Peptide-DNA Conjugates for Formation of Lipid Nanodiscs
Sundar Prakash, P.; Chandrasekhar, S.; Kabuga, J.; Goncalves, D. P. N.; Fadaei, F.; Schmidt, T. L.
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Nanoscale lipid bilayer mimetics are powerful tools for research on lipid bilayer, membrane proteins or for drug delivery. Established nanoscale bilayer systems that are stabilized by short peptides or polymers produce a broad size distribution and are difficult to customize. Here we introduce a DNA nanotechnology-based lipid bilayer mimetic, in which we covalently conjugated established nanodisc-forming amphiphilic peptides to oligonucleotides. These peptide-DNA conjugates were then hybridized with a circular single-stranded scaffold to form stiff, circular PDC minicircles with 14 peptide modifications at the inner rim of the torus. Lipid reconstitution yielded defined nanodisc with a tightly controlled circumference and component stoichiometry. Molecular dynamics simulations further validated the structural stability and reveal an asymmetric migration of the DNA to one rim of the bilayer. To mimic membrane protein insertion, we co-reconstituted a transmembrane peptide coupled to a bulky quantum dot. In future applications, the size and peptide arrangement can easily be modified in these DNA-templated PDC nanodiscs.
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