β-barrel nanopores designed for insertion into thick block copolymer membranes

Efficient integration of proteins into amphiphilic polymer membranes offers new opportunities in synthetic biology and nanotechnology. Long-term protein reconstitution into artificial membranes remains challenging due to a lack of stabilising protein-membrane interactions found in native lipid bilayers. Here, we redesigned the transmembrane region of a CytK-4D {beta}-barrel nanopore for stable insertion into 3.5-6.6 nm thick PBD-PEO (poly(1,2-butadiene)-b-poly(ethylene oxide)) bilayers. PBD-PEO membranes offer high mechanical and chemical stability and low electrical noise, but the thick membrane hinders anchoring of biological nanopores. By systematically investigating the elongation of the {beta}-barrel, we engineered nanopore constructs suitable for PBD11PEO8 and PBD22PEO14 membranes. Efficient insertions were observed by adding amino acids that stabilised the transmembrane {beta}-barrel structure and enhanced anchoring of the nanopore into the membrane. Molecular dynamics simulations and single-molecule assays revealed that nanopores folded naturally into PBD-PEO bilayers, enabling successful detection of cyclodextrins and translocation of polypeptides and full-length proteins. Our study offers important lessons for the reconstitution of membrane proteins into artificial membranes. Moreover, these highly robust nanopore-membrane interfaces can be readily integrated into biosensing devices, enabling peptide and protein analysis directly from complex solutions.