Litcius/Paper detail

3D DNA origami pincers that multitask on giant unilamellar vesicles

Pengfei Zhan, Juanjuan Yang, L L Ding, Xinxin Jing, Katharina Hipp, Stephan Nußberger, Hao Yan, Na Liu

2024Science Advances17 citationsDOIOpen Access PDF

Abstract

Proteins self-assemble to function in living cells. They may execute essential tasks in the form of monomers, complexes, or supramolecular cages via oligomerization, achieving a sophisticated balance between structural topology and functional dynamics. The modularity and programmability make DNA origami unique in mimicking these key features. Here, we demonstrate three-dimensional reconfigurable DNA origami pincers (DOPs) that multitask on giant unilamellar vesicles (GUVs). By programmably adjusting their pinching angle, the DOPs can dynamically control the degree of GUV remodeling. When oligomerized on the GUV to form origami cages, the DOP units interact with one another and undergo reorganization, resulting in the capture, compartmentalization, and detachment of lipid fragments. This oligomerization process is accompanied with membrane disruptions, enabling the passage of cargo across the membrane. We envisage that interfacing synthetic cells with engineered, multifunctional DNA nanostructures may help to confer customized cellular properties, unleashing the potential of both fields.

Topics & Concepts

DNA origamiNanotechnologyVesicleDNA nanotechnologyModularity (biology)Supramolecular chemistryMembraneInterfacingBiophysicsDNACompartmentalization (fire protection)Atomic force microscopyChemistryTopology (electrical circuits)NanostructureComputer scienceMaterials scienceBiologyCrystallographyComputer hardwareBiochemistryGeneticsCrystal structureMathematicsEnzymeCombinatoricsAdvanced biosensing and bioanalysis techniquesRNA Interference and Gene DeliveryLipid Membrane Structure and Behavior