trans-3-Chloroacrylic Acid Dehalogenase from Pseudomonas pavonaceae 170 Shares Structural and Mechanistic Similarities with 4-Oxalocrotonate Tautomerase

The genes (caaD1 and caaD2) encoding the trans-3-chloroacrylic acid dehalogenase (CaaD) of the 1,3-dichloropropene-utilizing bacterium Pseudomonas pavonaceae 170 were cloned and heterologously expressed in Escherichia coli and Pseudomonas sp. strain GJ1. CaaD is a protein of 50 kDa that is composed of alpha-subunits of 75 amino acid residues and beta-subunits of 70 residues. It catalyzes the hydrolytic cleavage of the beta-vinylic carbon-chlorine bond in trans-3-chloroacrylic acid with a turnover number of 6.4 s(-1). On the basis of sequence similarity, oligomeric structure, and subunit size, CaaD appears to be related to 4-oxalocrotonate tautomerase (4-OT). This tautomerase consists of six identical subunits of 62 amino acid residues and catalyzes the isomerization of 2-oxo-4-hexene-1,6-dioate, via hydroxymuconate, to yield 2-oxo-3-hexene-1,6-dioate. In view of the oligomeric architecture of 4-OT, a trimer of homodimers, CaaD is postulated to be a hexameric protein that functions as a trimer of alpha beta-dimers. The sequence conservation between CaaD and 4-OT and site-directed mutagenesis experiments suggested that Pro-1 of the beta-subunit and Arg-11 of the alpha-subunit are active-site residues in CaaD. Pro-1 could act as the proton acceptor/donor, and Arg-11 is probably involved in carboxylate binding. Based on these findings, a novel dehalogenation mechanism is proposed for the CaaD-catalyzed reaction which does not involve the formation of a covalent enzyme-substrate intermediate.     

Cloning, expression, and characterization of a cis-3-chloroacrylic acid dehalogenase: insights into the mechanistic, structural, and evolutionary relationship between isomer-specific 3-chloroacrylic acid dehalogenases

The gene encoding the cis-3-chloroacrylic acid dehalogenase (cis-CaaD) from coryneform bacterium strain FG41 has been cloned and overexpressed, and the enzyme has been purified to homogeneity and subjected to kinetic and mechanistic characterization. Kinetic studies show that cis-CaaD processes cis-3-haloacrylates, but not trans-3-haloacrylates, with a turnover number of approximately 10 s(-1). The product of the reaction is malonate semialdehyde, which was confirmed by its characteristic 1H NMR spectrum. The enzyme shares low but significant sequence similarity with the previously studied trans-3-chloroacrylic acid dehalogenase (CaaD) and with other members of the 4-oxalocrotonate tautomerase (4-OT) family. While 4-OT and CaaD function as homo- and heterohexamers, respectively, cis-CaaD appears to be a homotrimeric protein as assessed by gel filtration chromatography. On the basis of the known three-dimensional structures and reaction mechanisms of CaaD and 4-OT, a sequence alignment implicated Pro-1, Arg-70, Arg-73, and Glu-114 as important active-site residues in cis-CaaD. Subsequent site-directed mutagenesis experiments confirmed these predictions. The acetylene compounds, 2-oxo-3-pentynoate and 3-bromo- and 3-chloropropiolate, were processed by cis-CaaD to products consistent with an enzyme-catalyzed hydration reaction previously established for CaaD. Hydration of 2-oxo-3-pentynoate afforded acetopyruvate, while the 3-halopropiolates became irreversible inhibitors that modified Pro-1. The results of this work revealed that cis-CaaD and CaaD have different primary and quaternary structures, and display different substrate specificity and catalytic efficiencies, but likely share a highly conserved catalytic mechanism. The mechanism may have evolved independently because sequence analysis indicates that cis-CaaD is not a 4-OT family member, but represents the first characterized member of a new family in the tautomerase superfamily that probably resulted from an independent duplication of a 4-OT-like sequence. The discovery of a fifth family of enzymes within this superfamily further demonstrates the diversity of activities and structures that can be created from 4-OT-like sequences.     

Kinetic and stereochemical analysis of YwhB, a 4-oxalocrotonate tautomerase homologue in Bacillus subtilis: mechanistic implications for the YwhB- and 4-oxalocrotonate tautomerase-catalyzed reactions

