Redefining the concept of hydration water near soft interfaces

Water determines the properties of biological systems. Therefore, understanding the nature of the mutual interaction between water and biosystems is of primary importance for a proper assessment of any biological activity, e.g., the efficacy of new drugs or vaccines. A convenient way to characterize the interactions between biosystems and water is to analyze their impact on water density and dynamics in the proximity of the interfaces. It is commonly accepted that water bulk density and dynamical properties are recovered at distances of the order of 1 nm away from the surface of biological systems. This notion leads to the definition of hydration or biological water as the nanoscopic layer of water covering the surface of biosystems and to the expectation that all the effects of the water-interface interaction are limited to this thin region. Here, we review some of our latest contributions, showing that phospholipid membranes affect the water dynamics, structural properties, and hydrogen bond network at a distance that is more than twice as large as the commonly evoked similar to 1 nm thick layer and of the order of 2.4 nm. Furthermore, we unveil that at a shorter distance similar to 0.5 nm from the membrane, instead, there is an additional interface between lipid-bound and unbound water. Bound water has a structural role in the stability of the membrane. Our results imply that the concept of hydration water should be revised or extended and pave the way to a deeper understanding of the mutual interactions between water and biological systems. Published under license by AVS.

Automated summary

Water plays a crucial role in determining the properties of biological systems. Recent research has shown that phospholipid membranes impact water dynamics, structural properties, and hydrogen bond network at a distance of approximately 2.4 nm, which is more than twice the commonly accepted thickness of hydration water layer. This suggests that the concept of hydration water may need to be revised or expanded to deepen our understanding of the interactions between water and biological systems.