Mechanism of Chloride Elimination from 3-Chloro- and 2,4-Dichloro-cis,cis-Muconate: New Insight Obtained from Analysis of Muconate Cycloisomerase Variant CatB-K169A

doi:10.1128/JB.183.15.4551-4561.2001

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Journal of Bacteriology, August 2001, p. 4551-4561, Vol. 183, No. 15
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.15.4551-4561.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Mechanism of Chloride Elimination from 3-Chloro- and 2,4-Dichloro-cis,cis-Muconate: New Insight Obtained from Analysis of Muconate Cycloisomerase Variant CatB-K169A

Ursula Kaulmann,¹^, Stefan R. Kaschabek,²^,^§ and Michael Schlömann¹^,^*

Institut für Mikrobiologie, Universität Stuttgart, D-70569 Stuttgart,¹ and Chemische Mikrobiologie, Bergische Universität $---$ Gesamthochschule Wuppertal, D-42097 Wuppertal,² Germany

Received 16 January 2001/Accepted 15 May 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Chloromuconate cycloisomerases of bacteria utilizing chloroaromatic compounds are known to convert 3-chloro-cis,cis-muconateto cis-dienelactone (cis-4-carboxymethylenebut-2-en-4-olide),while usual muconate cycloisomerases transform the same substrateto the bacteriotoxic protoanemonin. Formation of protoanemoninrequires that the cycloisomerization of 3-chloro-cis,cis-muconateto 4-chloromuconolactone is completed by protonation of the exocycliccarbon of the presumed enol/enolate intermediate before chlorideelimination and decarboxylation take place to yield the finalproduct. The formation of cis-dienelactone, in contrast, couldoccur either by dehydrohalogenation of 4-chloromuconolactone or,more directly, by chloride elimination from the enol/enolate intermediate.To reach a better understanding of the mechanisms of chlorideelimination, the proton-donating Lys169 of Pseudomonas putidamuconate cycloisomerase was changed to alanine. As expected, substratesrequiring protonation, such as cis,cis-muconate as well as 2-and 3-methyl-, 3-fluoro-, and 2-chloro-cis,cis-muconate, werenot converted at a significant rate by the K169A variant. However,the variant was still active with 3-chloro- and 2,4-dichloro-cis,cis-muconate.Interestingly, cis-dienelactone and 2-chloro-cis-dienelactonewere formed as products, whereas the wild-type enzyme forms protoanemoninand the not previously isolated 2-chloroprotoanemonin, respectively.Thus, the chloromuconate cycloisomerases may avoid (chloro-)protoanemoninformation by increasing the rate of chloride abstraction fromthe enol/enolate intermediate compared to that of proton additiontoit.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Chloroaromatic compounds, in general, tend to be relatively persistent to microbial degradation (13, 21). Nevertheless,some of these compounds can be mineralized by specialized bacteria,in many cases via ortho cleavage of chlorocatechol intermediates.Cycloisomerization of the chloro-cis,cis-muconates resulting fromring cleavage is a key reaction, because in chlorocatechol assimilatingbacteria it is accompanied by dehalogenation (Fig. 1) (11, 12,38).

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FIG. 1. Reactions catalyzed by proteobacterial muconate cycloisomerases (MCI) and chloromuconate cycloisomerases (CMCI). Numbers on the arrows indicate whether the reaction is a 1,4- or a 3,6-cycloisomerization. "CMCI?" indicates that for chloromuconate cycloisomerases it is not clear whether cis-dienelactone is formed directly or via (+)-4-chloromuconolactone as intermediate. No attempt was made to differentiate between fast and slow turnover. The formation of chloromuconolactones involves the syn addition of a proton (bold italics) to the C $alpha$ atom.

For a long time, muconate cycloisomerases (EC 5.5.1.1) of catechol catabolic pathways and chloromuconate cycloisomerases(EC 5.5.1.7) of chlorocatechol degradative pathways were assumedto catalyze just the cycloisomerization reaction of, for example,2-chloro- and 3-chloro-cis,cis-muconate to 5-chloromuconolactone (4-carboxychloromethylbut-2-en-4-olide) and4-chloromuconolactone (4-carboxymethyl-4-chlorobut-2-en-4-olide),respectively (34). Chloride elimination to trans-dienelactoneand cis-dienelactone, respectively, was assumed to occur spontaneouslyin a secondary reaction. However, more recently Vollmer et al.(42) showed that proteobacterial muconate cycloisomerases forma pH-dependent equilibrium mixture of 2- and 5-chloromuconolactonefrom 2-chloro-cis,cis-muconate (Fig. 1), proving that these enzymes,in contrast to proteobacterial chloromuconate cycloisomerases,cannot cause dehalogenation during conversion of 2-chloro-cis,cis-muconate.Moreover, Blasco et al. (3) have shown that muconate cycloisomerasesconvert 3-chloro-cis,cis-muconate predominantly to the antibioticprotoanemonin and not to cis-dienelactone as assumed before (34).Only for chloromuconate cycloisomerases has cis-dienelactone beenshown to be the product (23, 34).

Blasco et al. (3) proposed that both muconate and chloromuconate cycloisomerases form 4-chloromuconolactone as an intermediateof 3-chloro-cis,cis-muconate conversion. This would be furthertransformed in different ways by the two classes of enzymes. However,since the muconate and chloromuconate cycloisomerases catalyzesyn additions to a double bond (2, 7), the $alpha$ , $beta$ eliminationof HCl from a 4-chloromuconolactone intermediate to yield cis-dienelactonewould imply that exactly the same proton as added in the firstpart of the reaction would be removed in the second (33). Consequently,chloride had been assumed to be abstracted before a proton couldbe added to what was then regarded as an carbanion intermediate(25). Recent comparative studies on the reaction mechanismsof muconate cycloisomerase and mandelate racemase suggested thatthe intermediate to which a proton is added in the reaction withcis,cis-muconate is an enol/enolate and not a carbanion (15).Thus, one might assume that in the reaction of chloromuconatecycloisomerases with 3-chloro-cis,cis-muconate, the correspondingenol/enolate intermediate is not protonated but rather loses thenegative charge by chloride abstraction. The formation of protoanemoninin the reaction of muconate cycloisomerase with 3-chloro-cis,cis-muconate,in contrast, should involve a protonation reaction, because twohydrogen atoms are present on the exocycliccarbon.

To test these hypotheses on the enzymatic reaction mechanism, the Lys169 residue of Pseudomonas putida muconate cycloisomeraseand the Lys165 residue of the chloromuconate cycloisomerase TfdDof pJP4, which are known to provide the proton for the protonationreaction (15, 32), were changed to alanine, and the catalyticproperties of the resulting enzyme variants (CatB-K169A and TfdD-K165A)were investigated with varioussubstrates.

(Some of the results have been published in a preliminary communication [U. Schell and M. Schlömann, Bioengineering {specialed.} abstr. PF220, 1998].)

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Strains, plasmids, and cultivation conditions. Escherichia coli strain DH5 $alpha$ was purchased from GIBCO BRL. E. coli strain BL21(DE3,pLysS) (37) was used for gene expressionunder T7lac promoter control. Plasmids used in this study arelisted in Table 1. Plasmid-containing strains were usually grownaerobically at 30 or 37°C with constant shaking in 2xYT medium(31) supplied with ampicillin (100 µg/ml). For growth on plates,Luria-Bertani (LB) medium (31) was supplemented with 1.5% (wt/vol)agar.