YwhB, a 4-oxalocrotonate tautomerase (4-OT) homologue in Bacillus subtilis, has no known biological role, and the gene has no apparent genomic context. The kinetic and stereochemical properties of YwhB have been examined using available enol and dienol compounds. The kinetic analysis shows that YwhB has a relatively nonspecific 1,3- and 1,5-keto-enol tautomerase activity, with the former activity prevailing. Replacement of Pro-1 or Arg-11 with an alanine significantly reduces or abolishes these activities, implicating both residues as critical ones for the activities. In D2O, ketonization of two monoacid substrates (2-hydroxy-2,4-pentadienoate and phenylenolpyruvate) produces a mixture of stereoisomers {2-keto-3-[2H]-4-pentenoate and 3-[2H]-phenylpyruvate}, where the (3R)-isomers predominate. Ketonization of 2-hydroxy-2,4-hexadienedioate, a diacid, in D2O affords mostly the opposite enantiomer, (3S)-2-oxo-[3-2H]-4-hexenedioate. The mono- and diacids apparently bind in different orientations in the active site of YwhB, but the highly stereoselective nature of the YwhB reaction using a diacid suggests that the biological substrate for YwhB may be a diacid. Moreover, of the three dienols examined, 1,3- and 1,5-keto-enol tautomerization reactions are only observed for 2-hydroxy-2,4-hexadienedioate, indicating that the C-3 and C-5 positions are accessible for protonation in this compound. Incubation of 4-OT with 2-hydroxy-2,4-hexadienedioate in D2O results in a racemic mixture of 2-oxo-[3-2H]-4-hexenedioate, suggesting that 4-OT may not catalyze a 1,3-keto-enol tautomerization reaction using this dienol. It has previously been shown that 4-OT catalyzes the near stereospecific conversion of 2-hydroxy-2,4-hexadienedioate to (5S)-[5-2H]-2-oxo-3-hexenedioate in D2O. Taken together, these observations suggest that 4-OT might function as a 1,5-keto-enol tautomerase using 2-hydroxy-2,4-hexadienedioate.     

Reactions of 4-oxalocrotonate tautomerase and YwhB with 3-halopropiolates: analysis and implications

4-Oxalocrotonate tautomerase (4-OT) and YwhB, a 4-OT homologue found in Bacillus subtilis, exhibit a low level hydratase activity that converts trans-3-haloacrylates to acetaldehyde, presumably through a malonate semialdehyde intermediate. The mechanism for the initial transformation of the 3-haloacrylate to malonate semialdehyde involves Pro-1 as well as an arginine, two residues that play critical roles in the 4-OT-catalyzed isomerization reaction and the YwhB-catalyzed tautomerization reaction. These residues are also critical for the trans-3-chloroacrylic acid dehalogenase (CaaD)-catalyzed conversion of trans-3-haloacrylates to malonate semialdehyde. Recently, 3-bromo- and 3-chloropropiolate, the acetylene analogues of 3-haloacrylates, were characterized as potent irreversible inhibitors of CaaD due to the covalent modification of the catalytic proline. In view of these observations, an investigation of the behavior of 4-OT and YwhB with the 3-halopropiolates was undertaken. The results show that these compounds are potent irreversible inhibitors of 4-OT and YwhB with Pro-1 being the sole site of covalent modification by 3-bromopropiolate. The inactivation process could involve the enzyme-catalyzed addition of water to the 3-halopropiolate yielding an acyl halide, which would inactivate the enzyme or be initiated by the nucleophilic attack of Pro-1 at the C-3 position of the 3-halopropiolate in a Michael type reaction. The presence of the halogen along with Arg-11 could facilitate both reactions with the latter causing the polarization of the alpha,beta-unsaturated acids. The 3-halopropiolates are the first identified inhibitors of YwhB and confirm the importance of Pro-1 in its mechanism. In addition, the results set the stage for the use of these compounds as mechanistic probes of the primary as well as low level activities of 4-OT and YwhB.     

The roles of active-site residues in the catalytic mechanism of trans-3-chloroacrylic acid dehalogenase: a kinetic, NMR, and mutational analysis

