Single stage bi-substrate transglycosylation reaction for the synthesis of ascorbic acid 2 glucoside using immobilized α-glucosidase

Abstract

Alpha glucosidases are multifunctional glycoside hydrolases with hydrolysis and transglycosylation ability. It can be utilized for the glycosidic bond synthesis or glycosylation of Ascorbic acid/Vitamin C to its stable analogue, Ascorbic acid 2 glucoside (AA2G), a compound with wide applications in cosmetics and pharma. The application of α-glucosidases for industrial scale transglycosylation is limited due to the low transglycosylation yield of free enzymes. Enzyme immobilization techniques could enable the development of efficient, reusable catalysts. Only a few glycoside hydrolases have been studied in immobilized form for transglycosylation reactions, and α-glucosidases are probably the least explored in this form. Transglycosylation activity of immobilized α-glucosidase from Aspergillus carbonarius BTCF 5 was studied for AA2G synthesis, where different immobilization techniques like calcium alginate encapsulation, adsorption on chitosan beads, covalent cross-linking on magnetic nanoparticles, and cross-linked enzyme aggregates (CLEA) were employed for the immobilization. The immobilization yield of calcium alginate encapsulated enzyme, enzyme immobilized on Fe-MNP support, enzyme immobilized on chitosan beads and as CLEA were 107%, 99%, 46% and 486%, respectively. CLEA was identified as the best immobilization technique for this bi-substrate reaction due to the high immobilization yield and activity retention (30% activity retained after 5 consecutive cycles). Enzyme immobilization increased the transglycosylation activity by 38%, yielding 118 mM AA2G against 72 mM by the free enzyme. This indicates the potential of immobilized α-glucosidase as a catalyst for synthesizing AA2G at an industrial scale.