Recently developed DNA-based analogues of membrane proteins have advanced synthetic biology. A fundamental question is how hydrophilic nanostructures reside in the hydrophobic environment of the membrane. Here, we use multiscale molecular dynamics (MD) simulations to explore the structure, stability and dynamics of an archetypical DNA nanotube inserted via a ring of membrane anchors into a phospholipid bilayer. Coarse-grained MD reveals that the lipids reorganize locally to interact closely with the membrane-spanning section of the DNA tube. Steered simulations along the bilayer normal establish the metastable nature of the inserted pore, yielding a force profile with barriers for membrane exit due to the membrane anchors. Atomistic, equili...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
DNA nanotechnology has revolutionised our capability to shape and control three-dimensional structur...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...
Recently developed DNA-based analogues of membrane proteins have advanced synthetic biology. A funda...
Recently developed DNA-based analogues of membrane proteins advance synthetic biology. A fundamental...
Equipping DNA with hydrophobic anchors enables targeted interaction with lipid bilayers for applicat...
Recently developed synthetic membrane pores composed of folded DNA enrich the current range of natur...
DNA origami offers the possibility of developing novel membrane-spanning pores with potential applic...
Transmembrane pores are highly specialised nano-devices, with intrinsic specificity and gate-keeping...
ABSTRACT: DNA nanotechnology excels at rationally designing bottom-up structures that can functional...
Engineering the synthetic nanopores through lipid bilayer membrane to access the interior of a cell ...
Chemistry is in a powerful position to synthetically replicate biomolecular structures. Adding funct...
Lipid-anchored DNA can attach functional cargo to bilayer membranes in DNA nanotechnology, synthetic...
DNA nanotechnology has emerged as a promising method for designing spontaneously inserting and fully...
Recently developed synthetic membrane pores composed of folded DNA enrich the current range of natur...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
DNA nanotechnology has revolutionised our capability to shape and control three-dimensional structur...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...
Recently developed DNA-based analogues of membrane proteins have advanced synthetic biology. A funda...
Recently developed DNA-based analogues of membrane proteins advance synthetic biology. A fundamental...
Equipping DNA with hydrophobic anchors enables targeted interaction with lipid bilayers for applicat...
Recently developed synthetic membrane pores composed of folded DNA enrich the current range of natur...
DNA origami offers the possibility of developing novel membrane-spanning pores with potential applic...
Transmembrane pores are highly specialised nano-devices, with intrinsic specificity and gate-keeping...
ABSTRACT: DNA nanotechnology excels at rationally designing bottom-up structures that can functional...
Engineering the synthetic nanopores through lipid bilayer membrane to access the interior of a cell ...
Chemistry is in a powerful position to synthetically replicate biomolecular structures. Adding funct...
Lipid-anchored DNA can attach functional cargo to bilayer membranes in DNA nanotechnology, synthetic...
DNA nanotechnology has emerged as a promising method for designing spontaneously inserting and fully...
Recently developed synthetic membrane pores composed of folded DNA enrich the current range of natur...
DNA nanopores are bio-inspired nanostructures that control molecular transport across lipid bilayer ...
DNA nanotechnology has revolutionised our capability to shape and control three-dimensional structur...
Biological channels control the transport of vital biomolecular cargo across the cellular membrane. ...