Fundamental Research (Nov 2021)
Programming cell entry of molecules via reversible synthetic DNA circuits on cell membrane
Abstract
Cellular uptake of biomolecules is crucial for regulating cell function. However, powerful and biocompatible tools for dynamically manipulating the cell entry of single-stranded DNAs (ssDNAs) remain elusive. Herein, we constructed synthetic DNA circuits on the cell membrane to program the cell entry of ssDNAs, using toehold-mediated DNA strand displacement reactions. We found that the dimerization and trimerization of cholesterol-ssDNAs enhanced membrane-anchoring and cellular uptake of ssDNAs. Moreover, we demonstrated that de-dimerization and de-trimerization of cholesterol-ssDNAs could be accomplished by inputting recovery ssDNAs into the synthetic DNA circuits, which could simultaneously decrease the cellular uptake of ssDNAs. We speculate that operating the synthetic DNA circuits on the cell membrane will be a powerful strategy for regulating the cellular uptake of exogenous materials, which has important implications for bioimaging, drug delivery, and gene therapy.