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TABLE 1. Plasmids used in this study

DNA preparation and in vitro manipulation. Plasmid DNA was isolated by use of a Pharmacia FlexiPrep kit. Restriction endonuclease digests, ligations, and detection ofcolonies carrying an insert were performed according to standardprocedures. DNA fragments were isolated from gels or purifiedin solution by use of a GeneClean II kit (Bio101, La Jolla, Calif.).Transformation of E. coli strains was achieved by the method ofInoue et al. (19).

PCR mutagenesis. The CatB-K169A variant was generated by PCR-based site-directed mutagenesis as described by Michael (24), using two outeramplification primers and one mutagenic phosphorylated oligonucleotidein one PCR. To avoid mutations other than the one desired, mutagenesiswas carried out with pCATB7, which had been constructed earlierby cloning the 419-bp SacII-HindIII fragment of P. putida catBinto pBluescript II KS(+) (M. D. Vollmer, unpublished results).The sequences of the two outer amplification primers were 5'-CTCGAAATTAACCCTCACTAAAG-3'(BS_T3, directed toward the T3 promoter region of the vector)and 5'-AATTGTAATACGACTCACTATAG-3' (BS_T7, reverse primerdirected toward the T7 promoter region of the vector). Since theseprimers were originally designed for use with pBluescript andnot pBluescript II, some 5'-terminal residues of the primers (bold)were not complementary to the template. To create the Lys (AAG)169-to-Ala (GCG) mutation, a mutant oligonucleotide was derivedfor positions 491 to 515 of P. putida catB (EMBL/GenBank accessionnumber U12557; 18, 43): 5'-GGGTGTTCAAGCTGGCGATTGGCG-3' (M_K169A).The underlined nucleotides indicate where the changes were madeto create the desired mutation. The melting temperature of themutagenic oligonucleotide was chosen to be about 20°C higher thanthat of the outer primers to ensure a high mutagenesis efficiency.The mutagenic oligonucleotide was phosporylated by T4 polynucleotidekinase (GIBCO BRL) and then added directly to the amplification-mutagenesisreaction. The reaction mixture (50-µl total volume) consistedof 100 pmol of each of the three primers, 200 µM each deoxynucleotidetriphosphate, 5% (vol/vol) dimethyl sulfoxide, thermostable ligasebuffer (25 mM potassium acetate, 20 mM Tris-HCl [pH 7.6], 10 mMmagnesium acetate, 0.1% Triton X-100, 10 mM dithiothreitol, 1mM NAD⁺), 0.3 U of Goldstar DNA polymerase (Eurogentech), 20 U of Taqligase (New England Biolabs), and 100 ng of XmnI-digested DNAof pCATB7 as the template. The thermocycling parameters were asfollows: 29 cycles of denaturing (94°C, 30 s), annealing (60°C,1 min), and polymerization-ligation (65°C, 4 min), with an additional4.5 min of denaturing before addition of the polymerase and ligaseduring the first cycle and an additional 11 min of polymerizationduring the last cycle. As expected, this reaction yielded twoproducts, a full-length product of about 530 bp and a smallerproduct of about 240 bp, the latter resulting from amplificationbetween the mutagenic oligonucleotide and the BS_T7 primer annealingto the complementary strand. The full-length product was excisedand isolated from an agarose gel, digested with NotI plus SacII,and after heat inactivation of both enzymes ligated into pBluescriptII KS(+). After transformation into E. coli DH5 $alpha$ , clones withthe expected 309-bp insert were checked by sequencing. One ofthree sequenced clones contained the mutation of interest. Themutated NotI-SacII-digested catB fragment was then cloned backinto the 6.48-kb NotI-SacII fragment of pCATB1. The resultingconstruct, designated pCATB8, was checked by complete sequencingof its mutated catBinsert.

An analogous substitution was introduced into the chloromuconate cycloisomerase gene tfdD from R. eutropha JMP134(pJP4). Thesite-directed TfdD-K165A variant was constructed by PCR usingthe same protocol as described above. The PCR template was pTFDD2,which carries the 568-bp EagI-AccI fragment of tfdD in pBluescriptII SK(+). A mutant oligonucleotide was derived from nucleotidepositions 480 to 505 of tfdD (EMBL/GenBank accession number M35097;28) and designed to create the same substitution on DNA and proteinsequence level as described above: 5'-TCGCTTCAAAGTCGCGCTTGGCTTCC-3'(M_K165A). As expected, a full-length product of about 680 bpand a smaller product of about 190 bp were observed as PCR products.The full-length product was excised and eluted from an agarosegel, digested with EagI plus AccI, and purified again, since heatinactivation was not possible in this case. Ligation of the 568-bpfragment into pBluescript II SK(+) and subsequent transformationof E. coli DH5 $alpha$ yielded at least four clones with correctly sizedinserts. One of these was checked by sequencing and confirmedto carry the correct mutation. The mutated EagI-AccI fragmentwas then cloned back into pTFDD1 which had been partially digestedwith EagI (27) and then further digested with AccI to yieldthe desired 3.29-kb pTFDD1 fragment. The complete, mutated tfdDinsert of the resulting plasmid pTFDD15 was checked bysequencing.

Sequencing was performed on an automated ABI sequencer model 373 (Applied Biosystems) using an Applied Biosystems Prizm kitand the dye terminator cycle-sequencing protocol (AmpliTaq DNApolymerase; 25 cycles of 1 s at 98°C, 15 s at 60°C, and a finalextension at 60°C for 4min).

Enzyme assays. Enzyme assays with chlorocatechol dioxygenase from R. eutropha JMP134 were performed as described by Schlömann et al. (33).Activities of cycloisomerases were assayed spectrophotometricallyat 260 nm and 25°C by a modification of published procedures (26,34), using 30 mM Tris-HCl (pH 7.5), 1 mM MnSO₄, and 0.1 mM cis,cis-muconateor substituted cis,cis-muconates. If chloro-substituted substrateswere used, dienelactone hydrolase of pJP4, partially purifiedby Q-Sepharose high-performance chromatography from an extractof E. coli DH5 $alpha$ (pDCA11), was provided in excess. The enzyme activitymeasurements were performed at least in duplicate. In general,extinction coefficients of substrates (9) were used for thecalculation of activities. Coefficients for the conversion of2,4-dichloro-cis,cis-muconate were chosen with respect to theproducts detected, using a coefficient of 5,800 M¹ cm¹, if the reaction proceeded via 2-chloro-cis-dienelactone to 2-chloromaleylacetate(23), or 4,300 M¹ cm¹, if the conversion proceeded to 2-chloroprotoanemonin (see Results).Correspondingly, a value of 12,400 M¹ cm¹ (9) was used when 3-chloro-cis,cis-muconate was convertedvia cis-dienelactone to maleylacetate, and a value of 4,000 M¹ cm¹ (43) was used when protoanemonin was formed. Protein concentrationswere calculated by the Bradford method (4), with bovine serumalbumin as thestandard.

