(582dt) Immobilization of Amylase On Metal Ceramic Powder: Application for Efficient Starch Hydrolysis

Amylase, a kind of hydrolase which can convert starch
into reduced-sugars, syrups and dextrin, is an important biocatalyst in food
industry. Usually, amylase immobilized on the solid carriers which have
suitable hardness, density and porosity, seems to be the most appropriate way
for industrial application (Singh et al., 2013);
while physical adsorption between carrier and enzyme would just supply weak
affinity and covalent cross-linking may lead to the loss of enzyme activity. In
recent years, due to the high immobilization efficiency, simple immobilization
method and improved stability, enzyme immobilized through metal affinity has
attracted increasing attention (Ho et al., 2004). The metal ceramic, with
significant mechanical strength, electrical conductivity and abrasive
resistance, would be a suitable carrier for enzyme immobilizaton. While the
applications of metal ceramic on enzyme immobilization have been little
reported.

In this work, the ceramic powder with high metal content
(MCP) were prepared as a new kind of carrier for amylase immobilization. Cu-MCP
showed the best affinity to alpha-amylase and exhibited maximal activity (Fig.1a). The effects of metal content, chelation
time and amylase concentration on the immobilized amylase (Cu-MCP-amylase)
activity were investigated. Under the optimal preparation conditions, the
activity of Cu-MCP-amylase could reach 31.5 U/g (54.5 % of activity yield). Next,
the characterizations confirmed that the Cu-MCP was a superior carrier with
significant mechanical strength, considerable surface area, stable environment,
homogeneous surface and low cost. Meanwhile, the properties of Cu-MCP-amylase were
determined. It had optimal pH 7.0 and optimal temperature 70^oC with
improved thermal stability. Finally, Cu-MCP-amylase packed in a column reactor (Fig.1b) and showed significant catalytic capacity
and stability, which could retain 80% of initial catalytic capacity after 40
recycle times. Thus, MCP as a novel immobilization carrier, would enhance mass
transfer and supply stable environment, which could provide an efficient and
practical method for enzyme immobilization in industrial application.

This
research was supported by the NSF of China (20976125, 31071509,
51173128, 21206113) and Tianjin (10JCYBJC05100), the Ministry of Science and Technology of
China (Nos. 2012YQ090194, 2013AA102204, 2012BAD29B05), the Program for New
Century Excellent Talents in Chinese University (NCET-08-0386), and Beiyang
Young Scholar Program (2012).

References

[1] Ho, L.F., Li, S.Y., Lin, S.C., Hsu, W.H.
2004. Integrated enzyme purification and immobilization processes with
immobilized metal affinity adsorbents. Process Biochemistry, 39(11),
1573-1581.

[2] Singh, R.K., Tiwari, M.K., Singh, R.,
Lee, J.-K. 2013. From Protein Engineering to Immobilization: Promising
Strategies for the Upgrade of Industrial Enzymes. International journal of
molecular sciences, 14(1), 1232-1277.

Fig.1
Amylase immobilization and application for starch hydrolysis

a) Preparation of Cu-MCP-amylase. b)
Application of Cu-MCP-amylase for starch hydrolysis