An enzymatically activated self-powered and self-recycled strategy for in situ tumor cell-specific molecular imaging

Abstract

Specific imaging of tumor cells with high sensitivity is urgently needed for evaluating the risk of tumor metastasis and progression. However, traditional tumor cell imaging strategies are still restricted by limited tumor specificity and sensitivity due to off-tumor signal leakage and a lower content of the targets. Therefore, a self-powered and self-recycled strategy based on molecular beacon (MB) hybridized on tetrahedral framework DNA (E-MB-tFNA) using the endogenous enzyme, apurinic/apyrimidinic endonuclease 1 (APE1), was rationally developed for tumor cell-specific molecular imaging with superior spatial specificity and improved sensitivity. The apurinic/apyrimidinic site (AP site) can be specifically recognized and cleaved by APE1, and was modified on the stem and loop region of E-MB-tFNA. The resultant E-MB-tFNA can be specifically recognized and cleaved by APE1 in the cytoplasm, which is overexpressed in tumor cells compared to normal cells. In particular, once APE1 cleaves the AP site on the stem region (double-stranded DNA) of E-MB-tFNA, the self-powered and self-recycled sequences modified on the stem region of E-MB-tFNA is freed to hybridize with the loop region of E-MB-tFNA, prompting APE1 to further hydrolyze the E-MB-tFNA loop region and generate fluorescence signals. In addition, the self-powered and self-recycled sequences can be hybridized with other E-MB-tFNA to continuously and cyclically amplify the fluorescence signal. The experimental results of this study showed that the E-MB-tFNA has the capability to monitor drug resistance and achieve guided precision surgical excision in vivo with superior spatial specificity and improved sensitivity. In particular, E-MB-tFNA can realize the risk classification of neuroblastoma patients in clinical plasma.