Enzyme expression and purification. E. coli BL21(DE3,pLysS) was used as the host strain to express wild-type CatB from pCATB1 (43), CatB-K169A from pCATB8,and TfdD-K165A from pTFDD15. Growth and induction conditions wereas described for overexpression of wild-type CatB (43) and wild-typeTfdD (44), respectively. Cell harvesting, the preparation ofextracts, and the enzyme purifications, in general, were performedas described by Vollmer et al. (43). The purification comprisedan initial anion-exchange chromatography (Q Sepharose high-performanceHR16/10) which was followed by hydrophobic interaction chromatography(Phenyl-Superose HR10/10). In the case of wild-type CatB, fractionswith the highest specific activity with cis,cis-muconate elutedfrom the first column at ca. 0.16 M NaCl and from the second columnat ca. 0.07 M (NH₄)₂SO₄. In the case of CatB-K169A, activitieswith cis,cis-muconate, due to the mutation, were so low that assayswould have required too much enzyme. Thus, those fractions which,as judged by reference to wild-type CatB, were expected to containthe variant CatB were checked for the presence of a 40-kDa bandby sodium dodecyl sulfate (SDS)-gel electrophoresis (42) withsubsequent Coomassie brilliant blue R-250 staining. Fractionswith strongest 40-kDa bands eluted from the first column at ca.0.18 M NaCl and from the second column at ca. 0.11 M (NH₄)₂SO₄.

TfdD-K165A was purified from a 2-liter culture because expression of an R. eutropha gene from the pRSET6a vector proved tobe not as effective as expression of a P. putida gene from pET11a*(43, 44). As with the CatB-K169A purification, the presenceof overexpressed protein was checked only by SDS-gel electrophoresissince activities were very low. Fractions with the strongest 40-kDabands eluted from the first column at ca. 0.37 M NaCl and fromthe second column at ca. 0.20 M (NH₄)₂SO₄, similar to the wild-typeenzyme (45).

The purity of the (chloro)muconate cycloisomerase preparations was analyzed by SDS-polyacrylamide gel electrophoresis andstaining with Coomassie brilliant blue (see above). In the caseof CatB, 21 mg of pure enzyme was obtained. The resulting preparationsof CatB-K169A and TfdD-K165A contained 12 and 8.2 mg, respectively,of pureenzyme.

HPLC. Substrates and products were quantified by reversed-phase high-pressure liquid chromatography (HPLC) with a SIL 100 C8 reversed-phasecolumn (length, 250 mm; internal diameter, 4.6 mm; Grom, Herrenberg,Germany) protected by a LiChrospher RP8 precolumn (20 by 4.6 mm;Grom). Usually, samples of 10 µl were analyzed. The column effluentwas monitored simultaneously at 210 and 260 nm by use of a variable-wavelengthdetector (Waters 490 programmable wavelength detector; Waters,Milford, Mass.). For analysis of products from cis,cis-muconateand 2,4-dichloro-cis,cis-muconate, 40% (wt/vol) methanol containing0.1% (wt/vol) H₃PO₄ was used as the solvent at a flow rate of0.7 ml min¹. Typical retention volumes were as follows: compound X (presumedreaction product of 2-chloro-cis-dienelactone and Tris), 3.0 ml;muconolactone, 3.2 ml; 2-chloromaleylacetic acid, 3.3 ml; 2-chloro-cis-acetylacrylicacid acylale, 3.8 ml; cis,cis-muconic acid and 2-chloro-trans-dienelactone,4.4 ml; 2,4-dichloro-cis,cis-muconic acid, 4.6 ml; 3-chloro-cis,cis-muconicacid and protoanemonin, 4.8 ml; 2-chloro-cis-dienelactone, 5.9ml; and 2-chloroprotoanemonin, 6.3 ml. Since protoanemonin couldnot be separated well from 3-chloro-cis,cis-muconic acid underthese conditions, 25% (wt/vol) methanol containing 0.1% (wt/vol)H₃PO₄ was used as the solvent for analysis of products from 3-chloro-cis,cis-muconateturnover (flow rate, 0.9 ml min¹). Typical retention volumes were as follows: maleylacetic acid,3.3 ml; cis-acetylacrylic acid acylale, 3.8 ml; trans-dienelactone,4.4 ml; cis-dienelactone, 5.9 ml; protoanemonin, 6.4 ml; and 3-chloro-cis,cis-muconicacid, 7.4ml.

For the preparation of 2-chloroprotoanemonin after conversion of 3,5-dichlorocatechol, a Grom SIL 100 C8 reversed-phase columnof 125-mm length and 4.6-mm internal diameter was used with 40%(wt/vol) methanol without H₃PO₄ as the solvent and a flow rateof 1 ml min¹. Retention volumes were as follows: 2,4-dichloro-cis,cis-muconate,1.2 ml; 2-chloro-cis-dienelactone, 1.6 ml; 2-chloroprotoanemonin,3.2 ml; and 3,5-dichlorocatechol, 7.9ml.

Preparation and identification of 2-chloroprotoanemonin. The reaction mixture contained, in a final volume of 100 ml, 5 mmol of BisTris-HCl [bis-(2-hydroxyethyl)imino-tris(hydroxymethyl)methane-HCl)(pH 6.5), 0.2 mmol of MnSO₄, 300 µmol of 3,5-dichlorocatechol,24 U (measured with 3,5-dichlorocatechol) of chlorocatechol 1,2-dioxygenase,provided as a cell extract of E. coli BL21(DE3,pLysS)(pTFDC1)(44), and 4,100 U (measured with cis,cis-muconate) of partiallypurified P. putida muconate cycloisomerase. 3,5-Dichlorocatechol(used as 20 mM stock solution) as well as muconate cycloisomerasewere added stepwise during the conversion. The mixture was incubatedat 25°C for 6 h and stirred slightly. The progress of the reactionwas followed by HPLC analyses (for conditions, see above). After6 h, a compound later identified as 2-chloroprotoanemonin wasthe major metabolite detected. Protein was removed at 4°C by ultrafiltrationwith an Amicon 8050 cell using a Diaflo ultrafiltration membrane(type PM10; Amicon). The preparation was extracted twice with25 and 10 ml of diethyl ether. The combined organic phases weredried over Na₂SO₄, vaporized using a rotation evaporator (VV2000;Heidolph, Kelheim, Germany), and finally completely dried withan Alpha I-5 freeze-dryer (Christ, Osterode, Germany). Small amounts(5 to 10 mg) of a white substance which appeared to have a meltingtemperature between 0 and 10°C were obtained. High-resolutionnuclear magnetic resonance (NMR) spectra were obtained on a BrukerAC 250 spectrometer with the Pulse-Fourier transform techniqueand with nominal frequencies of 500.133 MHz for ¹H NMR and 125.774 MHz for ¹³C NMR. The samples were dissolved in deuterated methanol, andtetramethylsilane was used as the internal standard. To estimatethe extinction coefficient of 2-chloroprotoanemonin, the spectrumof a 0.1 mM solution was recorded between 200 and 400 nm on adouble-beam spectrophotometer (Kontron Uvikon 941 Plus) againstwater as thebackground.

Preparation of a solution containing a 2-chloro-cis-dienelactone-Tris reaction product (compound X). To check the absorption spectra of compound X under acidic and neutral conditions, the compound was prepared in a small scaleby incubating a 0.5 mM 2-chloro-cis-dienelactone solution in 50mM Tris-HCl (pH 7.5) at room temperature for 12 h, yielding Xas the main product (at maximum, 82%). Upon acidification of 1ml of this solution to pH 3.0, most of the by-product 2-chloromaleylacetate(16%), but not compound X, could be removed by extraction withthe same volume of ethylacetate from the water phase. CompoundX was therefore isolated from the latter by evaporation of thewater under reduced pressure. Of the remaining pellet, 0.5 mgwas dissolved in 2 ml of water, and the spectrum was recordedbetween 200 and 400 nm (see above). After acidification to pH2.0 by addition of 1 µl of 85% H₃PO₄, a second spectrum wasrecorded.

