Molecular Recognition in a Diverse Set of Protein鈥揕igand Interactions Studied with Molecular Dynamics Simulations and End-Point Free Energy Calculations
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- 作者:Bo Wang ; Liwei Li ; Thomas D. Hurley ; Samy O. Meroueh
- 刊名:Journal of Chemical Information and Modeling
- 出版年:2013
- 出版时间:October 28, 2013
- 年:2013
- 卷:53
- 期:10
- 页码:2659-2670
- 全文大小:607K
- 年卷期:v.53,no.10(October 28, 2013)
- ISSN:1549-960X
文摘
End-point free energy calculations using MM-GBSA and MM-PBSA provide a detailed understanding of molecular recognition in protein鈥搇igand interactions. The binding free energy can be used to rank-order protein鈥搇igand structures in virtual screening for compound or target identification. Here, we carry out free energy calculations for a diverse set of 11 proteins bound to 14 small molecules using extensive explicit-solvent MD simulations. The structure of these complexes was previously solved by crystallography and their binding studied with isothermal titration calorimetry (ITC) data enabling direct comparison to the MM-GBSA and MM-PBSA calculations. Four MM-GBSA and three MM-PBSA calculations reproduced the ITC free energy within 1 kcal路mol鈥? highlighting the challenges in reproducing the absolute free energy from end-point free energy calculations. MM-GBSA exhibited better rank-ordering with a Spearman 蟻 of 0.68 compared to 0.40 for MM-PBSA with dielectric constant (蔚 = 1). An increase in 蔚 resulted in significantly better rank-ordering for MM-PBSA (蟻 = 0.91 for 蔚 = 10), but larger 蔚 significantly reduced the contributions of electrostatics, suggesting that the improvement is due to the nonpolar and entropy components, rather than a better representation of the electrostatics. The SVRKB scoring function applied to MD snapshots resulted in excellent rank-ordering (蟻 = 0.81). Calculations of the configurational entropy using normal-mode analysis led to free energies that correlated significantly better to the ITC free energy than the MD-based quasi-harmonic approach, but the computed entropies showed no correlation with the ITC entropy. When the adaptation energy is taken into consideration by running separate simulations for complex, apo, and ligand (MM-PBSAADAPT), there is less agreement with the ITC data for the individual free energies, but remarkably good rank-ordering is observed (蟻 = 0.89). Interestingly, filtering MD snapshots by prescoring protein鈥搇igand complexes with a machine learning-based approach (SVMSP) resulted in a significant improvement in the MM-PBSA results (蔚 = 1) from 蟻 = 0.40 to 蟻 = 0.81. Finally, the nonpolar components of MM-GBSA and MM-PBSA, but not the electrostatic components, showed strong correlation to the ITC free energy; the computed entropies did not correlate with the ITC entropy.