Abstract

Nanopore sensors could revolutionize single-molecule proteomics by providing a means for identification of known proteins through fingerprinting or by de novo sequencing. However, the complex chemical and physical properties of proteins present multiple challenges to the conventional nanopore sensing method, predominantly, the single-file threading of a protein chain into a nanopore and its transport through it. Herein we describe a general approach for realizing unidirectional transport of full-length proteins through nanopores. We show that the combination of a chemically resistant biological nanopore platform and a high concentration guanidinium chloride buffer enables protein unfolding and unidirectional transport through a pore, propelled by an electroosmotic effect that largely owes to the guanidinium chloride presence. The uniform and slow (~10 {micro}s/amino acid) single-file transport, when combined with supervised machine learning of the electrical current signatures obtained, allows us to use to discern the protein threading orientation and identity. In conjunction with a method for tail-modification of native proteins and higher-resolution nanopores, our approach could offer a path towards direct single-molecule protein fingerprinting without the requirement of a motor enzyme.