Your search keyword '"Theoretical Methods and Algorithms"' showing total 6 results

1. A critical perspective on Markov state model treatments of protein–protein association using coarse-grained simulations

Author

Fabian Paul, Ziwei He, and Benoît Roux

Subjects

Structure (mathematical logic), 010304 chemical physics, Markov chain, Stochastic modelling, Computer science, General Physics and Astronomy, Sampling (statistics), Context (language use), 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, ARTICLES, Robustness (computer science), Theoretical Methods and Algorithms, 0103 physical sciences, Statistical physics, Sensitivity (control systems), Physical and Theoretical Chemistry, Set (psychology)

Abstract

Atomic-level information is essential to explain the specific interactions governing protein-protein recognition in terms of structure and dynamics. Of particular interest is a characterization of the time-dependent kinetic aspects of protein-protein association and dissociation. A powerful framework to characterize the dynamics of complex molecular systems is provided by Markov State Models (MSMs). The central idea is to construct a reduced stochastic model of the full system by defining a set of conformational featured microstates and determining the matrix of transition probabilities between them. While a MSM framework can sometimes be very effective, different combinations of input featurization and simulation methods can significantly affect the robustness and the quality of the information generated from MSMs in the context of protein association. Here, a systematic examination of a variety of MSMs methodologies is undertaken to clarify these issues. To circumvent the uncertainties caused by sampling issues, we use a simplified coarse-grained model of the barnase-barstar protein complex. A sensitivity analysis is proposed to identify the microstates of an MSM that contribute most to the error in conjunction with the transition-based reweighting analysis method for a more efficient and accurate MSM construction.

Published

2021

2. Hierarchical algorithm for the reaction-diffusion master equation

Author

Andreas Hellander and Stefan Hellander

Subjects

Coupling, Mesoscopic physics, 010304 chemical physics, Computer science, General Physics and Astronomy, Computational mathematics, 010402 general chemistry, 01 natural sciences, 0104 chemical sciences, law.invention, ARTICLES, Orders of magnitude (time), law, Theoretical Methods and Algorithms, 0103 physical sciences, Reaction–diffusion system, Master equation, Polygon mesh, Cartesian coordinate system, Statistical physics, Physical and Theoretical Chemistry

Abstract

We have developed an algorithm coupling mesoscopic simulations on different levels in a hierarchy of Cartesian meshes. Based on the multiscale nature of the chemical reactions, some molecules in the system will live on a fine-grained mesh, while others live on a coarse-grained mesh. By allowing molecules to transfer from the fine levels to the coarse levels when appropriate, we show that we can save up to three orders of magnitude of computational time compared to microscopic simulations or highly resolved mesoscopic simulations, without losing significant accuracy. We demonstrate this in several numerical examples with systems that cannot be accurately simulated with a coarse-grained mesoscopic model.

Published

2020

3. Modeling delay in genetic networks: From delay birth-death processes to delay stochastic differential equations

Author

José Manuel López, Matthew R. Bennett, Krešimir Josić, Robert Azencott, Chinmaya Gupta, and William Ott

Subjects

Differential equation, Computer science, Molecular Networks (q-bio.MN), Gene regulatory network, General Physics and Astronomy, FOS: Physical sciences, Quantitative Biology - Quantitative Methods, Stochastic differential equation, Negative feedback, Theoretical Methods and Algorithms, Applied mathematics, Quantitative Biology - Molecular Networks, Computer Simulation, Gene Regulatory Networks, RNA, Messenger, Physical and Theoretical Chemistry, Temporal information, Mathematical Physics, Quantitative Methods (q-bio.QM), Stochastic Processes, Stochastic process, Proteins, Mathematical Physics (math-ph), 60G07, 60K10, 92B05, 92C40, Langevin equation, FOS: Biological sciences, Algorithms, Signal Transduction

Abstract

Delay is an important and ubiquitous aspect of many biochemical processes. For example, delay plays a central role in the dynamics of genetic regulatory networks as it stems from the sequential assembly of first mRNA and then protein. Genetic regulatory networks are therefore frequently modeled as stochastic birth-death processes with delay. Here we examine the relationship between delay birth-death processes and their appropriate approximating delay chemical Langevin equations. We prove that the distance between these two descriptions, as measured by expectations of functionals of the processes, converges to zero with increasing system size. Further, we prove that the delay birth-death process converges to the thermodynamic limit as system size tends to infinity. Our results hold for both fixed delay and distributed delay. Simulations demonstrate that the delay chemical Langevin approximation is accurate even at moderate system sizes. It captures dynamical features such as the spatial and temporal distributions of transition pathways in metastable systems, oscillatory behavior in negative feedback circuits, and cross-correlations between nodes in a network. Overall, these results provide a foundation for using delay stochastic differential equations to approximate the dynamics of birth-death processes with delay.

