The anaerobic oxidation of dihydroorotate by Escherichia coli K-12

The oxidation of dihydroorotate under anaerobic conditions has been examined using various mutant strains of Escherichia coli K-12. This oxidation in cells grown anaerobically in a glucose minimal medium is linked via menaquinone to the fumarate reductase enzyme coded for by the frd gene and is independent of the cytochromes. The same dihydroorotate dehydrogenase protein functions in both the anaerobic and aerobic oxidation of dihydroorotate. Ferricyanide can act as an artificial electron acceptor for dihydroorotate dehydrogenase and the dihydroorotate-menaquinone-ferricyanide reductase activity can be solubilised by 2 M guanidine · HCl with little loss of activity.     

Isolation and Properties of Fumarate Reductase Mutants of Escherichia coli

Escherichia coli produces two enzymes which interconvert succinate and fumarate: succinate dehydrogenase, which is adapted to an oxidative role in the tricarboxylic acid cycle, and fumarate reductase, which catalyzes the reductive reaction more effectively and allows fumarate to function as an electron acceptor in anaerobic growth. A glycerol plus fumarate medium was devised for the selection of mutants (frd) lacking a functional fumarate reductase by virtue of their inability to use fumarate as an anaerobic electron acceptor. Most of the mutants isolated contained less than 1% of the parental fumarate reduction activity. Measurements of the fumarate reduction and succinate oxidation activities of parental strains and frd mutants after aerobic and anaerobic growth indicated that succinate dehydrogenase was completely repressed under anaerobic conditions, the assayable succinate oxidation activity being due to fumarate reductase acting reversibly. Fumarate reductase was almost completely repressed under aerobic conditions, although glucose relieved this repression to some extent. The mutations, presumably in the structural gene (frd) for fumarate reductase, were located at approximately 82 min on the E. coli chromosome by conjugation and transduction with phage P1. frd is very close to the ampA locus, and the order of markers in this region was established as ampA-frd-purA.     

Enzyme Complex Which Couples Glycerol-3-Phosphate Dehydrogenation to Fumarate Reduction in Escherichia coli

Anaerobic growth of Escherichia coli on glycerol as carbon source and fumarate as hydrogen acceptor results in the induction of both anaerobic sn-glycerol-3-phosphate (G3P) dehydrogenase and fumarate reductase. In previous studies, the G3P dehydrogenase was measured by the G3P-dependent reduction of a tetrazolium dye mediated by phenazine methosulfate in the presence of flavine mononucleotide and flavine adenine dinucleotide, and fumarate reductase was measured by the fumarate-dependent oxidation of reduced flavine mononucleotide. Results from the present study indicate that these two enzymes actually constitute a functional complex which is sedimentable at 200,000 x g in 2 h and which can catalyze the dehydrogenation of G3P at the expense of fumarate without any added cofactor. This coupling activity is not constituted by simply mixing an extract containing anaerobic G3P dehydrogenase with another extract containing fumarate reductase. Additional evidence for an organized complex is provided by the high degree of sensitivity of the coupled reaction to low concentrations of the detergents Triton X-100 and Emasol 1130 in comparison with the individual activities of the two component enzymes measured with the aid of artificial cofactors.     

Dihydroorotate dehydrogenase from Saccharomyces cerevisiae: spectroscopic investigations with the recombinant enzyme throw light on catalytic properties and metabolism of fumarate analogues

In all organisms the fourth catalytic step of the pyrimidine biosynthesis is driven by the flavoenzyme dihydroorotate dehydrogenase (DHODH, EC 1.3.99.11). Cytosolic DHODH of the established model organism Saccharomyces cerevisiae catalyses the oxidation of dihydroorotate to orotate and the reduction of fumarate to succinate. Here, we investigate the structure and mechanism of DHODH from S. cerevisiae and show that the recombinant ScDHODH exists as a homodimeric enzyme in vitro. Inhibition of ScDHODH by the reaction product was observed and kinetic studies disclosed affinity for orotate (K(ic)=7.7 microM; K(ic) is the competitive inhibition constant). The binding constant for orotate was measured through comparison of UV-visible spectra of the bound and unbound recombinant enzyme. The midpoint reduction potential of DHODH-bound flavine mononucleotide determined from analysis of spectral changes was -242 mV (vs. NHE) under anaerobic conditions. A search for alternative electron acceptors revealed that homologues such as mesaconate can be used as electron acceptors.     

