Litcius/Paper detail

Nanopore-Based Protein Identification

Mazdak Afshar Bakshloo, John J. Kasianowicz, Manuela Pastoriza‐Gallego, Jérôme Mathé, Régis Daniel, Fabien Piguet, Abdelghani Oukhaled

2022Journal of the American Chemical Society147 citationsDOI

Abstract

The implementation of a reliable, rapid, inexpensive, and simple method for whole-proteome identification would greatly benefit cell biology research and clinical medicine. Proteins are currently identified by cleaving them with proteases, detecting the polypeptide fragments with mass spectrometry, and mapping the latter to sequences in genomic/proteomic databases. Here, we demonstrate that the polypeptide fragments can instead be detected and classified at the single-molecule limit using a nanometer-scale pore formed by the protein aerolysin. Specifically, three different water-soluble proteins treated with the same protease, trypsin, produce different polypeptide fragments defined by the degree by which the latter reduce the nanopore's ionic current. The fragments identified with the aerolysin nanopore are consistent with the predicted fragments that trypsin could produce.

Topics & Concepts

AerolysinChemistryProteomeTrypsinProteasesNanoporeProteomicsProteaseComputational biologyGlobular proteinBiochemistryBiophysicsEnzymeNanotechnologyBiologyGeneVirulenceMaterials scienceNanopore and Nanochannel Transport StudiesIon-surface interactions and analysisMicrofluidic and Capillary Electrophoresis Applications