Semirational Engineering Accelerates the Laboratory Evolution of Nitrilase Catalytic Efficiency for Nicotinic Acid Biosynthesis.

The nitrilase-mediated green synthesis of nicotinic acid, an important reaction in synthetic organic chemistry, has attracted considerable attention in recent years. However, the application potential of nitrilase is hindered by several limitations, such as low catalytic efficiency and byproduct formation. In this study, the site-saturation mutagenesis of asparagine 40, phenylalanine 50, and glutamine 207 in recombinant nitrilase from Pseudomonas putida CGMCC3830 was conducted to improve the specificity of nitrilase for nicotinic acid. The resulting mutants, which contain the mutations N40G (asparagine→glycine), F50W (phenylalanine→tryptophan), and Q207E (glutamine→glutamic acid), produced higher nicotinic acid yields than the wild type. Furthermore, double and triple mutations were introduced, and four mutants that contained N40G/F50W, N40G/Q207E, F50W/Q207E, and N40G/F50W/Q207E were obtained and evaluated for their capacity to produce nicotinic acid. The double mutant F50W/Q207E and the triple mutant N40G/F50W/Q207E displayed the highest activity, which was nearly twofold higher than that of the wild type. The kinetics analysis of nicotinic acid synthesis with the mutant nitrilase revealed the higher catalytic capability of all the mutants than the wild type. These results provide new insights into the catalytic performance of P. putida nitrilase toward 3-cyanopyridine to promote nicotinic acid production. [ABSTRACT FROM AUTHOR]