Bacterial 2,4-Dioxygenases: New Members of the alpha /beta  Hydrolase-Fold Superfamily of Enzymes Functionally Related to Serine Hydrolases

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Journal of Bacteriology, September 1999, p. 5725-5733, Vol. 181, No. 18
0021-9193/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Bacterial 2,4-Dioxygenases: New Members of the $alpha$ / $beta$ Hydrolase-Fold Superfamily of Enzymes Functionally Related to Serine Hydrolases

Frank Fischer, Stefan Künne, and Susanne Fetzner^*

Mikrobiologie, Fachbereich 7, Carl von Ossietzky Universität Oldenburg, Oldenburg, Germany

Received 31 March 1999/Accepted 17 June 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results and Discussion References

1H-3-hydroxy-4-oxoquinoline 2,4-dioxygenase (Qdo) from Pseudomonas putida 33/1 and 1H-3-hydroxy-4-oxoquinaldine 2,4-dioxygenase(Hod) from Arthrobacter ilicis Rü61a catalyze an N-heterocyclic-ringcleavage reaction, generating N-formylanthranilate and N-acetylanthranilate,respectively, and carbon monoxide. Amino acid sequence comparisonsbetween Qdo, Hod, and a number of proteins belonging to the $alpha$ / $beta$ hydrolase-fold superfamily of enzymes and analysis of the similaritybetween the predicted secondary structures of the 2,4-dioxygenasesand the known secondary structure of haloalkane dehalogenase fromXanthobacter autotrophicus GJ10 strongly suggested that Qdo andHod are structurally related to the $alpha$ / $beta$ hydrolase-fold enzymes.The residues S95 and H244 of Qdo were found to be arranged likethe catalytic nucleophilic residue and the catalytic histidine,respectively, of the $alpha$ / $beta$ hydrolase-fold enzymes. Investigationof the potential functional significance of these and other residuesof Qdo through site-directed mutagenesis supported the hypothesisthat Qdo is structurally as well as functionally related to serinehydrolases, with S95 being a possible catalytic nucleophile andH244 being a possible catalytic base. A hypothetical reactionmechanism for Qdo-catalyzed 2,4-dioxygenolysis, involving formationof an ester bond between the catalytic serine residue and thecarbonyl carbon of the substrate and subsequent dioxygenolysisof the covalently bound anionic intermediate, isdiscussed.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results and Discussion References

A number of bacterial strains which utilize quinoline or a quinoline derivative as the sole source of carbon and energy havebeen isolated and characterized (14). Degradation of 1H-4-oxoquinolineby Pseudomonas putida 33/1, for instance, is initiated by hydroxylationat C-3, followed by 2,4-dioxygenolytic cleavage of 1H-3-hydroxy-4-oxoquinolineto carbon monoxide and N-formylanthranilate (5, 8). Correspondingly,quinaldine utilization by Arthrobacter ilicis Rü61a (formerlyArthrobacter sp. strain Rü61a) proceeds via 1H-4-oxoquinaldineand 1H-3-hydroxy-4-oxoquinaldine to N-acetylanthranilate and carbonmonoxide (5, 24). In both strains, the N-acylanthranilateis degraded via anthranilate and catechol to intermediates ofcentral metabolic pathways. As proven by ¹⁸O₂/¹⁶O₂ incorporation studies, purified 1H-3-hydroxy-4-oxoquinoline2,4-dioxygenase (Qdo) from P. putida 33/1 and purified 1H-3-hydroxy-4-oxoquinaldine2,4-dioxygenase (Hod) from A. ilicis Rü61a catalyze the insertionof a single molecule of oxygen at C-2 and C-4 of the respectivesubstrate with concomitant release of carbon monoxide (6).The mechanism of Qdo- or Hod-catalyzed 2,4-dioxygenolytic ringcleavage is poorly understood. Based on a chemical model reaction,it has tentatively been proposed that the reaction proceeds viabase catalysis (6). After removal of a proton from the substrateby a catalytic base, molecular oxygen might attack the C-2 carbanionof the substrate, forming a peroxy anion which in a nucleophilicattack could react with the carbonyl carbon (C-4) of the substrate,forming a five-membered cyclic peroxide intermediate that decomposesto carbon monoxide and the N-acylanthranilate (6).

Biochemical and spectroscopic studies of purified Qdo and Hod have shown that these enzymes do not contain a metal centeror organic cofactor (6). This is remarkable, since transitionmetal ions, such as the mononuclear iron centers present in thewell-known nonheme iron dioxygenases catalyzing the cleavage ofdihydroxy-substituted aromatic compounds, or organic cofactors,such as flavins, are generally thought to be required for theactivation of molecular oxygen and/or the organic substrate (17,34, 53). Based on the unique feature of performing a dioxygenolyticreaction without the requirement of cofactors or metal ions, thebacterial 2,4-dioxygenases are presumed to belong to a novel typeofdioxygenases.

Cloning and sequencing of both qdo and hod confirmed that the gene products apparently do not have any similarity to knownoxygenases (35). Instead, Qdo and Hod showed low but significantsequence similarity to P. putida atropinesterase, a serine hydrolase(20).

Serine hydrolases belong to the $alpha$ / $beta$ hydrolase-fold family of enzymes, which comprises a large group of both procaryotic andeucaryotic proteins that share a three-dimensional core structure,even though there is only modest similarity between primary sequences.However, as outlined by Ollis et al. (42), these widely differentsequences can code for remarkably similar structures, since structuralsimilarity is preserved much longer than sequence similarity.Despite the marked variance in primary structure, it has beenfound that all of these enzymes contain a catalytic triad, whichis conserved in the primary sequence in the invariant order ofnucleophilic residue-acidic residue-histidine (42). These aminoacid residues, which are widely separated from each other in theprimary structure, are found in similar topological locationsin the folded proteins. The nucleophile, for example, which inmost cases is a serine residue, is located in a sharp bend, the"nucleophile elbow." This nucleophile elbow is represented bya conserved motif with the proposed consensus sequence Sm-X-Nu-X-Sm-Sm,where Sm indicates a small amino acid residue, X is any aminoacid, and Nu is the nucleophile (42). Although the enzymes ofthe $alpha$ / $beta$ hydrolase-fold family apparently show structural conservationof a catalytic subsite framework, their catalytic specificitiesare radically different (42). The enzyme family comprises allknown cofactor-free haloperoxidases (19, 22a, 44) and diversehydrolases catalyzing a wide variety of reactions (ester, amide,epoxide, C-halogen bond, and even C-C bond hydrolysis) (2,3, 12, 42, 43, 49, 56, 57, 59). However, theenzymes of the $alpha$ / $beta$ hydrolase-fold family are not only structurallybut also functionally and mechanistically related (42). Despitethe differences in catalytic specificities, they catalyze a hydrolyticreaction (however, the cofactor-free haloperoxidases use H₂O₂instead of H₂O as the cosubstrate [22a]).

