We examine stochastic coarse-graining strategies for two biomolecular systems. First,
we compute the large-scale transport properties of the basic flashing ratchet mathematical model
for (Brownian) molecular motors and consider in this light whether the underlying continuous-space,
continuous-time Markovian model can be coarse-grained as a discrete-state, continuous-time Markovian
random walk model. Through careful computation of associated statistical signatures of Markovianity,
we find that such a discrete coarse-graining is an excellent approximation over much but not
all of the parameter regime. In particular, for the parameter values associated with the fastest transport
by the flashing ratchet, the discretized model displays non-Markovian features such as waiting
times between jumps which are not exponentially distributed. We provide a theoretical framework
for understanding the conditions under which Markovianity is to be expected in the discretized
model and two mechanisms by which the flashing ratchet model coarse-grains to a non-Markovian
discretized model. Next we turn to a basic question of how the dynamics of water molecules near
the surface of a solute can be represented by a simple drift-diffusion stochastic model. This question
is of most interest for the purpose of accelerating molecular dynamics simulations of proteins, but
for simplicity, here we examine the simple case where the solute is a C60 buckyball, which has a
homogenous, roughly isotropic form. We compare the mathematical drift-diffusion framework with
a statistical quantification of water dynamics near a solute discussed in the biophysical literature.
A key concern is the choice of time interval on which to sample the molecular dynamics data to
generate estimators for the drift and diffusivity. We use a simple mathematical toy model to establish
insight and a strategy, but find for the actual molecular dynamics data that the sampling times
which produce the most faithful drift coefficient and the sampling times which produce the most
faithful diffusion coefficient do not overlap, so that sacrifice of quality in one or the other parameter
appears necessary.
@article{1274816892,
author = {Kramer, Peter R. and Latorre, Juan C. and Khan, Adnan A.},
title = {Two coarse-graining studies of stochastic models in molecular biology},
journal = {Commun. Math. Sci.},
volume = {8},
number = {1},
year = {2010},
pages = { 481-517},
language = {en},
url = {http://dml.mathdoc.fr/item/1274816892}
}
Kramer, Peter R.; Latorre, Juan C.; Khan, Adnan A. Two coarse-graining studies of stochastic models in molecular biology. Commun. Math. Sci., Tome 8 (2010) no. 1, pp. 481-517. http://gdmltest.u-ga.fr/item/1274816892/