Thermostable [alpha]-amylase immobilization: Enhanced stability and performance for starch biocatalysis

The uses of thermostable starch hydrolytic biocatalysts are steadily increasing for the industrial application because of their obvious need for biocatalytic performance at elevated temperatures. The starch liquefaction and saccharification can be carried out simultaneously by the use of thermostabl...

Full description

Saved in:
Bibliographic Details
Published in:Biotechnology and applied biochemistry 2016-01, Vol.63 (1), p.57
Main Authors: Kumar, Gudi Satheesh, Rather, Gulam Mohmad, Gurramkonda, Chandrasekhar, Reddy, Bontha Rajasekhar
Format: Article
Language:English
Subjects:
Biocatalysts
Enzymes
High temperature
Kinetics
Liquefaction
Silicon
Starch
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The uses of thermostable starch hydrolytic biocatalysts are steadily increasing for the industrial application because of their obvious need for biocatalytic performance at elevated temperatures. The starch liquefaction and saccharification can be carried out simultaneously by the use of thermostable starch hydrolytic biocatalysts, thus minimizing the unit operations, time, and efforts. The cost factor hampers the industrialization of expensive soluble (free) enzymes for biocatalytic applications and the immobilization of enzymes offers promising alternative to the hurdle. The present investigation was aimed for immobilization of thermostable [alpha]-amylase using calcium alginate, and statistical optimization studies were carried out for enhanced biocatalytic performance. Initially, one-parameter at a time optimization studies were carried out for identification of significant factors influencing the immobilization. Furthermore, a statistical approach, response surface methodology, was applied for immobilization of [alpha]-amylase. The immobilized [alpha]-amylase in alginate microbeads showed enhanced stability to temperature and reusable property for up to seven cycles (with the retention of 50% initial activity). Finally, the kinetic behavior of free and immobilized enzyme showed the Km value of 1.2% and 2.6% (w/v) and Vmax of 1,020 and 1,030 U, respectively. Fifty percent reduction in affinity of the immobilized enzyme toward substrate was compensated by its longer stability.
ISSN:0885-4513
1470-8744
DOI:10.1002/bab.1350