Abstract
While single-molecule force spectroscopy has greatly advanced the study of protein folding, there are limitations to what can be learned from studying the effect of force alone. We developed a novel technique, chemo-mechanical unfolding, that combines multiple perturbants—force and chemical denaturant—to more fully characterize the folding process by simultaneously probing multiple structural parameters—the change in end-to-end distance, and solvent accessible surface area. Here, we describe the theoretical background, experimental design, and data analysis for chemo-mechanical unfolding experiments probing protein folding thermodynamics and kinetics. This technique has been applied to characterize parallel protein folding pathways, the protein denatured state, protein folding on the ribosome, and protein folding intermediates.
Highlights
Advances in single-molecule force spectroscopy over the past decade have created a unique and powerful tool to study protein folding [1,2,3,4]
We quantify the effect of urea on protein folding thermodynamics and kinetics using a parameter called the m-value
Chemo-mechanical unfolding experiments simultaneously determine m-values and x-values or m‡ -values and x‡ -values, providing details about protein folding that could not be obtained from force or chemical denaturation alone
Summary
Advances in single-molecule force spectroscopy over the past decade have created a unique and powerful tool to study protein folding [1,2,3,4]. The resulting data are analyzed to characterize the protein energy landscape, the map of energetics and dynamics for the ensemble of possible protein conformations [8,9,10]. Single-molecule force experiments have revealed the role of mechanical stress on this energy landscape and opened up new avenues to probe unique aspects of the landscape. The degree to which a conformational change depends on the perturbant reveals specific structural information about the landscape. In single molecule force experiments, the force dependence of the reaction can be used to determine a structural parameter called the
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