Protein and hydration-water dynamics are decoupled: A new model connecting dynamics and biochemical function is required
Antonio Benedetto

TL;DR
This study uses high-resolution neutron scattering to demonstrate that protein and hydration water dynamics are decoupled, challenging existing models and indicating the need for a new framework linking dynamics to biochemical function.
Contribution
It provides experimental evidence that protein and hydration water dynamics are decoupled, contradicting the prevailing coupled-dynamics model.
Findings
Protein and hydration water dynamics are decoupled.
Existing models linking dynamics to function are insufficient.
A new model connecting dynamics and biochemical activity is needed.
Abstract
Water plays a major role in bio-systems, greatly contributing to determine their structure, stability and even function. It is well know, for instance, that proteins require a minimum amount of water to be functionally active. Since the biological functions of proteins involve changes of conformation, and sometimes chemical reactions, it is natural to expect a connection of these functions with dynamical properties of the coupled system of proteins and their hydration water. However, despite many years of intensive research, the detailed nature of protein - hydration water interactions, and their effect on the biochemical activity of proteins through peculiar dynamical effects, is still partly unknown. In particular, models proposed so far, fail to explain the full set of experimental data. The well-accepted 'protein dynamical transition' scenario is based on perfect coupling between…
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