Preparation of a solution containing the presumed 2-chloro-trans-dienelactone. To provide an HPLC standard for experiments on 2,4-dichloro-cis,cis-muconate conversion, preparation of the presumed 2-chloro-trans-dienelactonefrom 2-chloro-cis-dienelactone (20) was attempted by UV irradiationat 254 nm in an analogous manner to the preparation of trans-dienelactonefrom cis-dienelactone (33) (Fig. 2). Irradiation was carriedout at 4°C. A clear identification of 2-chloro-trans-dienelactoneby NMR spectroscopy was not performed, because the final preparationcontained large amounts of the cis isomer and further decay products(2-chloromaleylacetate and 2-chloro-cis-acetylacrylate). However,the correct assignment of this compound was supported by an E₂₁₀/E₂₆₀nm ratio identical to that of 2-chloro-cis-dienelactone. Furthermore,the spectrum of the putative 2-chloro-trans-dienelactone, performedunder stopped-flow conditions by HPLC, showed an absorption maximumat 282 nm similar to that of 2-chloro-cis-dienelactone ( $lambda$ _max =283 nm [20]).

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FIG. 2. Preparation of 2-chloro-trans-dienelactone ( $black-lozenge$ ) under UV irradiation. An aqueous solution (1 ml) of 0.5 mM 2-chloro-cis-dienelactone (pH 5.0) ( $black-down-triangle$ ) was incubated at 4°C under a UV lamp as described by Schlömann et al. (33) (A). A control solution (1 ml) was incubated in the dark (B). 2-Chloromaleylacetic acid (

) and 2-chloro-cis-acetylacrylic acid ( $black-triangle$ ) were detected as minor by-products. For the presumed 2-chloro-trans-dienelactone, peak areas in relative units are given. A peak area of 910 relative units was assumed to be equivalent to 0.1 mM, since for each time point this would result in an overall concentration of all compounds detected of approximately 0.5 mM.

Chemicals. Catechols and cis,cis-muconates, in general, were available from the same sources as described before (43). All other substitutedcis,cis-muconic acids were synthesized enzymatically from thecorresponding catechols, using cell extract from E. coli BL21(DE3,pLysS)(pTFDC1)(44). Protoanemonin was freshly prepared by converting 3-chloro-cis,cis-muconateby large amounts of purified P. putida muconate cycloisomerase(3). trans-Dienelactone as well as cis-dienelactone and 2-chloro-cis-dienelactonewere available from previous syntheses (17, 20, 30). Maleylacetateand 2-chloromaleylacetate were prepared from cis-dienelactoneand 2-chloro-cis-dienelactone, respectively, by alkaline hydrolysis(11). trans-Acetylacrylic acid was purchased from Lancaster.cis-Acetylacrylic acid acylale was synthesized from maleylaceticacid under acidic conditions (33). In an analogous manner, 2-chloro-cis-acetylacrylicacid acylale was prepared from 0.25 mM 2-chloromaleylacetic acidby incubation for 120 min in 10 mM citrate buffer (pH 3.0) (25°C).A product with the same retention volume was detected by heatingan acidified solution of 2-chloromaleylacetic acid (ca. pH 4)at 95°C for 2.5 h. A product suggested to have been formed from2-chloromaleylacetic acid by thermal decarboxylation and acidificationwas identified by Tiedje et al. (38) as 2-chloro-cis-acetylacrylicacidacylale.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Drastically reduced catalytic efficiency of muconate cycloisomerase variant K169A with most cis,cis-muconates. Wild-type muconate cycloisomerase and the CatB-K169A variant were both purified to homogeneity as judged by SDS-polyacrylamidegel electrophoresis (single bands at ca. 40 kDa). CatB, purified6.6-fold, gave a preparation with a specific activity of 224 Umg¹ measured with 0.1 mM cis,cis-muconate (Table 2). The purificationof CatB-K169A was performed twice and yielded preparations witha specific activity of 0.003 U mg¹ or less (Table 2). The specific activity could be measured onlyby using 400 to 500 µg of enzyme in the assay and representedonly 0.0015% or less of that of CatB, in accord with Lys169 beingessential for the enzyme mechanism. By HPLC, muconolactone wasshown to be formed by both CatB and CatB-K169A. CatB-K169A showeda residual activity with 0.1 mM 3-fluoro-cis,cis-muconate in thesame order of magnitude as with cis,cis-muconate (0.001 U mg¹). When CatB-K169A was tested for conversion of 2-chloro-, 2-methyl-,and 3-methyl-cis,cis-muconate, specific activities were belowthe detection limit of 0.0005 U mg¹.

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TABLE 2. Activity of muconate cycloisomerase variant CatB-K169A with various substrates

Conversion of 3-chloromuconate by P. putida muconate cycloisomerase and CatB-K169A. When 3-chloro-cis,cis-muconate conversion was followed by monitoring the extinction at 260 nm over at least 2 min in assayswithout auxiliary dienelactone hydrolase, a difference in productformation by CatB and CatB-K169A became obvious. An enzyme assaywith CatB (0.6 U ml¹, measured with cis,cis-muconate) showed a decrease of E₂₆₀ withinthe first ca. 20 s of measurement and then again an increase,indicating the formation of an intermediate with low absorptionat 260 nm, presumably 4-chloromuconolactone, and a subsequentspontaneous or enzyme-catalyzed conversion of the latter to protoanemonin( $lambda$ _max = 260 nm) (3). In contrast, an amount of CatB-K169A whichcorresponded to this experiment with respect to 3-chloro-cis,cis-muconateconversion (only 0.002 U ml¹, measured with cis,cis-muconate) showed a continuous slight decreasebut no increase of E₂₆₀.

Conversion of 3-chloro-cis,cis-muconate by CatB-K169A and CatB was subsequently investigated by running overlay UV spectraof enzyme assays and by analyses of products by HPLC (Fig. 3).When a 3-chloro-cis,cis-muconate-containing reaction mixture wasincubated with CatB, due to the relatively long cycle times betweenthe spectra and because of similar absorbances of the substrateand the product protoanemonin, practically no absorbance changesoccurred. With CatB-K169A, however, a strong shift toward 280nm was observed. Monitoring of the CatB-K169A-catalyzed turnoverby HPLC clearly showed the formation of a compound which cochromatographedwith authentic cis-dienelactone.

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FIG. 3. Conversion of 3-chloro-cis,cis-muconate by wild-type CatB and CatB-K169A at pH 7.5. For overlay spectra, reaction mixtures (1 ml) contained 30 mM Tris-HCl (pH 7.5), 1 mM MnSO₄, 0.1 mM 3-chloro-cis,cis-muconate, and 0.001 to 0.002 U enzyme (measured with 3-chloro-cis,cis-muconate). Reference cuvettes contained the same mixtures without substrate. Ten spectra were recorded at 25°C between 200 and 400 nm every 10 min, and at least 90% of the substrate was converted after the last cycle. Arrows indicate the shift of the absorption maximum. Product formation from 3-chloro-cis,cis-muconate was additionally examined by HPLC analyses. Reaction conditions were the same as described above, except that 0.5 mM substrate was supplied and more enzyme was added (0.002 U of CatB and 0.007 U of CatB-K169A). 3-Chloro-cis,cis-muconate (

) was converted to cis-dienelactone ( $black-down-triangle$ ), maleylacetate ( $open circle$ ), cis-acetylacrylate ( $black-lozenge$ ), and protoanemonin ( $diamond$ ). trans-Dienelactone was formed by CatB-K169A in concentrations no more than 0.014 mM (not shown).