trans-3-Chloroacrylic acid dehalogenase (CaaD) converts trans-3-chloroacrylic acid to malonate semialdehyde by the addition of H(2)O to the C-2, C-3 double bond, followed by the loss of HCl from the C-3 position. Sequence similarity between CaaD, an (alphabeta)(3) heterohexamer (molecular weight 47,547), and 4-oxalocrotonate tautomerase (4-OT), an (alpha)(6) homohexamer, distinguishes CaaD from those hydrolytic dehalogenases that form alkyl-enzyme intermediates. The recently solved X-ray structure of CaaD demonstrates that betaPro-1 (i.e., Pro-1 of the beta subunit), alphaArg-8, alphaArg-11, and alphaGlu-52 are at or near the active site, and the >or=10(3.4)-fold decreases in k(cat) on mutating these residues implicate them as mechanistically important. The effect of pH on k(cat)/K(m) indicates a catalytic base with a pK(a) of 7.6 and an acid with a pK(a) of 9.2. NMR titration of (15)N-labeled wild-type CaaD yielded pK(a) values of 9.3 and 11.1 for the N-terminal prolines, while the fully active but unstable alphaP1A mutant showed a pK(a) of 9.7 (for the betaPro-1), implicating betaPro-1 as the acid catalyst, which may protonate C-2 of the substrate. These results provide the first evidence for an amino-terminal proline, conserved in all known tautomerase superfamily members, functioning as a general acid, rather than as a general base as in 4-OT. Hence, a reasonable candidate for the general base in CaaD is the active site residue alphaGlu-52. CaaD has 10 arginine residues, six in the alpha-subunit (Arg-8, Arg-11, Arg-17, Arg-25, Arg-35, and Arg-43), and four in the beta-subunit (Arg-15, Arg-21, Arg-55, and Arg-65). (1)H-(15)N-heteronuclear single quantum coherence (HSQC) spectra of CaaD showed seven to nine Arg-NepsilonH resonances (denoted R(A) to R(I)) depending on the protein concentration and pH. One of these signals (R(D)) disappeared in the spectrum of the largely inactive alphaR11A mutant (deltaH = 7.11 ppm, deltaN = 89.5 ppm), and another one (R(G)) disappeared in the spectrum of the inactive alphaR8A mutant (deltaH = 7.48 ppm, deltaN = 89.6 ppm), thereby assigning these resonances to alphaArg-11NepsilonH, and alphaArg-8NepsilonH, respectively. (1)H-(15)N-HSQC titration of the enzyme with the substrate analogue 3-chloro-2-butenoic acid (3-CBA), a competitive inhibitor (K(I)(slope) = 0.35 +/- 0.06 mM), resulted in progressive downfield shifts of the alphaArg-8Nepsilon resonance yielding a K(D) = 0.77 +/- 0.44 mM, comparable to the (K(I)(slope), suggestive of active site binding. Increasing the pH of free CaaD to 8.9 at 5 degrees C resulted in the disappearance of all nine Arg-NepsilonH resonances due to base-catalyzed NepsilonH exchange. Saturating the enzyme with 3-CBA (16 mM) induced the reappearance of two NepsilonH signals, those of alphaArg-8 and alphaArg-11, indicating that the binding of the substrate analogue 3-CBA selectively slows the NepsilonH exchange rates of these two arginine residues. The kinetic and NMR data thus indicate that betaPro-1 is the acid catalyst, alphaGlu-52 is a reasonable candidate for the general base, and alphaArg-8 and alphaArg-11 participate in substrate binding and in stabilizing the aci-carboxylate intermediate in a Michael addition mechanism.     

Reactions of trans-3-chloroacrylic acid dehalogenase with acetylene substrates: consequences of and evidence for a hydration reaction

Various soil bacteria use 1,3-dichloropropene, a component of the commercially available fumigants Shell D-D and Telone II, as a sole source of carbon and energy. One enzyme involved in the catabolism of 1,3-dichloropropene is trans-3-chloroacrylic acid dehalogenase (CaaD), which converts the trans-isomers of 3-bromo- and 3-chloroacrylate to malonate semialdehyde. Sequence analysis suggested a relationship between the heterohexameric CaaD and the bacterial isomerase, 4-oxalocrotonate tautomerase (4-OT), thereby distinguishing CaaD from a number of dehalogenases whose mechanisms proceed through an alkyl- or aryl-enzyme intermediate. In this study, the genes for the alpha- and beta-subunits of CaaD have been synthesized using a polymerase chain reaction-based strategy, cloned into separate plasmids, and the proteins expressed and purified as the functional heterohexamer. Subsequently, the product of the reaction was confirmed to be malonate semialdehyde by (1)H and (13)C NMR spectroscopy, and kinetic constants were determined using a UV spectrophotometric assay. In view of the proposed hydrolytic nature of the CaaD-catalyzed reaction, three acetylene compounds were investigated as substrates for the enzyme. One compound, 2-oxo-3-pentynoate, a potent active site-directed irreversible inhibitor of 4-OT, is a substrate for CaaD, and was processed to acetopyruvate with kinetic constants similar to those determined for the trans-isomers of 3-bromo- and 3-chloroacrylate. The remaining two compounds, 3-bromo- and 3-chloropropiolic acid, were transformed into potent irreversible inhibitors of CaaD. The inactivation observed for 3-bromopropiolic acid is due to the covalent modification of Pro-1 of the beta-subunit. The results provide evidence for a hydratase activity and set the stage to use the 3-halopropiolic acids as ligands in inactivated CaaD complexes that can be studied by X-ray crystallography.     

The X-ray structure of trans-3-chloroacrylic acid dehalogenase reveals a novel hydration mechanism in the tautomerase superfamily

Isomer-specific 3-chloroacrylic acid dehalogenases function in the bacterial degradation of 1,3-dichloropropene, a compound used in agriculture to kill plant-parasitic nematodes. The crystal structure of the heterohexameric trans-3-chloroacrylic acid dehalogenase (CaaD) from Pseudomonas pavonaceae 170 inactivated by 3-bromopropiolate shows that Glu-52 in the alpha-subunit is positioned to function as the water-activating base for the addition of a hydroxyl group to C-3 of 3-chloroacrylate and 3-bromopropiolate, whereas the nearby Pro-1 in the beta-subunit is positioned to provide a proton to C-2. Two arginine residues, alphaArg-8 and alphaArg-11, interact with the C-1 carboxylate groups, thereby polarizing the alpha,beta-unsaturated acids. The reaction with 3-chloroacrylate results in the production of an unstable halohydrin, 3-chloro-3-hydroxypropanoate, which decomposes into the products malonate semialdehyde and HCl. In the inactivation mechanism, however, malonyl bromide is produced, which irreversibly alkylates the betaPro-1. CaaD is related to 4-oxalocrotonate tautomerase, with which it shares an N-terminal proline. However, in 4-oxalocrotonate tautomerase, Pro-1 functions as a base participating in proton transfer within a hydrophobic active site, whereas in CaaD, the acidic proline is stabilized in a hydrophilic active site. The altered active site environment of CaaD thus facilitates a previously unknown reaction in the tautomerase superfamily, the hydration of the alpha,beta-unsaturated bonds of trans-3-chloroacrylate and 3-bromopropiolate. The mechanism for these hydration reactions represents a novel catalytic strategy that results in carbon-halogen bond cleavage.     

