Control of lipase enantioselectivity by engineering the substrate binding site and access channel.

Lipase from Burkholderia cepacia (BCL) has proven to be a very useful biocatalyst for the resolution of 2-substituted racemic acid derivatives, which are important chiral building blocks. Our previous work showed that enantioselectivity of the wild-type BCL could be improved by chemical engineering of the substrate's molecular structure. From this earlier study, three amino acids (L17, V266 and L287) were proposed as targets for mutagenesis aimed at tailoring enzyme enantioselectivity. In the present work, a small library of 57 BCL single mutants targeted on these three residues was constructed and screened for enantioselectivity towards (R,S)-2-chloro ethyl 2-bromophenylacetate. This led to the fast isolation of three single mutants with a remarkable tenfold enhanced or reversed enantioselectivity. Analysis of substrate docking and access trajectories in the active site was then performed. From this analysis, the construction of 13 double mutants was proposed. Among them, an outstanding improved mutant of BCL was isolated that showed an E value of 178 and a 15-fold enhanced specific activity compared to the parental enzyme; thus, this study demonstrates the efficiency of the semirational engineering strategy.

Insights into lid movements of Burkholderia cepacia lipase inferred from molecular dynamics simulations.

The interfacial activation of many lipases at water/lipid interface is mediated by large conformational changes of a so-called lid subdomain that covers up the enzyme active site. Here we investigated using molecular dynamic simulations in different explicit solvent environments (water, octane and water/octane interface) the molecular mechanism by which the lid motion of Burkholderia cepacia lipase might operate. Although B. cepacia lipase has so far only been crystallized in open conformation, this study reveals for the first time the major conformational rearrangements that the enzyme undergoes under the influence of the solvent, which either exposes or shields the active site from the substrate. In aqueous media, the lid switches from an open to a closed conformation while the reverse motion occurs in organic environment. In particular, the role of a subdomain facing the lid on B. cepacia lipase conformational rearrangements was investigated using position-restrained MD simulations. Our conclusions indicate that the sole mobility of alpha9 helix side-chains of B. cepacia lipase is required for the full completion of the lid conformational change which is essentially driven by alpha5 helix movement. The role of selected alpha5 hydrophobic residues on the lid movement was further examined. In silico mutations of two residues, V138 and F142, were shown to drastically modify the conformational behavior of B. cepacia lipase. Overall, our results provide valuable insight into the role played by the surrounding environment on the lid conformational rearrangement and the activation of B. cepacia lipase.

The full-length mu-opioid receptor: a conformational study by circular dichroism in trifluoroethanol and membrane-mimetic environments.

The secondary structure content of the recombinant human mu-opioid receptor (HuMOR) solubilized in trifluoroethanol (TFE) and in detergent micelles was investigated by circular dichroism. In both conditions, this G protein-coupled receptor adopts a characteristic alpha-helical structure, with minima at 208 and 222 nm as observed in the circular dichroism spectra. After deconvolution of spectra, the alpha-helix contents were estimated to be in the range of 50% in TFE and in sodium dodecyl sulfate at pH 6. These values are in accordance with the predicted secondary structure content determined for the mu-opioid receptor. A pH-dependent effect was observed on the secondary structure of the receptor solubilized in detergents, which demonstrates the essential role of ionic and hydrophobic interactions on the secondary structure. Circular dichroism spectra of EGFP-HuMOR, a fusion protein between the enhanced green fluorescent protein (EGFP) and the mu-opioid receptor, and EGFP solubilized in TFE were also analyzed as part of this study.

A structure-controlled investigation of lipase enantioselectivity by a path-planning approach.

A novel approach based on efficient path-planning algorithms was applied to investigate the influence of substrate access on Burkholderia cepacia lipase enantioselectivity. The system studied was the transesterification of 2-substituted racemic acid derivatives catalysed by B. cepacia lipase. In silico data provided by this approach showed a fair qualitative agreement with experimental results, and hence the potential of this computational method for fast screening of racemates. In addition, a collision detector algorithm used during the pathway searches enabled the rapid identification of amino acid residues hindering the displacement of substrates along the deep, narrow active-site pocket of B. cepacia lipase and thus provided valuable information to guide the molecular engineering of lipase enantioselectivity.

Small-scale production of Burkholderia cepacia ATCC21808 lipase adapted to high-throughput screening.

The screening of variant libraries of recombinant Burkholderia cepacia ATCC21808 lipase generated in Escherichia coli is limited by expression difficulties that are mainly due to the formation of inclusion bodies. To circumvent these difficulties and provide an efficient small-scale screening protocol, the gene encoding the lipase from B. cepacia was expressed in various expression vectors. With the pFLAG-ATS-Lip-Hp construct, expression of up to 6807 U/L of culture was possible in Erlenmeyer flasks. The production protocol was miniaturized in 96 deep-well plates, yielding 1300 U/L of lipase in fusion with the FLAG tag. With this protocol, the activity was determined in less than 10 min for a full plate, with a coefficient of variance of about 25%. For validation, 18 mutants constructed by site-directed mutagenesis on position Valine 266 were screened. Nice variations of activity were detected and found to be in agreement with those obtained in Erlenmeyer flask cultures. The protocol enabled the identification of 5 mutants showing enhanced activity toward para-nitrophenyl butyrate.