Based on this knowledge, the specific activity of CatB with 3-chloro-cis,cis-muconate was determined to be 3.4 U mg¹, using a $Delta$ $varepsilon$ of 4,000 M¹ cm¹ for the reaction in the first 60 s (Table 2). The specific activityof CatB-K169A with 3-chloro-cis,cis-muconate was estimated tobe ca. 0.011 U mg¹, using an extinction coefficient of 12,400 M¹ cm¹ (Table 2). Thus, while the K169A mutation resulted in at leasta 7 × 10⁴-fold reduction of the reaction rate with cis,cis-muconate andin a ca. 11 × 10⁴-fold reduction of the reaction rate with 3-fluoro-cis,cis-muconate,turnover of 3-chloro-cis,cis-muconate was reduced only by a factorof 310 (Table 2).

Conversion of 2,4-dichloromuconate by CatB-K169A. The conversion of 2,4-dichloro-cis,cis-muconate by CatB-K169A was likewise investigated by overlay UV spectra and HPLC measurements(Fig. 4, right). The peak maximum at 267 nm initially shiftedtoward 280 nm, and a new maximum subsequently appeared at about254 nm. Monitoring of the CatB-K169A-catalyzed turnover by HPLCclearly showed the immediate formation of a compound which cochromatographedwith authentic, i.e., chemically synthesized, 2-chloro-cis-dienelactone( $lambda$ _max = 283 nm [20]). 2-Chloro-cis-dienelactone, however, provedto be relatively unstable at pH 7.5. Its concentrations neverexceeded 30% of provided substrate.

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FIG. 4. Conversion of 2,4-dichloro-cis,cis-muconate by wild-type CatB and CatB-K169A at pH 7.5. For overlay spectra, reaction mixtures (1 ml) contained 30 mM Tris-HCl (pH 7.5), 1 mM MnSO₄, 0.1 mM 2,4-dichloro-cis,cis-muconate, and 0.001-0.002 U enzyme (measured with 3-chloro-cis,cis-muconate). Reference cuvettes contained the same mixtures without substrate. Ten spectra were recorded as described in the legend to Fig. 3, and with both enzymes the substrate was completely converted after the last cycle. Arrows indicate the shift of the absorption maximum. For analysis of 2,4-dichloro-cis,cis-muconate turnover by HPLC, reaction conditions were the same as described above, except that 0.5 mM substrate was supplied and more enzyme was added (approximately 0.003 U). 2,4-Dichloro-cis,cis-muconate (

) was converted to 2-chloro-cis-dienelactone (

), 2-chloromaleylacetate ( $black-triangle$ ), 2-chloro-cis-acetylacrylate (

), 2-chloroprotoanemonin ( $open circle$ ), 2-chloro-trans-dienelactone ( $black-lozenge$ ), a reaction product of 2-chloro-cis-dienelactone and Tris, i.e., compound X ( $down-triangle$ ), and the unknown compound Y ( $diamond$ ). For compounds X and Y, peak areas at 210 nm are given in relative units. From a preparation of compound X as described in Material and Methods, a peak area of 660 relative units was assumed to be equivalent to 0.1 mM.

The accumulation of a new compound X as the main product of 2,4-dichloro-cis,cis-muconate conversion could be shown to resultfrom a nonenzymatic reaction of 2-chloro-cis-dienelactone. Stabilityexperiments with 0.5 mM 2-chloro-cis-dienelactone in Tris-HCl(pH 7.5) (in the absence of enzyme) gave a product with the sameUV spectrum and chromatographic behavior. Thus, a solution ofX prepared from chemically synthesized 2-chloro-cis-dienelactonerevealed different absorption spectra of X at neutral ( $lambda$ _max =252 nm) and acidic ( $lambda$ _max = 229 nm) conditions. This correspondswell to the different absorption maxima of X from enzymatic 2,4-dichloro-cis,cis-muconateconversion as determined by HPLC under acidic, stopped-flow conditions(230 nm) or by overlay UV spectra at pH 7.5 (shift toward 254nm [Fig. 4, right]). 2-Chloromaleylacetate and the presumed 2-chloro-trans-dienelactoneappeared as minor by-products from nonenzymatic 2-chloro-cis-dienelactoneconversion at pH 7.5.

Compound X is most probably a reaction product of 2-chloro-cis-dienelactone with Tris buffer. As illustrated by the UV spectra(Fig. 5), alkaline hydrolysis as well as hydrolysis of 2-chloro-cis-dienelactonein the presence of imidazole-HCl yielded 2-chloromaleylacetate( $lambda$ _max = 250 nm, $varepsilon$ = 8,400 M¹ cm¹) as the product. In contrast, the reaction of 2-chloro-cis-dienelactonein the presence of Tris-HCl gave a product with a similar $lambda$ _maxbut with a significantly higher molecular absorption coefficient( $varepsilon$ = 15,000 M¹ cm¹). In contrast to the products of alkaline- as well as imidazole-HCl-catalyzedhydrolysis, the product obtained with Tris showed no biologicalactivity with maleylacetate reductase (data not shown). The factthat compound X occurred with Tris-HCl (pH 7.5) but not with imidazole-HCl(pH 7.5) as the buffer suggests that hydroxyl groups of the Trisbuffer might be the reactive groups.

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FIG. 5. Formation of 2-chloromaleylacetate and compound X (a reaction product with Tris) during nonenzymatic turnover of 2-chloro-cis-dienelactone in aqueous NaOH and in the presence of different buffers, respectively. For alkaline hydrolysis, the reaction mixture (1 ml) contained 0.05 mM 2-chloro-cis-dienelactone in water. After recording the spectra using water as the reference, we added 2 µl of 2 M NaOH (4 µmol) to both cuvettes and recorded an overlay spectrum after 0.5 min. For the turnover in buffer, reaction mixtures (1 ml) contained 100 mM buffer and 0.05 mM 2-chloro-cis-dienelactone. Reference cuvettes contained the same buffer. Five spectra were recorded after 0.5, 8, 17, 30, and 60 min (Tris-HCl, pH 7.5) and after 0.5, 60, 120, 180, 240, and 270 min (imidazole-HCl, pH 7.5).

Since with respect to product formation from 2,4-dichloro-cis,cis-muconate, CatB-K169A resembled the chloromuconate cycloisomerases,the difference of extinction coefficients of substrate and productwas assumed to be 5,800 M¹ cm¹ (23). With this $Delta$ $varepsilon$ , values of up to 0.020 U mg¹ were determined for the specific activity of CatB-K169A with2,4-dichloro-cis,cis-muconate (Table 2).

Conversion of 2,4-dichloromuconate by wild-type muconate cycloisomerase to 2-chloroprotoanemonin. When a 2,4-dichloro-cis,cis-muconate-containing reaction mixture with CatB was followed by overlay UV spectra, the peak maximumfirst mainly decreased and then showed a gradual shift from 267nm toward 250 nm (Fig. 4). This shift even continued for sometime after the original substrate was completely converted. Whenfollowing the CatB-catalyzed turnover of 2,4-dichloro-cis,cis-muconateby HPLC, we observed a product which had a retention volume onlyslightly different from that of 2-chloro-cis-dienelactone butdiffered significantly from the latter in having a higher relativeabsorption at 260 nm, compared to 210 nm. This compound couldbe easily extracted with diethyl ether under approximately neutralconditions and was identified as 2-chloroprotoanemonin (4-methylene-2-chlorobut-2-en-4-olide)(seebelow).