Here we propose that the 2,4-dioxygenases Qdo and Hod, which belong to the class of oxidoreductases (E.C. 1.), are membersof the $alpha$ / $beta$ hydrolase-fold superfamily of enzymes, having structuraland functional features in common with serine hydrolases (E.C.3.). As a first step toward the analysis of the structure-functionrelationship in Qdo and Hod, we have compared the amino acid sequencesof Qdo and Hod with known members of the $alpha$ / $beta$ hydrolase-fold family.Based on these comparative sequence analyses, which suggestedthe possibility of a catalytic triad, we performed in vitro site-directedmutagenesis of Qdo to assess the putative involvement of distinctserine, aspartate, and histidine residues of Qdo incatalysis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results and Discussion References

Bacterial strains, plasmids, and growth conditions. Escherichia coli M15(pREP4) (Qiagen, Hilden, Germany) was used as a host for (recombinant) plasmid pQE30 (Qiagen) and forexpression of qdo. Epicurian Coli XL1-Blue supercompetent cells(Stratagene, Heidelberg, Germany) were used as the host for pQE30derivatives carrying mutations in the qdo gene constructed bysite-directed mutagenesis. E. coli clones were grown in Luria-Bertani(LB) medium (51) at 37°C, either in the presence of kanamycin(50 µg/ml) and ampicillin (100 µg/ml) (for cells harboring pQE30derivatives as well as pREP4) or in the presence of ampicillin(100 µg/ml, for XL-1 Bluecells).

Recombinant DNA techniques. The qdo gene (EMBL accession no Y14779) has previously been amplified by PCR with primers that created additional sequencesfor BamHI recognition and inserted into the BamHI restrictionsite of pQE30, resulting in pQE30-qdo (35). Transformation ofE. coli M15(pREP4) with pQE30 derivatives was performed by electroporation.Recombinant plasmid DNA was prepared with the QIAprep Spin Miniprepkit (Qiagen) as specified by the supplier. Agarose gel electrophoresiswas carried out by standard techniques (51).

Oligonucleotide site-directed mutagenesis. Mutagenesis was performed with the QuikChange site-directed mutagenesis kit (Stratagene) by the procedure recommended by thesupplier. Plasmid pQE30-qdo was used as the template for Pfu polymerase-mediatedamplification of qdo variants with the following oligonucleotidesas primers for mutagenesis of the codons: S93A, 5'-TTCCAAATGGTCGCCACCTCCCACGGC-3';S95A, 5'-ATGGTCTCCACCGCCCACGGCTGTTGG-3'; S95C, 5'-ATGGTCTCCACCTGCCACGGCTGTTGG-3';D120A, 5'-ACCATCGTCATCGCCTGGCTGCTGCAACCG-3'; S213A, 5'-TGCCACATCTACGCGCAACCCCTTTCC-3';D219A, 5'-CCCCTTTCCCAGGCCTACCGCCAGCTAC-3'; H244A, 5'CCGGGACGGACCGCCTTCCCTTCCCTG-3'(altered codons are underlined). Mutations were confirmed by sequenceanalysis of the DNA fragments encompassing the mutations. DNAsequencing was performed by the dideoxy chain termination method(52). The primers used for sequencing were 5'-end modified withIRD-800 (MWG-Biotech, Ebersberg, Germany). Primers SeqS95 (5'-GCGAAACAGACCGATAGC-3')(for sequencing of the DNA regions encompassing the triplettsencoding A93, A95, and A120), SeqH244 (5'-CCTGAAATCTGCCACATC-3'),and SeqD219 (5'-CGCGAGATCGAAGCGAAC-3') were used for sequencing.The sequencing reaction products were analyzed with a LI-COR 4000automatic sequencer (MWG-Biotech).

Analyses of amino acid sequences. Database searches and binary sequence comparisons were run with the program BLAST (1). Multiple amino acid sequence alignmentswere performed with the CLUSTAL W program (55; HUSAR 4.0 programpackage; European Molecular Biology Laboratory, Heidelberg, Germany).For comparison of the regions of the putative catalytic aminoacid residues, the sequences were manually realigned. Secondary-structurepredictions were carried out with the program PredictProtein (50).

Enzyme assay. The activity of Qdo was determined spectrophotometrically by measuring substrate consumption at 337 nm as described previously(6). One unit was defined as the amount of enzyme that converted1 µmol of substrate per min at 22°C. K_m and V_max were calculatedfrom Lineweaver-Burk plots (32).

Protein determinations. Protein concentrations were determined by the method of Lowry et al. (33) with bovine serum albumin as thestandard.