Identification and localization of enzymes of the fumarate reductase and nitrate respiration systems of escherichia coli by crossed immunoelectrophoresis

Crossed immunoelectrophoresis was used to analyze the components of membrane vesicles of anaerobically grown Escherichia coli. The number of precipitation lines in the crossed immunoelectrophoresis patterns of membrane vesicles isolated from E. coli grown anaerobically on glucose plus nitrate and on glycerol plus fumarate were 83 and 70, respectively. Zymogram staining techniques were used to identify immunoprecipitates corresponding to nitrate reductase, formate dehydrogenase, fumarate reductase, and glycerol-3-phosphate dehydrogenase in crossed immunoelectrophoresis reference patterns. The identification of fumarate reductase by its succinate oxidizing activity was confirmed with purified enzyme and with mutants lacking or overproducing this enzyme. In addition, precipitation lines were found for hydrogenase, cytochrome oxidase, the membrane-bound ATPase, and the dehydrogenases for succinate, malate, dihydroorotate, D-lactate, 6-phosphogluconate, and NADH. Adsorption experiments with intact and solubilized membrane vesicles showed that fumarate reductase, hydrogenase, glycerol-3-phosphate dehydrogenase, nitrate reductase, and ATPase are located at the inner surface of the cytoplasmic membrane; on the other hand, the results suggest that formate dehydrogenase is a transmembrane protein.     

Cloning, expression, purification, and characterization of Leishmania major dihydroorotate dehydrogenase

Leishmania major Friedlin (LmjF) is a protozoan parasite whose genomic sequence has been recently elucidated. Here we have cloned, overexpressed, purified, and characterized the product of the gene from LmjF chromosome 16: LmjF16.0530, which encodes a protein with putative dihydroorotate dehydrogenase activity. Dihydroorotate dehydrogenase (DHODH) is a flavoprotein that catalyses the oxidation of L-dihydroorotate to orotate, the fourth sequential step in the de novo pyrimidine nucleotide synthesis pathway. The predicted enzyme from L. major was cloned and expressed in Escherichia coli strain BL21(DE3) as a histidine-tag fusion protein and purified to homogeneity using affinity chromatography. The final product was homogeneous in SDS-PAGE gel electrophoresis. The dihydroorotate oxidase activity has been assayed and the steady-state kinetic mechanism has been determined using fumarate as the oxidizing substrate. The catalysis by LmDHODH enzyme proceeds by a Ping-Pong Bi-Bi mechanism and the kinetic parameters Km were calculated to be 90 and 418 microM for dihydroorotate and fumarate, respectively, and Vmax was calculated to be 11 micromol min-1 mg-1. Our results confirmed that the product of the gene LmjF16.0530, whose function has previously been predicted based on homology to known proteins, can therefore be positively assigned as L. major DHODH.     

Dihydrooxonate is a substrate of dihydroorotate dehydrogenase (DHOD) providing evidence for involvement of cysteine and serine residues in base catalysis.

The flavoprotein dihydroorotate dehydrogenase (DHOD) catalyzes the oxidation of dihydroorotate to orotate. Dihydrooxonate is an analogue of dihydroorotate in which the C5 carbon is substituted by a nitrogen atom. We have investigated dihydrooxonate as a substrate of three DHODs, each representing a distinct evolutionary class of the enzyme, namely the two family 1 enzymes from Lactococcus lactis, DHODA and DHODB, and the enzyme from Escherichia coli, which, like the human enzyme, belongs to family 2. Dihydrooxonate was accepted as a substrate although much less efficiently than dihydroorotate. The first half-reaction was rate limiting according to pre-steady-state and steady-state kinetics with different electron acceptors. Cysteine and serine have been implicated as active site base residues, which promote substrate oxidation in family 1 and family 2 DHODs, respectively. Mutants of DHODA (C130A) and E. coli DHOD (S175A) have extremely low activity in standard assays with dihydroorotate as substrate, but with dihydrooxonate the mutants display considerable and increasing activity above pH 8.0. Thus, the absence of the active site base residue in the enzymes seems to be compensated for by a lower pK(a) of the 5-position in the substrate. Oxonate, the oxidation product of dihydrooxonate, was a competitive inhibitor versus dihydroorotate, and DHODA was the most sensitive of the three enzymes. DHODA was reinvestigated with respect to product inhibition by orotate. The results suggest a classical one-site ping-pong mechanism with fumarate as electron acceptor, while the kinetics with ferricyanide is highly dependent on the detailed reaction conditions.     