Half-of-the-sites binding of reactive intermediates and their analogues to 4-oxalocrotonate tautomerase and induced structural asymmetry of the enzyme

4-Oxalocrotonate tautomerase (4-OT), a homohexameric enzyme, converts the unconjugated enone, 2-oxo-4-hexenedioate (1), to the conjugated enone, 2-oxo-3-hexenedioate (3), via a dienolic intermediate, 2-hydroxymuconate (2). Pro-1 serves as the general base, and both Arg-11 and Arg-39 function in substrate binding and catalysis in an otherwise hydrophobic active site. Although 4-OT exhibits hyperbolic kinetics and no structural asymmetry either by X-ray or by NMR, inactivation by two affinity labels showed half-site stoichiometry [Stivers, J. T., et al. (1996) Biochemistry 35, 803-813; Johnson, W. H., Jr., et al. (1997) Biochemistry 36, 15724-15732], and titration of the R39Q mutant with cis,cis-muconate showed negative cooperativity [Harris, T. K., et al. (1999) Biochemistry 38, 12343-12357]. To test for anticooperativity during catalysis, 4-OT was titrated with equilibrium mixtures (> or = 81% product) of the reactive dicarboxylate or monocarboxylate intermediates, 2 or 2-hydroxy-2,4-pentadienoate (4), respectively, in three types of NMR experiments: two-dimensional 1H-15N HSQC titrations of backbone NH and of Arg N epsilonH resonances and one-dimensional 15N NMR titrations of Arg N epsilon resonances. All titrations showed substoichiometric binding of the equilibrium mixtures to 3 +/- 1 sites per hexamer with apparent dissociation constants comparable to the Km values of the intermediates. Compound 4 also bound 1 order of magnitude less tightly at another site, suggesting negative cooperativity. Consistent with negative cooperativity, asymmetry of the resulting complexes at saturating levels of 2 and 4 is indicated by splitting of the backbone NH resonances of 11 residues and 10 residues of 4-OT, respectively. The dicarboxylate competitive inhibitor, (2E)-fluoromuconate (5), with a KI of 45 +/- 7 microM, also exhibited substoichiometric binding to 3 +/- 1 sites per hexamer, with a KD of 25 +/- 18 microM, and splitting of the backbone NH resonance of L8. The monocarboxylate inhibitors (2E)- (6) and (2Z)-2-fluoro-2,4-pentadienoate (7) showed much weaker binding (KD = 3.1 +/- 1.3 mM), as well as splitting of two and five backbone NH resonances, respectively, indicating asymmetry of the complexes. The N epsilon resonances of both Arg-11 and Arg-39 were shifted downfield, and that of Pro-1N was broadened by all ligands, consistent with the major catalytic roles of these residues. Structural pathways for the site-site interactions which result in negative cooperativity are proposed on the basis of the X-ray structures of free and affinity-labeled 4-OT. Selective resonance broadenings induced by the binding of inactive analogues and active intermediates indicate residues which may be mobilized during reversible ligand binding and during catalysis, respectively.     

Phenylpyruvate tautomerase activity of trans-3-chloroacrylic acid dehalogenase: evidence for an enol intermediate in the dehalogenase reaction?

The enzymatic conversion of cis- or trans-3-chloroacrylic acid to malonate semialdehyde is a key step in the bacterial degradation of the nematocide 1,3-dichloropropene. Two mechanisms have been proposed for the isomer-specific hydrolytic dehalogenases, cis- and trans-3-chloroacrylic acid dehalogenase (cis-CaaD and CaaD, respectively), responsible for this step. In one mechanism, the enol isomer of malonate semialdehyde is produced by the alpha,beta-elimination of HCl from an initial halohydrin species. Phenylenolpyruvate has now been found to be a substrate for CaaD with a kcat/Km value that approaches the one determined for the CaaD reaction using trans-3-chloroacrylate. Moreover, the reaction is stereoselective, generating the 3S isomer of [3-2H]phenylpyruvate in a 1.8:1 ratio in 2H2O. These two observations and a kinetic analysis of active site mutants of CaaD suggest that the active site of CaaD is responsible for the phenylpyruvate tautomerase (PPT) activity. The activity is a striking example of catalytic promiscuity and could reflect the presence of an enol intermediate in CaaD-mediated dehalogenation of trans-3-chloroacrylate. CaaD and cis-CaaD represent different families in the tautomerase superfamily, a group of structurally homologous proteins characterized by a core beta-alpha-beta building block and a catalytic Pro-1. The eukaryotic immunoregulatory protein known as macrophage migration inhibitory factor (MIF), also a tautomerase superfamily member, exhibits a PPT activity, but the biological relevance is unknown. In addition to the mechanistic implications, these results establish a functional link between CaaD and the superfamily tautomerases, highlight the catalytic and binding promiscuity of the beta-alpha-beta scaffold, and suggest that the PPT activity of MIF could reflect a partial reaction in an unknown MIF-catalyzed reaction.     

