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Lipid-anchored DNA can attach functional cargo to bilayer membranes in DNA nanotechnology, synthetic biology, and cell biology research. To optimize DNA anchoring, an understanding of DNA–membrane interactions in terms of binding strength, extent, and structural dynamics is required. Here we use experiments and molecular dynamics (MD) simulations to determine how the membrane binding of cholesterol-modified DNA depends on electrostatic and steric factors involving the lipid headgroup charge, duplexed or single-stranded DNA, and the buffer composition. The experiments distinguish between free and membrane vesicle-bound DNA and thereby reveal the surface density of anchored DNA and its binding affinity, something which had previously not been known. The Kd values range from 8.5 ± 4.9 to 466 ± 134 μM whereby negatively charged headgroups led to weak binding due to the electrostatic repulsion with respect to the negatively charged DNA. Atomistic MD simulations explain the findings and elucidate the dynamic nature of anchored DNA such as the mushroom-like conformation of single-stranded DNA hovering over the bilayer surface in contrast to a straight-up conformation of double-stranded DNA. The biophysical insight into the binding strength to membranes as well as the molecular accessibility of DNA for hybridization to molecular cargo is expected to facilitate the creation of biomimetic DNA versions of natural membrane nanopores and cytoskeletons for research and nanobiotechnology.
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DNA nanopores as artificial membrane channels for bioprotonics
Abstract Biological membrane channels mediate information exchange between cells and facilitate molecular recognition. While tuning the shape and function of membrane channels for precision molecular sensing via de-novo routes is complex, an even more significant challenge is interfacing membrane channels with electronic devices for signal readout, which results in low efficiency of information transfer - one of the major barriers to the continued development of high-performance bioelectronic devices. To this end, we integrate membrane spanning DNA nanopores with bioprotonic contacts to create programmable, modular, and efficient artificial ion-channel interfaces. Here we show that cholesterol modified DNA nanopores spontaneously and with remarkable affinity span the lipid bilayer formed over the planar bio-protonic electrode surface and mediate proton transport across the bilayer. Using the ability to easily modify DNA nanostructures, we illustrate that this bioprotonic device can be programmed for electronic recognition of biomolecular signals such as presence of Streptavidin and the cardiac biomarker B-type natriuretic peptide, without modifying the biomolecules. We anticipate this robust interface will allow facile electronic measurement and quantification of biomolecules in a multiplexed manner.
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- PAR ID:
- 10455450
- Publisher / Repository:
- Nature Publishing Group
- Date Published:
- Journal Name:
- Nature Communications
- Volume:
- 14
- Issue:
- 1
- ISSN:
- 2041-1723
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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