3-Carboxy-cis,cis-muconate lactonizing enzyme from Pseudomonas putida is homologous to the class II fumarase family: a new reaction in the evolution of a mechanistic motif.

The gene (pcaB) for 3-carboxymuconate lactonizing enzyme (CMLE; 3-carboxymuconate cycloisomerase; EC 5.5.1.2) from Pseudomonas putida has been cloned into pMG27NS, a temperature-sensitive expression vector, and expressed in Escherichia coli N4830. The specific activity and kinetic parameters of the recombinant CMLE were comparable to those previously reported. A comparison of the deduced amino acid sequence of CMLE with sequences available in the PIR and Genbank databases revealed that CMLE has highly significant sequence homology to the class II fumarase family, particularly to adenylosuccinate lyase from Bacillus subtilis. CMLE has no significant homology to muconate lactonizing enzyme (MLE) from P. putida, its sister enzyme in the beta-ketoadipate pathway. These findings fully corroborate a prediction made by us on the basis of mechanistic and stereochemical analyses of CMLE and MLE [Chari, R. V. J., Whitman, C. P., Kozarich, J. W., Ngai, K.-L., & Ornston, L. N. (1987) J. Am. Chem. Soc. 109, 5514-5519] and suggest that CMLE and MLE were recruited into this specialized pathway from two different enzyme families.     

The structure of Neurospora crassa 3-carboxy-cis,cis-muconate lactonizing enzyme, a beta propeller cycloisomerase

Muconate lactonizing enzymes (MLEs) convert cis,cis-muconates to muconolactones in microbes as part of the beta-ketoadipate pathway; some also dehalogenate muconate derivatives of xenobiotic haloaromatics. There are three different MLE classes unrelated by evolution. We present the X-ray structure of a eukaryotic MLE, Neurospora crassa 3-carboxy-cis,cis-muconate lactonizing enzyme (NcCMLE) at 2.5 A resolution, with a seven-bladed beta propeller fold. It is related neither to bacterial MLEs nor to other beta propeller enzymes, but is structurally similar to the G protein beta subunit. It reveals a novel metal-independent cycloisomerase motif unlike the bacterial metal cofactor MLEs. Together, the bacterial MLEs and NcCMLE structures comprise a striking structural example of functional convergence in enzymes for 1,2-addition-elimination of carboxylic acids. NcCMLE and bacterial MLEs may enhance the reaction rate differently: the former by electrophilic catalysis and the latter by electrostatic stabilization of the enolate.     

Cold-Sensitive Mutation of Pseudomonas putida Affecting Enzyme Synthesis at Low Temperature

A cold-sensitive mutant of Pseudomonas putida has been isolated which grows normally at 30 C but is unable to grow on mandelate as a source of carbon at 15 C. The mutation results in the inability of the strain to carry out the reaction catalyzed by cis,cis-muconate lactonizing enzyme at low temperature and must lie in the structural gene for that enzyme, because the mutant enzyme produced at 30 C shows altered thermal stability. The mutant enzyme is not intrinsically cold-labile, nor is it cold-labile at the moment of synthesis. The activity of the mutant enzyme is not inhibited at low temperature. Evidence is presented to establish that this mutation in the structural gene coding for cis,cis-muconate lactonizing enzyme results in the lack of expression of that gene at low temperature.     

Structure and function of the 3-carboxy-cis,cis-muconate lactonizing enzyme from the protocatechuate degradative pathway of Agrobacterium radiobacter S2

