Your search keyword '"Hocky, Glen M."' showing total 3 results

1. A Minimal Experimental Bias on the Hydrogen Bond Greatly Improves Ab Initio Molecular Dynamics Simulations of Water

Author

Calio, Paul B., Hocky, Glen M., and Voth, Gregory A.

Subjects

Chemical Physics (physics.chem-ph), Physics - Chemical Physics, FOS: Physical sciences

Abstract

Experiment Directed Simulations (EDS) is a method within a class of techniques seeking to improve molecular simulations by minimally biasing the system Hamiltonian to reproduce certain experimental observables. In a previous application of EDS to ab initio molecular dynamics (AIMD) simulation-based on electronic density functional theory (DFT), the AIMD simulations of water were biased to reproduce its experimentally derived solvation structure. In particular, by solely biasing the O-O pair correlation functions, other structural and dynamical properties that were not biased were improved. In this work, the hypothesis is tested that directly biasing the OH pair correlation, will provide an even better improvement of DFT-based water properties in AIMD simulations. The logic behind this hypothesis is that for most electronic DFT descriptions of water the hydrogen bonding is known to be deficient due to anomalous charge transfer and over polarization in the DFT. Using recent advances to the EDS learning algorithm, we thus train a minimal bias on AIMD water that reproduces the O-H radial distribution function derived from the highly accurate MB-pol model of water. It is then confirmed that biasing the O-H pair correlation alone can lead to improved AIMD water properties, with structural and dynamical properties in even closer to experiment than the previous EDS-AIMD model., Comment: 28 pages, 10 total figures

Published

2020

2. A strong non-equilibrium bound for sorting of crosslinkers on growing biopolymers

Author

Qiu, Yuqing, Nguyen, Michael, Hocky, Glen M., Dinner, Aaron R., and Vaikuntanathan, Suriyanarayanan

Subjects

Quantitative Biology::Subcellular Processes, Statistical Mechanics (cond-mat.stat-mech), Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, macromolecular substances, Condensed Matter - Soft Condensed Matter, Condensed Matter - Statistical Mechanics, Quantitative Biology::Cell Behavior

Abstract

Understanding the role of non-equilibrium driving in self-organization is crucial for developing a predictive description of biological systems, yet it is impeded by their complexity. The actin cytoskeleton serves as a paradigm for how equilibrium and non-equilibrium forces combine to give rise to self-organization. Motivated by recent experiments that show that actin filament growth rates can tune the morphology of a growing actin bundle crosslinked by two competing types of actin binding proteins, we construct a minimal model for such a system and show that the dynamics are subject to a set of thermodynamic constraints that relate the non-equilibrium driving, bundle morphology, and molecular fluxes. The thermodynamic constraints reveal the importance of correlations between these molecular fluxes, and offer a route to estimating microscopic driving forces from microscopy experiments., Comment: 5 Figs + SI

Published

2020

3. Design principles for selective self-assembly of active networks

Author

Freedman, Simon L., Hocky, Glen M., Banerjee, Shiladitya, and Dinner, Aaron R.

Subjects

Quantitative Biology - Subcellular Processes, Biological Physics (physics.bio-ph), FOS: Biological sciences, Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, Physics - Biological Physics, macromolecular substances, Condensed Matter - Soft Condensed Matter, Subcellular Processes (q-bio.SC)

Abstract

Living cells dynamically modulate the local morphologies of their actin cytoskeletons to perform biological functions, including force transduction, intracellular transport, and cell division. A major challenge is to understand how diverse structures of the actin cytoskeleton are assembled from a limited set of molecular building blocks. Here we study the spontaneous self-assembly of a minimal model of cytoskeletal materials, consisting of semiflexible actin filaments, crosslinkers, and molecular motors. Using coarse-grained simulations, we demonstrate that by changing concentrations and kinetics of crosslinkers and motors we can generate three distinct structural phases of actomyosin assemblies: bundled, polarity-sorted, and contracted. We introduce new metrics to distinguish these structural phases and demonstrate their functional roles. We find that the binding kinetics of motors and crosslinkers can be tuned to optimize contractile force generation, motor transport, and mechanical response. By quantitatively characterizing the relationships between modes of cytoskeletal self-assembly, the resulting structures, and their functional consequences, our work suggests new principles for the design of active materials., Comment: 17 pages, 15 figures

Published

2017