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Intracellular Entropy‐Driven Multi‐Bit DNA Computing for Tumor Progression Discrimination

Min Bai, Feng Chen, Xiaowen Cao, Yue Zhao, Yue Zhao, Jing Xue, Xu Yu, Chunhai Fan, Yongxi Zhao, Yongxi Zhao

2020Angewandte Chemie International Edition120 citationsDOI

Abstract

Tumor progressions such as metastasis are complicated events that involve abnormal expression of different miRNAs and enzymes. Monitoring these biomolecules in live cells with computational DNA nanotechnology may enable discrimination of tumor progression via digital outputs. Herein, we report intracellular entropy-driven multivalent DNA circuits to implement multi-bit computing for simultaneous analysis of intracellular telomerase and microRNAs including miR-21 and miR-31. These three biomolecules can trigger respective DNA strand displacement recycling reactions for signal amplification. They are visualized by fluorescence imaging, and their signal outputs are encoded as multi-bit binary codes for different cell types. The results can discriminate non-tumorigenic, malignant and metastatic breast cells as well as respective tumors. This DNA computing circuit is further performed in a microfluidic chip to differentiate rare co-cultured cells, which holds a potential for the analysis of clinical samples.

Topics & Concepts

IntracellularComputer scienceEntropy (arrow of time)Cell biologyPhysicsBiologyThermodynamicsAdvanced biosensing and bioanalysis techniquesDNA and Biological ComputingGene expression and cancer classification
Intracellular Entropy‐Driven Multi‐Bit DNA Computing for Tumor Progression Discrimination | Litcius