3-carboxy-cis,cis-muconate lactonizing enzymes participate in the protocatechuate branch of the 3-oxoadipate pathway of various aerobic bacteria. The gene encoding a 3-carboxy-cis,cis-muconate lactonizing enzyme (pcaB1S2) was cloned from a gene cluster involved in protocatechuate degradation by Agrobacterium radiobacter strain S2. This gene encoded for a 3-carboxy-cis,cis-muconate lactonizing enzyme of 353 amino acids - significantly smaller than all previously studied 3-carboxy-cis,cis-muconate lactonizing enzymes. This enzyme, ArCMLE1, was produced in Escherichia coli and shown to convert not only 3-carboxy-cis,cis-muconate but also 3-sulfomuconate. ArCMLE1 was purified as a His-tagged enzyme variant, and the basic catalytic constants for the conversion of 3-carboxy-cis,cis-muconate and 3-sulfomuconate were determined. In contrast, Agrobacterium tumefaciens 3-carboxy-cis,cis-muconate lactonizing enzyme 1 could not, despite 87% sequence identity to ArCMLE1, use 3-sulfomuconate as substrate. The crystal structure of ArCMLE1 was determined at 2.2 A resolution. Consistent with the sequence, it showed that the C-terminal domain, present in all other members of the fumarase II family, is missing in ArCMLE1. Nonetheless, both the tertiary and quaternary structures, and the structure of the active site, are similar to those of Pseudomonas putida 3-carboxy-cis,cis-muconate lactonizing enzyme. One principal difference is that ArCMLE1 contains an Arg, as opposed to a Trp, in the active site. This indicates that activation of the carboxylic nucleophile by a hydrophobic environment is not required for lactonization, unlike earlier proposals [Yang J, Wang Y, Woolridge EM, Arora V, Petsko GA, Kozarich JW & Ringe D (2004) Biochemistry43, 10424-10434]. We identified citrate and isocitrate as noncompetitive inhibitors of ArCMLE1, and found a potential binding pocket for them on the enzyme outside the active site.     

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

Chloromuconate cycloisomerases of bacteria utilizing chloroaromatic compounds are known to convert 3-chloro-cis,cis-muconate to cis-dienelactone (cis-4-carboxymethylenebut-2-en-4-olide), while usual muconate cycloisomerases transform the same substrate to the bacteriotoxic protoanemonin. Formation of protoanemonin requires that the cycloisomerization of 3-chloro-cis,cis-muconate to 4-chloromuconolactone is completed by protonation of the exocyclic carbon of the presumed enol/enolate intermediate before chloride elimination and decarboxylation take place to yield the final product. The formation of cis-dienelactone, in contrast, could occur 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 chloride elimination, the proton-donating Lys169 of Pseudomonas putida muconate cycloisomerase was changed to alanine. As expected, substrates requiring protonation, such as cis,cis-muconate as well as 2- and 3-methyl-, 3-fluoro-, and 2-chloro-cis,cis-muconate, were not 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-dienelactone were formed as products, whereas the wild-type enzyme forms protoanemonin and the not previously isolated 2-chloroprotoanemonin, respectively. Thus, the chloromuconate cycloisomerases may avoid (chloro-)protoanemonin formation by increasing the rate of chloride abstraction from the enol/enolate intermediate compared to that of proton addition to it.     

Crystal structure of 3-carboxy-cis,cis-muconate lactonizing enzyme from Pseudomonas putida, a fumarase class II type cycloisomerase: enzyme evolution in parallel pathways

3-Carboxy-cis,cis-muconate lactonizing enzymes (CMLEs), the key enzymes in the protocatechuate branch of the beta-ketoadipate pathway in microorganisms, catalyze the conversion of 3-carboxy-cis,cis-muconate to muconolactones. We have determined the crystal structure of the prokaryotic Pseudomonas putida CMLE (PpCMLE) at 2.6 A resolution. PpCMLE is a homotetramer and belongs to the fumarase class II superfamily. The active site of PpCMLE is formed largely by three regions, which are moderately conserved in the fumarase class II superfamily, from three respective monomers. It has been proposed that residue His141, which is highly conserved in all fumarase class II enzymes and forms a charge relay with residue Glu275 (both His141 and Glu275 are in adenylosuccinate lyase numbering), acts as the general base in most fumarase class II superfamily members. However, this charge relay pair is broken in PpCMLE. The residues corresponding to His141 and Glu275 are Trp153 and Ala289, respectively, in PpCMLE. The structures of prokaryotic MLEs and that of CMLE from the eukaryotic Neurospora crassa are completely different from that of PpCMLE, indicating MLEs and CMLEs, as well as the prokaryotic and eukaryotic CMLEs, evolved from distinct ancestors, although they catalyze similar reactions. The structural differences may be related to recognition by substrates and to differences in the mechanistic pathways by which these enzymes catalyze their respective reactions.     

Inability of muconate cycloisomerases to cause dehalogenation during conversion of 2-chloro-cis,cis-muconate.