Published

2014

4. Proximal distributions from angular correlations: A measure of the onset of coarse-graining

Author

Kippi M. Dyer and B. Montgomery Pettitt

Subjects

Length scale, Work (thermodynamics), Quantitative Biology::Biomolecules, Alanine, Hierarchy (mathematics), Chemistry, General Physics and Astronomy, Pair distribution function, Water, Measure (mathematics), Distribution function, Models, Chemical, Computational chemistry, Theoretical Methods and Algorithms, Thermodynamics, Point (geometry), Granularity, Statistical physics, Physical and Theoretical Chemistry, Oligopeptides, Algorithms

Abstract

In this work we examine and extend the theory of proximal radial distribution functions for molecules in solution. We point out two formal extensions, the first of which generalizes the proximal distribution function hierarchy approach to the complete, angularly dependent molecular pair distribution function. Second, we generalize from the traditional right-handed solute-solvent proximal distribution functions to the left-handed distributions. The resulting neighbor hierarchy convergence is shown to provide a measure of the coarse-graining of the internal solute sites with respect to the solvent. Simulation of the test case of a deca-alanine peptide shows that this coarse-graining measure converges at a length scale of approximately 5 amino acids for the system considered.

Published

2013

5. Calculating the binding free energies of charged species based on explicit-solvent simulations employing lattice-sum methods: An accurate correction scheme for electrostatic finite-size effects

Author

Philippe H. Hünenberger, David L. Mobley, Ken A. Dill, and Gabriel J. Rocklin

Subjects

Binding energy, Static Electricity, General Physics and Astronomy, Saccharomyces cerevisiae, Molecular Dynamics Simulation, Ligands, Molecular physics, Molecular dynamics, Engineering, Quantum mechanics, Theoretical Methods and Algorithms, Periodic boundary conditions, Boundary value problem, Physical and Theoretical Chemistry, Quantitative Biology::Biomolecules, Chemical Physics, Chemistry, Solvation, Water, Charge (physics), Cytochrome-c Peroxidase, Electrostatics, Thiazoles, Physical Sciences, Chemical Sciences, Mutation, Solvents, Thermodynamics, Solvent effects

Abstract

The calculation of a protein-ligand binding free energy based on molecular dynamics (MD) simulations generally relies on a thermodynamic cycle in which the ligand is alchemically inserted into the system, both in the solvated protein and free in solution. The corresponding ligand-insertion free energies are typically calculated in nanoscale computational boxes simulated under periodic boundary conditions and considering electrostatic interactions defined by a periodic lattice-sum. This is distinct from the ideal bulk situation of a system of macroscopic size simulated under non-periodic boundary conditions with Coulombic electrostatic interactions. This discrepancy results in finite-size effects, which affect primarily the charging component of the insertion free energy, are dependent on the box size, and can be large when the ligand bears a net charge, especially if the protein is charged as well. This article investigates finite-size effects on calculated charging free energies using as a test case the binding of the ligand 2-amino-5-methylthiazole (net charge +1 e) to a mutant form of yeast cytochrome c peroxidase in water. Considering different charge isoforms of the protein (net charges -5, 0, +3, or +9 e), either in the absence or the presence of neutralizing counter-ions, and sizes of the cubic computational box (edges ranging from 7.42 to 11.02 nm), the potentially large magnitude of finite-size effects on the raw charging free energies (up to 17.1 kJ mol(-1)) is demonstrated. Two correction schemes are then proposed to eliminate these effects, a numerical and an analytical one. Both schemes are based on a continuum-electrostatics analysis and require performing Poisson-Boltzmann (PB) calculations on the protein-ligand system. While the numerical scheme requires PB calculations under both non-periodic and periodic boundary conditions, the latter at the box size considered in the MD simulations, the analytical scheme only requires three non-periodic PB calculations for a given system, its dependence on the box size being analytical. The latter scheme also provides insight into the physical origin of the finite-size effects. These two schemes also encompass a correction for discrete solvent effects that persists even in the limit of infinite box sizes. Application of either scheme essentially eliminates the size dependence of the corrected charging free energies (maximal deviation of 1.5 kJ mol(-1)). Because it is simple to apply, the analytical correction scheme offers a general solution to the problem of finite-size effects in free-energy calculations involving charged solutes, as encountered in calculations concerning, e.g., protein-ligand binding, biomolecular association, residue mutation, pKa and redox potential estimation, substrate transformation, solvation, and solvent-solvent partitioning.

Published

2013

6. The application of the thermodynamic perturbation theory to study the hydrophobic hydration

Author

Tomaz Urbic, Tomaž Mohorič, and Barbara Hribar-Lee

Subjects

Standard enthalpy of reaction, Quantitative Biology::Biomolecules, Chemistry, Monte Carlo method, Enthalpy, Solvation, General Physics and Astronomy, Thermodynamics, Water, Hydrophobic effect, Free energy perturbation, Entropy (classical thermodynamics), Models, Chemical, Theoretical Methods and Algorithms, Water model, Computer Simulation, Physical and Theoretical Chemistry, Hydrophobic and Hydrophilic Interactions, Monte Carlo Method

Abstract

The thermodynamic perturbation theory was tested against newly obtained Monte Carlo computer simulations to describe the major features of the hydrophobic effect in a simple 3D-Mercedes-Benz water model: the temperature and hydrophobe size dependence on entropy, enthalpy, and free energy of transfer of a simple hydrophobic solute into water. An excellent agreement was obtained between the theoretical and simulation results. Further, the thermodynamic perturbation theory qualitatively correctly (with respect to the experimental data) describes the solvation thermodynamics under conditions where the simulation results are difficult to obtain with good enough accuracy, e.g., at high pressures.

Published

2013