Dienelactone hydrolases play a crucial role in chlorocatechol degradation via the modified ortho cleavage pathway. Enzymes induced in 4-fluorobenzoate-utilizing bacteria have been classified into three groups on the basis of their specificity towards cis- and trans-dienelactone. The catalytic triad of the prototype psepu-clcd1 consists of Cys123, His202 and Asp171
8 moreTitle: Substrate-induced activation of dienelactone hydrolase: an enzyme with a naturally occurring Cys-His-Asp triad Cheah E, Austin C, Ashley GW, Ollis D Ref: Protein Engineering, 6:575, 1993 : PubMed
The Cys-His-Asp catalytic triad found in dienelactone hydrolase (DLH) is unusual for several reasons. It has not been observed in other hydrolytic enzymes and it is virtually inactive when it is produced by site-directed mutagenesis in the proteases. We propose a model to explain why this triad is catalytically active in DLH but not in the proteases. In the resting state of DLH, His202 forms an ion pair with Asp171 and Cys123 exists as a thiol. The resting state thiol does not interact with His202 in the active site but instead forms a hydrogen bond with Glu36 in the interior of the molecule. In the absence of substrate, Glu36 is also ion paired with Arg206. When substrate binds, Arg206 forms a second ion pair with the anionic substrate and the Arg206/Glu36 ion pair weakens. The destabilized Glu36 carboxylate shifts towards and deprotonates the Cys123 thiol, thereby activating the nucleophile. As the thiolate anion is not energetically favoured in the hydrophobic interior of the enzyme, it swings into the active site where it can be stabilized by the His202 imidazolium and the dipole of helix C. The Cys123 thiolate which now lies adjacent to the acyl carbon of the substrate, is thus generated only in the presence of substrate. The mode of thiolate activation reduces the susceptibility of DLH towards thiol alkylating agents.
        
Title: Catalysis by dienelactone hydrolase: a variation on the protease mechanism Cheah E, Ashley GW, Gary J, Ollis D Ref: Proteins, 16:64, 1993 : PubMed
Dienelactone hydrolase (DLH), an enzyme from the beta-ketoadipate pathway, catalyzes the hydrolysis of dienelactone to maleylacetate. Our inhibitor binding studies suggest that its substrate, dienelactone, is held in the active site by hydrophobic interactions around the lactone ring and by the ion pairs between its carboxylate and Arg-81 and Arg-206. Like the cysteine/serine proteases, DLH has a catalytic triad (Cys-123, His-202, Asp-171) and its mechanism probably involves the formation of covalently bound acyl intermediate via a tetrahedral intermediate. Unlike the proteases, DLH seems to protonate the incipient leaving group only after the collapse of the first tetrahedral intermediate, rendering DLH incapable of hydrolyzing amide analogues of its ester substrate. In addition, the triad His probably does not protonate the leaving group (enolate) or deprotonate the water for deacylation; rather, the enolate anion abstracts a proton from water and, in doing so, supplies the hydroxyl for deacylation.
        
