This book describes hydration structures of proteins by combining experimental results with theoretical considerations. It is designed to introduce graduate students and researchers to microscopic views of the interactions between water and biological macromolecules and to provide them with an overview of the field. Topics on protein hydration from the past 25 years are examined, most of which involve crystallography, fluorescence measurements, and molecular dynamics simulations.
In X-ray crystallography and molecular dynamics simulations, recent advances have accelerated the study of hydration structures over the entire surface of proteins. Experimentally, crystal structure analysis at cryogenic temperatures is advantageous in terms of visualizing the positions of hydration water molecules on the surfaces of proteins in their frozen-hydrated crystals. A set of massive data regarding hydration sites on protein surfaces provides an appropriate basis, enabling us to identify statistically significant trends in geometrical characteristics. Trajectories obtained from molecular dynamics simulations illustrate the motion of water molecules in the vicinity of protein surfaces at sufficiently high spatial and temporal resolution to study the influences of hydration on protein motion. Together with the results and implications of these studies, the physical principles of the measurement and simulation of protein hydration are briefly summarized at an undergraduate level.
Further, the author presents recent results from statistical approaches to characterizing hydrogen-bond geometry in local hydration structures of proteins. The book equips readers to better understand the structures and modes of interaction at the interface between water and proteins. Referred to as "hydration structures", they are the subject of much discussion, as they may help to answer the question of why water is indispensable for life at the molecular and atomic level.
Auteur
Masayoshi Nakasako is a professor at Keio University, and his work involves structural analysis of soft matter. He received his Doctor of Science from Tohoku University in 1990. After his doctoral program, he was a research associate at the Faculty of Pharmaceutical Sciences, The University of Tokyo; a researcher at RIKEN; a lecturer at the Institute of Molecular and Cellular Biosciences, The University of Tokyo; and an assistant professor at Keio University in 2002. In 2005, he was promoted to his present position. Currently, he also serves Spring-8 Center, RIKEN, as a guest researcher.
His research interest is in imaging of protein hydration, protein structures, and cells by various physicochemical experimental techniques including X-ray imaging using synchrotron radiation and X-ray free electron laser and molecular dynamics simulations.
Contenu
1.1 Water: the cradle of life
1.2 Structure and interaction of water molecules
1.2.1 Structure of water molecules
1.2.2 Interactions between water molecules
1.2.3 Hydrogen bond between water molecules
1.3 Phase diagram of water
1.3.1 Three phases of water
1.3.2 Hexagonal ice and amorphous ice 1.4 Properties of liquid water
1.4.1 Unusual physical properties
1.4.2 Brownian motion in liquid water
1.4.3 Structure of liquid water
1.5 Hydration
1.5.1 Solvation
1.5.2 Hydration
1.5.3 Hydration of hydrophobic molecules
1.6 Hydration structures of proteins
1.6.1 Proteins
1.6.2 Hydration structures of proteins
1.7 Scope of this monograph
References
2.1 Introduction
2.2 X-ray crystallography at cryogenic temperatures
2.2.1 Outline
2.2.2 Crystallographic structure refinement
2.2.3 Difference Fourier map
2.2.4 X-ray crystallography at cryogenic temperatures
2.3 Cryogenic electron microscopy 2.3.1 Outline
2.3.2 Specimen preparation and image collection
2.3.3 Image processing and single-particle analysis 2.4 Time-resolved fluorescence measurement
2.4.1 Outline
2.4.2 Up-conversion method 2.5 Molecular dynamic simulation
2.5.1 Outline
2.5.2 Force field References
3.1 Introduction
3.2 Water molecules inside proteins 3.2.1 Tightly-bound water molecules
3.2.2 Water molecules confined inside proteins
3.3 Hydration water molecules as glue in protein complexes
3.3.1 Hydration at the subunit interface of a protein complex
3.3.2 Hydration sites conserved in protein families
3.4 Hydration water molecules as lubricant at protein interface
3.5 Hydration water molecules in the ligand-binding sites References
4.1 Introduction
4.2 Hydration layer
4.2.1 First- and second-layer classes
4.2.2 Distance distribution and positional fluctuation
4.2.3 Monolayer hydration
4.2.4 Contact class
4.3 Local patterns in protein hydration
4.3.1 Patterns on hydrophilic surfaces 4.3.2 Hydration on hydrophobic surfaces
4.3.3 Tetrahedral hydrogen bond geometry of water molecules 4.4 Hydration structures in molecular dynamics simulation
4.4.1 Computation of solvent density
4.4.2 Characteristic of solvent density
References
5.1 Introduction
5.2 Empirical hydration distribution around polar atoms 5.2.1 Construction
5.2.2 Distribution around polar protein atoms
5.2.3 Hydration of aromatic acceptors 5.2.4 Characteristics and benefits of the empirical hydration distributions.
5.2.5 Tetrahedral hydrogen bond geometry
5.3 Assessment of force fields of polar protein atoms
5.3.1 Models of water molecule suitable for simulation
5.3.2 Hydration of deprotonated polar atoms in *sp*2-hybridization 5.3...