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Single-Molecule Unfolding Force Distributions Reveal a Funnel-Shaped Energy Landscape

Physik-Department E22, Technische Universität München, D-85748 Garching b. Munich, Germany

Correspondence: Address reprint requests and inquiries to Matthias Rief, E-mail: mrief{at}ph.tum.de.

The protein folding process is described as diffusion on a high-dimensional energy landscape. Experimental data showing details of the underlying energy surface are essential to understanding folding. So far in single-molecule mechanical unfolding experiments a simplified model assuming a force-independent transition state has been used to extract such information. Here we show that this so-called Bell model, although fitting well to force velocity data, fails to reproduce full unfolding force distributions. We show that by applying Kramers' diffusion model, we were able to reconstruct a detailed funnel-like curvature of the underlying energy landscape and establish full agreement with the data. We demonstrate that obtaining spatially resolved details of the unfolding energy landscape from mechanical single-molecule protein unfolding experiments requires models that go beyond the Bell model.

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