Dual signal amplification-integrated single-molecule biosensing of flap endonuclease 1 in breast cancer tissues

Abstract

Flap endonuclease 1 (FEN1) is a structure-specific nuclease that may act as a valuable biomarker for cancer diagnosis. Herein, we construct a dual signal amplification-integrated single-molecule fluorescent biosensor for ultrasensitive detection of FEN1 in breast cancer tissues. We design a triplex DNA containing a flap structure for both recognizing and amplifying FEN1 signal. When FEN1 is present, flap is specifically cleaved by FEN1 and released from triplex DNA to form a short ssDNA strand with free 3' OH terminus, and the resultant ssDNA can serve as the primer and binds to circular template in triplex DNA to trigger rolling circle amplification (RCA), generating a long ssDNA product with abundant repeated activator sequences. The hybridization of the resultant activators with crRNAs subsequently activates Cas12a to catalyze trans-cleavage of Cy5- and BHQ-labeled probes to restore Cy5 fluorescence that can be quantified by single-molecule detection. Notably, only a single triplex DNA is required for both initiating and implementing RCA, greatly simplifying the reaction system and eliminating nonspecific amplification. This biosensor exhibits ultrahigh sensitivity with a detection limit of 2.24 × 10-5 U/μL, facilitating accurate detection of endogenous FEN1 activity with single-cell sensitivity and discrimination of different FEN1 levels in clinical breast cancer tissues.