AI Article Synopsis
- The study presents initial parameters for heme redox cofactors using the AMOEBA force field, focusing on their ferric and ferrous forms and two different ligand configurations.
- Validation of these parameters is achieved through comparisons of AMOEBA interaction energies with results from quantum mechanical methods like MP2 and DFT, demonstrating good agreement, especially in electrostatic interactions.
- The research includes long molecular dynamics simulations of cytochromes with various AMOEBA water models, suggesting that this approach could enhance the understanding and application of the AMOEBA force field in hemeprotein studies.
Article Abstract
We report the first parameters of the heme redox cofactors for the polarizable AMOEBA force field in both the ferric and ferrous forms. We consider two types of complexes, one with two histidine side chains as axial ligands and one with a histidine and a methionine side chain as ligands. We have derived permanent multipoles from second-order Møller-Plesset perturbation theory (MP2). The sets of parameters have been validated in a first step by comparison of AMOEBA interaction energies of heme and a collection of biologically relevant molecules with MP2 and Density Functional Theory (DFT) calculations. In a second validation step, we consider interaction energies with large aggregates comprising around 80 HO molecules. These calculations are repeated for 30 structures extracted from semiempirical PM7 DM simulations. Very encouraging agreement is found between DFT and the AMOEBA force field, which results from an accurate treatment of electrostatic interactions. We finally report long (10 ns) MD simulations of cytochromes in two redox states with AMOEBA testing both the 2003 and 2014 AMOEBA water models. These simulations have been carried out with the TINKER-HP (High Performance) program. In conclusion, owing to their ubiquity in biology, we think the present work opens a wide array of applications of the polarizable AMOEBA force field on hemeproteins.
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| http://dx.doi.org/10.1021/acs.jctc.7b01128 | DOI Listing |
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