Inducing Lipid Domains in Membranes by Self‐Assembly of DNA Origami

Kanwa, Nishu; Gavrilovic, Svetozar; Brüggenthies, Gereon A.; Qutbuddin, Yusuf; Schwille, Petra

doi:10.1002/admi.202202500

Cited by 6 publications

(4 citation statements)

References 98 publications

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“…50 This contrasts with previous studies where membrane anchors have been attached via polymeric and DNA linkers of 20 up to 10 nanometers in length on flat 32,33,49,50,54 and curved 19,23,28 DNA nanostructures. While long linkers increase conformational flexibility and hence improve membrane interaction, they can blur the picture of how anchor position influences binding 19,20,23,33,49,50 even though molecular accessibility of lipid anchors controls vesicles binding 54 and the related phenomenon of DNA duplex aggregation. 44 However, 3D geometries of DNA nanostructure are relevant parameters for biological applications such as shown by in vivo uptake of DNA origami into human cells via the pathway of small endosome vesicles for drug delivery applications.…”

Section: Discussionmentioning

confidence: 67%

“…First, we elucidated how DNA nanostructure-membrane interactions are influenced by the number and the geometric position of the membrane anchors in 3D geometries as opposed to flat nanostructures. 32,33,49,50,54 To maximize insight, the membrane anchors were placed close to the DNA nanostructure surface to force tight interaction to lipid bilayer vesicles. 50 This contrasts with previous studies where membrane anchors have been attached via polymeric and DNA linkers of 20 up to 10 nanometers in length on flat 32,33,49,50,54 and curved 19,23,28 DNA nanostructures.…”

Section: Discussionmentioning

confidence: 99%

“…32,33,49,50,54 To maximize insight, the membrane anchors were placed close to the DNA nanostructure surface to force tight interaction to lipid bilayer vesicles. 50 This contrasts with previous studies where membrane anchors have been attached via polymeric and DNA linkers of 20 up to 10 nanometers in length on flat 32,33,49,50,54 and curved 19,23,28 DNA nanostructures. While long linkers increase conformational flexibility and hence improve membrane interaction, they can blur the picture of how anchor position influences binding 19,20,23,33,49,50 even though molecular accessibility of lipid anchors controls vesicles binding 54 and the related phenomenon of DNA duplex aggregation.…”

Section: Discussionmentioning

confidence: 99%

“…While DNA nanotechnology excels at precisely tuning the shape and dimensions of 2D and 3D nanostructures spanning from the nanoscale 1-13 to the macroscale, 13-15 semifluid lipid bilayers stand out by compartmentalizing hydrophobic environments, 16 setting up concentration gradients for energy conversion, 17 and providing lateral diffusive platforms for enhanced molecular assembly. 18 Combining DNA nanotechnology with lipid membranes can unlock considerable synergy as illustrated by a range of DNA nanostructures that can mimic cellular cytoskeletons and shape membranes into biologically unprecedented forms, 19-23 define lipid domains, 24 selectively label leaflets, 25,26 measure membrane curvature, 27 fuse membrane bilayers, 28 spatially activate membrane proteins, 29,30 tune endosomal uptake, 31 facilitate macrostructure assembly, 32,33 and even help produce synthetic protocells. [34][35][36][37] In complementary approaches, DNA nanostructures can insert into lipid membranes to emulate the function of membrane proteins, including receptors, 38 nanopores, 39,40 gated channels, 41 membrane force sensors, 42 and lipid flippases.…”

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confidence: 99%

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DNA Origami – Lipid Membrane Interactions Defined at Single-Molecular Resolution

