Immobilization of metallothionein on highly oriented pyrolytic graphite for biosensor design

Abstract

AbstractImmobilization of protein molecules on solid supports or surfaces in a controlled fashion is an important task for protein analysis at the solid/solution or solid/gas interface and biosensor fabrication. In this paper, the structure and biological activities of metallothionein (MT) layers immobilized on highly oriented pyrolytic graphite (HOPG) surfaces by means of two different strategies based on unspecific adsorption/chemisorption (MT‐HOPG system) and covalent binding (MT‐modified HOPG system) were studied respectively. The MT layers obtained by covalent binding to a previously functionalized HOPG surface are smooth and show a close‐packed ordered monolayer in contrast to those obtained by direct adsorption of the protein on substrate, which are disordered and relatively rough. Both adsorbed proteins exhibit reversible electron transfer at 0.25 V (Ag/AgCl) after immersion in CuSO4 solution, whereas redox current of MT‐modified HOPG system is four times larger than that of MT‐HOPG system. Moreover, the MTs adsorbed on bare HOPG surfaces are obviously denatured. All the above results show that covalent binding strategies lead to high structural regularity and mechanical stability of the adsorbed protein molecules with a maintained biological activity, which is prospective for applications in immobilizing MT on a transducer for biosensor design. Copyright © 2009 John Wiley & Sons, Ltd.