Improved thermostability and the optimum temperature of Rhizopus arrhizus lipase by directed evolution

To expand the functionality of lipase from Rhizopus arrhizus (RAL) we have used error-prone PCR and DNA shuffling methods to create RAL mutants with improved thermostability and the optimum temperature. One desirable mutant with three amino acids substitution was obtained. The mutated lipase was purified and characterized. The optimum temperature of the mutant lipase was higher by 10 °C than that of the wild-type RAL (WT-RAL). In addition, the thermostability characteristic of the mutant was also improved as the result of directed evolution. The half-life (T1/2) at 50 °C of the mutant exceeded those of WT-RAL by 12-fold. To confirm which substitution contributed to enhance thermostability and the optimum temperature for lipase activity, three chimeric lipases: chimeric lipase 1(CL-1; A9T), chimeric lipase 2 (CL-2; E190V) and chimeric lipase 3 (CL-3; M225I) from the WT-RAL gene were constructed. Each of the chimeric enzymes was purified and characterized. Amino acid substitution at position 190 was determined to be critical for lipase thermostability and the optimum temperature, while the residue at position 9 and 225 had only marginal effect. The mutational effect is interpreted according to a simulated three-dimensional structure for the mutant lipase.