crystallium (ice plant). This mechanism represents a novel pathway for the formation of halometabolites. The Michaelis constants for chloride and bromide ion and for S-adenosyl methionine in the reaction have been determined for the enzyme from E. muricata. A recent survey of marine algae indicates that there may be a broad distribution of this enzyme among marine algae.