Title: Refined structure of dienelactone hydrolase at 1.8 A Pathak D, Ollis D Ref: Journal of Molecular Biology, 214:497, 1990 : PubMed
The structure of dienelactone hydrolase (DLH) from Pseudomonus sp. B13, after stereochemically restrained least-squares refinement at 1.8 A resolution, is described. The final molecular model of DLH has a conventional R value of 0.150 and includes all but the carboxyl-terminal three residues that are crystallographically disordered. The positions of 279 water molecules are included in the final model. The root-mean-square deviation from ideal bond distances for the model is 0.014 A and the error in atomic co-ordinates is estimated to be 0.15 A. DLH is a monomeric enzyme containing 236 amino acid residues and is a member of the beta-ketoadipate pathway found in bacteria and fungi. DLH is an alpha/beta protein containing seven helices and eight strands of beta-pleated sheet. A single 4-turn 3(10)-helix is seen. The active-site Cys123 residues at the N-terminal end of an alpha-helix that is peculiar in its consisting entirely of hydrophobic residues (except for a C-terminal lysine). The beta-sheet is composed of parallel strands except for strand 2, which gives rise to a short antiparallel region at the N-terminal end of the central beta-sheet. The active-site cysteine residue is part of a triad of residues consisting of Cys123, His202 and Asp171, and is reminiscent of the serine/cysteine proteases. As in papain and actinidin, the active thiol is partially oxidized during X-ray data collection. The positions of both the reduced and the oxidized sulphur are described. The active site geometry suggests that a change in the conformation of the native thiol occurs upon diffusion of substrate into the active site cleft of DLH. This enables nucleophilic attack by the gamma-sulphur to occur on the cyclic ester substrate through a ring-opening reaction.
Unculturable bacterial communities provide a rich source of biocatalysts, but their experimental discovery by functional metagenomics is difficult, because the odds are stacked against the experimentor. Here we demonstrate functional screening of a million-membered metagenomic library in microfluidic picolitre droplet compartments. Using bait substrates, new hydrolases for sulfate monoesters and phosphotriesters were identified, mostly based on promiscuous activities presumed not to be under selection pressure. Spanning three protein superfamilies, these break new ground in sequence space: promiscuity now connects enzymes with only distantly related sequences. Most hits could not have been predicted by sequence analysis, because the desired activities have never been ascribed to similar sequences, showing how this approach complements bioinformatic harvesting of metagenomic sequencing data. Functional screening of a library of unprecedented size with excellent assay sensitivity has been instrumental in identifying rare genes constituting catalytically versatile hubs in sequence space as potential starting points for the acquisition of new functions.
        
Title: Directed evolution of new and improved enzyme functions using an evolutionary intermediate and multidirectional search Porter JL, Boon PL, Murray TP, Huber T, Collyer CA, Ollis DL Ref: ACS Chemical Biology, 10:611, 2015 : PubMed
The ease with which enzymes can be adapted from their native roles and engineered to function specifically for industrial or commercial applications is crucial to enabling enzyme technology to advance beyond its current state. Directed evolution is a powerful tool for engineering enzymes with improved physical and catalytic properties and can be used to evolve enzymes where lack of structural information may thwart the use of rational design. In this study, we take the versatile and diverse alpha/beta hydrolase fold framework, in the form of dienelactone hydrolase, and evolve it over three unique sequential evolutions with a total of 14 rounds of screening to generate a series of enzyme variants. The native enzyme has a low level of promiscuous activity toward p-nitrophenyl acetate but almost undetectable activity toward larger p-nitrophenyl esters. Using p-nitrophenyl acetate as an evolutionary intermediate, we have generated variants with altered specificity and catalytic activity up to 3 orders of magnitude higher than the native enzyme toward the larger nonphysiological p-nitrophenyl ester substrates. Several variants also possess increased stability resulting from the multidimensional approach to screening. Crystal structure analysis and substrate docking show how the enzyme active site changes over the course of the evolutions as either a direct or an indirect result of mutations.
        
Title: Crystallization of dienelactone hydrolase in two space groups: structural changes caused by crystal packing Porter JL, Carr PD, Collyer CA, Ollis DL Ref: Acta Crystallographica F Struct Biol Commun, 70:884, 2014 : PubMed
Dienelactone hydrolase (DLH) is a monomeric protein with a simple [alpha]/[beta]-hydrolase fold structure. It readily crystallizes in space group P212121 from either a phosphate or ammonium sulfate precipitation buffer. Here, the structure of DLH at 1.85 A resolution crystallized in space group C2 with two molecules in the asymmetric unit is reported. When crystallized in space group P212121 DLH has either phosphates or sulfates bound to the protein in crucial locations, one of which is located in the active site, preventing substrate/inhibitor binding. Another is located on the surface of the enzyme coordinated by side chains from two different molecules. Crystallization in space group C2 from a sodium citrate buffer results in new crystallographic protein-protein interfaces. The protein backbone is highly similar, but new crystal contacts cause changes in side-chain orientations and in loop positioning. In regions not involved in crystal contacts, there is little change in backbone or side-chain configuration. The flexibility of surface loops and the adaptability of side chains are important factors enabling DLH to adapt and form different crystal lattices.
        
