A Stable Organic Free Radical in Anaerobic Benzylsuccinate Synthase of Azoarcus sp. Strain T*

Cynthia J. KriegerDagger , Winfried Roseboom§, Simon P. J. Albracht§, and Alfred M. SpormannDagger ||**

From the Dagger  Department of Civil and Environmental Engineering, Environmental Engineering and Science, Stanford University, Stanford, California 94305, the § Department of Biochemistry, Swammerdam Institute for Life Sciences, University of Amsterdam, Plantage Muidergracht 12, NL-1018 TV Amsterdam, The Netherlands, and the || Department of Biological Sciences, Stanford University, Stanford, California 94305

Received for publication, October 17, 2000, and in revised form, December 14, 2000



    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

The novel enzyme benzylsuccinate synthase initiates anaerobic toluene metabolism by catalyzing the addition of toluene to fumarate, forming benzylsuccinate. Based primarily on its sequence similarity to the glycyl radical enzymes, pyruvate formate-lyase and anaerobic ribonucleotide reductase, benzylsuccinate synthase was speculated to be a glycyl radical enzyme. In this report we use EPR spectroscopy to demonstrate for the first time that active benzylsuccinate synthase from the denitrifying bacterium Azoarcus sp. strain T harbors an oxygen-sensitive stable organic free radical. The EPR signal of the radical was centered at g = 2.0021 and was characterized by a major 2-fold splitting of about 1.5 millitesla. The strong similarities between the EPR signal of the benzylsuccinate synthase radical and that of the glycyl radicals of pyruvate formate-lyase and anaerobic ribonucleotide reductase provide evidence that the benzylsuccinate synthase radical is located on a glycine residue, presumably glycine 828 in Azoarcus sp. strain T benzylsuccinate synthase.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Benzylsuccinate synthase initiates anaerobic toluene mineralization in denitrifying bacteria by catalyzing the addition of toluene to fumarate, forming benzylsuccinate (Fig. 1; Refs. 1 and 2). This toluene fumarate addition reaction may be a general mode for anaerobic toluene metabolism as it has been demonstrated recently in phylogenetically distant bacteria, including several toluene-mineralizing, denitrifying (1, 2), and sulfate-reducing (3, 4) bacteria, as well as a toluene-utilizing phototrophic bacterium (5). Furthermore, this type of fumarate addition reaction may be a general strategy for activating methylbenzenes in the absence of molecular oxygen as it has been shown to be the initial step in anaerobic m-xylene mineralization (6) and has been implicated as the initial step in anaerobic m-cresol mineralization (7). Unlike the initial activation steps in aerobic methylbenzene metabolism whereby the methylbenzene is oxidized directly by molecular oxygen as a cosubstrate (8, 9), benzylsuccinate synthase catalyzes a strictly anaerobic, nonredox reaction. Notably, the benzylsuccinate synthase reaction also seems to be a novel biochemical means for forming a new carbon-carbon bond.


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Fig. 1.   The benzylsuccinate synthase reaction.