2-Chloroprotoanemonin proved to be considerably more stable at pH 6.5 (half-life of 11 h) than at pH 7.5 (half-life of <2h). The by-products observed during 2,4-dichloro-cis,cis-muconateconversion at pH 7.5 (Fig. 4, left) included (i) the presumed2-chloro-cis-acetylacrylate, (ii) a compound with the same retentionvolume and the same relative absorption at 210 and 260 nm as thepresumed reaction product of 2-chloro-cis-dienelactone and Tris(compound X; see above), and (iii) a third, as yet unidentifiedcompound Y eluting from the reversed-phase column between thelatter two compounds. It thus had a retention volume similar tothat of 2-chloromaleylacetic acid but differed from the latterin having a higher relative absorption at 260 nm, compared to210nm.

The $Delta$ $varepsilon$ at 260 nm for formation of 2-chloroprotoanemonin from 2,4-dichloro-cis,cis-muconate was determined to be 4,300 M¹ cm¹. This value was determined by monitoring E₂₆₀ during 2,4-dichloro-cis,cis-muconateconversion by 18 U of CatB (measured with cis,cis-muconate) ina 1-ml reaction mixture with dienelactone hydrolase and by correlatingthe $Delta$ E₂₆₀ to the difference in substrate concentrations as analyzedby HPLC prior to CatB addition and after 1.5 min. A specific activityof 0.052 U mg¹ was calculated for CatB with 2,4-dichloro-cis,cis-muconate (Table2). Thus, the K169A mutation decreased the turnover rate of 2,4-dichloro-cis,cis-muconateby a factor of only 2.6, i.e., less than that of 3-chloro-cis,cis-muconateand much less than that of cis,cis-muconate and other substitutedmuconates (Table 2).

The product formed from 2,4-dichloro-cis,cis-muconate by muconate cycloisomerase was isolated as described in Materials andMethods. The ¹H NMR spectrum (Fig. 6) showed three olefinic protons, centeredat two different carbon atoms. One of the protons had a chemicalshift value of 7.75 ppm, which is typical for the $beta$ proton inan $alpha$ , $beta$ -unsaturated carbonyl system. This proton did not show anylong-range coupling to 5-H_A or 5-H_B and was identified as 3-H.A geminal coupling of 2.9 Hz was observed between 5-H_A and 5-H_B.For the interpretation of ¹³C NMR spectra, it was useful to compare data with recently publisheddata for 3-bromoprotoanemonin and protoanemonin (8). The mostsignificant difference in chemical shifts of the carbon atomsis observed for C-2. The chlorine of 2-chloroprotoanemonin shiftsthe signal of C-2 around 5.5 ppm downfield compared to the C-2signals of protoanemonin and 3-bromoprotoanemonin. The signalsof C-3 of both 2-chloro- and 3-bromoprotoanemonin were shiftedupfield in comparison to protoanemonin by 5 and 6.7 ppm, respectively.The $lambda$ _max of an aqueous solution of 2-chloroprotoanemonin was determinedto be 268 nm, and $varepsilon$ was 15,780 M¹ cm¹. These values were quite similar to those reported for protoanemonin( $lambda$ _max = 260 nm; $varepsilon$ = 15,100 M¹ cm¹) (3).

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FIG. 6. ¹H NMR and ¹³C NMR data for different protoanemonins. The chemical shifts $delta$ and the coupling constants J of 2-chloroprotoanemonin were determined with CD₃OD as the solvent. ¹H and ¹³C NMR data for 3-bromoprotoanemonin with CDCl₃ as the solvent were taken from de March et al. (8). ¹H NMR data for protoanemonin with CD₃OD as the solvent were taken from Blasco et al. (3); ¹³C-NMR data with CDCl₃ as the solvent were taken from de March et al. (8).

When 0.1 mM 2-chloroprotoanemonin dissolved in water was dropped on an LB plate which had been streaked with E. coli BL21(DE3,pLysS),overnight cell growth did not occur at the site of application.This preliminary experiment indicates that 2-chloroprotoanemonin,like protoanemonin, might be toxic for bacteria (3, 5, 35).

Inefficiency of TfdD-K165A with all tested cis,cis-muconates. TfdD-K165A which was also purified to homogeneity gave specific activities below 0.001 U mg¹ with most cis,cis-muconates tested. 2,4-Dichloro-cis,cis-muconatewas the only substrate still converted. A specific activity of0.005 U mg¹ was measured with 0.1 mM substrate. From 2,4-dichloro-cis,cis-muconate,TfdD-K165A formed the same product as CatB-K169A, i.e., 2-chloro-cis-dienelactone.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

As outlined in the introduction, we wanted to test the hypothesis that the formation of protoanemonin from 3-chloro-cis,cis-muconateby muconate cycloisomerases requires enzymatic protonation ofthe respective enol/enolate intermediate, while the formationof cis-dienelactone from 3-chloro-cis,cis-muconate by chloromuconatecycloisomerases should not necessitate a protonation, but insteadchloride abstraction could take place. We thus changed the lysinethat has been suggested to be responsible for protonation (15)to an alanine in both P. putida muconate cycloisomerase CatB andin the pJP4-encoded chloromuconate cycloisomeraseTfdD.

We expected to find activity of the TfdD variant with those substrates which should not require protonation, i.e., 3-chloro-and 2,4-dichloro-cis,cis-muconate (29, 34). We also expectedthe CatB and the TfdD variants to be inactive toward substratesnecessarily requiring protonation, like cis,cis-muconate (36),2-chloro-cis,cis-muconate (42), 3-fluoro-cis,cis-muconate (33),and 2-methyl- and 3-methyl-cis,cis-muconate (6, 22). We werecurious to see what the CatB variant would do with substrateswhich are obviously protonated by the wild-type enzyme, specifically3-chloro-cis,cis-muconate, and finally we wanted to investigatethe product formation from 2,4-dichloro-cis,cis-muconate.

In contrast to our expectations, TfdD-K165A was completely inactive with 3-chloro-cis,cis-muconate, and 2,4-dichloro-cis,cis-muconate conversion was also severely affected. The lack ofany activity of TfdD-K165A with cis,cis-muconate or methylmuconates,on the other hand, was in accord with our expectations, as wasthe fact that the product formed from 2,4-dichloro-cis,cis-muconatewas 2-chloro-cis-dienelactone. One might explain the inefficiencyof this enzyme variant by the charge change of the active site.In analogy to CatB (16), the binding pocket of TfdD is probablypositively charged and should be created by Mn²⁺ and the amino groups of Lys163 and Lys165. Upon replacement ofLys165 by a nonpolar alanine, the substrate which is negativelycharged at pH 7 might bind less effectively. The K165A replacementcould also have resulted in other unintended, structural changeswhich might negatively affect not only the protonation of theenol/enolate intermediate but also other steps of the cycloisomerizationreaction.

In concordance with our expectations, CatB-K169A converted cis,cis-muconate and 3-fluoro-cis,cis-muconate about 10⁵-fold slower than the wild-type enzyme (Table 2), while the activitieswith other substrates requiring protonation (methylmuconates and2-chloro-cis,cis-muconate) were below the detection limit. Atthe same time, 3-chloro- and 2,4-dichloro-cis,cis-muconate werestill converted at a considerable rate, thus proving that thealmost complete inactivation of CatB observed with the other substrateswas not due to some nonspecific effect as discussed above forTfdD-K165A. In fact, these observations provide experimental evidencefor the inference from comparisons with mandelate racemase (15)and modeling studies on CatB (32) that Lys169 should be theprotonating aminoacid.