Title: Following directed evolution with crystallography: structural changes observed in changing the substrate specificity of dienelactone hydrolase Kim HK, Liu JW, Carr PD, Ollis DL Ref: Acta Crystallographica D Biol Crystallogr, 61:920, 2005 : PubMed
The enzyme dienelactone hydrolase (DLH) has undergone directed evolution to produce a series of mutant proteins that have enhanced activity towards the non-physiological substrates alpha-naphthyl acetate and p-nitrophenyl acetate. In terms of steady-state kinetics, the mutations caused a drop in the K(m) for the hydrolysis reaction with these two substrates. For the best mutant, there was a 5.6-fold increase in k(cat)/K(m) for the hydrolysis of alpha-naphthyl acetate and a 3.6-fold increase was observed for p-nitrophenyl acetate. For alpha-naphthyl acetate the pre-steady-state kinetics revealed that the rate constant for the formation of the covalent intermediate had increased. The mutations responsible for the rate enhancements map to the active site. The structures of the starting and mutated proteins revealed small changes in the protein owing to the mutations, while the structures of the same proteins with an inhibitor co-crystallized in the active site indicated that the mutations caused significant changes in the way the mutated proteins recognized the substrates. Within the active site of the mutant proteins, the inhibitor was rotated by about 180 degrees with respect to the orientation found in the starting enzyme. This rotation of the inhibitor caused the displacement of a large section of a loop on one side of the active site. Residues that could stabilize the transition state for the reaction were identified.
        
Title: Monitoring key reactions in degradation of chloroaromatics by in situ (1)H nuclear magnetic resonance: solution structures of metabolites formed from cis-dienelactone Pieper DH, Pollmann K, Nikodem P, Gonzalez B, Wray V Ref: Journal of Bacteriology, 184:1466, 2002 : PubMed
A (1)H nuclear magnetic resonance ((1)H NMR) assay was used to study the enzymatic transformation of cis-dienelactone, a central intermediate in the degradation of chloroaromatics. It was shown that the product of the cis-dienelactone hydrolase reaction is maleylacetate, in which there is no evidence for the formation of 3-hydroxymuconate. Under acidic conditions, the product structure was 4-carboxymethyl-4-hydroxybut-2-en-4-olide. Maleylacetate was transformed by maleylacetate reductase into 3-oxoadipate, a reaction competing with spontaneous decarboxylation into cis-acetylacrylate. One-dimensional (1)H NMR in (1)H(2)O could thus be shown to be an excellent noninvasive tool for monitoring enzyme activities and assessing the solution structure of substrates and products.
        
Title: Structure of the C123S mutant of dienelactone hydrolase (DLH) bound with the PMS moiety of the protease inhibitor phenylmethylsulfonyl fluoride (PMSF) Robinson A, Edwards KJ, Carr PD, Barton JD, Ewart GD, Ollis DL Ref: Acta Crystallographica D Biol Crystallogr, 56:1376, 2000 : PubMed
The structure of DLH (C123S) with PMS bound was solved to 2.5 A resolution (R factor = 15.1%). PMSF in 2-propanol was delivered directly to crystals in drops and unexpectedly caused the crystals to dissolve. New crystals displaying a different morphology emerged within 2 h in situ, a phenomenon that appears to be described for the first time. The changed crystal form reflected altered crystal-packing arrangements elicited by structural changes to the DLH (C123S) molecule on binding inhibitor. The new unit cell remained in the P2(1)2(1)2(1) space group but possessed different dimensions. The structure showed that PMS binding in DLH (C123S) caused conformational changes in the active site and in four regions of the polypeptide chain that contain reverse turns. In the active site, residues with aromatic side chains were repositioned in an edge-to-face cluster around the PMS phenyl ring. Their redistribution prevented restabilization of the triad His202 side chain, which was disordered in electron-density maps. Movements of other residues in the active site were shown to be related to the four displaced regions of the polypeptide chain. Their implied synergy suggests that DLH may be able to accommodate and catalyse a range of compounds unrelated to the natural substrate owing to an inherent coordinated flexibility in its overall structure. Implications for mechanism and further engineering studies are discussed.
        