Benzylsuccinate synthase, which has been characterized at both the biochemical and molecular level (10-12),1 is believed to be a heterohexamer (alpha 2beta 2gamma 2) composed of three subunits with molecular masses of approximately 98 (alpha  subunit), 8.6 (beta  subunit), and 6.6 (gamma  subunit) kDa. The predicted amino acid sequence of the alpha  subunit of benzylsuccinate synthase (11, 12)1 has strong homology to the well characterized glycyl-radical enzymes, pyruvate formate-lyase (PFL)2 and anaerobic ribonucleotide reductase (ARNR), including a conserved glycine residue and a conserved cysteine residue. Although all of the reported PFLs have two conserved vicinal cysteines, cysteine 418 and cysteine 419 in Escherichia coli PFL, benzylsuccinate synthases and ARNRs have only one conserved cysteine, corresponding to cysteine 419 of E. coli PFL. The conserved amino acids in PFL (13-16) and ARNR (17, 18) are essential for catalysis of their respective reactions. The catalytically active forms of PFL (13-16, 19, 20) and ARNR (17, 18, 21, 22) contain a free radical at the conserved glycine residue; this radical is generated enzymatically by a PFL activase and an ARNR activase, respectively. A gene located immediately upstream of the benzylsuccinate synthase structural genes shares strong predicted amino acid sequence similarity to the PFL- and ARNR-activating enzymes, suggesting that benzylsuccinate synthase may be activated in a similar fashion (11, 12).1 In activated PFL and ARNR, the glycyl radical is assumed to abstract a hydrogen atom from a conserved cysteine residue generating a thiyl radical that initiates substrate transformation (14, 15, 20, 23). Genetic complementation studies in Thauera aromatica sp. T1 showed that the conserved glycine and cysteine residues of benzylsuccinate synthase are important for toluene utilization (12). Based on the molecular similarity of benzylsuccinate synthase to PFL and ARNR, we examined active benzylsuccinate synthase for the presence of an organic free radical.

Using EPR spectroscopy we report here the first experimental evidence that active benzylsuccinate synthase carries a stable organic free radical. Based on the strong spectral similarities between the EPR signal of the benzylsuccinate synthase radical and that of the glycyl radicals of PFL and ARNR, the free radical of benzylsuccinate synthase appears to be located on a glycine residue. Furthermore we found a direct correlation between the appearance of the free radical and enzyme activity, suggesting that the radical is essential for catalysis.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Materials-- All the chemicals used in this study, including 2H2O (D2O; 99.9 atom %) and [ring-U-14C]toluene (>= 98 atom %; 2.8 mCi/mmol specific activity), were purchased from either Aldrich or Sigma. The [ring-U-14C]toluene was diluted to a specific activity of ~42 µCi/mmol for the experiments.

Cultivation of Azoarcus sp. Strain T and Preparation of Cell Extracts-- Azoarcus sp. strain T, a denitrifying bacterium capable of anaerobically mineralizing toluene and m-xylene (24), was cultivated under denitrifying conditions in a bicarbonate-buffered mineral salts medium as described previously (1). Batch cultures totaling 10-12 liters were grown in glass reactors sealed with polytetrafluoroethylene Mininert valves (Alltech Associates, Inc., Deerfield, IL). These cultures were incubated at room temperature (25 °C) in an anaerobic glove box (Coy Laboratory Products, Inc., Grass Lake, MI) with an atmosphere of 80% N2, 10% H2, and 10% CO2. Azoarcus sp. strain T was grown exponentially with benzoate (initial concentration 3 mM) and nitrate (initial concentration 2.5 mM) to an A600 of 0.25-0.5. Benzoate and nitrate were amended repeatedly to the cultures prior to reaching the desired A600. Approximately 20 h prior to harvesting the cells, toluene (initial concentration 350 µM) was added to the cultures to induce synthesis of benzylsuccinate synthase. During the remaining growth period residual benzoate was consumed completely, and the cells switched to toluene metabolism as indicated by the induction of benzylsuccinate synthase activity (data not shown). Cells were harvested anaerobically by centrifugation (1), washed once in anoxic 120 mM potassium phosphate buffer, pH 6.8, amended with 2 mM dithiothreitol (designated as buffer A), and resuspended in 7-12 ml of buffer A (amended with 12 mg of DNase I and ~6 mM MgCl2). Cells were broken anaerobically by four passages through a French pressure cell at 138 megapascal. Unbroken cells and cell debris were removed by anaerobic centrifugation (27,000 × g, 15 min, 4 °C). The supernatant, defined as the cell extract, was divided into 0.5- and 1-ml fractions that were frozen under anaerobic conditions at -20 °C until further use.

