Programming Cell Adhesion for On-Chip Sequential Boolean Logic Functions

Xiangmeng Qu; Shaopeng Wang; Zhilei Ge; Jianbang Wang; Guangbao Yao; Jiang Li; Xiaolei Zuo; Jiye Shi; Shiping Song; Lihua Wang; Li Li; Hao Pei; Chunhai Fan

doi:10.1021/jacs.7b04040

Programming Cell Adhesion for On-Chip Sequential Boolean Logic Functions

Xiangmeng Qu, Shaopeng Wang, Zhilei Ge, Jianbang Wang, Guangbao Yao, Jiang Li, Xiaolei Zuo, Jiye Shi, Shiping Song, Lihua Wang, Li Li, Hao Pei, Chunhai Fan

School of Chemistry and Molecular Engineering

Research output: Contribution to journal › Article › peer-review

104 Scopus citations

Abstract

Programmable remodelling of cell surfaces enables high-precision regulation of cell behavior. In this work, we developed in vitro constructed DNA-based chemical reaction networks (CRNs) to program on-chip cell adhesion. We found that the RGD-functionalized DNA CRNs are entirely noninvasive when interfaced with the fluidic mosaic membrane of living cells. DNA toehold with different lengths could tunably alter the release kinetics of cells, which shows rapid release in minutes with the use of a 6-base toehold. We further demonstrated the realization of Boolean logic functions by using DNA strand displacement reactions, which include multi-input and sequential cell logic gates (AND, OR, XOR, and AND-OR). This study provides a highly generic tool for self-organization of biological systems.

Original language	English
Pages (from-to)	10176-10179
Number of pages	4
Journal	Journal of the American Chemical Society
Volume	139
Issue number	30
DOIs	https://doi.org/10.1021/jacs.7b04040
State	Published - 2 Aug 2017

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title = "Programming Cell Adhesion for On-Chip Sequential Boolean Logic Functions",

abstract = "Programmable remodelling of cell surfaces enables high-precision regulation of cell behavior. In this work, we developed in vitro constructed DNA-based chemical reaction networks (CRNs) to program on-chip cell adhesion. We found that the RGD-functionalized DNA CRNs are entirely noninvasive when interfaced with the fluidic mosaic membrane of living cells. DNA toehold with different lengths could tunably alter the release kinetics of cells, which shows rapid release in minutes with the use of a 6-base toehold. We further demonstrated the realization of Boolean logic functions by using DNA strand displacement reactions, which include multi-input and sequential cell logic gates (AND, OR, XOR, and AND-OR). This study provides a highly generic tool for self-organization of biological systems.",

author = "Xiangmeng Qu and Shaopeng Wang and Zhilei Ge and Jianbang Wang and Guangbao Yao and Jiang Li and Xiaolei Zuo and Jiye Shi and Shiping Song and Lihua Wang and Li Li and Hao Pei and Chunhai Fan",

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T1 - Programming Cell Adhesion for On-Chip Sequential Boolean Logic Functions

AU - Qu, Xiangmeng

AU - Wang, Shaopeng

AU - Ge, Zhilei

AU - Wang, Jianbang

AU - Yao, Guangbao

AU - Li, Jiang

AU - Zuo, Xiaolei

AU - Shi, Jiye

AU - Song, Shiping

AU - Wang, Lihua

AU - Li, Li

AU - Pei, Hao

AU - Fan, Chunhai

PY - 2017/8/2

Y1 - 2017/8/2

N2 - Programmable remodelling of cell surfaces enables high-precision regulation of cell behavior. In this work, we developed in vitro constructed DNA-based chemical reaction networks (CRNs) to program on-chip cell adhesion. We found that the RGD-functionalized DNA CRNs are entirely noninvasive when interfaced with the fluidic mosaic membrane of living cells. DNA toehold with different lengths could tunably alter the release kinetics of cells, which shows rapid release in minutes with the use of a 6-base toehold. We further demonstrated the realization of Boolean logic functions by using DNA strand displacement reactions, which include multi-input and sequential cell logic gates (AND, OR, XOR, and AND-OR). This study provides a highly generic tool for self-organization of biological systems.

AB - Programmable remodelling of cell surfaces enables high-precision regulation of cell behavior. In this work, we developed in vitro constructed DNA-based chemical reaction networks (CRNs) to program on-chip cell adhesion. We found that the RGD-functionalized DNA CRNs are entirely noninvasive when interfaced with the fluidic mosaic membrane of living cells. DNA toehold with different lengths could tunably alter the release kinetics of cells, which shows rapid release in minutes with the use of a 6-base toehold. We further demonstrated the realization of Boolean logic functions by using DNA strand displacement reactions, which include multi-input and sequential cell logic gates (AND, OR, XOR, and AND-OR). This study provides a highly generic tool for self-organization of biological systems.

UR - https://www.scopus.com/pages/publications/85026801221

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Programming Cell Adhesion for On-Chip Sequential Boolean Logic Functions

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