Litcius/Paper detail

Construction of Fluorescent G-Quadruplex Nanowires for Label-Free and Accurate Monitoring of Circular RNAs in Breast Cancer Cells and Tissues with Low Background

Shu-hua Wei, Jinping Hu, Zhimei Sheng, Qian Zhang, Jie Zhang, Baogang Zhang, Meng Liu, Chun‐yang Zhang

2023Analytical Chemistry19 citationsDOI

Abstract

Circular RNAs (circRNAs) represent an emerging category of endogenous transcripts characterized by long half-life time, covalently closed structures, and cell-/tissue-specific expression patterns, making them potential disease biomarkers. Herein, we demonstrate the construction of fluorescent G-quadruplex nanowires for label-free and accurate monitoring of circular RNAs in breast cancer cells and tissues by integrating proximity ligation-rolling circle amplification cascade with lighting up G-quadruplex. The presence of target circRNA facilitates the SplintR ligase-mediated ligation of the padlock probe. Upon the addition of primers, the ligated padlock probe can serve as a template to initiate subsequent rolling circle amplification (RCA), generating numerous long G-quadruplex nanowires that can incorporate with thioflavin T (ThT) to generate a remarkably improved fluorescence signal. Benefiting from good specificity of SplintR ligase-mediated ligation reaction and exponential amplification efficiency of RCA, this strategy can sensitively detect target circRNA with a limit of detection of 4.65 × 10 –18 M. Furthermore, this method can accurately measure cellular circRNA expression with single-cell sensitivity and discriminate the circRNA expression between healthy para-carcinoma tissues and breast cancer tissues, holding great potential in studying the pathological roles of circRNA and clinic diagnostics.

Topics & Concepts

Rolling circle replicationChemistryG-quadruplexCircular RNAFluorescenceDNA ligaseLigationComputational biologyMolecular biologyCell biologyRNABiochemistryDNABiologyPolymeraseGenePhysicsQuantum mechanicsCircular RNAs in diseasesSemiconductor materials and interfacesMXene and MAX Phase Materials