Title: Evolution of chlorocatechol catabolic pathways. Conclusions to be drawn from comparisons of lactone hydrolases Schlomann M Ref: Biodegradation, 5:301, 1994 : PubMed
The aerobic bacterial degradation of chloroaromatic compounds often involves chlorosubstituted catechols as central intermediates. They are converted to 3-oxoadipate in a series of reactions similar to that for catechol catabolism and therefore designated as modified ortho-cleavage pathway. Among the enzymes of this catabolic route, the chlorocatechol 1,2-dioxygenases are known to have a relaxed substrate specificity. In contrast, several chloromuconate cycloisomerases are more specific, and the dienelactone hydrolases of chlorocatechol catabolic pathways do not even convert the corresponding intermediate of catechol degradation, 3-oxoadipate enol-lactone. While the sequences of chlorocatechol 1,2-dioxygenases and chloromuconate cycloisomerases are very similar to those of catechol 1,2-dioxygenases and muconate cycloisomerases, respectively, the relationship between dienelactone hydrolases and 3-oxoadipate enol-lactone hydrolases is more distant. They seem to share an alpha/beta hydrolase fold, but the sequences comprising the fold are quite dissimilar. Therefore, for chlorocatechol catabolism, dienelactone hydrolases might have been recruited from some other, preexisting pathway. Their relationship to dienelactone (hydrolases identified in 4-fluorobenzoate utilizing strains of Alcaligenes and Burkholderia (Pseudomonas) cepacia is investigated). Sequence evidence suggests that the chlorocatechol catabolic operons of the plasmids pJP4, pAC27, and pP51 have been derived from a common precursor. The latter seems to have evolved for the purpose of halocatechol catabolism, and may be considerably older than the chemical industry.
        
Title: Substrate-induced activation of dienelactone hydrolase: an enzyme with a naturally occurring Cys-His-Asp triad Cheah E, Austin C, Ashley GW, Ollis D Ref: Protein Engineering, 6:575, 1993 : PubMed
The Cys-His-Asp catalytic triad found in dienelactone hydrolase (DLH) is unusual for several reasons. It has not been observed in other hydrolytic enzymes and it is virtually inactive when it is produced by site-directed mutagenesis in the proteases. We propose a model to explain why this triad is catalytically active in DLH but not in the proteases. In the resting state of DLH, His202 forms an ion pair with Asp171 and Cys123 exists as a thiol. The resting state thiol does not interact with His202 in the active site but instead forms a hydrogen bond with Glu36 in the interior of the molecule. In the absence of substrate, Glu36 is also ion paired with Arg206. When substrate binds, Arg206 forms a second ion pair with the anionic substrate and the Arg206/Glu36 ion pair weakens. The destabilized Glu36 carboxylate shifts towards and deprotonates the Cys123 thiol, thereby activating the nucleophile. As the thiolate anion is not energetically favoured in the hydrophobic interior of the enzyme, it swings into the active site where it can be stabilized by the His202 imidazolium and the dipole of helix C. The Cys123 thiolate which now lies adjacent to the acyl carbon of the substrate, is thus generated only in the presence of substrate. The mode of thiolate activation reduces the susceptibility of DLH towards thiol alkylating agents.
        