Guanidine-induced equilibrium unfolding of a homo-hexameric enzyme 4-oxalocrotonate tautomerase (4-OT)

4-Oxalocrotonate tautomerase (4-OT) is a bacterial enzyme that is comprised of 6 identical 62 amino acid subunits. The 4-OT enzyme is an attractive model system in which to study the interrelationship between protein folding, subunit assembly, and catalytic function. Here we report on the GuHCl-induced equilibrium unfolding properties of wild-type 4-OT using catalytic activity measurements and using far-UV circular dichroism (CD) spectroscopy. We demonstrate that the unfolding of wild-type 4-OT in 50 mM phosphate buffers containing 6 M GuHCl is reversible at pHs 6.0, 7.4, and 8.5; and we find that there is both an enzyme concentration dependence and a pH dependence to the equilibrium unfolding properties of 4-OT. Our data suggests that the GuHCl-induced unfolding of 4-OT in 50 mM phosphate buffer at pH 8.5 can be modeled as a two-state process involving folded hexamer and unfolded monomer. On the basis of this model, we determined a free-energy value for the unfolding of 4-OT at pH 8.5 to be 68.7 +/- 3.2 kcal/mol under standard state conditions (1 M hexamer). In 50 mM phosphate buffers at pHs 6.0 and 7.4, only the catalytic activity denaturation curves are consistent with a two-state folding mechanism. At the lower pHs the far-UV-CD transitions are not well described by a two-state model. Our results at pHs 6.0 and 7.4 suggest that intermediate state(s) are populated in the equilibrium unfolding reaction at these lower pHs and that these intermediate state(s) have some helical content but no measurable catalytic activity.     

The 4-oxalocrotonate tautomerase family of enzymes: how nature makes new enzymes using a beta-alpha-beta structural motif

4-Oxalocrotonate tautomerase (4-OT) catalyzes the isomerization of beta,gamma-unsaturated enones to their alpha,beta-isomers. The enzyme is part of a plasmid-encoded pathway, which enables bacteria harboring the plasmid to use various aromatic hydrocarbons as their sole sources of carbon and energy. Among isomerases and enzymes in general, 4-OT is unusual for two reasons: it has one of the smallest known monomer sizes (62 amino acids) and the amino-terminal proline functions as the catalytic base. In addition to Pro-1, three other residues (Arg-11, Arg-39, and Phe-50) have been identified as critical catalytic residues by kinetic analysis, site-directed mutagenesis, chemical synthesis, NMR, and crystallographic studies. Arginine-39 functions as the general acid catalyst (assisted by an ordered water molecule) in the reaction while Arg-11 plays a role in substrate binding and facilitates catalysis by acting as an electron sink. Finally, the hydrophobic nature of the active site, which lowers the pK(a) of Pro-1 to approximately 6.4 and provides a favorable environment for catalysis, is largely maintained by Phe-50. 4-OT is also the title enzyme of the 4-OT family of enzymes. The chromosomal homologues in this family are composed of monomers ranging in size from 61 to 79 amino acids, which code a beta-alpha-beta structural motif. The homologues all retain Pro-1 and generally have an aromatic or hydrophobic amino acid at the Phe-50 position. Characterization of representative members has uncovered mechanistic and structural diversity. A new activity, a trans-3-chloroacrylic acid dehalogenase, has been identified in addition to the previously known tautomerase and isomerase activities. Two new structures have also been found, along with the 4-OT hexamer. The dehalogenase functions as a heterohexamer while the Escherichia coli homologue, designated YdcE, functions as a dimer. Moreover, both 4-OT and the Bacillus subtilis homologue, designated YwhB, exhibit low-level dehalogenase activity. Amplification of this activity could have produced the full-fledged dehalogenase. The sum of these observations indicates that Nature uses the beta-alpha-beta structural motif as a building block in a variety of manners to create new enzymes.     

Kinetic, stereochemical, and structural effects of mutations of the active site arginine residues in 4-oxalocrotonate tautomerase.

