Your search keyword '"Jaebeom Han"' showing total 6 results

1. Determining the atomic charge of calcium ion requires the information of its coordination geometry in an EF-hand motif

Author

Margaret S. Cheung, Piotr Cieplak, Jaebeom Han, and Pengzhi Zhang

Subjects

Quantitative Biology - Subcellular Processes, Static Electricity, Ab initio, General Physics and Astronomy, Ionic bonding, Context (language use), Molecular Dynamics Simulation, 010402 general chemistry, 01 natural sciences, Quantitative Biology::Cell Behavior, Coordination complex, Quantitative Biology::Subcellular Processes, ARTICLES, Calmodulin, 0103 physical sciences, Animals, Humans, Molecule, EF Hand Motifs, Physical and Theoretical Chemistry, Subcellular Processes (q-bio.SC), Coordination geometry, Physics, chemistry.chemical_classification, Quantitative Biology::Biomolecules, Binding Sites, Quantitative Biology::Neurons and Cognition, 010304 chemical physics, Force field (physics), Water, Biomolecules (q-bio.BM), 0104 chemical sciences, Atomic radius, Quantitative Biology - Biomolecules, chemistry, Chemical physics, FOS: Biological sciences, Quantum Theory, Calcium, Cattle, Protein Binding

Abstract

It is challenging to parameterize the force field for calcium ions (Ca2+) in calcium-binding proteins because of their unique coordination chemistry that involves the surrounding atoms required for stability. In this work, we observed wide variation in Ca2+ binding loop conformations of the Ca2+-binding protein calmodulin (CaM), which adopts the most populated ternary structures determined from the MD simulations, followed by ab initio quantum mechanical (QM) calculations on all twelve amino acids in the loop that coordinate Ca2+ in aqueous solution. Ca2+ charges were derived by fitting to the electrostatic potential (ESP) in the context of a classical or polarizable force field (PFF). We discovered that the atomic radius of Ca2+ in conventional force fields is too large for the QM calculation to capture the variation in the coordination geometry of Ca2+ in its ionic form, leading to unphysical charges. Specifically, we found that the fitted atomic charges of Ca2+ in the context of PFF depend on the coordinating geometry of electronegative atoms from the amino acids in the loop. Although nearby water molecules do not influence the atomic charge of Ca2+, they are crucial for compensating for the coordination of Ca2+ due to the conformational flexibility in the EF-hand loop. Our method advances the development of force fields for metal ions and protein binding sites in dynamic environments., Comment: The following article has been accepted by Journal of Chemical Physics

Published

2021

2. Phenol-benzene complexation dynamics: Quantum chemistry calculation, molecular dynamics simulations, and two dimensional IR spectroscopy.

Author

Kijeong Kwac, Chewook Lee, Yousung Jung, Jaebeom Han, Kyungwon Kwak, Junrong Zheng, Fayer, M. D., and Minhaeng Cho

Subjects

PHENOL, BENZENE, QUANTUM chemistry, MOLECULAR dynamics, INFRARED spectroscopy, QUANTUM theory

Abstract

Molecular dynamics (MD) simulations and quantum mechanical electronic structure calculations are used to investigate the nature and dynamics of the phenol-benzene complex in the mixed solvent, benzene/CCl4. Under thermal equilibrium conditions, the complexes are continuously dissociating and forming. The MD simulations are used to calculate the experimental observables related to the phenol hydroxyl stretching mode, i.e., the two dimensional infrared vibrational echo spectrum as a function of time, which directly displays the formation and dissociation of the complex through the growth of off-diagonal peaks, and the linear absorption spectrum, which displays two hydroxyl stretch peaks, one for the complex and one for the free phenol. The results of the simulations are compared to previously reported experimental data and are found to be in quite reasonable agreement. The electronic structure calculations show that the complex is T shaped. The classical potential used for the phenol-benzene interaction in the MD simulations is in good accord with the highest level of the electronic structure calculations. A variety of other features is extracted from the simulations including the relationship between the structure and the projection of the electric field on the hydroxyl group. The fluctuating electric field is used to determine the hydroxyl stretch frequency-frequency correlation function (FFCF). The simulations are also used to examine the number distribution of benzene and CCl4 molecules in the first solvent shell around the phenol. It is found that the distribution is not that of the solvent mole fraction of benzene. There are substantial probabilities of finding a phenol in either a pure benzene environment or a pure CCl4 environment. A conjecture is made that relates the FFCF to the local number of benzene molecules in phenol’s first solvent shell. [ABSTRACT FROM AUTHOR]

