Part I: Basis of ATP Hydrolysis Reaction -- 1. Free Energy Analyses for the ATP Hydrolysis in Aqueous Solution by Large-Scale QM/MM Simulations Combined with a Theory of Solutions -- 2. Role of Metal Ion Binding and Protonation in ATP Hydrolysis Energetics -- 3. Spatial Distribution of Ionic Hydration Energy and Hyper-mobile Water -- 4. Theoretical studies of strong attractive interaction between macro-anions mediated by multivalent metal cations and related association behavior: Effective interaction between ATP binding proteins can be regulated by hydrolysis -- 5. Statistical mechanical integral equation approach to reveal the solvation effect on hydrolysis free energy of ATP and its analogue -- 6. A Solvent Model of Nucleotide-protein interaction - Partition coefficients of phosphates in solvent-water mixtures- -- Part II: Basis of Protein-Ligand and Protein-Protein Interactions -- 7. Energetics of myosin-ATP hydrolysis by calorimetry -- 8. Orchestrated electrostatic interactions among myosin, actin, ATP, and water -- 9. Protonation/deprotonation of proteins by neutron diffraction structure analysis -- 10. All-atom analysis of free energy of protein solvation through molecular simulation and solution theory -- 11. Uni-directional propagation of structural changes in actin filaments -- 12. Functional mechanisms of ABC transporters as revealed by molecular simulations -- 13. Statistical thermodynamics on the binding of biomolecules -- Part III: Functioning Mechanisms of Protein Machinery -- 14. Ratchet model of motor proteins and its energetics -- 15. Single Molecule Analysis of Actomyosin in the Presence of Osmolyte -- 16. Novel intermolecular surface force unveils the driving force of actomyosin system -- 17. Extremophilic enzymes related to energy conversion -- 18. Functioning mechanism of ATP-driven proteins inferred on the basis of water-entropy effect -- 19. Controlling the motility of ATP-driven molecular motors using high hydrostatic pressure -- 20. Modulation of the sliding movement of myosin-driven actin filaments associated with their distortion: The effect of ATP, ADP, and inorganic phosphate.