Your search keyword '"Ji, Chang G."' showing total 2 results

1. Molecular dynamics study of DNA binding by INT-DBD under a polarized force field.

Author

Yao, Xue X., Ji, Chang G., Xie, Dai Q., and Zhang, John Z.H.

Subjects

*DNA-binding proteins, *MOLECULAR dynamics, *MOLECULAR force constants, *TRANSPOSONS, *INTEGRASES, *ELECTROSTATICS, *BINDING energy, *POLARIZATION (Electricity), *HYDROGEN bonding

Abstract

The DNA binding domain of transposon Tn916 integrase (INT-DBD) binds to DNA target site by positioning the face of a three-stranded antiparallel β-sheet within the major groove. As the negatively charged DNA directly interacts with the positively charged residues (such as Arg and Lys) of INT-DBD, the electrostatic interaction is expected to play an important role in the dynamical stability of the protein-DNA binding complex. In the current work, the combined use of quantum-based polarized protein-specific charge (PPC) for protein and polarized nucleic acid-specific charge (PNC) for DNA were employed in molecular dynamics simulation to study the interaction dynamics between INT-DBD and DNA. Our study shows that the protein-DNA structure is stabilized by polarization and the calculated protein-DNA binding free energy is in good agreement with the experimental data. Furthermore, our study revealed a positive correlation between the measured binding energy difference in alanine mutation and the occupancy of the corresponding residue's hydrogen bond. This correlation relation directly relates the contribution of a specific residue to protein-DNA binding energy to the strength of the hydrogen bond formed between the specific residue and DNA. © 2013 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2013

2. Effect of Interprotein Polarization on Protein-Protein Binding Energy.

Author

Ji, Chang G. and Zhang, John Z. H.

Subjects

*PROTEIN-protein interactions, *BINDING energy, *MOLECULAR dynamics, *HYDROGEN bonding, *CHARGE-charge interactions

Abstract

Molecular dynamics simulation in explicit water for the binding of the benchmark barnase-barstar complex was carried out to investigate the effect polarization of interprotein hydrogen bonds on its binding free energy. Our study is based on the AMBER force field but with polarized atomic charges derived from fragment quantum mechanical calculation for the protein complex. The quantum-derived atomic charges include the effect of polarization of interprotein hydrogen bonds, which was absent in the standard force fields that were used in previous theoretical calculations of barnase-barstar binding energy. This study shows that this polarization effect impacts both the static (electronic) and dynamic interprotein electrostatic interactions and significantly lowers the free energy of the barnase-barstar complex. [ABSTRACT FROM AUTHOR]

Published

2012