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Free-Standing DNA Origami Superlattice to Facilitate Cryo-EM Visualization of Membrane Vesicles

Nesrine Aissaoui, Allan Mills, Joséphine Lai‐Kee‐Him, Nicolas Triomphe, Quentin Cece, Christine Doucet, Anne Bonhoure, Michel Vidal, Yonggang Ke, Gaëtan Bellot

2024Journal of the American Chemical Society12 citationsDOI

Abstract

Technological breakthroughs in cryo-electron microscopy (cryo-EM) methods open new perspectives for highly detailed structural characterizations of extracellular vesicles (EVs) and synthetic liposome-protein assemblies. Structural characterizations of these vesicles in solution under a nearly native hydrated state are of great importance to decipher cell-to-cell communication and to improve EVs' application as markers in diagnosis and as drug carriers in disease therapy. However, difficulties in preparing holey carbon cryo-EM grids with low vesicle heterogeneities, at low concentration and with kinetic control of the chemical reactions or assembly processes, have limited cryo-EM use in the EV study. We report a straightforward membrane vesicle cryo-EM sample preparation method that assists in circumventing these limitations by using a free-standing DNA-affinity superlattice for covering holey carbon cryo-EM grids. Our approach uses DNA origami to self-assemble to a solution-stable and micrometer-sized ordered molecular template in which structure and functional properties can be rationally controlled. We engineered the template with cholesterol-binding sites to specifically trap membrane vesicles. The advantages of this DNA-cholesterol-affinity lattice (DCAL) include (1) local enrichment of artificial and biological vesicles at low concentration and (2) isolation of heterogeneous cell-derived membrane vesicles (exosomes) from a prepurified pellet of cell culture conditioned medium on the grid.

Topics & Concepts

ChemistryVesicleVisualizationSuperlatticeNanotechnologyMembraneDNABiophysicsBiochemistryOptoelectronicsArtificial intelligencePhysicsBiologyComputer scienceMaterials scienceNanowire Synthesis and ApplicationsAdvanced biosensing and bioanalysis techniquesQuantum Dots Synthesis And Properties
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