Purification of recombinant Qdo. E. coli M15(pREP4) clones harboring recombinant pQE30-qdo or pQE30-qdo variants were grown in 100 ml of Luria-Bertani brothat 37°C to an optical density at 600 nm of 0.6. A 700-ml volumeof Luria-Bertani broth was inoculated with this cell suspension,and synthesis of hexahistidine-tagged Qdo protein (His₆Qdo) wasinduced by adding 0.5 mM isopropyl- $beta$ -D-thiogalactopyranoside (IPTG).After incubation for 16 h at 20°C, the cells were harvested bycentrifugation at 4000 × g for 20 min at 4°C, resuspended in 50mM sodium phosphate buffer containing 0.5 M NaCl (pH 7.8), andbroken by ultrasonic treatment (Sonifier model 250; Branson Ultrasonics,Danbury, Conn.). Cell debris was removed by centrifugation at48,000 × g for 40 min at 4°C. In a polypropylene tube slowly rotatedovernight at 4°C, the crude cell extract was mixed with 4 ml ofa 50% (vol/vol) slurry of Ni²⁺-nitrilotriacetate resin beads (Ni-NTA Superflow, Qiagen) thathad been equilibrated in sodium phosphate buffer containing NaCl(see above). Subsequently, the resin was packed into a Bio-ScaleMT2 column (Bio-Rad Laboratories, Munich, Germany). A BioLogicHR liquid chromatography system (Bio-Rad) was used for all chromatographicsteps. After two washing steps, first with sodium phosphate buffercontaining NaCl and supplemented with 5 mM imidazole and thenwith sodium phosphate buffer containing NaCl and supplementedwith 20 mM imidazole, His₆Qdo was eluted with a linear gradient(25 ml) from 100 to 300 mM imidazole in the same NaCl-containingbuffer at a flow rate of 0.5 ml/min. Fractions containing recombinantenzyme were identified by measurement of Qdo activity and/or bypolyacrylamide gel electrophoresis. The eluted His₆Qdo proteinwas washed in an ultrafiltration device (membrane cutoff 10 kDa)with 50 mM Tris-HCl containing 10 mM EDTA (pH 7.8). The purifiedHis₆Qdo was used immediately for determination of its catalyticproperties or was stored at $-$ 80°C. Storage was not accompaniedby any losses in activity (data notshown).

SDS-PAGE. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate (SDS-PAGE) was performed with 10% separatinggels by the method of Laemmli (31). Proteins were stained withCoomassie blue G-250 (0.2% [wt/vol] in water-methanol-acetic acid[60/30/10, by vol]).

	RESULTS AND DISCUSSION

Top Abstract Introduction Materials and Methods Results and Discussion References

Comparison of the amino acid sequences of Qdo, Hod, and $alpha$ / $beta$ hydrolase-fold enzymes, and predicted secondary structures of Qdo and Hod. The amino acid sequences of Qdo and Hod showed 37% identity (Fig. 1). The highest similarity between Qdo and any sequencedeposited in databases was found with atropinesterase (Tpes) fromP. putida (20). Qdo and Tpes had 18% identical amino acids (Fig.1). Further hydrolases and cofactor-free haloperoxidases thathad low but significant sequence similarity to Qdo and Hod arelisted in Fig. 1 to 3. The three-dimensional structures of haloalkanehalidohydrolase (DhlA) from Xanthobacter autotrophicus GJ10 (15,56, 57), bromoperoxidase A2 (BpoA2) from Streptomyces aureofaciensATCC 10762 (19), and epoxide hydrolase (EchA) from Agrobacteriumradiobacter AD1 (39) have been elucidated by X-ray diffraction.These enzymes belong to the structural family of $alpha$ / $beta$ hydrolase-foldenzymes, and the other enzymes aligned with Qdo and Hod have alsobeen proposed to show the general topology of the $alpha$ / $beta$ hydrolasefold (2, 3, 12, 19, 29). Low sequence similaritiesbetween the members of the $alpha$ / $beta$ hydrolase-fold family are common(42). The NH₂-terminal end and a large central segment of theproteins compared in Fig. 1 indeed exhibit very low (if any) similarity.The central segment of the $alpha$ / $beta$ hydrolase-fold enzymes has beensuggested to be involved in substrate specificity (12, 48).The central region of Qdo, which was predicted to be completely $alpha$ -helical, may correspond to the $alpha$ -helical "cap" domain of DhlA(helices H₄ to H₈), which would be in agreement with its possiblerole in contributing to substrate specificity.

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FIG. 1. Multiple amino acid sequence alignment of Qdo, Hod, and some hydrolases and cofactor-free haloperoxidases performed with the program CLUSTAL W (55), and prediction of secondary-structure elements for Qdo and DhlA. Abbreviations: Qdo, P. putida 33/1 1H-3-hydroxy-4-oxoquinoline 2,4-dioxygenase (35; EMBL accession no. Y14779); Hod, A. ilicis Rü61a 1H-3-hydroxy-4-oxoquinaldine 2,4-dioxygenase (35; EMBL accession no. Y14778); Tpes, P. putida atropinesterase (20); CpoL, Streptomyces lividans TK64 chloroperoxidase (4); BpoA2, Streptomyces aureofaciens ATCC 10762 bromoperoxidase (45); XylF, P. putida 2-hydroxymuconic semialdehyde hydrolase (23; the sequence has been corrected in the N-terminal region according to reference 12; see also reference 22); DhlA, Xanthobacter autotrophicus GJ10 haloalkane dehalogenase (26). The numbering does not refer to any of the sequences. Presumed triad residues are marked with a star and printed in boldface. Conserved amino acid motifs surrounding the catalytic nucleophile and the catalytic histidine residue of the $alpha$ / $beta$ hydrolase-fold enzymes are enclosed in a box. S93, D120, and S213 of Qdo are marked by an arrow. The first line at the bottom of the sequences shows the secondary-structure elements of Qdo as calculated by the program PredictProtein (50). The second and third lines indicate the secondary-structure elements of DhlA as predicted (line 2) and as deduced from the X-ray analyses of DhlA (56) (line 3). Hatched and open boxes indicate $beta$ -sheets and $alpha$ -helices, respectively. The $alpha$ -helices of DhlA are numbered according to the numbering scheme of Verschueren et al. (56). Note that the Qdo sequence (35) has been corrected in the C-terminal region (FLQA instead of FLHGLSTCNHELKR) and at position 98 (C instead of V). Qdo thus consists of 264 amino acids, its calculated molecular mass is 30,347 Da, and its calculated isoelectric point is pH 5.43.