Partial Purification of Benzylsuccinate Synthase-- Benzylsuccinate synthase was partially purified from cell extracts of anaerobically grown toluene-induced Azoarcus sp. strain T using a modification of the method described previously (10). Purification steps were conducted anaerobically at ~15 °C in an anaerobic glove box with an atmosphere of 90% N2 and 10% H2. Crude cell extract was passed through a 0.45-µm filter and then applied in batches (35-80 mg of protein) to an Econo-Pac CHT-II hydroxyapatite column (5-ml bed volume, Bio-Rad) attached to an Amersham Pharmacia Biotech FPLC System. The binary eluents used to enrich for benzylsuccinate synthase activity consisted of a 10 mM potassium phosphate buffer, pH 6.8, and a 500 mM potassium phosphate buffer, pH 6.6. Both degassed eluents were amended with 5 mM dithiothreitol. The chromatographic conditions, as described previously (10), consisted of a 1 ml min-1 flow rate starting at an initial phosphate concentration of 120 mM for 1.2 column volumes and then a linear gradient from 120 to 400 mM phosphate at a rate of 25 mM min-1. One-ml fractions were collected and assayed for benzylsuccinate synthase activity as described below. Results from the hydroxyapatite chromatography were similar to those described earlier (10) with the following exception: the specific activity of the cell extract was 25 nmol min-1 (mg of protein)-1 and that of enriched benzylsuccinate synthase ranged from 150 to 400 nmol min-1 (mg of protein)-1, depending on the particular fraction. Benzylsuccinate synthase activity typically eluted between 160 and 235 mM phosphate. Attempts to purify benzylsuccinate synthase further by gel filtration resulted in a greater than 95% loss of specific activity relative to the hydroxyapatite fraction (10). Thus, to retain activity of benzylsuccinate synthase, hydroxyapatite-enriched fractions were used for this study. The hydroxyapatite fractions used in this study contained a greater than 7-fold enrichment of benzylsuccinate synthase and less than 3% of the protein of the cell extract placed on the column. Protein concentrations were determined by the method of Bradford (25) using a commercially available protein-binding dye from Bio-Rad. Bovine serum albumin was used as the standard.

In Vitro Assay for Benzylsuccinate Synthase-- The activity of benzylsuccinate synthase was measured using a modified version of the radiological assay developed previously (10). Assays were performed in 2.8-ml glass vials sealed with Mininert valves. The anoxic assay mixtures (final volume 1 ml) contained 100 mM Tris-HCl buffer, pH 7.8, 300 nmol of [ring-U-14C]toluene (specific activity, ~42 µCi/mmol), 10 mM fumarate, and 5 mM dithiothreitol as a reductant. The assay buffer was changed to a Tris-HCl buffer, pH 7.8, because the pH optimum of benzylsuccinate synthase activity was found to be between 7.5 and 8, consistent with the findings of Leuthner et al. (11).

Assays were conducted at room temperature (25 °C) in an anaerobic glove box with an atmosphere of 80% N2, 10% H2, and 10% CO2. To prevent a decrease in the pH of the reaction mixture due to the presence of CO2 in the glove box atmosphere, the reaction mixtures were prepared in a glove box with an atmosphere of 90% N2 and 10% H2 and then transferred to the former glove box in a stoppered anoxic glass bottle. Assay components were added by syringe through Mininert valves. Reactions were started by the addition of crude cell extract or hydroxyapatite-enriched benzylsuccinate synthase. After incubation for 0, 10, or 12 min on an orbital shaker, the reactions were stopped by the addition of 0.1 ml of M NaOH. The assay vials were removed from the glove box and amended with an antifoaming agent (Antifoam A, Sigma; ~100 ppm final concentration). Assay mixtures were purged with N2 for 20 min to remove any residual [14C]toluene. Ultima Gold XR scintillation liquid (10 ml; Packard Instrument Co.) then was added to the mixtures, and the remaining nonvolatile radioactivity (primarily [14C]benzylsuccinate) was measured with a Tri-Carb model 2500 TR/AB liquid scintillation analyzer (Packard Instrument Co.). Benzylsuccinate has been shown to be the only significant product formed from toluene under the experimental conditions of these assays (10).

