Kinetic coherence underlies the dynamics of disordered proteins.

The dynamics of two proteins of similar size, the globular lysozyme and the intrinsically disordered Huntingtin interacting protein, has been simulated in three states resembling a globule, a pre-molten globule, and a molten globule. A coherence time has been defined, measuring the delay in the display of a stochastic behaviour after a perturbation of the system. This time has been computed for two sets of collective variables: the projection of the phase point onto the positions and momenta subspaces ( and ), and the principal components (PCs) of positions and momenta produced by a covariance analysis in these subspaces ( and ). In all states ≈ 3.5 , and ≈ 3.5 . The coherence times of individual PCs, and , have also been computed, and > in all states. The prevalence of over , or of over , drives the dynamics of the protein over a time range of ≈1-2 ps; moreover, a hidden synchronism appears to raise the momenta subspace's coherence above that of its individual PCs. In the transition of lysozyme to the molten globule the decrease but, unexpectedly, the increase; after this transition ≈ 5 and ≈ 5 . A gain of accompanies thus the loss of caused by the denaturation of the protein in the transition from globule to molten globule. The increase of the does not take place in the analogous transition of the Huntingtin protein. These results are compared with those of a similar analysis performed on three pseudo-proteins designed by scrambling the primary sequence of the Huntingtin interacting protein, and on two oligopeptides. The hidden synchronism appears to be a generic property of these polypeptides. The spectrum is similar in denaturated and in intrinsically disordered biomolecules; but the gain of kinetic coherence as a result of denaturation seems to be a specific property of the biologically functional lysozyme.