ABSTRACT
Solid-state nanopores have been used extensively in biomolecular studies involving DNA and proteins. However, the interpretation of signals generated by the translocation of proteins or protein-DNA complexes remains challenging. Here, we investigate the behavior of monovalent streptavidin and the complex it forms with short biotinylated DNA over a range of nanopore sizes, salts and voltages. We describe a simple geometric model that is broadly applicable and employ it to explain observed variations in conductance blockage and dwell time with experimental conditions. The general approach developed here underscores the value of nanopore-based protein analysis and represents progress toward the interpretation of complex translocation signals.
STATEMENT OF SIGNIFICANCE Nanopore sensing allows investigation of biomolecular structure in aqueous solution, including electricfield-induced changes in protein conformation. This nanopore-based study probes: (1) the tetramerdimer transition of streptavidin, observing the effects of increasing voltage with varying salt type and concentration; (2) the possible conformational states of DNA-streptavidin complexes when confined inside a pore. We describe a broadly applicable geometric approach that maps stepwise changes in the nanopore signal to real-time conformational transitions. These results represent progress toward accurate interpretation of nanopore signals generated by molecular complexes.
Competing Interest Statement
The authors have declared no competing interest.