Substrate Report for: 3-Oxoadipate-enol-lactone

Lactones are a class of structurally diverse molecules that serve essential roles in biological processes ranging from quorum sensing to the aerobic catabolism of aromatic compounds. Not surprisingly, enzymes involved in the bioprocessing of lactones are often targeted for protein engineering studies with the potential, for example, of optimized bioremediation of aromatic pollutants. The enol-lactone hydrolase (ELH) represents one such class of targeted enzymes and catalyzes the conversion of 3-oxoadipate-enol-lactone into the linear beta-ketoadipate. To define the structural details that govern ELH catalysis and assess the impact of divergent features predicted by sequence analysis, we report the first structural characterization of an ELH (PcaD) from Burkholderia xenovorans LB400 in complex with the product analog levulinic acid. The overall dimeric structure of PcaD reveals an alpha-helical cap domain positioned atop a core alpha/beta-hydrolase domain. Despite the localization of the conserved catalytic triad to the core domain, levulinic acid is bound largely within the region of the active site defined by the cap domain, suggesting a key role for this divergent substructure in mediating product release. Furthermore, the architecture of the cap domain results in an unusually deep active-site pocket with topological features to restrict binding to small or kinked substrates. The evolutionary basis for this substrate selectivity is discussed with respect to the homologous dienelactone hydrolase. Overall, the PcaD costructure provides a detailed insight into the intimate role of the cap domain in influencing all aspects of substrate binding, turnover, and product release.

The pca operon from the Gram- bacterium Acinetobacter calcoaceticus encodes all of the enzymes required for catabolism of protocatechuate to common intermediary metabolites. This report presents the 2754-nucleotide (nt) sequence of a HindIII restriction fragment containing pcaD, the 801-bp gene encoding beta-ketoadipate enol-lactone hydrolase I. The deduced primary structure of A. calcoaceticus PcaD shares 44% amino acid (aa) sequence identity with the aligned primary structure of CatD (beta-ketoadipate enol-lactone hydrolase II) from the same organism, and the overall nt sequence identity of the two genes is 51.8%. In the 56% of the genes where selection for identical aa residues was not imposed, pcaD and catD have diverged so extensively that nt sequence identity of the aligned segments is only 28.2%; the G+C contents of these segments from the respective genes differ by 8%. Conserved within the aligned PcaD and CatD aa sequences is a Ser residue corresponding to the nucleophile within the alpha/beta-fold of many hydrolytic enzymes. In this region of primary structure, PcaD and CatD appear to have maintained some different aa sequences derived from a common ancestor. Conservation of the different aa sequences during extreme evolutionary divergence suggests that separate segments of primary structure, conserved within either PcaD or CatD, may be functionally incompatible within recombinant enzymes. Consequently, selection for avoidance of genetic exchange between pcaD and catD could account for the thorough nt substitution in regions where identical aa were not selected. Sequence repetitions within pcaD suggest that the multiple mutations required for its extensive divergence from catD were achieved in part by acquisition of a complex DNA slippage structure.