Three arginine residues (Arg-11, Arg-39, Arg-61) are found at the active site of 4-oxalocrotonate tautomerase in the X-ray structure of the affinity-labeled enzyme [Taylor, A. B., Czerwinski, R. M., Johnson, R. M., Jr., Whitman, C. P., and Hackert, M. L. (1998) Biochemistry 37, 14692-14700]. The catalytic roles of these arginines were examined by mutagenesis, kinetic, and heteronuclear NMR studies. With a 1,6-dicarboxylate substrate (2-hydroxymuconate), the R61A mutation showed no kinetic effects, while the R11A mutation decreased k(cat) 88-fold and increased K(m) 8.6-fold, suggesting both binding and catalytic roles for Arg-11. With a 1-monocarboxylate substrate (2-hydroxy-2,4-pentadienoate), no kinetic effects of the R11A mutation were found, indicating that Arg-11 interacts with the 6-carboxylate of the substrate. The stereoselectivity of the R11A-catalyzed protonation at C-5 of the dicarboxylate substrate decreased, while the stereoselectivity of protonation at C-3 of the monocarboxylate substrate increased in comparison with wild-type 4-OT, indicating the importance of Arg-11 in properly orienting the dicarboxylate substrate by interacting with the charged 6-carboxylate group. With 2-hydroxymuconate, the R39A and R39Q mutations decreased k(cat) by 125- and 389-fold and increased K(m) by 1.5- and 2.6-fold, respectively, suggesting a largely catalytic role for Arg-39. The activity of the R11A/R39A double mutant was at least 10(4)-fold lower than that of the wild-type enzyme, indicating approximate additivity of the effects of the two arginine mutants on k(cat). For both R11A and R39Q, 2D (1)H-(15)N HSQC and 3D (1)H-(15)N NOESY-HSQC spectra showed chemical shift changes mainly near the mutated residues, indicating otherwise intact protein structures. The changes in the R39Q mutant were mainly in the beta-hairpin from residues 50 to 57 which covers the active site. HSQC titration of R11A with the substrate analogue cis, cis-muconate yielded a K(d) of 22 mM, 37-fold greater than the K(d) found with wild-type 4-OT (0.6 mM). With the R39Q mutant, cis, cis-muconate showed negative cooperativity in active site binding with two K(d) values, 3.5 and 29 mM. This observation together with the low K(m) of 2-hydroxymuconate (0.47 mM) suggests that only the tight binding sites function catalytically in the R39Q mutant. The (15)Nepsilon resonances of all six Arg residues of 4-OT were assigned, and the assignments of Arg-11, -39, and -61 were confirmed by mutagenesis. The binding of cis,cis-muconate to wild-type 4-OT upshifts Arg-11 Nepsilon (by 0.05 ppm) and downshifts Arg-39 Nepsilon (by 1.19 ppm), indicating differing electronic delocalizations in the guanidinium groups. A mechanism is proposed in which Arg-11 interacts with the 6-carboxylate of the substrate to facilitate both substrate binding and catalysis and Arg-39 interacts with the 1-carboxylate and the 2-keto group of the substrate to promote carbonyl polarization and catalysis, while Pro-1 transfers protons from C-3 to C-5. This mechanism, together with the effects of mutations of catalytic residues on k(cat), provides a quantitative explanation of the 10(7)-fold catalytic power of 4-OT. Despite its presence in the active site in the crystal structure of the affinity-labeled enzyme, Arg-61 does not play a significant role in either substrate binding or catalysis.     

A stable dimer in the pH-induced equilibrium unfolding of the homo-hexameric enzyme 4-oxalocrotonate tautomerase (4-OT)

4-Oxalocrotonate tautomerase (4-OT) is a multimeric, bacterial enzyme comprised of 6 identical 62-amino acid subunits, which associate under native conditions to form a homo-hexameric structure stabilized entirely by noncovalent interactions. We have previously shown that the GuHCl-induced equilibrium unfolding of 4-OT at pH 8.5 is well modeled as a two-state process involving only hexamer and unfolded monomer; and we have obtained spectroscopic evidence that intermediate state(s) is (are) populated in the equilibrium unfolding reaction at pHs 6.0 and 7.4 [Silinski, P., Allingham, M. J., and Fitzgerald, M. C. (2001) Biochemistry 40, 4493-4502]. Here, we report on the pH-induced equilibrium unfolding of 4-OT using size-exclusion chromatography (SEC), far-UV-circular dichroism (CD) spectroscopy, and catalytic activity measurements over the pH range from 1.5 to 10.1. Our results indicate that the native hexamer of 4-OT is the predominant species in solution at pHs > or =6.2, that a partially folded dimeric state of 4-OT is stabilized in solution at pH 4.8, and that the enzyme is largely denatured in strongly acidic solutions (pH < or =3.1). GuHCl-induced equilibrium unfolding studies on 4-OT at pH 4.8 indicate that the folded 4-OT dimer populated at this pH is stabilized by 11.7 kcal.mol(-1). The results of biophysical studies on a fluorescent analogue of the enzyme, 4-OT(F50Y), and the results of UV photo-cross-linking studies on a synthetically derived 4-OT analogue, 4-OT(P1Bpa), suggest the polypeptide chains in the 4-OT dimer are nativelike in structure with the exception of their C-termini.     

