Proteins are dynamic molecular machines having structural flexibility that allows conformational changes1,2. Current methods for the determination of protein flexibility rely mainly on the measurement of thermal fluctuations and disorder in protein conformations3,4,5 and tend to be experimentally challenging. Moreover, they reflect atomic fluctuations on picosecond timescales, whereas the large conformational changes in proteins typically happen on micro- to millisecond timescales6,7. Here, we directly determine the flexibility of bacteriorhodopsin—a protein that uses the energy in light to move protons across cell membranes—at the microsecond timescale by monitoring force-induced deformations across the protein structure with a technique based on atomic force microscopy. In contrast to existing methods, the deformations we measure involve a collective response of protein residues and operate under physiologically relevant conditions with native proteins.
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This work was supported by the Rowland Junior Fellows program.
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Dong, M., Husale, S. & Sahin, O. Determination of protein structural flexibility by microsecond force spectroscopy. Nature Nanotech 4, 514–517 (2009). https://doi.org/10.1038/nnano.2009.156
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