Isolation of mitochondria from Plasmodium falciparum showing dihydroorotate dependent respiration.

Using N₂ cavitation, we established a protocol to prepare the active mitochondria from Plasmodium falciparum showing a higher succinate dehydrogenase activity than previously reported and a dihydroorotate-dependent respiration. The fact that fumarate partially inhibited the dihydroorotate dependent respiration suggests that complex II (succinate–ubiquinone reductase/quinol–fumarate reductase) in the erythrocytic stage cells of P. falciparum functions as a quinol–fumarate reductase.     

The Origin of Dihydroorotate Dehydrogenase Genes of Kinetoplastids, with Special Reference to Their Biological Significance and Adaptation to Anaerobic, Parasitic Conditions

Trypanosoma cruzi dihydroorotate dehydrogenase (DHOD), the fourth enzyme of the de novo pyrimidine biosynthetic pathway, is localized in the cytosol and utilizes fumarate as electron acceptor (fumarate reductase activity), while the enzyme from other various eukaryotes is mitochondrial membrane-linked. Here we report that DHOD-knockout T. cruzi did not express the enzyme protein and could not survive even in the presence of pyrimidine nucleosides, substrates for the potentially active salvage pathway, suggesting a vital role of fumarate reductase activity in the regulation of cellular redox balance. Cloning and phylogenetic analysis of euglenozoan DHOD genes showed that the euglenoid Euglena gracilis had a mitochondrial DHOD and that biflagellated bodonids, a sister group of trypanosomatids within kinetoplastids, harbor the cytosolic DHOD. Further, Bodo saliens, a bodonid, had an ACT/DHOD gene fusion encoding aspartate carbamoyltransferase (ACT), the second enzyme of the de novo pyrimidine pathway, and DHOD. This is the first report of this novel gene structure. These results are consistent with suggestions that an ancient common ancestor of Euglenozoa had a mitochondrial DHOD whose descendant exists in E. gracilis and that a common ancestor of kinetoplastids (bodonids and trypanosomatids) subsequently acquired a cytosolic DHOD by horizontal gene transfer. The cytosolic DHOD gene thus acquired may have contributed to adaptation to anaerobiosis in the kinetoplastid lineage and further contributed to the subsequent establishment of parasitism in a trypanosomatid ancestor. Different molecular strategies for anaerobic adaptation in pyrimidine biosynthesis, used by kinetoplastids and by euglenoids, are discussed. Evolutionary implications of the ACT/DHOD gene fusion are also discussed.Sequence availability: The nucleotide sequence data reported here appear in the GenBank, EMBL, and DDBJ databases with the accession numbers AB120414, AB159227, and AB159228 for Euglena gracilis dihydroorotate dehydrogenase (DHOD), Bodo saliens aspartate carbamoyltransferase/dihydroorotate dehydrogenase (ACT/DHOD), and B. caudatus DHOD, respectively.Reviewing Editor: Dr. Patrick Keeling     

Evidence for a multiple function of the alcohol dehydrogenase allozyme ADH71k of Drosophila melanogaster

Alcohol dehydrogenase of Drosophila melanogaster catalyzes the oxidation of many primary and secondary alcohols. We show that sarcosine, choline and dihydroorotate are substrates of ADH in vitro. The first two substrates are regular substrates of the choline shunt, and the latter of the de novo pyrimidine synthesis. Differences in oxidative ability towards sarcosine and dihydroorotate between two ADH allozymes, ADH71k and ADHF, are observed. The catalytic activity of ADH71k towards sarcosine and dihydroorotate might be responsible for its allelic fixation in Notch8 mutant stocks, in which Notch females have a decreased level of the regular enzymes for these substrates. Their oxidation by ADH71k might act as a bypass, which restores at least part of the decreased activity of enzymes encoded by the Notch locus.     