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FIG. 2. Multiple alignment of 2,4-dioxygenases, various hydrolases, and some cofactor-free haloperoxidases in the region of the potential catalytic nucleophile of the enzymes. The alignments are based on database searches and binary alignments run with the program BLAST (1) and have been manually realigned. Abbreviations (see also the legend to Fig. 1): BphD, P. putida KF715 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoate hydrolase (18) (the amino acid sequences of BphD from strain KF715 and from Pseudomonas sp. strain LB400 [22] show 95% identity); TodF, P. putida F1 2-hydroxy-6-oxohepta-2,4-dienoate hydrolase (37); DmpD, Pseudomonas sp. CF600 2-hydroxymuconic semialdehyde hydrolase (41); Lip3, Moraxella sp. strain TA144 lipase 3 (13); CpoP, Pseudomonas pyrrocinia chloroperoxidase (62); LinB, Sphingomonas (formerly Pseudomonas) paucimobilis 1,3,4,6-tetrachloro-1,4-cyclohexadiene halidohydrolase (38); DhaA, Rhodococcus rhodochrous NCIMB 13064 1-chloroalkane dehalogenase (30); DehH1, Moraxella sp. strain B haloacetate dehalogenase (27); EchA, Agrobacterium radiobacter AD1 epoxide hydrolase (49); rsEH, soluble epoxide hydrolase from rat liver (28); hPL, human pancreatic lipase (59). The structures of BpoA2 (19), DhlA (15, 56, 57), EchA (39), and hPL (59) (the abbreviations are underlined in the figure) have been solved by X-ray diffraction. The putative catalytic nucleophilic residues are underlined and marked by a star. S93 and D120 of Qdo and the catalytic triad acid D176 of hPL are marked by arrows. Amino acid residues conserved in at least half of the aligned sequences are in boldface.

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FIG. 3. Multiple alignment of 2,4-dioxygenases, various hydrolases, and some cofactor-free haloperoxidases in the region of the potential catalytic aspartate and histidine residues of the enzymes. The alignments are based on database searches and binary alignments run with the program BLAST (1) and have been manually realigned. Abbreviations are given in the legends to Fig. 1 and 2. The structures of BpoA2 (19), DhlA (15, 56, 57), and EchA (39) (abbreviations are underlined in the figure) have been solved by X-ray diffraction. The putative triad histidine residues are underlined and marked by a star. The putative acidic residues of the catalytic triad are underlined. S213 and D219 of Qdo are marked by arrows. Amino acid residues conserved in at least half of the aligned sequences are in boldface.

Despite the low sequence similarity, which limits the accuracy of the secondary-structure prediction, most of the $beta$ -strandsof Qdo were predicted to be at roughly the same position in thealignment as the $beta$ -strands of DhlA (Fig. 1). The same holds forthe predicted $alpha$ -helices of Qdo corresponding to helices H₁, H₂,H₃, H₄, H₅, H₁₀, and H₁₁ of DhlA (Fig. 1). The pattern of thesecondary-structure elements predicted for Hod (not shown) resembledthe pattern calculated for Qdo. Taken together, the comparativesequence analyses as well as the secondary-structure predictionssuggest that Qdo and Hod are structurally related to the $alpha$ / $beta$ hydrolase-foldsuperfamily ofenzymes.

Conserved amino acid sequence motifs of Qdo, Hod, and $alpha$ / $beta$ hydrolase-fold enzymes. The consensus motif Sm-X-Nu-X-Sm-Sm encompassing the catalytic nucleophilic residue of the $alpha$ / $beta$ hydrolase-fold enzymes is wellconserved in all aligned sequences (Fig. 1 and 2). In DhlA (15,46, 56, 57), EchA (39, 49), and rat soluble epoxidehydrolase (rsEH) (3), for instance, the nucleophilic residuesare D124, D107, and D333, respectively. In DhlA, the residuesQ123, D124, and W125 form an extremely sharp bend, the nucleophileelbow (56). At the position of the putative nucleophile, a serineresidue is conserved in many hydrolases and in all cofactor-freehaloperoxidases. This serine residue is catalytically essentialin BpoA2 (44), 2-hydroxymuconic semialdehyde hydrolase (XylF)(12), and human pancreatic lipase (hPL) (59). Thus, S95 ofQdo and S101 of Hod are likely candidates for a putative catalyticresidue. It is interesting that the first small amino acid withinthe consensus sequence, which usually is a glycine residue, isanother serine in Qdo (S93) and Hod (S99). With S93, T94, andS95, Qdo even has three adjacent amino acids with a hydroxyl group(Fig. 2). The side chains of residues Nu $-$ 2 and Nu+2 are thoughtto be close to each other (42). If the two serine residues inthe conserved motif S-X-S-H-G-Sm of Qdo and Hod indeed are inclose proximity, this might well be of functionalsignificance.

The amino acid residue immediately following the putative nucleophile of the $alpha$ / $beta$ hydrolase-fold enzymes has been proposedto be involved in substrate binding (3, 12, 56). Whereasmost hydrolases have an aromatic (F or W) or methionine residuein this position, the 2,4-dioxygenases Qdo and Hod are the onlyenzymes where a histidine residue follows the presumptive nucleophile(Fig. 1 and 2). In DhlA, where the active-site nucleophile isD124, the side chain of the adjacent residue W125 points intothe internal active site cavity and is proposed to be involvedin stabilization of the negatively charged five-coordinate carbonin the transition state and the released halide ion (56, 57).

Apart from the Sm-X-Nu-X-Sm-Sm motif, which occurs in all aligned sequences shown in Fig. 2, a number of further motifs orresidues are conserved in subgroups of the aligned enzymes (Fig.2 and 3). An example is a P-E-R-V motif, which is conserved inXylF, DmpD, DhaA, and rsEH and is similar in most other enzymes,situated 13 to 15 amino acid residues from the catalytic nucleophile.An amino acid segment conserved in a number of hydrolases andcofactor-free haloperoxidases is the sequence D/E-A-L-G/D(/E)-L(/I),which is located 8 to 9 amino acid residues NH₂-terminal to thenucleophilic residue (Fig. 2). This region, however, is ratherdifferent in Qdo, Hod, and Tpes (P. putida atropinesterase). Themotif R-V-I-A(/X)-P(/X)-D-X-X-G-X-G-X-S-(X)_2/4-P, which is found30 to 35 amino acids NH₂-terminal to the nucleophilic residuein many $alpha$ / $beta$ hydrolase-fold enzymes, is also conserved in Hod (exceptthat the conserved aspartate is replaced by asparagine), whereasin Qdo, this motif is hardly recognizable (Fig. 2).