Published

2006

3. Explicit Polarization (X-Pol) Potential Using ab Initio Molecular Orbital Theory and Density Functional Theory

Author

Jiali Gao, Jaebeom Han, Lingchun Song, Yen-Lin Lin, and Wangshen Xie

Subjects

Hydrogen bond, Chemistry, Orbital-free density functional theory, Ab initio, Water, Hydrogen Bonding, Molecular orbital theory, Electronic structure, Time-dependent density functional theory, Molecular physics, Article, Physics::Atomic and Molecular Clusters, Quantum Theory, Density functional theory, Physics::Chemical Physics, Physical and Theoretical Chemistry, Atomic physics, Dimerization, Fragment molecular orbital

Abstract

The explicit polarization (X-Pol) method has been examined using ab initio molecular orbital theory and density functional theory. The X-Pol potential was designed to provide a novel theoretical framework for developing next-generation force fields for biomolecular simulations. Importantly, the X-Pol potential is a general method, which can be employed with any level of electronic structure theory. The present study illustrates the implementation of the X-Pol method using ab initio Hartree-Fock theory and hybrid density functional theory. The computational results are illustrated by considering a set of bimolecular complexes of small organic molecules and ions with water. The computed interaction energies and hydrogen bond geometries are in good accord with CCSD(T) calculations and B3LYP/aug-cc-pVDZ optimizations.

Published

2009

4. Classical and quantum mechanical/molecular mechanical molecular dynamics simulations of alanine dipeptide in water: comparisons with IR and vibrational circular dichroism spectra

Author

Kwang-Im Oh, Kyung Koo Lee, Jaebeom Han, Minhaeng Cho, and Kijeong Kwac

Subjects

Circular dichroism, Dipeptide, Spectrophotometry, Infrared, Circular Dichroism, Molecular Conformation, General Physics and Astronomy, Computational Biology, Water, Hydrogen Bonding, Dipeptides, Quantum chemistry, Molecular physics, Molecular dynamics, chemistry.chemical_compound, chemistry, Polarizability, Molecular vibration, Vibrational circular dichroism, Quantum Theory, Computer Simulation, Physical and Theoretical Chemistry, Mulliken population analysis

Abstract

We have implemented the combined quantum mechanical (QM)/molecular mechanical (MM) molecular dynamics (MD) simulations of alanine dipeptide in water along with the polarizable and nonpolarizable classical MD simulations with different models of water. For the QM/MM MD simulation, the alanine dipeptide is treated with the AM1 or PM3 approximations and the fluctuating solute dipole moment is calculated by the Mulliken population analysis. For the classical MD simulations, the solute is treated with the polarizable or nonpolarizable AMBER and polarizable CHARMM force fields and water is treated with the TIP3P, TIP4P, or TIP5P model. It is found that the relative populations of right-handed alpha-helix and extended beta and P(II) conformations in the simulation trajectory strongly depend on the simulation method. For the QM/MM MD simulations, the PM3/MM shows that the P(II) conformation is dominant, whereas the AM1/MM predicts that the dominant conformation is alpha(R). Polarizable CHARMM force field gives almost exclusively P(II) conformation and other force fields predict that both alpha-helical and extended (beta and P(II)) conformations are populated with varying extents. Solvation environment around the dipeptide is investigated by examining the radial distribution functions and numbers and lifetimes of hydrogen bonds. Comparing the simulated IR and vibrational circular dichroism spectra with experimental results, we concluded that the dipeptide adopts the P(II) conformation and PM3/MM, AMBER03 with TIP4P water, and AMBER polarizable force fields are acceptable for structure determination of the dipeptide considered in this paper.