The activity of Escherichia coli dihydroorotate dehydrogenase is dependent on a conserved loop identified by sequence homology, mutagenesis, and limited proteolysis

Dihydroorotate dehydrogenase catalyzes the oxidation of dihydroorotate to orotate. The enzyme from Escherichia coli was overproduced and characterized in comparison with the dimeric Lactococcus lactis A enzyme, whose structure is known. The two enzymes represent two distinct evolutionary families of dihydroorotate dehydrogenases, but sedimentation in sucrose gradients suggests a dimeric structure also of the E. coli enzyme. Product inhibition showed that the E. coli enzyme, in contrast to the L. lactis enzyme, has separate binding sites for dihydroorotate and the electron acceptor. Trypsin readily cleaved the E. coli enzyme into two fragments of 182 and 154 residues, respectively. Cleavage reduced the activity more than 100-fold but left other molecular properties, including the heat stability, intact. The trypsin cleavage site, at R182, is positioned in a conserved region that, in the L. lactis enzyme, forms a loop where a cysteine residue is very critical for activity. In the corresponding position, the enzyme from E. coli has a serine residue. Mutagenesis of this residue (S175) to alanine or cysteine reduced the activities 10000- and 500-fold, respectively. The S175C mutant was also defective with respect to substrate and product binding. Structural and mechanistic differences between the two different families of dihydroorotate dehydrogenase are discussed.     

Superoxide production and electron transport in mitochondrial oxidation of dihydroorotic acid.

Production of superoxide radical during oxidation of dihydroorotate in rat liver mitochondria was not affected by antimycin A, thenoyltrifluoroacetone, or added ubiquinone but was inhibited by orotate, a product inhibitor of dihydroorotate dehydrogenase. It appears likely that superoxide is generated at the primary dehydrogenase. Dihydroorotate dehydrogenase differs from succinate dehydrogenase both in its utilization of ubiquinone and in the mechanism of cytochrome b reduction. Thenoyltrifluoroacetone completely inhibits fumarate synthesis and reduction of cytochrome b by succinate. Formation of orotate is only partially inhibited by thenolytrifluoroacetone and the inhibitor does not prevent reduction of cytochrome b by dihydroorotate. It is proposed that several pathways exist for linkage of the primary dihydrorotate dehydrogenase with the electron transport chain. One route involves electron transfer from ubiquinone to cytochrome c and is inhibited by thenoyltrifluoroacetone. A second route bypasses ubiquinone and is inhibited by antimycin A. A third pathway utilizes both ubiquinone and cytochrome b and is partiayly inhibited by either thenoyltrifluoroacetone or antimycin A.     

Isolation of mitochondria from Plasmodium falciparum showing dihydroorotate dependent respiration

Using N₂ cavitation, we established a protocol to prepare the active mitochondria from Plasmodium falciparum showing a higher succinate dehydrogenase activity than previously reported and a dihydroorotate-dependent respiration. The fact that fumarate partially inhibited the dihydroorotate dependent respiration suggests that complex II (succinate–ubiquinone reductase/quinol–fumarate reductase) in the erythrocytic stage cells of P. falciparum functions as a quinol–fumarate reductase.     

Purification and properties of the bovine liver mitochondrial dihydroorotate dehydrogenase

Dihydroorotate dehydrogenase has been purified 6,000-fold from bovine liver mitochondria to apparent homogeneity in six steps. Electrophoretic migration of the homogeneous enzyme on sodium dodecyl sulfate-polyacrylamide gels reveals a subunit Mr of 42,000. By contrast to the well-characterized, cytosolic dihydroorotate oxidases (EC 1.3.3.1), the purified bovine dehydrogenase is a dihydroorotate:ubiquinone oxidoreductase. Maximal rates of orotate formation are obtained using coenzymes Q6 or Q7 as cosubstrate electron acceptors. Concomitant with substrate oxidation, the enzyme will reduce simple quinones, such as benzoquinone, but at significantly lower rates (10-15%) than that obtained for reduction of coenzyme Q6. Enzyme-catalyzed substrate oxidation is not supported by molecular oxygen. The specificity of the purified enzyme for dihydropyrimidine substrates has also been explored. The methyl-, ethyl-, t-butyl-, and benzyl-S-dihydroorotates are substrates, but 1- and 3-methyl and 1,3-dimethyl methyl-S-dihydroorotates are not. Competitive inhibitors include product orotate, 5-methyl orotate, and racemic cis-5-methyl dihydroorotate.     

Generation of a proton potential by succinate dehydrogenase of Bacillus subtilis functioning as a fumarate reductase.

