• 文献标题:   A universal aptasensing platform based on cryonase-assisted signal amplification and graphene oxide induced quenching of the fluorescence of labeled nucleic acid probes: application to the detection of theophylline and ATP
  • 文献类型:   Article
  • 作  者:   LOU YF, PENG YB, LUO XW, YANG ZM, WANG RF, SUN DW, LI LXY, TAN YY, HUANG JH, CUI L
  • 作者关键词:   aptamer, atp, detection limit, nucleic acid molecular probe, theophylline, signal amplification
  • 出版物名称:   MICROCHIMICA ACTA
  • ISSN:   0026-3672 EI 1436-5073
  • 通讯作者地址:   Zhejiang Sci Tech Univ
  • 被引频次:   12
  • DOI:   10.1007/s00604-019-3596-1
  • 出版年:   2019

▎ 摘  要

This study describes a universal fluorometric method for sensitive detection of analytes by using aptamers. It is based on the use ofgraphene oxide (GO) and cryonase-assisted signal amplification. GO is a strong quencher of FAM-labeled nucleic acid probes, while cryonase digests all types of nucleic acid probes. This makes the platform widely applicable to analytes for which the corresponding aptamers are available. Theophylline and ATP were chosen as model analytes. In the absence of targets, dye-labeled aptamers are in a flexible single strand state and adsorb on the GO.As a result, the probes are non-fluorescent due to the efficient quenching of dyes by GO. Upon the addition of a specific target, the aptamer/target complex desorbed from the GO surface and the probe becomes fluorescent. The released complex will immediately become a substrate for cryonase digestion and subsequently releasing the target to bind to another aptamer to initiate the next round of cleavage. This cyclic reaction will repeat again and again until all the related-probes are consumed and all fluorophores light up, resulting in significant fluorescent signal amplification. The detection limits are 47nM for theophylline and 22.5nM for ATP. This is much better than that of known methods. The assay requires only mix-and-measure steps that can be accomplished rapidly. In our perception, the detection scheme holds great promise for the design enzyme-aided amplification mechanisms for use in bioanalytical methods.