Sample Preparations for EPR Spectroscopy-- Hydroxyapatite fractions of catalytically active benzylsuccinate synthase were analyzed by EPR spectroscopy. Although a portion of the hydroxyapatite-enriched benzylsuccinate synthase was tested for activity to ensure the enzyme was catalytically active (see above), the remaining portion of benzylsuccinate synthase analyzed by EPR spectroscopy was not amended with the substrates, toluene and fumarate, and therefore did not catalyze the benzylsuccinate synthase reaction. In an anaerobic glove box (atmosphere of 90% N2 and 10% H2), samples (300 µl) of benzylsuccinate synthase were transferred to EPR tubes. Anaerobic tubing was placed over the end of each EPR tube and clamped closed. The EPR tubes were removed from the glove box and immediately frozen in liquid nitrogen. The samples were sent in liquid nitrogen in a shipping Dewar (CryoPak Shipper, CP-100, Taylor-Wharton, Theodore, AL) to Amsterdam where they were analyzed by EPR spectroscopy. Three sample sets of benzylsuccinate synthase were prepared and analyzed by EPR spectroscopy: 1) benzylsuccinate synthase, 2) benzylsuccinate synthase exchanged into phosphate-buffered 2H2O, and 3) benzylsuccinate synthase amended with toluene but not fumarate.

Benzylsuccinate Synthase-- A sample (300 µl) of hydroxyapatite-enriched benzylsuccinate synthase (1.8 mg of protein ml-1) was transferred to an EPR tube and analyzed by EPR spectroscopy.

Deuterium-exchanged Benzylsuccinate Synthase-- A 200 mM potassium phosphate buffer, pH 6.8, was prepared anoxically in 99.9% D2O (referred to as phosphate-buffered D2O). A hydroxyapatite fraction of enriched benzylsuccinate synthase (800 µl of 1.4 mg of protein ml-1) was exchanged into the anoxic phosphate-buffered D2O by applying the fraction onto a HiTrap desalting column (5-ml bed volume; Amersham Pharmacia Biotech) and then eluting it with 2.6 ml of the phosphate-buffered D2O. Only the last 1.9 ml of eluted liquid were collected, and a portion of this (300 µl of 0.5 mg of protein ml-1) was transferred to an EPR tube and analyzed by EPR spectroscopy.

Benzylsuccinate Synthase Amended with Toluene-- Portions (300 µl) of the same hydroxyapatite fraction of benzylsuccinate synthase (1.9 mg of protein ml-1) were added to three EPR tubes. One EPR tube had no amendment, another was amended with the nonmetabolizable substrate, benzene (180 nmol), and the third EPR tube was amended with the substrate, toluene (190 nmol). Both benzene and toluene were amended from a methanolic stock solution (final methanol concentration less than 0.7% (v/v)). Fumarate, a cosubstrate of the benzylsuccinate synthase reaction, was not added to any of the three samples. The three EPR tubes then were analyzed by EPR spectroscopy.

EPR Spectroscopy-- EPR spectra at X-band (9 GHz) were obtained with a Bruker ECS 106 EPR spectrometer equipped with an Oxford Instruments ESR 900 helium-flow cryostat with an ITC4 temperature controller. A field modulation frequency of 100 kHz was used. The magnetic field was calibrated with an AEG magnetic field meter. The microwave frequency was measured with an HP 5350B microwave frequency counter. The microwave power incident to the cavity was measured with an HP 432 B power meter. Simulations were carried out as described earlier (26). Quantification of EPR signals was carried out by direct double integration of the experimental spectra (27, 28) or by comparison with a good fitting simulation (29).

