Nanopore electro-osmotic trap for the label-free study of single proteins and their conformations

Abstract

Many strategies have been pursued to trap and monitor single proteins over time in order to detect the molecular mechanisms of these essential nanomachines. Single protein sensing with nanopores is particularly attractive because it allows label-free high-bandwidth detection based on ion currents. Here we present the Nanopore Electro-Osmotic trap (NEOtrap) that allows trapping and observing single proteins for hours with sub-millisecond time resolution. The NEOtrap is formed by docking a DNA-origami sphere onto a passivated solid-state nanopore, which seals off a nanocavity of a user-defined size and creates an electro-osmotic flow that traps nearby particles irrespective of their charge. We demonstrate the NEOtrap’s ability to sensitively distinguish proteins based on size and shape, and discriminate nucleotide-dependent protein conformations, as exemplified by the chaperone protein Hsp90. Given the experimental simplicity and capacity for label-free single-protein detection over the broad bio-relevant time range, the NEOtrap opens new avenues to study the molecular kinetics underlying protein function.