Abstract
Solvent pH is an important property that defines the protonation state of the amino acids and, therefore, modulates the interactions and the conformational space of the biochemical systems. Generally, this thermodynamic variable is poorly considered in Molecular Dynamics (MD) simulations. Fortunately, this lack has been overcome by means of the Constant pH Molecular Dynamics (CPHMD) methods in the recent decades. Several studies have reported promising results from these approaches that include pH in simulations but focus on the prediction of the effective pKa of the amino acids. In this work, we want to shed some light on the CPHMD method and its implementation in the AMBER suitcase from a conformational point of view. To achieve this goal, we performed CPHMD and conventional MD (CMD) simulations of six protonatable amino acids in a blocked tripeptide structure to compare the conformational sampling and energy distributions of both methods. The results reveal strengths and weaknesses of the CPHMD method in the implementation of AMBER18 version. The change of the protonation state according to the chemical environment is presumably an improvement in the accuracy of the simulations. However, the simulations of the deprotonated forms are not consistent, which is related to an inaccurate assignment of the partial charges of the backbone atoms in the CPHMD residues. Therefore, we recommend the CPHMD methods of AMBER program but pointing out the need to compare structural properties with experimental data to bring reliability to the conformational sampling of the simulations.
Highlights
Nowadays, there are a large number of theoretical approaches that reproduce the behaviour of proteins in a multiple description level
The conformational profile of the blocked tripeptides was studied by delimitating the Ramachandran map in nine regions according to Rubio-Martinez et al [58], which are related with a certain conformation (C5, PII, αD, β2, C7axial, αL, α’, αR, and C7eq)
The conformational profile of the blocked tripeptides was studied by delimitating the Ramachandran map in nine regions according to Rubio-Martinez et al [58], which are related with a certain conformation6 o(fC250, PII, αD, β2, C7axial, αL, α’, αR, and C7eq)
Summary
There are a large number of theoretical approaches that reproduce the behaviour of proteins in a multiple description level. To overcome the resource limitation, many efforts have been focused on the enhanced-sampling techniques, currently providing a wide range of them, such as accelerated MD [7], metadynamics [8,9], replica exchange MD [10], etc. These new methods have been successful for a better exploration of the conformational space of biochemical systems, it seems that other aspects to improve the accuracy of the simulations have not been as developed as the mentioned above, e.g., solvent pH, force field parameterization, or water models
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