The presumptive histidine residue of the catalytic triad is completely conserved in all hydrolases and cofactor-free haloperoxidases.H244 of Qdo and H251 of Hod clearly align with the triad histidineof the $alpha$ / $beta$ hydrolase-fold enzymes (Fig. 3). In BpoA2 (44), DhlA(47, 56, 57), XylF (12), EchA (39, 49), and rsEH (3),the equivalent histidine residue indeed has been proven to bethe general base residue which is functional in the catalytictriad. The sequence encompassing the conserved histidine (underlined)is G-(X)-H-Ar in most hydrolases (where Ar is an aromatic aminoacid residue). In Qdo and Hod, an aromatic residue likewise followsthe histidine, but the conserved glycine residue preceding theputative catalytic histidine is replaced by threonine. Althoughthe primary sequences of the cofactor-free haloperoxidases divergein this region, their presumptive catalytic histidine aligns withthe histidine of all hydrolases (Fig. 3).

Whereas the nucleophilic residue and the histidine residue of the putative catalytic triads are located within distinct sequencemotifs, the amino acid sequences around the catalytic acidic residueappear to be less highly conserved among the $alpha$ / $beta$ -fold hydrolases.However, as shown in Fig. 3, some (but not all) hydrolases showthe sequence H/(X)-G-X-X-D-X-X-X-(X)-P 23 to 24 residues NH₂-terminalto the catalytic histidine (the catalytic aspartate is underlined).A number of hydrolases and cofactor-free haloperoxidases possessanother acidic residue immediately preceding the catalytic aspartateresidue. In Tpes, an asparagine residue aligns with the catalyticacidic residue of the cofactor-free haloperoxidases and many hydrolases,but its functional significance is not known. In Qdo and Hod,the above-mentioned conserved sequence is not evident, and comparisonof this region of Qdo and Hod to the $alpha$ / $beta$ hydrolase-fold proteinsled to divergent alignments when different algorithms were used(Fig. 1 and 3). All BLAST searches indicated that in Qdo and Hod,a glutamine residue might be in the equivalent position of thecatalytic acidic residue of the hydrolases and cofactor-free haloperoxidases(Fig. 3). D219 of Qdo and E226 of Hod are located 4 amino acidresidues from these glutamine residues Q214 (Qdo) and Q221 (Hod).The primary sequences of BphD, TodF, Lip3, DhlA, rsEH, and allcofactor-free haloperoxidases also show an acidic residue, whichis located 5 or 6 residues from the catalytic aspartate, but thisresidue is not involved in the catalytic mechanism. In DhlA, thisnonfunctional aspartate (D266) is positioned within the $alpha$ -helixH₁₀, near to its NH₂-terminal end (56) (Fig. 1). The predictionof secondary-structure elements of Qdo likewise assigned D219near to the NH₂-terminal end of an $alpha$ -helix (Fig. 1). In contrast,the region around Q214 of Qdo was proposed to form a loop. Dueto the secondary-structure predictions and to the poor sequencesimilarities between Qdo, Hod, and the aligned members of the $alpha$ / $beta$ hydrolase-fold superfamily of enzymes in this region, thepossibility of a catalytic significance of D219 in Qdo appearedambiguous.

The conserved amino acid sequence motifs and presumptive catalytic serine and histidine residues of Qdo show the same sequenceorder and similar spacings as the respective motifs and triadresidues of the $alpha$ / $beta$ hydrolase-fold enzymes. Despite the poor aminoacid sequence homology among the proteins belonging to the $alpha$ / $beta$ hydrolase-fold superfamily of enzymes, their catalytic-triad residuesare known to have similar topological and three-dimensional positions(42).

Mutagenesis of qdo and detection of the Qdo variants. To investigate the potential functional role of the conserved S95 and H244 and to assess the hypothesis of a putative catalytictriad of the 2,4-dioxygenase Qdo, these and other residues werereplaced by site-directed mutagenesis. Provided that the foldingof the recombinant His₆Qdo proteins is correct, loss of activityshould be a direct consequence of the replacement of amino acidresidues involved in catalysis and/or substrate binding by nonfunctionalamino acid sidechains.

In the case of the presumptive catalytic nucleophile S95, the serine residue was replaced by the nonionizable amino acid alanineand by cysteine as another possible but stronger nucleophile.H244 of Qdo, which aligns with the catalytic histidine residuesof the $alpha$ / $beta$ hydrolase-fold enzymes, also was replaced by alanine.As described above, the amino acid sequence comparisons were difficultin the region of D219 of Qdo, and the secondary-structure predictionsof Qdo indicated an $alpha$ -helical structure around D219 rather thana loop. However, considering the spacing between the active-siteresidues, D219 could nevertheless be a possible candidate fora catalytic aspartate residue. Its functional significance wasalso assessed by replacing it by an alanine residue. Furthermore,His₆QdoS93A, His₆QdoD120A, and His₆QdoS213A mutants were constructed.The secondary-structure predictions for the 93A, 95A, 95C, 120A,213A, 219A, and 244A Qdo proteins, as determined by the programPredictProtein (50), corresponded to those of wild-type Qdo.Thus, the replacements were not supposed to alter the secondary-structureelements.

Recombinant His₆Qdo as well as His₆-tagged QdoS95A, QdoS95C, QdoH244A, QdoD219A, and QdoD120A were purified to electrophoretichomogeneity (Fig. 4a) by metal chelate affinity chromatographyon an Ni²⁺-nitrilotriacetate column. Recombinant His₆Qdo as well as theHis₆-tagged S95A, S95C, H244A, D219A, and D120A variants elutedfrom the metal chelate affinity column at an imidazole concentrationof 180 mM. In contrast, no protein peaks eluted at this imidazoleconcentration when crude extracts from the E. coli clones supposedto express His₆QdoS93A and His₆QdoS213A were separated by metalchelate affinity chromatography, indicating that these crude extractsdid not contain soluble His₆-tagged Qdo protein. In SDS-PAGE,protein bands corresponding to a molecular mass of about 31 kDa(corresponding to His₆Qdo) were hardly visible when crude extractsfrom the E. coli expression clones supposed to express His₆QdoS93Aand His₆QdoS213A were separated (Fig. 4b). The presumed absenceof soluble Qdo protein in these recombinant E. coli expressionclones could be caused either by precipitation of the Qdo variantto insoluble aggregates and/or proteolysis or by a lack of Qdosynthesis.