The most direct evidence for the validity of our basic hypothesis that protoanemonin formation from 3-chloro-cis,cis-muconateshould require a protonation step, whereas cis-dienelactone formationshould not, came from the observed shifts of product formation:while wild-type CatB formed protoanemonin from 3-chloro-cis,cis-muconateand 2-chloroprotoanemonin from 2,4-dichloro-cis,cis-muconate,the K169A variant formed cis-dienelactone and 2-chloro-cis-dienelactone,respectively (Fig. 7). Thus, a protonation reaction is definitelynecessary for (chloro-)protoanemonin formation but not for (chloro-)cis-dienelactoneformation.

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FIG. 7. Model for the mechanism of cycloisomerization and dehalogenation of 3-chloro-cis,cis-muconate and 2,4-dichloro-cis,cis-muconate by proteobacterial muconate cycloisomerases (MCI), by chloromuconate cycloisomerases (CMCI), and by CatB-K169A. The proton provided by the active-site lysine is marked in bold italics. X indicates an active-site residue which might facilitate dehalogenation of the enol/enolate intermediate. Hypothetical intermediates are shown in brackets, with important active-site residues and Mn²⁺ included for the enzyme bound enol/enolate intermediate.

The findings just discussed cast a new light on the catalytic differences between muconate and chloromuconate cycloisomerases(Fig. 7). One might speculate that after the protonation of the(di-)chlorinated enol/enolate intermediate to 4-chloromuconolactoneor 2,4-dichloromuconolactone, as catalyzed by muconate cycloisomerases,the decarboxylation and chloride elimination to (chloro-)protoanemoninoccur as spontaneous, nonenzymatic reactions. Then the differencebetween muconate and chloromuconate cycloisomerases, with respectto product formation from 3-chloro- and 2,4-dichloro-cis,cis-muconate,would be due to the fact that of the competing possible reactionsof the (di-)chlorinated enol/enolate, different ones are favored:protonation by Lys169 in case of the muconate cycloisomerases,and chloride elimination in case of the chloromuconatecycloisomerases.

It is not clear how this shift in favored reactions was accomplished during the divergence of the chloromuconate cycloisomerasesfrom the muconate cycloisomerases. Obviously the evolutionarysolution was different from our experimental one: the Lys169 ofP. putida muconate cycloisomerase is conserved as Lys165 in thechloromuconate cycloisomerases of pJP4, pAC27, and pP51 (14,28, 39) and as Lys168 in the chloromuconate cycloisomeraseof Rhodococcus opacus 1CP (10). In principle, two possibilitiesexist: in chloromuconate cycloisomerases, (i) protonation of the(di-)chlorinated enol/enolate intermediate could be slowed downor (ii) chloride elimination could be accelerated. The formerpossibility appears to be less likely because the chloromuconatecycloisomerase TfdD converts 2- and 3-methyl-cis,cis-muconateto 3- and 4-methylmuconolactone almost as fast as the muconatecycloisomerase of P. putida converts cis,cis-muconate to muconolactone(43, 44). Thus, TfdD is fully capable of catalyzing a fastprotonation. An enhanced rate of chloride elimination from theenol/enolate intermediate is therefore moreprobable.

In recent modeling studies with TfdD, a residue which could accelerate chloride elimination and which is in the correct positionand geometry to the chlorine substituent has not yet been identified.At first sight, an active-site tryptophan appears to be a likelycandidate (U. Schell, H.-J. Hecht, and M. Schlömann, unpublisheddata), because a chloride binding site comprising two tryptophanresidues has also been found in haloalkane dehalogenase of Xanthobacterautotrophicus GJ10 (40). However, a replacement of Tyr59 inP. putida muconate cycloisomerase by tryptophan, the correspondingamino acid of chloromuconate cycloisomerase, did not avoid protoanemoninformation (43), nor did a reciprocal replacement of Trp55 inpJP4-encoded chloromuconate cycloisomerase by tyrosine abolishproductive dehalogenation to dienelactones (Schell et al., unpublished).Thus, it remains to be elucidated which other amino acid residuesare, in fact, responsible for (chloro-)cis-dienelactoneformation.

	ACKNOWLEDGMENTS

We are indebted to H.-J. Knackmuss and to W. Reineke for providing excellent facilities and for stimulating discussions. Weare also indebted to A. Goldman (Centre for Biotechnology, Turku,Finland) for advice on the mutation. For measuring the NMR spectra,we thank J. Rebell, Institute for Organic Chemistry and IsotopeResearch, University of Stuttgart. We also thank U. Riegert forsupport on the interpretation of NMR spectra. Thanks are due toR. Schmid (Institute for Technical Biochemistry, University ofStuttgart) for providing the facility for automated sequencingand to S. Lakner and S. Bürger for performing thesequencing.

This work was supported by a grant from the Federal Ministry of Research (project A10U; Zentrales Schwerpunktprojekt Bioverfahrenstechnik,Stuttgart,Germany).

	FOOTNOTES

^* Corresponding author. Present address: TU Bergakademie Freiberg, Interdisziplinäres Ökologisches Zentrum, Leipziger Str.29, D-09599 Freiberg, Germany. Phone: 49 3731 39 3739. Fax: 493731 39 3012. E-mail: michael.schloemann{at}ioez.tu-freiberg.de.

Dedicated to Hans-Joachim Knackmuss on the occasion of his 65thbirthday.

Present address: Hans-Knöll-Institut für Naturstoff-Forschung, D-07745 Jena,Germany.

^§ Present address: TU Bergakademie Freiberg, Interdisziplinäres Ökologisches Zentrum, D-09599 Freiberg,Germany.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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29. Pieper, D. H., A. E. Kuhm, K. Stadler-Fritzsche, P. Fischer, and H.-J. Knackmuss. 1991. Metabolism of 3,5-dichlorocatechol by Alcaligenes eutrophus JMP134. Arch. Microbiol. 156:218-222[CrossRef].

30. Reineke, W., and H.-J. Knackmuss. 1984. Microbial metabolism of haloaromatics: isolation and properties of a chlorobenzene-degrading bacterium. Appl. Environ. Microbiol. 47:395-402[Abstract/Free Full Text].

31. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

32. Schell, U., S. Helin, T. Kajander, M. Schlömann, and A. Goldman. 1999. Structural basis for the activity of two muconate cycloisomerase variants towards substituted muconates. Proteins Struct. Funct. Genet. 34:125-136[CrossRef][Medline].

33. Schlömann, M., P. Fischer, E. Schmidt, and H.-J. Knackmuss. 1990. Enzymatic formation, stability, and spontaneous reactions of 4-fluoromuconolactone, a metabolite of the bacterial degradation of 4-fluorobenzoate. J. Bacteriol. 172:5119-5129[Abstract/Free Full Text].

34. Schmidt, E., and H.-J. Knackmuss. 1980. Chemical structure and biodegradability of halogenated aromatic compounds. Conversion of chlorinated muconic acids into maleoylacetic acid. Biochem. J. 192:339-347[Medline].

35. Seegal, B. C., and M. Holden. 1945. The antibiotic activity of extracts of Ranunculaceae. Science 101:413-414[Free Full Text].