    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Benzylsuccinate synthase, as partially purified from extracts of anaerobically grown toluene-induced cells of Azoarcus sp. strain T, was active and catalyzed the addition of toluene to fumarate to form benzylsuccinate at high specific activities (150 to 400 nmol min-1 (mg of protein)-1). Using EPR spectroscopy, we analyzed a hydroxyapatite fraction of benzylsuccinate synthase (1.8 mg of protein ml-1; ~8 µM holoenzyme) for the presence of a free radical and observed an EPR signal as shown in Fig. 2A. The EPR signal was centered at g = 2.0021 and was characterized by a 2-fold splitting of about 1.5 mT. The g value of the signal is very close to that of a free radical. Most importantly, the line shape of the EPR signal closely resembles that of the glycyl radicals of PFL (15, 16) and ARNR (17, 18) from E. coli. The EPR signals of all three enzymes are characterized by a g value between 2.002 and 2.004, as well as a resolved 2-fold splitting of about 1.5 mT (15-18). The simulation in Fig. 2B shows that the hyperfine interactions and linewidth proposed for PFL by Wagner et al. (15) results in an EPR spectrum that is indistinguishable from that of benzylsuccinate synthase (Fig. 2A). The EPR spectral similarities between benzylsuccinate synthase and the glycyl radical enzymes, PFL and ARNR, strongly suggest that the radical observed in benzylsuccinate synthase is located on a glycine residue.


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Fig. 2.   EPR spectra of partially purified benzylsuccinate synthase. A, experimental spectrum of untreated enzyme (1.8 mg of protein ml-1; ~8 µM holoenzyme; spin concentration 2.5 µM). B, simulation assuming an isotropic signal with g = 2.00211 and a linewidth (W) and isotropic hyperfine interactions (A) with three protons as reported by Wagner et al. (15): W = 0.7 mT; A(Halpha ) = 1.5 mT; A(Hbeta ) = 0.6 mT; A(Hdelta ) = 0.45 mT. C, experimental spectrum of enzyme treated with D2O (0.5 mg of protein ml-1; ~2 µM holoenzyme; spin concentration 0.8 µM). D, the same simulation as under B, where the alpha  proton has been replaced by a deuteron with A = 0.2 mT (15). EPR conditions: microwave frequency, 9423.4 MHz; microwave power incident to the cavity, 41 microwatts; modulation amplitude, 0.254 mT; temperature, 120 K.

When an EPR sample was thawed under a flow of argon for 15 min and refrozen in liquid nitrogen, the EPR signal did not change (data not shown). However, when the sample was thawed in the presence of air and refrozen in liquid nitrogen, no EPR signal was detected. The absence of an EPR signal is consistent with benzylsuccinate synthase activity being extremely oxygen sensitive (10, 11). The correlation between benzylsuccinate synthase activity and the presence of an EPR signal suggests that the radical is essential for catalysis.

The chemical nature of the radical moiety was investigated further by exchanging hydroxyapatite-enriched benzylsuccinate synthase into phosphate-buffered D2O (see "Experimental Procedures") and analyzing the sample by EPR spectroscopy. The resulting EPR spectrum revealed no resolved hyperfine splitting (Fig. 2C), as opposed to the spectrum of the enzyme as determined in H2O (Fig. 2A). This implies that the 2-fold splitting observed in the EPR spectrum of the normal protonated enzyme is caused by a hydrogen atom and that this hydrogen is exchangeable with deuterium atoms originating from the solvent. Notably, this hydrogen/deuterium exchange occurs in the absence of catalysis because the catalytically competent enzyme was not amended with any substrates prior to analysis by EPR spectroscopy. When PFL was exchanged into D2O and analyzed by EPR spectroscopy, the resulting EPR spectrum (15, 16) indicated an analogous behavior. A rapidly exchangeable hydrogen was found in PFL and was assigned to the alpha  position of the glycyl radical (15). Analogous with this assignment, the 2-fold splitting in the EPR spectrum of benzylsuccinate synthase is also assigned to an exchangeable hydrogen, most likely the alpha  hydrogen of the glycyl radical. The simulation in Fig. 2D shows that the hyperfine interactions and linewidth proposed for PFL in D2O (15) results in an EPR spectrum indistinguishable from that of benzylsuccinate synthase in D2O (Fig. 2C). Contrary to benzylsuccinate synthase and PFL, no such rapidly exchangeable hydrogen was observed for ARNR (17).

