Molecular traffic
across lipid membranes is a vital process in
cell biology that involves specialized biological pores with a great
variety of pore diameters, from fractions of a nanometer to >30
nm.
Creating artificial membrane pores covering similar size and complexity
will aid the understanding of transmembrane molecular transport in
cells, while artificial pores are also a necessary ingredient for
synthetic cells. Here, we report the construction of DNA origami nanopores
that have an inner diameter as large as 30 nm. We developed methods
to successfully insert these ultrawide pores into the lipid membrane
of giant unilamellar vesicles (GUVs) by administering the pores concomitantly
with vesicle formation in an inverted-emulsion cDICE technique. The
reconstituted pores permit the transmembrane diffusion of large macromolecules,
such as folded proteins, which demonstrates the formation of large
membrane-spanning open pores. The pores are size selective, as dextran
molecules with a diameter up to 28 nm can traverse the pores, whereas
larger dextran molecules are blocked. By FRAP measurements and modeling
of the GFP influx rate, we find that up to hundreds of pores can be
functionally reconstituted into a single GUV. Our technique bears
great potential for applications across different fields from biomimetics,
to synthetic biology, to drug delivery.