Georgiou,

Cabello-Garcia,

Xing

et al. 2023

Preprint

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Rigid DNA nanostructures that bind to floppy bilayer membranes are of fundamental interest as they replicate biological cytoskeletons for synthetic biology, biosensing, and biological research. Here, we establish principles underpinning the controlled interaction of DNA structures and lipid bilayers. As membrane anchors mediate interaction, more than 20 versions of a core DNA nanostructure are built each carrying up to five individual cholesterol anchors of different steric accessibility within the 3D geometry. The structures’ binding to membrane vesicles of tunable curvature is determined with ensemble methods and by single-molecule localization microscopy. This screen yields quantitative and unexpected insight on which steric anchor points cause efficient binding. Strikingly, defined nanostructures with a single molecular anchor discriminate effectively between vesicles of different nanoscale curvatures which may be exploited to discern diagnostically relevant membrane vesicles based on size. Furthermore, we reveal anchor-mediated bilayer interaction to be co-controlled by non-lipidated DNA regions and localized membrane curvatures stemming from heterogenous lipid composition, which modifies existing biophysical models. Our study extends DNA nanotechnology to control interactions with bilayer membranes and thereby facilitate the design of nanodevices for vesicle-based diagnostics, biosensing, and protocells.

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Section: Discussionmentioning

confidence: 67%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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DNA Origami – Lipid Membrane Interactions Defined at Single-Molecular Resolution

Georgiou,

Cabello-Garcia,

Xing

et al. 2023

Preprint

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DNA Origami – Lipid Membrane Interactions Controlled by Nanoscale Sterics

Georgiou,

Cabello‐Garcia,

Xing

et al. 2024

Small

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DNA nanostructures designed to interact with bilayer membranes are of fundamental interest as they mimic biological cytoskeletons and other membrane‐associated proteins for applications in synthetic biology, biosensing, and biological research. Yet, there is limited insight into how the binary interactions are influenced by steric effects produced by 3D geometries of DNA structures and membranes. This work uses a 3D DNA nanostructure with membrane anchors in four different steric environments to elucidate the interaction with membrane vesicles of varying sizes and different local bilayer morphology. It is found that interactions are significantly affected by the steric environments of the anchors ‐often against predicted accessibility‐ as well as local nanoscale morphology of bilayers rather than on the usually considered global vesicle size. Furthermore, anchor‐mediated bilayer interactions are co‐controlled by weak contacts with non‐lipidated DNA regions, as showcased by pioneering size discrimination between 50 and 200 nm vesicles. This study extends DNA nanotechnology to controlled bilayer interactions and can facilitate the design of nanodevices for vesicle‐based diagnostics, biosensing, and protocells.

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Artificial Molecular Systems for Complex Functions Based on DNA Nanotechnology and Cell‐Sized Lipid Vesicles

Sato

2024

ChemSystemsChem

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Cells are highly functional and complex molecular systems. Artificially creating such systems remains a challenge, which has been extensively studied in various research fields, including synthetic biology and molecular robotics. DNA nanotechnology is a powerful tool for bottom‐up engineering for constructing functional nanostructures or chemical reaction networks which can be utilized as components for artificial molecular systems. Encapsulation of these components into a giant unilamellar vesicle (GUV) composed of a lipid bilayer, the base structure of the cellular membrane, results in a functional cell‐sized structure that partially mimics some cellular functions. This review discusses the studies contributing to the construction of GUV‐based artificial molecular systems based on DNA nanotechnology. Molecular transport and signal transduction through lipid membranes are essential to uptake molecules from the environment and respond to stimuli. Membrane shaping relates to various functions, including motility and signaling. A chemical reaction network is required to autonomously regulate the system's functions. This review describes the functions realized using DNA nanostructures and DNA reaction networks. Given the designability and programmability of DNA nanotechnology, it may be possible that the functionality of artificial molecular systems could be comparable to or even surpass that of natural molecular systems.

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Inducing Lipid Domains in Membranes by Self‐Assembly of DNA Origami

Cited by 6 publications

References 98 publications

DNA Origami – Lipid Membrane Interactions Defined at Single-Molecular Resolution

DNA Origami – Lipid Membrane Interactions Defined at Single-Molecular Resolution

DNA Origami – Lipid Membrane Interactions Controlled by Nanoscale Sterics

Artificial Molecular Systems for Complex Functions Based on DNA Nanotechnology and Cell‐Sized Lipid Vesicles

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