The conversion of 2-chloro-cis,cis-muconate by muconate cycloisomerase from Pseudomonas putida PRS2000 yielded two products which by nuclear magnetic resonance spectroscopy were identified as 2-chloro- and 5-chloromuconolactone. High-pressure liquid chromatography analyses showed the same compounds to be formed also by muconate cycloisomerases from Acinetobacter calcoaceticus ADP1 and Pseudomonas sp. strain B13. During 2-chloro-cis,cis-muconate turnover by the enzyme from P. putida, 2-chloromuconolactone initially was the major product. After prolonged incubation, however, 5-chloromuconolactone dominated in the resulting equilibrium. In contrast to previous assumptions, both chloromuconolactones were found to be stable at physiological pH. Since the chloromuconate cycloisomerases of Pseudomonas sp. strain B13 and Alcaligenes eutrophus JMP134 have been shown previously to produce the trans-dienelactone (trans-4-carboxymethylene-but-2-en-4-olide) from 2-chloro-cis,cis-muconate, they must have evolved the capability to cleave the carbon-chlorine bond during their divergence from normal muconate cycloisomerases.     

Characterization of muconate and chloromuconate cycloisomerase from Rhodococcus erythropolis 1CP: indications for functionally convergent evolution among bacterial cycloisomerases.

Muconate cycloisomerase (EC 5.5.1.1) and chloromuconate cycloisomerase (EC 5.5.1.7) were purified from extracts of Rhodococcus erythropolis 1CP cells grown with benzoate or 4-chlorophenol, respectively. Both enzymes discriminated between the two possible directions of 2-chloro-cis, cis-muconate cycloisomerization and converted this substrate to 5-chloromuconolactone as the only product. In contrast to chloromuconate cycloisomerases of gram-negative bacteria, the corresponding R. erythropolis enzyme is unable to catalyze elimination of chloride from (+)-5-chloromuconolactone. Moreover, in being unable to convert (+)-2-chloromuconolactone, the two cycloisomerases of R. erythropolis 1CP differ significantly from the known muconate and chloromuconate cycloisomerases of gram-negative strains. The catalytic properties indicate that efficient cycloisomerization of 3-chloro- and 2,4-dichloro-cis,cis-muconate might have evolved independently among gram-positive and gram-negative bacteria.     

Conversion of 2-chloro-cis,cis-muconate and its metabolites 2-chloro- and 5-chloromuconolactone by chloromuconate cycloisomerases of pJP4 and pAC27.

2-Chloro-cis,cis-muconate, the product of ortho-cleavage of 3-chlorocatechol, was converted by purified preparations of the pJP4- and pAC27-encoded chloromuconate cycloisomerases (EC 5.5.1.7) to trans-dienelactone (trans-4-carboxymethylenebut-2-en-4-olide). The same compound was also formed when (+)-2-chloro- and (+)-5-chloromuconolactone were substrates of these enzyme preparations. Thus, the pJP4- and pAC27-encoded chloromuconate cycloisomerases are able to catalyze chloride elimination from (+)-5-chloromuconolactone. The ability to convert (+)-2-chloromuconolactone differentiates these enzymes from other groups of cycloisomerases.     

Genetic Control of Enzyme Induction in the β-Ketoadipate Pathway of Pseudomonas putida: Deletion Mapping of cat Mutations

A number of spontaneous mutant strains of Pseudomonas putida, obtained by repeated selection for inability to grow with cis,cis-muconate, have been shown to carry deletions in catB, the structural gene for muconate lactonizing enzyme. These strains have been employed for deletion mapping of the genetic region containing catB and catC (the structural gene for muconolactone isomerase, the synthesis of which is coordinate with that of muconate lactonizing enzyme). All deletions that overlap mutant sites located on the left side of the genetic map, as well as the point mutations in that region, lead to a pleiotropic loss of both catB and catC activities. We propose that this region to the left of catB has a regulatory function. Although the details of regulation at the molecular level are unclear, our data indicate that catB and catC may well be controlled by a mechanism unlike any yet described by workers on enteric bacteria.     

cis,cis-Muconate cyclase from Trichosporon cutaneum.

The inducible enzyme catalysing the conversion of cis,cis-muconate to (+)-muconolactone was purified 300-fold from the yeast Trichosporon cutaneum, grown on phenol. The enzyme has a sharp pH optimum at pH 6.6. It reacts also with several monohalogen derivatives and with one monomethyl derivative of cis,cis-muconate, but not with cis,trans- or trans,trans-muconate or 3-carboxy-cis,cis-muconate. In contrast with the corresponding enzymes in bacteria, the yeast enzyme does not require added divalent metal ions for activity and is not inhibited by EDTA. The purified enzyme can be resolved into two peaks by isoelectric focusing. The two forms have pI 4.58 (cis,cis-muconate cyclase I) and pI 4.74 (cis, cis-muconate cyclase II), respectively. Each of these is homogenous on polyacrylamide-gel electrophoresis in the absence or presence of sodium dodecyl sulphate. The two enzyme forms have the same molecular weight (50000) as determined by gel filtration and by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. They have the same Km value (25 microM) for cis,cis-muconate. They differ with respect to their content of free thiol groups. cis, cis-Muconate cyclase I contains one thiol group, essential for activity, but relatively stable upon storage. cis, cis-Muconate cyclase II contains two thiol groups that are readily oxidized during storage with concomitant loss of activity.     

