Litcius/Paper detail

Upconversion Luminescence-Controlled DNA Computation for Spatiotemporally Resolved, Multiplexed Molecular Imaging

Yongsheng Mi, Jian Zhao, Hongqian Chu, Zhixiang Li, Mingming Yu, Lele Li

2021Analytical Chemistry53 citationsDOI

Abstract

DNA-based molecular circuits able to perform complex information processing in biological systems are highly desirable. However, conventional DNA circuits are constitutively always in an ON state and immediately operate when they meet the biomolecular inputs, precluding precise molecular computation at a desired time and in a desired site. In this work, we report a conceptual methodology for the construction of photonic nanocircuits that enable DNA molecular computation in vitro and in vivo with high spatial precision. Upon remote activation by spatially restricted NIR-light input, two types of cancer biomarker inputs can sequentially trigger conformational changes of the DNA circuit through a structure-switching aptamer and toehold-mediated strand exchange, leading to release of a signaling output. Of note, the NIR-light-gated nanocircuit allows for intended control over the specific timing and location of DNA computation, providing spatial and temporal capabilities for multiplexed imaging. Furthermore, an OR-AND-gated nanocircuit of higher complexity was designed to illustrate the versatility of our approach. The present work illustrates the potential of the use of upconversion nanotechnology as a regulatory tool for spatial and temporal control of DNA computation in cells and animals.

Topics & Concepts

ComputationMultiplexingChemistryDNABiological systemNanotechnologyComputer scienceAlgorithmMaterials scienceBiologyTelecommunicationsBiochemistryAdvanced biosensing and bioanalysis techniquesMolecular Communication and NanonetworksBiosensors and Analytical Detection