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Reduced Graphene Oxide-Zirconium Dioxide-Thionine Nanocomposite Integrating Recognition, Amplification, and Signaling for an Electrochemical Assay of Protein Kinase Activity and Inhibitor Screening.

Zhiqiang ChenYing LiuLijie HaoZhencai ZhuFang LiShu-Feng Liu
Published in: ACS applied bio materials (2018)
Protein kinase activity analysis is essential and important for elucidation of many fundamental biological processes, disease diagnosis, and drug discovery. Herein, a novel electrochemical biosensing method for protein kinase (PKA) activity was demonstrated by the use of a reduced graphene oxide-zirconium dioxide-thionine (rGO-ZrO 2 -Thi) nanocomposite, which interestingly served as an integral phosphopeptide-recognizing, signal amplifying and reporting platform. The ZrO 2 nanoparticle-decorated reduced graphene oxide (rGO-ZrO 2 ) was first prepared by a hydrothermal reaction route, and then the thionine was conjugated onto the rGO surface via π-π stacking as an excellent electrochemical probe. The prepared rGO-ZrO 2 -Thi nanocomposites were well-characterized by various techniques. With the full advantage of specific recognition of ZrO 2 nanoparticles for the phosphate group, signal amplification, and transduction of abundant thionines onto the rGO surface, and excellent conductivity of rGO, the rGO-ZrO 2 -Thi nanocomposite endowed a label-free and one-step electrochemical analysis of kemptide phosphorylation catalyzed by PKA. The detection limit for PKA activity was experimentally achieved as 0.005 U/mL, which was evidently lower than most of the reported methods. The proposed sensing strategy could be also applied for an efficient inhibitor evaluation. Therefore, it offered an excellent pathway for a generic and sensitive electrochemical assay of PKA activity and inhibitor.
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