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  • Title: Fluorometric determination of RNase H via a DNAzyme conjugated to reduced graphene oxide, and its application to screening for inhibitors and activators.
    Author: Tong C, Zhou T, Zhao C, Yuan L, Xu Y, Liu B, Fan J, Li D, Zhu A.
    Journal: Mikrochim Acta; 2019 May 07; 186(6):335. PubMed ID: 31065868.
    Abstract:
    A new fluorometric method is delineated for the detection of RNase H activity by combining DNAzyme with reduced graphene oxide (rGO). In the absence of RNase H, the fluorescence of FAM-labeled probe is quenched due to the strong adsorption on the rGO. The presence of RNase H can release the active DNAzyme from the DNA-RNA chimeric strand. This triggers the cleavage of the signal probe at the rA site with the help of the cofactor Mg2+. The recycle cleavage can directly result in the amplified signal emitted by the FAM-labeled short fragment. The method allows the activity of RNase H to be detected in a linear range of 0.01 to 5 U·mL-1. The detection limit of 0.018 U·mL-1 is calculated by the principle of three-time standard deviation over the blank signal. Then, RNase H-targeting natural compounds were screened for their inhibitory action. Among the investigated compounds, five were screened as RNase H inhibitors in a concentration-dependent manner, and 4 compounds were identified as activators. Finally, the method was reliably used for discriminating the difference of RNase H activity in human serum. It is found that RNase H activity was upregulated in patients with hepatitis C virus infection. Graphical abstract The schematic presentation of rGO-DNAzyme-based RNase H detection. RNase H triggers the active DNAzyme releasing from the DNA-RNA chimeric strand, which can cleavage probes to FAM-labeled short fragments and make the fluorescence signal cycle amplified.
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