Saved in:
Bibliographic Details
Main Authors: Oestereich, Marco, Gauss, Jürgen, Diezemann, Gregor
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2407.11838
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866911957227929600
author Oestereich, Marco
Gauss, Jürgen
Diezemann, Gregor
author_facet Oestereich, Marco
Gauss, Jürgen
Diezemann, Gregor
contents The unfolding of molecular complexes or biomolecules under the influence of external mechanical forces can routinely be simulated with atomistic resolution. To obtain a match of the characteristic time scales with those of experimental force spectroscopy, often coarse graining procedures are employed. Here, building on a previous study, we apply the adaptice resolution scheme (AdResS) to force probe molecular dynamics (FPMD) simulations using two model systems as examples. One system is the previously investigated calix[4]arene dimer that shows reversible one-step unfolding and the other example is provided by a small peptide, a $β$-alanine octamer in methanol solvent. The mechanical unfolding of this peptide proceeds via a metastable intermediate and therefore represents a first step towards a complex unfolding pathway. In addition to increasing the complexity of the relevant conformational changes we study the impact of the methodology used for coarse graining. Apart from a standard technique, the iterative Boltzmann inversion method, we apply an ideal gas approximation and therefore we replace the solvent by a non-interacting system of spherical particles. In all cases we find excellent agreement between the results of FPMD simulations performed fully atomistically and the AdResS simulations also in the case of fast pulling. This holds for all details of the unfolding pathways like the distributions of the characteristic forces and also the sequence of hydrogen-bond opening in case of the $β$-alanine octamer. Therefore, the methodology is very well suited to simulate the mechanical unfolding of systems of experimental relevance also in the presence of protic solvents.
format Preprint
id arxiv_https___arxiv_org_abs_2407_11838
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Adaptive Resolution Force Probe Simulations: Coarse Graining in the Ideal Gas Approximation
Oestereich, Marco
Gauss, Jürgen
Diezemann, Gregor
Soft Condensed Matter
The unfolding of molecular complexes or biomolecules under the influence of external mechanical forces can routinely be simulated with atomistic resolution. To obtain a match of the characteristic time scales with those of experimental force spectroscopy, often coarse graining procedures are employed. Here, building on a previous study, we apply the adaptice resolution scheme (AdResS) to force probe molecular dynamics (FPMD) simulations using two model systems as examples. One system is the previously investigated calix[4]arene dimer that shows reversible one-step unfolding and the other example is provided by a small peptide, a $β$-alanine octamer in methanol solvent. The mechanical unfolding of this peptide proceeds via a metastable intermediate and therefore represents a first step towards a complex unfolding pathway. In addition to increasing the complexity of the relevant conformational changes we study the impact of the methodology used for coarse graining. Apart from a standard technique, the iterative Boltzmann inversion method, we apply an ideal gas approximation and therefore we replace the solvent by a non-interacting system of spherical particles. In all cases we find excellent agreement between the results of FPMD simulations performed fully atomistically and the AdResS simulations also in the case of fast pulling. This holds for all details of the unfolding pathways like the distributions of the characteristic forces and also the sequence of hydrogen-bond opening in case of the $β$-alanine octamer. Therefore, the methodology is very well suited to simulate the mechanical unfolding of systems of experimental relevance also in the presence of protic solvents.
title Adaptive Resolution Force Probe Simulations: Coarse Graining in the Ideal Gas Approximation
topic Soft Condensed Matter
url https://arxiv.org/abs/2407.11838