A integrated process for nitrilase-catalyzed asymmetric hydrolysis and easy biocatalyst recycling by introducing biocompatible biphasic system.

The whole-cell nitrilase-catalyzed asymmetric hydrolysis of nitriles is a green and efficient preparation approach for chiral carboxylic acids, but often suffers from toxicity and cell lysis from organic substrates. In this work, a novel integrated process for whole-cell nitrilase-catalyzed asymmetric hydrolysis was developed for the first time by introducing a biocompatible ionic liquid (IL)-based biphasic system. The whole-cell nitrilases displayed an outstanding stability and recyclability in the biphasic system and still retained > 85% activity even after 7 cycles reaction. A preparative-scale fed-batch hydrolysis of o-chloromandelonitrile to (R)-o-chloromandelic acid (R-CMA) was performed using the integrated process. The results revealed a yield of 91.3% and a space-time yield of 746.4 g·L-1·d-1, which are currently the highest reported values for R-CMA biosynthesis. The proposed integrated process avoids substrate inhibition, facilitates the reusability of whole-cell nitrilases, and thus shows great potential for the sustainable production of chiral carboxylic acids.

Improving catalytic performance of an arylacetonitrilase by semirational engineering.

Arylacetonitrilases have been widely acknowledged as important alternatives to chemical catalysts for synthesizing optically pure 2-hydroxyphenylacetic acids from nitriles. In this work, two residues (Thr132 and Ser190) located at the catalytic tunnel in the active site of an arylacetonitrilase nitA from uncultured organisms were mutated separately by site-directed mutagenesis. Ser190 was demonstrated to be the critical position which has a greater influence on arylacetonitrilase nitA activity than Thr132. The replacement of serine at position 190 with glycine increases its activity toward mandelonitrile and (o, m, p)-chloromandelonitrile, whereas replacing it with leucine abolished its activity. The best mutant S190G exhibited threefold higher specific activity toward mandelonitrile compared with that of wild-type nitA, which rendered it promising for industrial application. Homology modeling and molecular docking experiments were in agreement with the kinetic assays and support the improved catalytic performance.