36. Sistrom, W. R., and R. Y. Stanier. 1954. The mechanism of formation of $beta$ -ketoadipic acid by bacteria. J. Biol. Chem. 210:821-836[Free Full Text].

37. Studier, F. W., A. H. Rosenberg, J. J. Dunn, and J. W. Dubendorff. 1990. Use of T7 RNA polymerase to direct expression of cloned genes. Methods Enzymol. 185:60-89[Medline].

38. Tiedje, J. M., J. M. Duxbury, M. Alexander, and J. E. Dawson. 1969. 2,4-D metabolism: pathway of degradation of chlorocatechols by Arthrobacter sp. J. Agric. Food Chem. 17:1021-1026[CrossRef].

39. van der Meer, J. R., R. I. L. Eggen, A. J. B. Zehnder, and W. M. de Vos. 1991. Sequence analysis of the Pseudomonas sp. strain P51 tcb gene cluster, which encodes metabolism of chlorinated catechols: evidence for specialization of catechol 1,2-dioxygenases for chlorinated substrates. J. Bacteriol. 173:2425-2434[Abstract/Free Full Text].

40. Verschueren, K. H. G., J. Kingma, H. J. Rozeboom, K. H. Kalk, D. B. Janssen, and B. W. Dijkstra. 1993. Crystallographic studies of the interaction of haloalkane dehalogenase with halide ions. Studies with halide compounds reveal a halide binding site in the active site. Biochemistry 32:9031-9037[CrossRef][Medline].

41. Vollmer, M. D. 1992. Untersuchungen zur Dehalogenierung im Dichloraromatenabbau in In Alcaligenes eutrophus Stamm JMP134. Diplomarbeit. Universität Stuttgart, Stuttgart, Germany.

42. Vollmer, M. D., P. Fischer, H.-J. Knackmuss, and M. Schlömann. 1994. Inability of muconate cycloisomerases to cause dehalogenation during conversion of 2-chloro-cis,cis-muconate. J. Bacteriol. 176:4366-4375[Abstract/Free Full Text].

43. Vollmer, M. D., H. Hoier, H.-J. Hecht, U. Schell, J. Gröning, A. Goldman, and M. Schlömann. 1998. Substrate specificity and product formation by muconate cycloisomerases: an analysis of wild-type enzymes and engineered variants. Appl. Environ. Microbiol. 64:3290-3299[Abstract/Free Full Text].

44. Vollmer, M. D., U. Schell, V. Seibert, and M. Schlömann. 1999. Substrate specificities of the chloromuconate cycloisomerases from Pseudomonas sp. B13, Ralstonia eutropha JMP134 and Pseudomonas sp. P51 and implications for enzyme evolution. Appl. Microbiol. Biotechnol. 51:598-605[CrossRef][Medline].

45. Vollmer, M. D., and M. Schlömann. 1995. Conversion of 2-chloro-cis,cis-muconate and its metabolites 2-chloro- and 5-chloromuconolactone by chloromuconate cycloisomerases of pJP4 and pAC27. J. Bacteriol. 177:2938-2941[Abstract/Free Full Text].

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30.	Reineke, W., and H.-J. Knackmuss. 1984. Microbial metabolism of haloaromatics: isolation and properties of a chlorobenzene-degrading bacterium. Appl. Environ. Microbiol. 47:395-402[Abstract/Free Full Text].
31.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.
32.	Schell, U., S. Helin, T. Kajander, M. Schlömann, and A. Goldman. 1999. Structural basis for the activity of two muconate cycloisomerase variants towards substituted muconates. Proteins Struct. Funct. Genet. 34:125-136[CrossRef][Medline].
33.	Schlömann, M., P. Fischer, E. Schmidt, and H.-J. Knackmuss. 1990. Enzymatic formation, stability, and spontaneous reactions of 4-fluoromuconolactone, a metabolite of the bacterial degradation of 4-fluorobenzoate. J. Bacteriol. 172:5119-5129[Abstract/Free Full Text].
34.	Schmidt, E., and H.-J. Knackmuss. 1980. Chemical structure and biodegradability of halogenated aromatic compounds. Conversion of chlorinated muconic acids into maleoylacetic acid. Biochem. J. 192:339-347[Medline].
35.	Seegal, B. C., and M. Holden. 1945. The antibiotic activity of extracts of Ranunculaceae. Science 101:413-414[Free Full Text].
36.	Sistrom, W. R., and R. Y. Stanier. 1954. The mechanism of formation of $beta$ -ketoadipic acid by bacteria. J. Biol. Chem. 210:821-836[Free Full Text].
37.	Studier, F. W., A. H. Rosenberg, J. J. Dunn, and J. W. Dubendorff. 1990. Use of T7 RNA polymerase to direct expression of cloned genes. Methods Enzymol. 185:60-89[Medline].
38.	Tiedje, J. M., J. M. Duxbury, M. Alexander, and J. E. Dawson. 1969. 2,4-D metabolism: pathway of degradation of chlorocatechols by Arthrobacter sp. J. Agric. Food Chem. 17:1021-1026[CrossRef].
39.	van der Meer, J. R., R. I. L. Eggen, A. J. B. Zehnder, and W. M. de Vos. 1991. Sequence analysis of the Pseudomonas sp. strain P51 tcb gene cluster, which encodes metabolism of chlorinated catechols: evidence for specialization of catechol 1,2-dioxygenases for chlorinated substrates. J. Bacteriol. 173:2425-2434[Abstract/Free Full Text].
40.	Verschueren, K. H. G., J. Kingma, H. J. Rozeboom, K. H. Kalk, D. B. Janssen, and B. W. Dijkstra. 1993. Crystallographic studies of the interaction of haloalkane dehalogenase with halide ions. Studies with halide compounds reveal a halide binding site in the active site. Biochemistry 32:9031-9037[CrossRef][Medline].
41.	Vollmer, M. D. 1992. Untersuchungen zur Dehalogenierung im Dichloraromatenabbau in In Alcaligenes eutrophus Stamm JMP134. Diplomarbeit. Universität Stuttgart, Stuttgart, Germany.
42.	Vollmer, M. D., P. Fischer, H.-J. Knackmuss, and M. Schlömann. 1994. Inability of muconate cycloisomerases to cause dehalogenation during conversion of 2-chloro-cis,cis-muconate. J. Bacteriol. 176:4366-4375[Abstract/Free Full Text].
43.	Vollmer, M. D., H. Hoier, H.-J. Hecht, U. Schell, J. Gröning, A. Goldman, and M. Schlömann. 1998. Substrate specificity and product formation by muconate cycloisomerases: an analysis of wild-type enzymes and engineered variants. Appl. Environ. Microbiol. 64:3290-3299[Abstract/Free Full Text].
44.	Vollmer, M. D., U. Schell, V. Seibert, and M. Schlömann. 1999. Substrate specificities of the chloromuconate cycloisomerases from Pseudomonas sp. B13, Ralstonia eutropha JMP134 and Pseudomonas sp. P51 and implications for enzyme evolution. Appl. Microbiol. Biotechnol. 51:598-605[CrossRef][Medline].
45.	Vollmer, M. D., and M. Schlömann. 1995. Conversion of 2-chloro-cis,cis-muconate and its metabolites 2-chloro- and 5-chloromuconolactone by chloromuconate cycloisomerases of pJP4 and pAC27. J. Bacteriol. 177:2938-2941[Abstract/Free Full Text].