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. 2020 Sep;4(9):e2000102.
doi: 10.1002/adbi.202000102. Epub 2020 Jul 21.

Engineering Light-Responsive Contractile Actomyosin Networks with DNA Nanotechnology

Kevin Jahnke  1   2 Marian Weiss  3   4 Cornelia Weber  3   4 Ilia Platzman  3   4 Kerstin Göpfrich  1   2 Joachim P Spatz  3   4   5
Affiliations

Engineering Light-Responsive Contractile Actomyosin Networks with DNA Nanotechnology

Kevin Jahnke et al. Adv Biosyst. 2020 Sep.

Abstract

External control and precise manipulation is key for the bottom-up engineering of complex synthetic cells. Minimal actomyosin networks have been reconstituted into synthetic cells; however, their light-triggered symmetry breaking contraction has not yet been demonstrated. Here, light-activated directional contractility of a minimal synthetic actomyosin network inside microfluidic cell-sized compartments is engineered. Actin filaments, heavy-meromyosin-coated beads, and caged ATP are co-encapsulated into water-in-oil droplets. ATP is released upon illumination, leading to a myosin-generated force which results in a motion of the beads along the filaments and hence a contraction of the network. Symmetry breaking is achieved using DNA nanotechnology to establish a link between the network and the compartment periphery. It is demonstrated that the DNA-linked actin filaments contract to one side of the compartment forming actin asters and quantify the dynamics of this process. This work exemplifies that an engineering approach to bottom-up synthetic biology, combining biological and artificial elements, can circumvent challenges related to active multi-component systems and thereby greatly enrich the complexity of synthetic cellular systems.

Keywords: DNA nanotechnology; actomyosin networks; bottom-up synthetic biology; symmetry break; water-in-oil droplets.

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