Abstract
The hydrophobic effect is a major driving force in protein folding. A complete understanding of this effect requires the description of the conformational states of water and protein molecules at different temperatures. Towards this goal, we characterise the cold and hot denatured states of a protein by modelling NMR chemical shifts using restrained molecular dynamics simulations. A detailed analysis of the resulting structures reveals that water molecules in the bulk and at the protein interface form on average the same number of hydrogen bonds. Thus, even if proteins are ‘large’ particles (in terms of the hydrophobic effect, i.e. larger than 1 nm), because of the presence of complex surface patterns of polar and non-polar residues their behaviour can be compared to that of ‘small’ particles (i.e. smaller than 1 nm). We thus find that the hot denatured state is more compact and richer in secondary structure than the cold denatured state, since water at lower temperatures can form more hydrogen bonds than at high temperatures. Then, using Φ-value analysis we show that the structural differences between the hot and cold denatured states result in two alternative folding mechanisms. These findings thus illustrate how the analysis of water-protein hydrogen bonds can reveal the molecular origins of protein behaviours associated with the hydrophobic effect.
Highlights
A detailed understanding of the molecular origins of the hydrophobic effect[1,2,3,4,5,6,7,8,9,10] in proteins and of its role as a driving force in protein folding and assembly[10,11,12,13,14] is still an open problem
The cold denatured state (CDS) is more expanded than the hot denatured state (HDS)
The two ensembles are different in terms of their radii of gyration (Rg), with 1.7 nm in the CDS and 1.6 nm in the HDS; for reference, this value is 1.5 nm in the native state (NS), even if this difference is may be underestimated because of known limitations of current force fields[28]
Summary
A detailed understanding of the molecular origins of the hydrophobic effect[1,2,3,4,5,6,7,8,9,10] in proteins and of its role as a driving force in protein folding and assembly[10,11,12,13,14] is still an open problem. Our aim is to clarify first whether proteins, whose surfaces as mentioned above are characterized by the presence of complex polar and non-polar patterns, behave effectively like small or large non-polar solutes, and to investigate the consequences of this fact on their folding behaviour[11,12,13] Addressing this question requires an accurate characterization of the conformational space of a protein in water to study the number of hydrogen bonds formed by water molecules in proximity of its surface with respect to the bulk. By using Φ-values analysis[25,26,27] and Φ-values restrained molecular simulations[26], we determined their cold transition state (CTS) and hot transition state (HTS) to describe the differences in the cold and hot denaturation processes corresponding to the differences between the cold and hot denatured states
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