Immunological comparison of enzymes of the β-ketoadipate pathway

-Carboxy-cis,cis-muconate lactonizing enzyme and -carboxymuconolactone decarboxylase catalyze sequential reactions in the -ketoadipate pathway, the subunit sizes of the enzymes from Pseudomonas putida, biotype A, are 40000 and 13000, respectively. The cross reaction of antisera prepared against the enzymes was tested with the isofunctional enzymes formed by representatives of other bacterial species. Despite the differences in the subunit sizes of the enzymes, the antisera revealed the same general pattern: cross reaction was observed with the corresponding enzymes formed by other strains in the fluorescent Pseudomonas RNA homology group I and generally was not observed with enzymes from other Pseudomonas species or from other bacterial genera. Exceptions were provided by representatives of Pseudomonas cepacia. Members of this species are classified outside the fluorescent Pseudomonas RNA homology group. Nevertheless, the -carboxymuconolactone decarboxylases from these organisms formed precipitin bands with antisera prepared against the corresponding enzyme from P. putida, biotype A; the lactonizing enzymes from the two species did not appear to cross react. Immunodiffusion experiments with -carboxymuconolactone decarboxylase indicated that a common set of antigenic determinants for the enzyme is conserved among strains that have been classified together by other criteria; the relative immunological distances of the decarboxylases of each taxon from the reference P. putida, biotype A, enzyme were indicated by spurring patterns on Ouchterlony plates. These results suggested that the interspecific transfer of the structural gene for the enzyme is not a common event in Pseudomonas.Non-Standard Abbreviations CMLE -carboxy-cis,cis-muconate lactonizing enzyme (EC 5.5.1.2) - CMD -carboxymuconolactone decarboxylase (EC 4.1.1.44) - MLE cis,cis-muconate lactonizing enzyme (EC 5.5.1.1) - MI muconolactone isomerase (EC 5.3.3.4) Dedicated with affection and admiration to Professor R. Y. Stanier on his 60th birthday     

Enzymology of the beta-ketoadipate pathway in Trichosporon cutaneum.

Cell extracts were prepared from Trichosporon cutaneum grown with phenol or p-cresol, and activities were assayed for enzymes catalyzing conversion of these two carbon sources into 3-ketoadipate (beta-ketoadipate) and 3-keto-4-methyladipate, respectively. When activities of each enzyme were expressed as a ratio, the rate for methyl-substituted substrate being divided by that for the unsubstituted substrate, it was apparent that p-cresol-grown cells elaborated pairs of enzymes for hydroxylation, dioxygenation, and delactonization. One enzyme of each pair was more active against its methyl-substituted substrate, and the other was more active against its unsubstituted substrate. Column chromatography was used to separate two hydroxylase activities and also 1,2-dioxygenase activities; the catechol 1,2-dioxygenases were further purified to electrophoretic homogeneity. Extracts of phenol-grown cells contained only those enzymes in this group that were more active against unsubstituted substrates. In contrast, whether cells were grown with phenol or p-cresol, only one muconate cycloisomerase (lactonizing enzyme) was elaborated which was more active against 3-methyl-cis,cis-muconate than against cis,cis-muconate; in this respect it differed from a cycloisomerase of another strain of T. cutaneum which has been characterized. The cycloisomerase was purified from both phenol-grown and p-cresol-grown cells, and some characteristics were determined.     