The product of the natural reaction catalyzed by 4-oxalocrotonate tautomerase becomes an affinity label of its mutant

4-Oxalocrotonate tautomerase (4-OT) catalyzes the isomerization of 4-oxalocrotonate, 1, to 2-oxo-3E-hexenedioate, 3, using a general acid/base mechanism that involves a conserved N-terminal proline residue. The P1A and P1G mutants have been shown to catalyze this isomerization but at reduced rates. Analysis of these mutants by mass spectrometry demonstrated that P1A is susceptible to a 1,4-addition of the N-terminal primary amine across the double bond of enone 3 to form a covalent adduct. Although slower than the isomerization reaction, the addition is fast, with 50% of the active sites being alkylated within 12 min. By contrast, the wt4-OT shows no detectable modification over 24 h. These results support the hypothesis that avoidance of nucleophilic reactions, such as the irreversible Michael addition to the product, could be a contributing factor in the evolutionary conservation of N-terminal proline residues in 4OT.     

4-Oxalocrotonate tautomerase, its homologue YwhB, and active vinylpyruvate hydratase: synthesis and evaluation of 2-fluoro substrate analogues

A series of 2-fluoro-4-alkene and 2-fluoro-4-alkyne substrate analogues were synthesized and examined as potential inhibitors of three enzymes: 4-oxalocrotonate tautomerase (4-OT) and vinylpyruvate hydratase (VPH) from the catechol meta-fission pathway and a closely related 4-OT homologue found in Bacillus subtilis designated YwhB. All of the compounds were potent competitive inhibitors of 4-OT with the monocarboxylated 2E-fluoro-2,4-pentadienoate and the dicarboxylated 2E-fluoro-2-en-4-ynoate being the most potent. Despite the close mechanistic and structural similarities between 4-OT and YwhB, these compounds were significantly less potent inhibitors of YwhB with K(i) values ranging from 5- to 633-fold lower than those determined for 4-OT. The study of VPH is complicated by the fact that the enzyme is only active as a complex with the metal-dependent 4-oxalocrotonate decarboxylase (4-OD), the enzyme following 4-OT in the catechol meta-fission pathway. A structure-based sequence analysis identified 4-OD as a member of the fumarylacetoacetate hydrolase (FAH) superfamily and implicated Glu-109 and Glu-111 as potential metal-binding ligands. Changing these residues to a glutamine verified their importance for enzymatic activity and enabled the production of soluble E109Q4-OD/VPH or E111Q4-OD/VPH complexes, which retained full hydratase activity but had little decarboxylase activity. Subsequent incubation of the E109Q4-OD/VPH complex with the substrate analogues identified the 2E and 2Z isomers of the monocarboxylated 2-fluoropent-2-en-4-ynoate as competitive inhibitors. The combined results set the stage for crystallographic studies of 4-OT, YwhB, and VPH using these inhibitors as ligands.     

Kinetic, crystallographic, and mechanistic characterization of TomN: elucidation of a function for a 4-oxalocrotonate tautomerase homologue in the tomaymycin biosynthetic pathway

The biosynthesis of the C ring of the antitumor antibiotic agent, tomaymycin, is proposed to proceed through five enzyme-catalyzed steps from l-tyrosine. The genes encoding these enzymes have recently been cloned and their functions tentatively assigned, but there is limited biochemical evidence supporting the assignments of the last three steps. One enzyme, TomN, shows 58% pairwise sequence similarity with 4-oxalocrotonate tautomerase (4-OT), an enzyme found in a catabolic pathway for aromatic hydrocarbons. The TomN sequence includes three amino acids (Pro-1, Arg-11, and Arg-39) that have been identified as critical catalytic residues in 4-OT. However, the proposed substrate for TomN is very different from that processed by 4-OT. To establish the function and mechanism of TomN and its relationship with 4-OT, we conducted kinetic, mutagenic, and structural studies. The kinetic parameters for TomN, and four alanine mutants, P1A, R11A, R39A, and R61A, were determined using 2-hydroxymuconate, the substrate for 4-OT. The TomN-catalyzed reaction using this substrate compares favorably to that of 4-OT. In addition, the kinetic parameters for the P1A, R11A, and R39A mutants of TomN parallel the trends observed for the corresponding 4-OT mutants, implicating an analogous mechanism. A high-resolution crystal structure (1.4 ?) of TomN shows that the overall structure and the active site region are highly similar to those of 4-OT with a root-mean-square deviation of 0.81 ?. Moreover, key active site residues are positionally conserved. The combined results suggest that the tentative assignment for TomN and the proposed sequence of events in the biosynthetic pathway leading to the formation of the C ring of tomaymycin might not be correct. An alternative pathway that awaits biochemical confirmation is proposed.     

The crystal structure of YdcE,a 4-oxalocrotonate tautomerase homologue from Escherichia coli,confirms the structural basis for oligomer diversity

The tautomerase superfamily consists of three major families represented by 4-oxalocrotonate tautomerase (4-OT), 5-(carboxymethyl)-2-hydroxymuconate isomerase (CHMI), and macrophage migration inhibitory factor (MIF). The members of this superfamily are structurally homologous proteins constructed from a simple beta-alpha-beta fold that share a key mechanistic feature; they use an amino-terminal proline, which has an unusually low pK(a), as the general base in a keto-enol tautomerization. Several new members of the 4-OT family have now been identified using PSI-BLAST and categorized into five subfamilies on the basis of multiple-sequence alignments and the conservation of key catalytic and structural residues. The members of subfamily 5, which includes a hypothetical protein designated YdcE from Escherichia coli, are predicted not to form hexamers. The crystal structure of YdcE has been determined to 1.35 A resolution and confirms that it is a dimer. In addition, YdcE complexed with (E)-2-fluoro-p-hydroxycinnamate, identified as a potent competitive inhibitor of this enzyme, as well as N-(2-hydroxyethyl)piperazine-N'-2-ethanesulfonic acid (HEPES) and benzoate are also presented. These latter crystal structures reveal the location of the active site and suggest a mechanism for the observed YdcE-catalyzed tautomerization reaction. The dimeric arrangement of YdcE represents a new structure in the 4-OT family and demonstrates structural diversity within the 4-OT family not previously reported.     