Title: Catalysis by dienelactone hydrolase: a variation on the protease mechanism Cheah E, Ashley GW, Gary J, Ollis D Ref: Proteins, 16:64, 1993 : PubMed
Dienelactone hydrolase (DLH), an enzyme from the beta-ketoadipate pathway, catalyzes the hydrolysis of dienelactone to maleylacetate. Our inhibitor binding studies suggest that its substrate, dienelactone, is held in the active site by hydrophobic interactions around the lactone ring and by the ion pairs between its carboxylate and Arg-81 and Arg-206. Like the cysteine/serine proteases, DLH has a catalytic triad (Cys-123, His-202, Asp-171) and its mechanism probably involves the formation of covalently bound acyl intermediate via a tetrahedral intermediate. Unlike the proteases, DLH seems to protonate the incipient leaving group only after the collapse of the first tetrahedral intermediate, rendering DLH incapable of hydrolyzing amide analogues of its ester substrate. In addition, the triad His probably does not protonate the leaving group (enolate) or deprotonate the water for deacylation; rather, the enolate anion abstracts a proton from water and, in doing so, supplies the hydroxyl for deacylation.
        
Title: Refined structure of dienelactone hydrolase at 1.8 A Pathak D, Ollis D Ref: Journal of Molecular Biology, 214:497, 1990 : PubMed
The structure of dienelactone hydrolase (DLH) from Pseudomonus sp. B13, after stereochemically restrained least-squares refinement at 1.8 A resolution, is described. The final molecular model of DLH has a conventional R value of 0.150 and includes all but the carboxyl-terminal three residues that are crystallographically disordered. The positions of 279 water molecules are included in the final model. The root-mean-square deviation from ideal bond distances for the model is 0.014 A and the error in atomic co-ordinates is estimated to be 0.15 A. DLH is a monomeric enzyme containing 236 amino acid residues and is a member of the beta-ketoadipate pathway found in bacteria and fungi. DLH is an alpha/beta protein containing seven helices and eight strands of beta-pleated sheet. A single 4-turn 3(10)-helix is seen. The active-site Cys123 residues at the N-terminal end of an alpha-helix that is peculiar in its consisting entirely of hydrophobic residues (except for a C-terminal lysine). The beta-sheet is composed of parallel strands except for strand 2, which gives rise to a short antiparallel region at the N-terminal end of the central beta-sheet. The active-site cysteine residue is part of a triad of residues consisting of Cys123, His202 and Asp171, and is reminiscent of the serine/cysteine proteases. As in papain and actinidin, the active thiol is partially oxidized during X-ray data collection. The positions of both the reduced and the oxidized sulphur are described. The active site geometry suggests that a change in the conformation of the native thiol occurs upon diffusion of substrate into the active site cleft of DLH. This enables nucleophilic attack by the gamma-sulphur to occur on the cyclic ester substrate through a ring-opening reaction.
        
Title: X-ray crystallographic structure of dienelactone hydrolase at 2.8 A Pathak D, Ngai KL, Ollis D Ref: Journal of Molecular Biology, 204:435, 1988 : PubMed
The structure of dienelactone hydrolase, an enzyme of the beta-ketoadipate pathway, has been determined at 2.8 A resolution using multiple isomorphous replacement techniques. An unambiguous assignment of C alpha atoms to electron density has been accomplished and a preliminary identification of the active site made. Dienelactone hydrolase is an alpha/beta protein consisting of an eight-stranded beta-pleated sheet with seven parallel strands, surrounded by seven helices. Preliminary enzyme inactivation data and an examination of the atomic model have implicated cysteine 123, histidine 202 and aspartate 171 with the active site of the enzyme. It is believed that the enzymic mechanism of dienelactone hydrolase may be similar to that of the thiol and serine proteases.
Crystal Structure Analysis of the dienelactone hydrolase mutant (C123S) bound with the PMS moiety of the protease inhibitor, Phenylmethylsulfonyl fluoride (PMSF) - 1.9 A.
Crystal Structure Analysis of the dienelactone hydrolase mutant (E36D, C123S) bound with the PMS moiety of the protease inhibitor, Phenylmethylsulfonyl fluoride (PMSF) - 1.7 A.
Crystal Structure Analysis of the dienelactone hydrolase mutant (E36D, C123S, A134T, S208G, A229V, K234R) bound with the PMS moiety of the protease inhibitor, Phenylmethylsulfonyl fluoride (PMSF) - 1.7 A.