The membrane fraction of Bacillus subtilis catalyzes the reduction of fumarate to succinate by NADH. The activity is inhibited by low concentrations of 2-(heptyl)-4-hydroxyquinoline-N-oxide (HOQNO), an inhibitor of succinate: quinone reductase. In sdh or aro mutant strains, which lack succinate dehydrogenase or menaquinone, respectively, the activity of fumarate reduction by NADH was missing. In resting cells fumarate reduction required glycerol or glucose as the electron donor, which presumably supply NADH for fumarate reduction. Thus in the bacteria, fumarate reduction by NADH is catalyzed by an electron transport chain consisting of NADH dehydrogenase (NADH:menaquinone reductase), menaquinone, and succinate dehydrogenase operating in the reverse direction (menaquinol:fumarate reductase). Poor anaerobic growth of B. subtilis was observed when fumarate was present. The fumarate reduction catalyzed by the bacteria in the presence of glycerol or glucose was not inhibited by the protonophore carbonyl cyanide m-chlorophenyl hydrazone (CCCP) or by membrane disruption, in contrast to succinate oxidation by O2. Fumarate reduction caused the uptake by the bacteria of the tetraphenyphosphonium cation (TPP+) which was released after fumarate had been consumed. TPP+ uptake was prevented by the presence of CCCP or HOQNO, but not by N,N'-dicyclohexylcarbodiimide, an inhibitor of ATP synthase. From the TPP+ uptake the electrochemical potential generated by fumarate reduction was calculated (Deltapsi = -132 mV) which was comparable to that generated by glucose oxidation with O2 (Deltapsi = -120 mV). The Deltapsi generated by fumarate reduction is suggested to stem from menaquinol:fumarate reductase functioning in a redox half-loop.     

Biosynthetic Dihydroorotate Dehydrogenase from Lactobacillus bulgaricus

This paper describes the first detailed study on a dihydroorotate dehydrogenase involved in pyrimidine biosynthesis. In most organisms the enzyme is membrane-bound; however, a soluble dihydroorotate dehydrogenase was produced in relatively high levels when the anaerobe, Lactobacillus bulgaricus, was released from repression. The enzyme was purified 213-fold over derepressed levels with a 39% recovery of enzyme units. The enzyme showed only one minor protein contaminant when analyzed by polyacrylamide electrophoresis. It was characterized as a flavoprotein containing only flavine mononucleotide as the prosthetic group. Molecular weight estimations by gel filtration gave a value of approximately 55,000, which is one-half that of the degradative enzyme described by others. During aerobic oxidation of dihydroorotate, the rates of oxygen consumption, orotate formation, and hydrogen peroxide formation were equal, as would be expected in a flavoprotein-catalyzed reaction. The enzymatic activity with ferricyanide as acceptor was optimum around pH 7.7. The stimulation of enzymatic activity over a wide pH range by ammonium sulfate was attributed to an effect on the maximum velocity of the reaction. As analyzed by polyacrylamide electrophoresis, inactivation of the enzyme by visible light resulted in the appearance of a second protein band with lowered specific activity. The purified enzyme used redox dyes, oxygen, or cytochrome c as electron acceptors but was not active with pyridine nucleotides. Flavine adenine dinucleotide has been implicated at the active site for pyridine nucleotide reduction in the degradative enzyme. The biosynthetic enzyme lacks this flavine and the associated activity.     

Biosynthetic Dihydroorotate Dehydrogenase from Lactobacillus bulgaricus: Partial Characterization of the Enzyme

Some of the catalytic properties of the biosynthetic dihydroorotate dehydrogenase purified from an anaerobic bacterium, Lactobacillus bulgaricus, are described. Studies with p-hydroxymercuribenzoate, N-ethylmaleimide, and mercuric chloride showed that sulfhydryl groups are necessary for transfer of electrons from dihydroorotate to a variety of electron acceptors. Protection studies with substrates for the enzyme indicated that free sulfhydryl groups at or near the active center are required for catalytic activity. Evidence is presented for the production of superoxide free radicals during reaction of the enzyme with molecular oxygen. Inhibitor studies with Tiron indicated that reduction of cytochrome c by the enzyme may involve the superoxide free radical as an intermediate. Orotate, one of the substrates for the enzyme, has been found to be a competitive inhibitor for the dihydroorotate site. The K(i) for orotate as estimated by several techniques is 0.1 mM. The K(m) for dihydroorotate with ferricyanide as the electron acceptor is estimated to be 0.5 mM.     