Crystal structure of human D-dopachrome tautomerase, a homologue of macrophage migration inhibitory factor, at 1.54 A resolution

D-Dopachrome tautomerase shares a low homologous amino acid sequence (33% homology) with the macrophage migration inhibitory factor (MIF) and possesses similar tautomerase activity as well. MIF is a cytokine involved in inflammatory reactions and immune responses. Whereas recent studies have identified MIF as a pituitary hormone and immunoregulator, much less is known about the structural basis of these physiological functions and the real significance of tautomerase activity. Therefore, interest in the structure-function relationship between D-dopachrome tautomerase and MIF has increased, especially with regard to inflammation and immune responses. We have determined the X-ray crystal structure of human D-dopachrome tautomerase at 1.54 A resolution. D-Dopachrome tautomerase folds to form a homotrimer that has extensive contact between subunits by intersubunit beta-sheets. Its overall topology and trimeric formations are similar to those of human MIF. The N-terminal proline is located at the bottom of a positively charged pocket in which the conformations of Lys32 and Ser63 are highly conserved. These positively charged properties are also seen in the active site pocket of human MIF, bacterial 5-(carboxymethyl)-2-hydroxymuconate isomerase (CHMI), and 4-oxalocrotonate tautomerase (4-OT). A detailed comparison of these structures revealed significant differences in the environment around the potential active site, the intersubunit contacts, and charge distribution on the molecular surface. It can be concluded that these features are related to the physiological role and tautomerase activity of MIF and D-dopachrome tautomerase. The present structural study could be helpful for designing effective inhibitors that modulate immunoregulatory and hormone-like effects.     

Kinetic and structural characterization of DmpI from Helicobacter pylori and Archaeoglobus fulgidus, two 4-oxalocrotonate tautomerase family members

The tautomerase superfamily consists of structurally homologous proteins that are characterized by a β-α-β fold and a catalytic amino-terminal proline. 4-Oxalocrotonate tautomerase (4-OT) family members have been identified and categorized into five subfamilies on the basis of multiple sequence alignments and the conservation of key catalytic and structural residues. Representative members from two subfamilies have been cloned, expressed, purified, and subjected to kinetic and structural characterization. The crystal structure of DmpI from Helicobacter pylori (HpDmpI), a 4-OT homolog in subfamily 3, has been determined to high resolution (1.8 Å and 2.1 Å) in two different space groups. HpDmpI is a homohexamer with an active site cavity that includes Pro-1, but lacks the equivalent of Arg-11 and Arg-39 found in 4-OT. Instead, the side chain of Lys-36 replaces that of Arg-11 in a manner similar to that observed in the trimeric macrophage migration inhibitory factor (MIF), which is the title protein of another family in the superfamily. The electrostatic surface of the active site is also quite different and suggests that HpDmpI might prefer small, monoacid substrates. A kinetic analysis of the enzyme is consistent with the structural analysis, but a biological role for the enzyme remains elusive. The crystal structure of DmpI from Archaeoglobus fulgidus (AfDmpI), a 4-OT homolog in subfamily-4, has been determined to 2.4 Å resolution. AfDmpI is also a homohexamer, with a proposed active site cavity that includes Pro-1, but lacks any other residues that are readily identified as catalytic ones related to 4-OT activity. Indeed, the electrostatic potential of the active site differs significantly in that it is mostly neutral, in contrast to the usual electropositive features found in other 4-OT family members, suggesting that AfDmpI might accommodate hydrophobic substrates. A kinetic analysis has been carried out, but does not provide any clues about the type of reaction the enzyme might catalyze.     

Quantum chemical modeling of enzymatic reactions: the case of 4-oxalocrotonate tautomerase

The reaction mechanism of 4-oxalocrotonate tautomerase (4-OT) is studied using the density functional theory method B3LYP. This enzyme catalyzes the isomerisation of unconjugated alpha-keto acids to their conjugated isomers. Two different quantum chemical models of the active site are devised and the potential energy curves for the reaction are computed. The calculations support the proposed reaction mechanism in which Pro-1 acts as a base to shuttle a proton from the C3 to the C5 position of the substrate. The first step (proton transfer from C3 to proline) is shown to be the rate-limiting step. The energy of the charge-separated intermediate (protonated proline-deprotonated substrate) is calculated to be quite low, in accordance with measured pKa values. The results of the two models are used to evaluate the methodology employed in modeling enzyme active sites using quantum chemical cluster models.