Mutant studies conducted with PFL from E. coli showed that the hydrogen exchange of the glycyl radical of PFL is not spontaneous but involves the active site cysteine 419 (14). Based on this finding, Parast et al. (14) proposed that the alpha  hydrogen of the glycyl radical does not exchange directly with the solvent. Instead, the hydrogen of the thiol group of cysteine 419 is proposed to exchange with the solvent, in this case solvent deuterons, forming a deuterated thiol group. The glycyl radical is then proposed to abstract the deuterium from the thiol group, generating a transient thiyl radical and a chirally deuterated glycine residue. To form a glycyl radical with a deuterium in the alpha  position, as observed in the EPR spectra of PFL (15, 16), the thiyl radical of cysteine 419 must nonstereospecifically abstract the hydrogen from the chirally deuterated glycine residue (14). As an analogy to the findings for PFL, one may postulate that the hydrogen exchange of the glycyl radical of benzylsuccinate synthase may not be spontaneous but may involve the conserved cysteine residue. This would suggest that the glycyl radical and the conserved cysteine residue in benzylsuccinate synthase are in close proximity to each other in the active site and interact during catalysis.

We also examined whether amending samples of enriched benzylsuccinate synthase with toluene as the sole substrate alters the EPR signal of the benzylsuccinate synthase radical. Control samples included benzylsuccinate synthase alone and benzylsuccinate synthase amended with benzene, a nonmetabolizable surrogate. The intensity and line shapes of the EPR spectra of all three samples were similar to those of the untreated enzyme (data not shown). This suggests that the presence of toluene alone does not quench the radical to any significant degree, or if it does, the quenching is too transient to be observed.

The spectroscopic characteristics of benzylsuccinate synthase reported here and the molecular properties discussed previously (10-12, 30) suggest the following reaction mechanism for benzylsuccinate synthase. At the beginning of the enzymatic reaction, active benzylsuccinate synthase harbors an oxygen-sensitive, stable glycyl free radical (presumably at glycine 828 in Azoarcus sp. strain T benzylsuccinate synthase). The glycyl radical abstracts a hydrogen atom from the conserved cysteine residue forming a transient thiyl radical (presumably at cysteine 492 in Azoarcus sp. strain T benzylsuccinate synthase). The thiyl radical then abstracts a hydrogen atom from the toluene methyl group to form a benzylic radical as an intermediate, which then attacks the double bond of fumarate forming a benzylsuccinyl radical. The benzylsuccinyl radical then reabstracts the same hydrogen atom from the conserved cysteine residue, forming benzylsuccinate and regenerating the thiyl radical. Based on proposed reaction mechanisms of PFL (14, 20, 31), we presume that the thiyl radical then abstracts a hydrogen atom from the conserved glycine residue regenerating the glycyl radical. At this point the glycyl radical enzyme is competent to undergo another catalytic cycle. Consequently benzylsuccinate synthase can undergo multiple turnovers without reintroduction of its glycyl radical by an activating enzyme, as also indicated by in vitro assays of benzylsuccinate synthase activity conducted in this study: 150 pmol of enriched benzylsuccinate synthase produced 160 nmol of benzylsuccinate in 12 min.

    FOOTNOTES

* This work was supported by National Science Foundation Grants MCB-9733535 and MCB-9723312.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Supported by a grant from The Netherlands Organization for Scientific Research (NWO).

** Recipient of a Terman Fellowship. To whom correspondence should be addressed. Tel.: 650-723-3668; Fax: 650-725-3164; E-mail: spormann@ce.stanford.edu.

Published, JBC Papers in Press, January 30, 2001, DOI 10.1074/jbc.M009453200

1 G. Achong, A. Rodriguez, and A. Spormann, unpublished data.

    ABBREVIATIONS

The abbreviations used are: PFL, pyruvate formate-lyase; ARNR, anaerobic ribonucleotide reductase; mT, millitesla.

    REFERENCES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

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