Phase transfer catalyzed bioconversion of penicillin G to 6-APA by immobilized penicillin acylase in recyclable aqueous two-phase systems with light/pH sensitive copolymers.
- Author:
Ke-ming JIN
1
;
Xue-jun CAO
;
Jin SU
;
Li MA
;
Ying-ping ZHUANG
;
Ju CHU
;
Si-liang ZHANG
Author Information
1. State Key Laboratory of Bioreactor Engineering, East China University of Science and Technology, Shanghai 200237, China.
- Publication Type:Journal Article
- MeSH:
Catalysis;
Enzymes, Immobilized;
metabolism;
Hydrogen-Ion Concentration;
Kinetics;
Penicillanic Acid;
analogs & derivatives;
chemistry;
metabolism;
Penicillin Amidase;
metabolism;
Penicillin G;
chemistry;
metabolism;
Phase Transition;
Polymers;
chemistry;
Substrate Specificity
- From:
Journal of Southern Medical University
2008;28(3):360-362
- CountryChina
- Language:Chinese
-
Abstract:
Immobilized penicillin acylase was used for bioconversion of penicillin PG into 6-APA in aqueous two-phase systems consisting of a light-sensitive polymer PNBC and a pH-sensitive polymer PADB. Partition coefficients of 6-APA was found to be about 5.78 in the presence of 1% NaCl. Enzyme kinetics showed that the reaction reached equilibrium at roughly 7 h. The 6-APA mole yields were 85.3% (pH 7.8, 20 degrees C), with about 20% increment as compared with the reaction of single aqueous phase buffer. The partition coefficient of PG (Na) varied scarcely, while that of the product, 6-APA and phenylacetic acid (PA) significantly varied due to Donnan effect of the phase systems and hydrophobicity of the products. The variation of the partition coefficients of the products also affected the bioconversion yield of the products. In the aqueous two-phase systems, the substrate, PG, the products of 6-APA and PA were biased in the top phase, while immobilized penicillin acylase at completely partitioned at the bottom. The substrate and PG entered the bottom phase, where it was catalyzed into 6-APA and PA and entered the top phase. Inhibition of the substrate and products was removed to result in improvement of the product yield, and the immobilized enzyme showed higher efficiency than the immobilized cells and occupied smaller volume. Compared with the free enzyme, immobilized enzyme had greater stability, longer life-time, and was completely partitioned in the bottom phase and recycle. Bioconversion in two-phase systems using immobilized penicillin acylase showed outstanding advantage. The light-sensitive copolymer forming aqueous two-phase systems could be recovered by laser radiation at 488 nm or filtered 450 nm light, while pH-sensitive polymer PADB could be recovered at the isoelectric point (pH 4.1). The recovery of the two copolymers was between 95% and 99%.