The structure of Pseudomonas P51 Cl-muconate lactonizing enzyme: co-evolution of structure and dynamics with the dehalogenation function

Bacterial muconate lactonizing enzymes (MLEs) catalyze the conversion of cis,cis-muconate as a part of the beta-ketoadipate pathway, and some MLEs are also able to dehalogenate chlorinated muconates (Cl-MLEs). The basis for the Cl-MLEs dehalogenating activity is still unclear. To further elucidate the differences between MLEs and Cl-MLEs, we have solved the structure of Pseudomonas P51 Cl-MLE at 1.95 A resolution. Comparison of Pseudomonas MLE and Cl-MLE structures reveals the presence of a large cavity in the Cl-MLEs. The cavity may be related to conformational changes on substrate binding in Cl-MLEs, at Gly52. Site-directed mutagenesis on Pseudomonas MLE core positions to the equivalent Cl-MLE residues showed that the variant Thr52Gly was rather inactive, whereas the Thr52Gly-Phe103Ser variant had regained part of the activity. These residues form a hydrogen bond in the Cl-MLEs. The Cl-MLE structure, as a result of the Thr-to-Gly change, is more flexible than MLE: As a mobile loop closes over the active site, a conformational change at Gly52 is observed in Cl-MLEs. The loose packing and structural motions in Cl-MLE may be required for the rotation of the lactone ring in the active site necessary for the dehalogenating activity of Cl-MLEs. Furthermore, we also suggest that differences in the active site mobile loop sequence between MLEs and Cl-MLEs result in lower active site polarity in Cl-MLEs, possibly affecting catalysis. These changes could result in slower product release from Cl-MLEs and make it a better enzyme for dehalogenation of substrate.     

Production of cis,cis-muconate from benzoate and 2-fluoro-cis,cis-muconate from 3-fluorobenzoate by 3-chlorobenzoate degrading bacteria

Summary 3-Chlorobenzoate grown cells of Pseudomonas sp. strain B13 or Alcaligenes sp. strain A7-2 converted 3-fluorobenzoate to 2-fluoro-cis,cis-muconate with 87% yield. The latter strain produced 1.6 g/l. The type II muconate cycloisomerases of neither strain exhibit acitivity for 2-fluoro-cis,cis-muconate. Succinate grown cells of Pseudomonas sp. strain B13 converted benzoate to cis,cis-muconate (91% yield; 7.4 g/l). Enzyme tests confirmed that no muconate cycloisomerising enzyme was induced within 24 h.     

Aspartase/fumarase superfamily: a common catalytic strategy involving general base-catalyzed formation of a highly stabilized aci-carboxylate intermediate

Members of the aspartase/fumarase superfamily share a common tertiary and quaternary fold, as well as a similar active site architecture; the superfamily includes aspartase, fumarase, argininosuccinate lyase, adenylosuccinate lyase, δ-crystallin, and 3-carboxy-cis,cis-muconate lactonizing enzyme (CMLE). These enzymes all process succinyl-containing substrates, leading to the formation of fumarate as the common product (except for the CMLE-catalyzed reaction, which results in the formation of a lactone). In the past few years, X-ray crystallographic analysis of several superfamily members in complex with substrate, product, or substrate analogues has provided detailed insights into their substrate binding modes and catalytic mechanisms. This structural work, combined with earlier mechanistic studies, revealed that members of the aspartase/fumarase superfamily use a common catalytic strategy, which involves general base-catalyzed formation of a stabilized aci-carboxylate (or enediolate) intermediate and the participation of a highly flexible loop, containing the signature sequence GSSxxPxKxN (named the SS loop), in substrate binding and catalysis.     

Degradation of lawsone by Pseudomonas putida L2

From humus obtained from Stuttgart, a bacterium was isolated with lawsone (2-hydroxy-1,4-naphthoquinone) as selective source of carbon. This bacterium is capable of utilizing lawsone as sole source of carbon and energy. Morphological and physiological characteristics of the bacterium were examined and it was identified as a strain of Pseudomonas putida. The organism is referred to as Pseudomonas putida L2. The degradation of lawsone by Pseudomonas putida L2 was investigated. Salicylic acid and catechol were isolated and identified as metabolites. In lawsone-induced cells of Pseudomonas putida L2, salicylic acid is converted to catechol by salicylate 1-monooxygenase. Catechol 1,2-dioxygenase catalyses ortho-fission of catechol which is then metabolized via the beta-ketoadipate pathway. Formation of cis,cis-muconate and beta-ketoadipate was demonstrated by enzyme assays. Salicylate 1-monooxygenase and catechol 1,2-dioxygenase are induced sequentially. The enzymes of the beta-ketoadipate pathway are also inducible. Naphthoquinone hydroxylase, however, was demonstrated in induced and non-induced cells. This constitutive enzyme enables Pseudomonas putida L2 to degrade various 1,4-naphthoquinones in experiments with resting cells.