De Novo Design of an Intercellular Signaling Toolbox for Multi-channel Cell-cell Communication and Biological Computation

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Aug 26

PMID 32839450

Citations 35

Authors

Pei Du

Huiwei Zhao

Haoqian Zhang

Ruisha Wang

Jianyi Huang

Ye Tian

Xudong Luo

Xunxun Luo

Min Wang

Yanhui Xiang

Long Qian

Yihua Chen

Yong Tao

Chunbo Lou

Affiliations

Soon will be listed here.

Abstract

Intercellular signaling is indispensable for single cells to form complex biological structures, such as biofilms, tissues and organs. The genetic tools available for engineering intercellular signaling, however, are quite limited. Here we exploit the chemical diversity of biological small molecules to de novo design a genetic toolbox for high-performance, multi-channel cell-cell communications and biological computations. By biosynthetic pathway design for signal molecules, rational engineering of sensing promoters and directed evolution of sensing transcription factors, we obtain six cell-cell signaling channels in bacteria with orthogonality far exceeding the conventional quorum sensing systems and successfully transfer some of them into yeast and human cells. For demonstration, they are applied in cell consortia to generate bacterial colony-patterns using up to four signaling channels simultaneously and to implement distributed bio-computation containing seven different strains as basic units. This intercellular signaling toolbox paves the way for engineering complex multicellularity including artificial ecosystems and smart tissues.

Citing Articles

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