Molten globule-like transition state of protein barnase measured with calorimetric force spectroscopy

Abstract

Understanding how proteins fold into their native structure is a fundamental problem in biophysics, crucial for protein design. It has been hypothesized that the formation of a molten globule intermediate precedes folding to the native conformation of globular proteins; however, its thermodynamic properties are poorly known. We perform single-molecule pulling experiments of protein barnase in the range of 7 to 37 using a temperature-jump optical trap. We derive the folding free energy, entropy and enthalpy, and heat capacity change ( Cp = 105050 cal/mol·K) at low ionic strength conditions. From the measured unfolding and folding kinetic rates, we also determine the thermodynamic properties of the transition state, finding a significant change in Cp ( 90\%) between the unfolded and the transition states. In contrast, the major change in enthalpy ( 80\%) occurs between the transition and native states. These results highlight a transition state of high energy and low configurational entropy structurally similar to the native state, in agreement with the molten globule hypothesis.