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FIG. 4. SDS-PAGE of recombinant His₆-tagged Qdo proteins. (a) His₆Qdo variants purified by metal chelate affinity chromatography. Lanes: 2, recombinant Qdo; 3, QdoD120A; 4, QdoD219A; 5, QdoH244A; 7, QdoS95A; 8, QdoS95C. (b) Crude extracts of E. coli clones expressing recombinant His₆-tagged Qdo (lane 2) and of clones supposed to express His₆-tagged QdoS93A (lane 3) and QdoS213A (lane 4). The molecular masses of the marker proteins (lanes 1, 6, and 9 in panel a and lanes 1 and 5 in panel b) are 97.2, 66.2, 55, 42.7, 40, and 31 kDa.

The specific activity of recombinant His₆Qdo in crude extracts of E. coli M15(pREP4)pQE30-qdo was 0.25 U mg of protein¹. Crude extracts of the E. coli clones containing mutant qdo showedspecific activities as follows: His₆QdoS95A, 0.003 U mg of protein¹; His₆QdoS95C, below detection; His₆QdoH244A, below detection;His₆QdoD219A, 0.24 U mg of protein¹; and His₆QdoD120A, 0.28 U mg of protein¹. Crude extract of the clone supposed to produce His₆QdoS213A,which apparently did not contain soluble Qdo (Fig. 4b), likewisedid not show detectable Qdo activity. In contrast, freshly preparedcrude extract of the E. coli mutant synthesizing His₆QdoS93A exhibiteda specific 2,4-dioxygenase activity of about 0.01 U mg of protein¹, which rapidly vanished, presumably due to precipitation of theprotein (Fig. 4b).

The catalytic properties of wild-type Qdo isolated from P. putida 33/1 (7), purified recombinant His₆Qdo, and purifiedmutant His₆Qdo proteins are summarized in Table 1. The apparentK_m values of wild-type and recombinant Qdo were similar, suggestingthat the recombinant Qdo enzyme is not affected by the NH₂-terminalhexahistidine tag.

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TABLE 1. Kinetic parameters for purified wild-type, recombinant, and mutant Qdo enzymes

Assessment of the potential nucleophilic serine residue of Qdo. Interestingly, replacement of the putative active-site nucleophile S95 by alanine or cysteine did not result in complete lossof enzyme activity. The apparent K_m value of the S95A mutant wasincreased 4.8-fold compared to recombinant His₆Qdo, and its turnovernumber was decreased 13.5-fold. Purified His₆QdoS95C showed arelatively low K_m value, but its turnover number was decreasedmore than 300-fold compared with recombinant His₆Qdo (Table 1).However, if the critical active-site nucleophilic side chain hasbeen removed in His₆QdoS95A and His₆QdoS95C, complete loss ofactivity would be expected. Possibly, S95 has some backup in Qdo.Thus, the assumption that the nearby S93, which was predictedto immediately follow a $beta$ -sheet structure, might to some extenttake over the catalytic role of S95 was assessed by constructionof an E. coli clone which should produce His₆QdoS93A. Unfortunately,it was not possible to isolate the His₆QdoS93A protein, as describedabove. On the other hand, it is even possible that S213 of Qdo,which presumably is located in the topological position of theacidic residue of a catalytic triad (Fig. 1) and which is conservedin Qdo and Hod (Fig. 3), is of functional significance. However,as outlined above, the His₆QdoS213A enzyme was not detected inthe crude extract of the corresponding E. coli clone. Thus, noneof the assumed nearby potential nucleophiles could be tested,because the relevant Qdo proteins were not expressed orfolded.

The nucleophile of the hydrolases possessing a catalytic triad can be either a serine, an aspartate, or a cysteine residue.In hydrolases with an active-site cysteine residue, cysteine hasbeen replaced by serine. Pathak et al. (43), for instance, showthat about 10% of the activity was retained in a C123S mutantof dienelactone hydrolase whereas the C123A dienelactone hydrolasewas inactive. In contrast, conversion of the active-site thiolgroup of C25 in papain to a hydroxyl group led to S25 papain thatwas devoid of enzymatic activity (11). Considering the serinehydrolases, Witkowski et al. (60, 61) engineered a S101C mutantof the rat mammary gland thioesterase II which retained up to90% of catalytic activity. Whereas replacement of the seryl oxygenwith the larger cysteinyl sulfur had only a minor effect on thecatalytic efficiency of thioesterase II, attempts to engineerefficient thiol active sites from the serine active-site proteasessubtilisin (40) and trypsin (21, 36, 63) as well as acetylcholinesterase(16) and XylF (12) produced enzymes with activities reducedby 2 to 6 orders of magnitude. In this study, the activity ofHis₆QdoS95C was likewise very low (Table 1). In dienelactonehydrolase, the active-site cysteine thiol is converted to thecatalytically functional thiolate only in the presence of substrate(10). Additionally, a glutamate residue is required to formthe cysteine-thiolate from cysteine thiol (10). Thus, the serinehydrolases unable to utilize cysteine in their active site maynot possess a mechanism for activation (i.e., deprotonation) ofthe cysteine thiol, or steric problems may preclude the use ofcysteine as an active-site nucleophile. Analysis of the crystalstructure of the S195C trypsin mutant revealed that the sulfuratom was pointing away from the binding pocket, obstructing theoxyanion hole in trypsin (36). Thus, most serine hydrolasesappear to show an absolute requirement for serine in their catalytictriad. Thioesterases utilize both types of serine codons, TCN(where N is a purine or pyrimidine base) and AGY (where Y is apyrimidine base). The latter could be derived from the cysteinecodons TGY by a single base change. In contrast, the 2,4-dioxygenasesQdo and Hod use TCN codons for the presumptive catalytic serineresidue. Whereas the S101C thioesterase II mutant might supportthe hypothesis of Brenner (9) that considers the serine active-sitehydrolases to be evolved from ancestral cysteine active-site enzymes,other studies indicate that during evolution of the hydrolases,a shift toward a catalytic mechanism of higher stringency witha strong bias for serine has occurred (12). Indeed, in responseto Brenner's hypothesis, Irwin (25) proposed that there aremultiple origins of the serine codons of the hydrolase activesite, with an accompanying switch from one type of codon to theother.

Catalytic histidine residue of Qdo. The activity of the His₆QdoH244A protein, which was purified by metal chelate affinity chromatography (Fig. 4a), was belowthe level of detection, clearly indicating a functional role ofthis histidine residue inQdo.

