Litcius/Paper detail

Responsive DNA artificial cells for contact and behavior regulation of mammalian cells

Miao Wang, Hexin Nan, Meixia Wang, Sihui Yang, Lin Liu, Hong‐Hui Wang, Zhou Nie

2025Nature Communications24 citationsDOIOpen Access PDF

Abstract

Artificial cells have emerged as synthetic entities designed to mimic the functionalities of natural cells, but their interactive ability with mammalian cells remains challenging. Herein, we develop a generalizable and modular strategy to engineer DNA-empowered stimulable artificial cells designated to regulate mammalian cells (STARM) via synthetic contact-dependent communication. Constructed through temperature-controlled DNA self-assembly involving liquid-liquid phase separation (LLPS), STARMs feature organized all-DNA cytoplasm-mimic and membrane-mimic compartments. These compartments can integrate functional nucleic acid (FNA) modules and light-responsive gold nanorods (AuNRs) to establish a programmable sense-and-respond mechanism to specific stimuli, such as light or ions, orchestrating diverse biological functions, including tissue formation and cellular signaling. By combining two designer STARMs into a dual-channel system, we achieve orthogonally regulated cellular signaling in multicellular communities. Ultimately, the in vivo therapeutic efficacy of STARM in light-guided muscle regeneration in living animals demonstrates the promising potential of smart artificial cells in regenerative medicine. Interaction between synthetic and natural cells is a major goal with huge potential. Here, the authors developed DNA-assembled, stimuli-responsive artificial cells capable of contact-dependent communication to precisely modulate mammalian cell behaviors.

Topics & Concepts

DNACell biologyComputational biologyBiologyGeneticsAdvanced biosensing and bioanalysis techniquesMolecular Communication and NanonetworksDNA and Biological Computing