Published

2008

5. Phenol-benzene complexation dynamics: quantum chemistry calculation, molecular dynamics simulations, and two dimensional IR spectroscopy

Author

Kijeong Kwac, Kyungwon Kwak, Yousung Jung, Minhaeng Cho, Chewook Lee, Jaebeom Han, Michael D. Fayer, and Junrong Zheng

Subjects

Models, Molecular, Absorption spectroscopy, Spectrophotometry, Infrared, Macromolecular Substances, Molecular Conformation, General Physics and Astronomy, Infrared spectroscopy, Electronic structure, Quantum chemistry, Molecular physics, chemistry.chemical_compound, Molecular dynamics, Physics::Atomic and Molecular Clusters, Vibrational energy relaxation, Computer Simulation, Physics::Chemical Physics, Physical and Theoretical Chemistry, Benzene, Carbon Tetrachloride, Phenol, chemistry, Models, Chemical, Chemical physics, Solvents, Quantum Theory, Density functional theory

Abstract

Molecular dynamics (MD) simulations and quantum mechanical electronic structure calculations are used to investigate the nature and dynamics of the phenol-benzene complex in the mixed solvent, benzene∕CCl4. Under thermal equilibrium conditions, the complexes are continuously dissociating and forming. The MD simulations are used to calculate the experimental observables related to the phenol hydroxyl stretching mode, i.e., the two dimensional infrared vibrational echo spectrum as a function of time, which directly displays the formation and dissociation of the complex through the growth of off-diagonal peaks, and the linear absorption spectrum, which displays two hydroxyl stretch peaks, one for the complex and one for the free phenol. The results of the simulations are compared to previously reported experimental data and are found to be in quite reasonable agreement. The electronic structure calculations show that the complex is T shaped. The classical potential used for the phenol-benzene interaction in the MD simulations is in good accord with the highest level of the electronic structure calculations. A variety of other features is extracted from the simulations including the relationship between the structure and the projection of the electric field on the hydroxyl group. The fluctuating electric field is used to determine the hydroxyl stretch frequency-frequency correlation function (FFCF). The simulations are also used to examine the number distribution of benzene and CCl4 molecules in the first solvent shell around the phenol. It is found that the distribution is not that of the solvent mole fraction of benzene. There are substantial probabilities of finding a phenol in either a pure benzene environment or a pure CCl4 environment. A conjecture is made that relates the FFCF to the local number of benzene molecules in phenol’s first solvent shell.

Published

2007

6. Quantum mechanical force field for water with explicit electronic polarization

Author

Michael J. M. Mazack, Jiali Gao, Donald G. Truhlar, Jaebeom Han, and Peng Zhang

Subjects

Physics, Intermolecular force, Water, General Physics and Astronomy, Electrons, Electronic structure, Liquids, Glasses, and Crystals, Potential energy, symbols.namesake, Chemical physics, Proton transport, Intramolecular force, symbols, Water model, Quantum Theory, Quantum-mechanical explanation of intermolecular interactions, Physical and Theoretical Chemistry, Atomic physics, Hamiltonian (quantum mechanics)

Abstract

A quantum mechanical force field (QMFF) for water is described. Unlike traditional approaches that use quantum mechanical results and experimental data to parameterize empirical potential energy functions, the present QMFF uses a quantum mechanical framework to represent intramolecular and intermolecular interactions in an entire condensed-phase system. In particular, the internal energy terms used in molecular mechanics are replaced by a quantum mechanical formalism that naturally includes electronic polarization due to intermolecular interactions and its effects on the force constants of the intramolecular force field. As a quantum mechanical force field, both intermolecular interactions and the Hamiltonian describing the individual molecular fragments can be parameterized to strive for accuracy and computational efficiency. In this work, we introduce a polarizable molecular orbital model Hamiltonian for water and for oxygen- and hydrogen-containing compounds, whereas the electrostatic potential responsible for intermolecular interactions in the liquid and in solution is modeled by a three-point charge representation that realistically reproduces the total molecular dipole moment and the local hybridization contributions. The present QMFF for water, which is called the XP3P (explicit polarization with three-point-charge potential) model, is suitable for modeling both gas-phase clusters and liquid water. The paper demonstrates the performance of the XP3P model for water and proton clusters and the properties of the pure liquid from about 900 × 10(6) self-consistent-field calculations on a periodic system consisting of 267 water molecules. The unusual dipole derivative behavior of water, which is incorrectly modeled in molecular mechanics, is naturally reproduced as a result of an electronic structural treatment of chemical bonding by XP3P. We anticipate that the XP3P model will be useful for studying proton transport in solution and solid phases as well as across biological ion channels through membranes.

Published

2013