Assessment of possible catalytic aspartate residues of Qdo. According to the alignment shown in Fig. 1, there was a remote possibility that D219 of Qdo was a candidate for the acidicresidue of the catalytic triad. Its replacement by alanine resultedin His₆QdoD219A protein showing a ca. 2.5-fold increase in K_mand a 5.6-fold decrease in k_cat (Table 1). Although this is amarked decrease in activity, the substrate turnover is significant.Based on the relatively high turnover number and the secondary-structurepredictions strongly suggesting an $alpha$ -helix in this region (seeabove), it seems rather unlikely that D219 is the catalyticallyessential acidic residue of a putative active-sitetriad.

It is interesting that atropinesterase possesses an asparagine which aligns with the catalytic aspartate of the cofactor-freehaloperoxidases and most hydrolases (Fig. 3). The proteolyticenzyme papain possesses a Cys-His-Asn triad, where the asparagineresidue is assumed to be required for the formation of the Cys/His⁺ ion pair. (However, papain constitutes a separate group of thehydrolases and forms a nucleophilic elbow quite different fromthe sharp bend of the $alpha$ / $beta$ hydrolase-fold enzymes [42].)

The acidic residue corresponding to the triad acid of the classical $alpha$ / $beta$ hydrolase-fold enzymes likewise does not seem to beconserved in the halidohydrolases LinB, DhaA, and DehH1 (Fig.3). On the other hand, LinB, DhaA, and DehH1, as well as Qdo andHod, possess an asparate or glutamate residue at the equivalentposition of the triad acid D176 of hPL (Fig. 2) (29, 54).This aspartate residue aligns with D120 of Qdo. Although thereis no significant sequence similarity between hPL and the hydrolasescompared in Fig. 2, the topology of the first domain of hPL isknown to be like that of the $alpha$ / $beta$ hydrolase-fold enzymes (42,54, 59). The catalytic-triad residues of hPL are organizeddifferently from the classical $alpha$ / $beta$ hydrolase-fold enzymes. Whereasthe active-site serine and histidine residues in hPL are locatedafter $beta$ -strands 5 and 8 and thus correspond to the topologicalorganization of the $alpha$ / $beta$ hydrolase-fold enzymes, the catalyticaspartate (D176) follows $beta$ -strand 6 instead of $beta$ -strand 7 (42,54). In DhlA, N148 is the analogue of D176 of hPL (Fig. 2) andis located directly behind $beta$ -strand 6, where it forms a hydrogenbond with the nucleophilic D124 (56). Krooshof et al. (29)suggested that the acidic residue of the catalytic triad is presentin LinB, DhaA, and DehH1 at a position analogous to D176 of hPLand N148 of DhlA (Fig. 2). Experimental evidence for this hypothesiswas provided by replacing N148 of DhlA with aspartate or glutamateand replacing the catalytic D260 of DhlA by asparagine. In theDhlA-D260N+N148E and DhlA-D260N+N148D mutants, the acidic residueat position 148 indeed could to some extent take over the roleof the triad acid, interacting with H289 of DhlA (29). Thus,we tentatively assumed that D120 of Qdo, which aligns with N148of DhlA, the catalytic D176 of hPL, and the presumptive triadacids of LinB, DhaA, and DehH1, might be the triad acid. However,replacement of D120 of His₆Qdo by alanine resulted in a Qdo enzymewhose catalytic activity was of the same order of magnitude asthe recombinant His₆Qdo enzyme (Table 1), clearly disprovingthe hypothesis that D120 is the acidic residue of a potentialcatalytic triad ofQdo.

Tentative hypothesis on the possible functional role of the catalytically essential amino acids of Qdo. The hydrogen-bonded triad, consisting of a nucleophilic amino acid, histidine, and an acidic amino acid residue, is essentialin the catalysis of known hydrolases and haloperoxidases belongingto the $alpha$ / $beta$ hydrolase-fold family of enzymes. In the catalysisof a hydrolytic reaction, the side chain of the nucleophilic aminoacid residue attacks the electropositive carbon atom of the substrate(e.g., a carbonyl carbon in an ester or amide hydrolysis, or,as in DhlA, the chlorine-substituted carbon atom) to form a covalentlybonded enzyme-substrate complex (46, 56, 57). The role ofthe catalytic histidine is very different in different membersof the $alpha$ / $beta$ hydrolase-fold family. In the serine proteases, thehistidine is needed both for formation and hydrolysis of the acyl-enzymeintermediate, since it activates the nucleophile by base catalysisand also donates a proton to the serine leaving group when theacyl-enzyme intermediate is hydrolyzed. In dienelactone hydrolase,which has a cysteine residue as the nucleophile, the catalytichistidine is involved only in maintenance of the nucleophilicityof the catalytic cysteine residue and not in hydrolysis of thecovalently bound intermediate (10). In DhlA, which has an aspartateas catalytic nucleophile, the catalytic histidine residue is abstractinga proton from the water molecule which hydrolyzes the alkyl-enzymeintermediate (47, 56, 57). The breakdown of the covalentintermediate by the activated water molecule results in releaseof the product and restoration of the active-site residues. Theacidic residue of the triad of the hydrolases facilitates theproton abstraction by histidine and stabilizes the positive chargeon histidine electronically (58).

By analogy to the serine hydrolases, S95 of Qdo should be a likely candidate for an active-site nucleophile, which in itsactivated (deprotonated) form might perform a nucleophilic attackon the electropositive carbonyl carbon atom (C-4) of the substrate1H-3-hydroxy-4-oxoquinoline, likewise leading to the formationof a covalent bond, i.e., an ester intermediate, as shown in Fig.5. Formation of an ester bond, which involves cleavage of theN-heterocyclic ring of 1H-3-hydroxy-4-oxoquinoline, would thusgenerate an enzyme-bound substrate anion (Fig. 5). By furtheranalogy to the serine hydrolases, the catalytic base (H244 ofQdo) may activate the nucleophilic serine residue by acceptinga proton. The positively charged catalytic histidine residue maybe stabilized by a yet unknown acidic residue (the triad acid).Alternatively, the protonated catalytic histidine of Qdo may interactwith the enzyme-bound substrate anion, and so the substrate anionand the positively charged histidine might stabilize each other.In the latter case, it is even possible that Qdo and Hod are devoidof the catalytic acid of the canonical triad. Another alternativeis that the substrate anion is stabilized by another positivelycharged residue of the enzyme (e.g., protonated H96 of Qdo, ifH96, by analogy to W125 of DhlA, contributes to the active-sitecavity).

