Multi-functional DNA nanostructures that puncture and remodel lipid membranes into hybrid materials
Polymers
Science
Lipid Bilayers
Polymer-Supported Membranes
Article
Membrane Lipids
Nanopores
03 medical and health sciences
Microscopy, Electron, Transmission
0303 health sciences
Science & Technology
Microscopy, Confocal
Nanotubes
Curvature
Q
Cell Membrane
DNA
Single-Particle Tracking
Lipids
Nanostructures
Multidisciplinary Sciences
Transmembrane Proteins
Cholesterol
Microscopy, Fluorescence
Protein-Protein Interactions
Localization
Science & Technology - Other Topics
Mitochondrial Cristae
Synthetic Biology
Organization
DOI:
10.1038/s41467-018-02905-w
Publication Date:
2018-04-12T09:17:31Z
AUTHORS (6)
ABSTRACT
AbstractSynthetically replicating key biological processes requires the ability to puncture lipid bilayer membranes and to remodel their shape. Recently developed artificial DNA nanopores are one possible synthetic route due to their ease of fabrication. However, an unresolved fundamental question is how DNA nanopores bind to and dynamically interact with lipid bilayers. Here we use single-molecule fluorescence microscopy to establish that DNA nanopores carrying cholesterol anchors insert via a two-step mechanism into membranes. Nanopores are furthermore shown to locally cluster and remodel membranes into nanoscale protrusions. Most strikingly, the DNA pores can function as cytoskeletal components by stabilizing autonomously formed lipid nanotubes. The combination of membrane puncturing and remodeling activity can be attributed to the DNA pores’ tunable transition between two orientations to either span or co-align with the lipid bilayer. This insight is expected to catalyze the development of future functional nanodevices relevant in synthetic biology and nanobiotechnology.
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