Properties and synthesis regulation of NAD(P)H dehydrogenases from Rhodobacter capsulatus

Three NAD(P)H dehydrogenases were found and purified from a soluble fraction of cells of the purple non-sulfur bacterium Rhodobacter capsulatus, strain B10. Molecular mass of NAD(P)H, NADPH and NADH dehydrogenases are 67 000 (4 · 18 000), 35 000 and 39 000, and the isoelectric points are 4.6, 4.3 and 4.5, respectively. NAD(P)H dehydrogenase is characterized by a higher sensitivity to quinacrine, NADPH dehydrogenase by its sensitivity to p-chloromercuribenzoate and NADH dehydrogenase by its sensitivity to sodium arsenite. In contrast to the other two enzymes, NAD(P)H dehydrogenase is capable of oxidizing NADPH as well as NADH, but the ratio of their oxidation rates depends on the pH. All NAD(P)H dehydrogenases reacted with ferricyanide, 2,6-dichlorophenolindophenol, benzoquinone and naphthoquinone, but did not exhibit transhydrogenase, reductase or oxidase activity. Moreover, NADH dehydrogenase was also capable of reducing FAD and FMN. NAD(P)H and NADH dehydrogenases possessed cytochrome-c reductase activity, which was stimulated by menadione and ubiquinone Q₁. The activity of NAD(P)H and NADH dehydrogenases depended on culture-growth conditions. The activity of NAD(P)H dehydrogenase from cells grown under chemoheterotrophic aerobic conditions was the lowest and it increased notably under photoheterotrophic anaerobic conditions upon lactate or malate growth limitation. The activity of NADH dehydrogenase was higher from the cells grown under photoheterotrophic anaerobic conditions upon nitrate growth limitation and under chemoheterotrophic aerobic conditions. NADPH dehydrogenase synthesis dependence on R. capsulatus growth conditions was insignificant.     

Identification of a novel gene of pyrimidine nucleotide biosynthesis, pyrDII, that is required for dihydroorotate dehydrogenase activity in Bacillus subtilis.

An in-frame deletion in the coding region of a gene of previously unidentified function (which is called orf2 and which we propose to rename pyrDII) in the Bacillus subtilis pyr operon led to pyrimidine bradytrophy, markedly reduced dihydroorotate dehydrogenase activity, and derepressed levels of other enzymes of pyrimidine biosynthesis. The deletion mutation was not corrected by a plasmid encoding pyrDI, the previously identified gene encoding dihydroorotate dehydrogenase, but was complemented by a plasmid encoding pyrDII. We propose that pyrDII encodes a protein subunit of dihydroorotate dehydrogenase that catalyzes electron transfer from the pyrDI-encoded subunit to components of the electron transport chain.     

Anaerobic oxidation of toluene (analogues) to benzoate (analogues) by whole cells and by cell extracts of a denitrifying Thauera sp.

Toluene and related aromatic compounds can be mineralized to CO₂ under anoxic conditions. Oxidation requires new dehydrogenase-type enzymes and water as oxygen source, as opposed to the aerobic enzymatic attack by oxygenases, which depends on molecular oxygen. We studied the anaerobic process in the denitrifying bacterium Thauera sp. strain K172. Toluene and a number of its fluoro-, chloro- and methyl-analogues were transformed to benzoate and the respective analogues by whole cells and by cell extracts. The transformation of xylene isomers to methylbenzoate isomers suggests that xylene degradation is similarly initiated by oxidation of one of the methyl groups. Toluene oxidation was strongly, but reversibly inhibited by benzyl alcohol. The in vitro oxidation of the methyl group was coupled to the reduction of nitrate, required glycerol for activity, and was inhibited by oxygen. Cells also contained benzyl alcohol dehydrogenase (NAD⁺), benzaldehyde dehydrogenase (NADP⁺), benzoate-CoA ligase (AMP-forming), and benzoyl-CoA reductase (dearomatizing). The toluene-oxidizing activity was induced when cells were grown anaerobically with toluene and also with benzyl alcohol or benzaldehyde, suggesting that benzyl alcohol or benzaldehyde acts as inducer. The other enzymes were similarly active in cells grown with toluene, benzyl alcohol, benzaldehyde, or benzoate. This is the first in vitro study of anaerobic oxidation of an aromatic hydrocarbon and of the whole-cell regulation of the toluene-oxidizing enzyme.Dedicated to Prof. Achim Trebst