Highly efficient production of inverted syrup in an analytical column with immobilized invertase

Production, immobilization and application of invertase from new wild strain Cunninghamella echinulata PA3S12MM

AIMS

The objective of this study was to determine the best conditions to produce invertase by Cunninghamella echinulata PA3S12MM and to immobilize and apply the enzyme.

METHODS AND RESULTS

The maximum production was verified in 8 days of cultivation at 28°C supplemented with 10 g L^-1 apple peel, reaching 1054.85 U ml^-1 . The invertase was purified from the DEAE-Sephadex column. The derivative immobilized in alginate-gelatin-calcium phosphate showed reusability >50% for 19 cycles. The derivative immobilized in glutaraldehyde-chitosan showed greater thermostability and at a different pH. The hydrolysis of 15 ml of sucrose 500 g L^-1 in a fixed bed reactor (total volume of 31 ml) produced 24.44 µmol min^-1 of glucose and fructose at a residence time of 30 min and a conversion factor of 0.5.

CONCLUSIONS

The new wild strain C. echinulata PA3S12MM presents high invertase production in medium supplemented with an agro-industrial residue and the immobilized enzyme showed high thermal stability and resistance at a different pH.

SIGNIFICANCE AND IMPACT OF THE STUDY

The fungus C. echinulata PA3S12MM is an excellent producer of invertases in Vogel medium supplemented with apple peel. The enzyme is promising for industrial application since it has good performance in reusability and inverted sugar production.

Highly reusable invertase biocatalyst: Biological fibrils functionalized by photocrosslinking

Here we report a novel strategy for the immobilization of invertase using amyloid-like fibrils as a support. Optimal conditions to get Tyr-Tyr covalent binding between invertase and the support were determined using a photocrosslinking approach. The biological fibrils with invertase activity turn into microstructured catalysts according to electron microscopy outcomes. Thermal and storage stability as well as optimal pH and temperature of the enzyme were conserved. Moreover, the immobilized enzyme recovered by low g-force centrifugation retained 83% of its initial enzymatic activity after 15 reuse cycles. Considering that enzyme cost is the most significant part of the overall fee of enzymatic biomass conversion, the highly efficient recovery/reuse strategy described herein becomes relevant. Besides, it can also be applied to the immobilization of other enzymes for industrial biocatalysis.