Your search keyword '"Thermodynamic integration method"' showing total 4 results

1. Free energy surface for rotamers of cis -enol malonaldehyde in aqueous solution studied by molecular dynamics calculations.

Author

Kojima, Hidekazu, Yamada, Atsushi, and Okazaki, Susumu

Subjects

*CONFORMATIONAL isomers, *MALONDIALDEHYDE, *FREE energy (Thermodynamics), *ENOLS, *AQUEOUS solutions, *MOLECULAR dynamics

Abstract

Two-dimensional free energy surfaces for four rotamers ofcis-enol malonaldehyde in water have been investigated by umbrella sampling molecular dynamics (MD) calculations. Biasing potential used in the umbrella sampling calculation was adopted to be the minus of conformational free energy preliminary obtained by the thermodynamic integration MD calculations for the rigid malonaldehyde whose stretching and bending were all fixed. The calculated free energy surface shows that, in water, a rotamer that has an intramolecular hydrogen bond is most stable among the rotamers. This is the same as that in vacuum, while order of relative stability of the other three rotamers is different in water and in vacuum. Inclusion of intramolecular vibrations changed the free energy surface little, i.e. at most 2.6 kJ/mol, which is much smaller than the solvation free energy. Free energy barriers from the most stable intramolecular hydrogen bonded rotamer to the others are lowered by hydration but they are still very high, >50 kJ/mol, such that the malonaldehyde molecule spends most of its time in water taking this conformation. Thus, reaction coordinate for intramolecular proton transfer reaction in water may be constructed assuming this rotamer. [ABSTRACT FROM AUTHOR]

Published

2015

2. Modelling copper-containing proteins

Author

Bosch, Marieke van den, Canters, G.W., and Leiden University

Subjects

Quercetinase, Phosphorescene decay times, Loop mobility, Azurin, Metal force field, Free energy calculation, Molecular Dynamics, Thermodynamic integration method, Blue copper proteins

Abstract

To be able to perform Molecular Dynamics (MD) simulations of proteins, a model is needed to describe the interactions between the atoms witin the protein. The interactions between a metal-ion, in this case copper, and a ligand can vary strongly so that a standard set can not be used. This thesis describes the development of a non-bonded and a covalently bonded force field for the copper-site by using an empirically resp. quantum chemically derived charge distribution. The force fields were applied on several instances. 1) It appears that the possible involvement of a mobile loop after substrate binding to the copper-containing quercetinase may help keeping the substrate in place. 2) It turns out that the thermodynamic integration method only allows qualitative predictions of the variation in redox potential observed for azurin variants. 3) The dynamics of the hydrophobic core of azurin variants were analysed in light of previous time dependent phosphorescence experiments. They stress the importance of charge and dipole variations of the surroundings of the tryptophane in the structure for its phosphorescence properties. 4) Finally MD simulations show that a loop, carrying an engineered cysteine, is able to undergo a large conformational change enabling to co-ordinate the copper site of azurin.

Published

2006

3. Buried Hydrogen Bond Interactions Contribute to the High Potency of Complement Factor D Inhibitors.

Author

Yang CY, Phillips JG, Stuckey JA, Bai L, Sun H, Delproposto J, Brown WC, and Chinnaswamy K

Abstract

Aberrant activation of the complement system is associated with diseases, including paroxysmal nocturnal hemoglobinuria and age-related macular degeneration. Complement factor D is the rate-limiting enzyme for activating the alternative pathway in the complement system. Recent development led to a class of potent amide containing pyrrolidine derived factor D inhibitors. Here, we used biochemical enzymatic and biolayer interferometry assays to demonstrate that the amide group improves the inhibitor potency by more than 80-fold. Our crystal structures revealed buried hydrogen bond interactions are important. Molecular orbital analysis from quantum chemistry calculations dissects the chemical groups participating in these interactions. Free energy calculation supports the differential contributions of the amide group to the binding affinities of these inhibitors. Cell-based hemolysis assay confirmed these compounds inhibit factor D mediated complement activation via the alternative pathway. Our study highlights the important interactions contributing to the high potency of factor D inhibitors reported recently.

Published

2016

4. Phase equilibria and nucleation in condensed phases: a statistical mechanical study

Author

Apte, Pankaj A.

Subjects

Engineering, Chemical, Bubble Nucleation, Crystal Nucleation, Melting Temperature, Sublimation Temperature, Solid fluid equilibrium, Thermodynamic integration method

Abstract

A molecular level understanding of nucleation occurring in condensed phases is important in a number of industrial applications like polymer foaming, sonolysis, manufacturing of drugs, polymorphic transformations, and metallic alloy production. The recently developed statistical mechanical approaches based on density functional theory and Monte Carlo (MC) simulation can provide valuable insight into these nucleation processes. In this work, we applied density functional theory to study bubble nucleation in a micellar solution. Our results showed that the presence of surfactant molecules lowers the free energy barrier of bubble nucleation. We also found that under moderate negative pressures, the stable micelle may evolve to form the critical bubble and the resulting free energy barrier is lower than that in the absence of this mechanism. A kinetic consideration revealed that the above mechanism is less effective at lower pressures closer to spinodal. Further, the mechanism of bubble nucleation from the stable micelle correlated well with the liquid-liquid miscibility. In another study, we aimed at understanding crystal nucleation in binary Lennard-Jones (LJ) mixtures. An important factor dictating the crystal nucleation behavior is the underlying phase diagram. Thus, we developed thermodynamic integration (TDI) methods that predict accurately the coexistence points on the phase diagram. In particular, we introduced a method to directly calculate Gibbs free energy difference between the solid and the liquid phases by connecting these phases by a reversible path. Further, we showed that this technique extends naturally to a binary mixture, which allows us to predict its melting temperature. We also developed a new technique to calculate sublimation temperature of single component and binary systems by TDI method. We used these methods to predict eutectic and spindle-shaped phase diagram for the LJ binary mixtures. We then studied the free energy surface for crystal nucleation using MC simulation aided by umbrella sampling technique at a few representative points on these phase diagrams. The emphasis in this work was to identify proper order parameters that correctly describe the crystal nucleation. Our work provides a useful starting point to study how the phase diagram affects the crystal nucleation behavior.

Published

2006