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FIG. 5. Tentative hypothesis for the mechanism of Qdo-catalyzed 2,4-dioxygenolysis of 1H-3-hydroxy-4-oxoquinoline to carbon monoxide and N-formylanthranilic acid (for a detailed explanation, see the text). [Ser-O], deprotonated serine residue of Qdo; [His-H⁺], protonated histidine residue of Qdo.

Qdo and Hod have been proven to be 2,4-dioxygenases, catalyzing the incorporation of a single molecule of oxygen at C-2 andC-4 of their respective substrate (6). Since dioxygen insteadof a water molecule must be involved in the subsequent catalyticsteps, the mechanistic role of the presumed catalytic amino acidsof the hydrolases and the 2,4-dioxygenases is difficult to compare.As suggested previously, the C-2 carbanion form of the enzyme-boundsubstrate anion subsequently might be attacked by dioxygen, yieldinga peroxy anion intermediate (6). This peroxy anion, via a five-memberedcyclic peroxide transition form, could release the catalytic serineand eliminate carbon monoxide, thus generating the product N-formylanthranilicacid (Fig. 5).

Conclusions. Although the structural relatedness of Qdo, Hod, and enzymes belonging to the $alpha$ / $beta$ hydrolase-fold superfamily of enzymes andthe catalytic significance of H244 and, presumably, S95 of Qdohave been established in this study, it is not yet clear whetherQdo actually possesses the canonical catalytic triad of the hydrolasesand cofactor-free haloperoxidases. Despite the marked similarityof Qdo to serine hydrolases and other proteins belonging to the $alpha$ / $beta$ hydrolase-fold superfamily, our tentative hypothesis on themechanism of Qdo-catalyzed 2,4-dioxygenolysis is highly speculativeand the structure-function relationship of Qdo is not yet clear.It is obvious that further investigations are needed to validatethe roles of putative catalytically essential amino acid residuesof Qdo. In particular, it would be most exciting to perform crystallizationand X-ray diffraction analyses of the 2,4-dioxygenases in orderto describe the active site and to elucidate the catalytic mechanismof 2,4-dioxygenolysis.

	ACKNOWLEDGMENTS

We thank Erhard Rhiel, Geomicrobiology, Universität Oldenburg, for sequence analysis of the mutated regions of qdo.

The financial support of the Deutsche Forschungsgemeinschaft is gratefullyacknowledged.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Microbiology, FB 7, Carl von Ossietzky-University of Oldenburg, P.O.Box 2503, D-26111 Oldenburg, Germany. Phone: 49 (0)441-7983295.Fax: 49 (0)441-7983250. E-mail: fetzner{at}hrz2.uni-oldenburg.de.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results and Discussion
References

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50. Rost, B., and C. Sander. 1994. Combining evolutionary information and neural networks to predict protein secondary structure. Protein Struct. Funct. Genet. 19:55-72.

51. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

52. Sanger, F., S. Nicklen, and A. R. Coulson. 1977. DNA sequencing with chain-termination inhibitors. Proc. Natl. Acad. Sci. USA 74:5463-5467[Abstract/Free Full Text].

53. Sariaslani, F. S. 1989. Microbial enzymes for oxidation of organic molecules. Crit. Rev. Biotechnol. 9:171-257[Medline].

54. Schrag, J. D., F. K. Winkler, and M. Cygler. 1992. Pancreatic lipases: evolutionary intermediates in a positional change of catalytic carboxylates? J. Biol. Chem. 267:4300-4303[Abstract/Free Full Text].

55. Thompson, J. D., D. G. Higgins, and T. J. Gibson. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].

56. Verschueren, K. H. G., S. M. Franken, H. J. Rozeboom, K. H. Kalk, and B. W. Dijkstra. 1993. Refined X-ray structures of haloalkane dehalogenase at pH 6.2 and pH 8.2 and implications for the reaction mechanism. J. Mol. Biol. 232:856-872[Medline].

57. Verschueren, K. H. G., F. Seljée, H. J. Rozeboom, K. H. Kalk, and B. W. Dijkstra. 1993. Crystallographic analysis of the catalytic mechanism of haloalkane dehalogenase. Nature 363:693-698[Medline].

58. Warshel, A., G. Naray-Szabo, F. Sussman, and J.-K. Hwang. 1989. How do serine proteases really work? Biochemistry 28:3629-3637[Medline].

59. Winkler, F. K., A. D'Arcy, and W. Hunziker. 1990. Structure of human pancreatic lipase. Nature 343:771-774[Medline].

60. Witkowski, A., J. Naggert, H. E. Witkowska, Z. I. Randhawa, and S. Smith. 1992. Utilization of an active serine 101 $right-arrow$ cysteine mutant to demonstrate the proximity of the catalytic serine 101 and histidine 237 residues in thioesterase II. J. Biol. Chem. 267:18488-18492[Abstract/Free Full Text].

61. Witkowski, A., H. E. Witkowska, and S. Smith. 1994. Reengineering the specificity of a serine active-site enzyme. J. Biol. Chem. 269:379-383[Abstract/Free Full Text].

62. Wolfframm, C., F. Lingens, R. Mutzel, and K.-H. van Pée. 1993. Chloroperoxidase-encoding gene from Pseudomonas pyrrocinia: sequence, expression in heterologous hosts, and purification of the enzyme. Gene 130:131-135[Medline].

63. Yokosawa, H., S. Ojima, and S. Ishii. 1977. Thioltrypsin. Chemical transformation of the active-site serine residue of Streptomyces griseus trypsin to a cysteine residue. J. Biochem. (Tokyo) 82:869-876[Abstract/Free Full Text].

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Bacterial 2,4-Dioxygenases: New Members of the / Hydrolase-Fold Superfamily of Enzymes Functionally Related to Serine Hydrolases

Bacterial 2,4-Dioxygenases: New Members of the $alpha$ / $beta$ Hydrolase-Fold Superfamily of Enzymes Functionally Related to Serine Hydrolases