From cdea7cbeb917120d09df674e2fdaa984a03e1df7 Mon Sep 17 00:00:00 2001 From: "W. Trevor King" Date: Fri, 21 Jun 2013 13:57:56 -0400 Subject: [PATCH] sawsim/discussion.tex: Rework sawsim Monte Carlo review Start with the big picture, and zoom in on the finer points. --- src/sawsim/discussion.tex | 60 ++++++++++++++++++--------------------- 1 file changed, 27 insertions(+), 33 deletions(-) diff --git a/src/sawsim/discussion.tex b/src/sawsim/discussion.tex index bf73a1f..bea8c66 100644 --- a/src/sawsim/discussion.tex +++ b/src/sawsim/discussion.tex @@ -759,29 +759,6 @@ solutions for unforced $k$ for cusp-like and quartic potentials. \section{Review of current research} -There are two main approaches to modeling protein domain unfolding -under tension: Bell's and Kramers'\citep{schlierf06,hummer03,dudko06}. -Bell introduced his model in the context of cell -adhesion\citep{bell78}, but it has been widely used to model -mechanical unfolding in -proteins\citep{rief97a,carrion-vazquez99b,schlierf06} due to its -simplicity and ease of use\citep{hummer03}. Kramers introduced his -theory in the context of thermally activated barrier crossings, which -is how we use it here. - -\subsection{Evolution of unfolding modeling} - -Evans introduced the saddle-point Kramers' approximation in a protein unfolding context in 1997 (\citet{evans97} Eqn.~3). -However, early work on mechanical unfolding focused on the simpler Bell model\citep{rief97a}.%TODO -In the early 2000's, the saddle-point/steepest-descent approximation to Kramer's model (\xref{hanggi90}{equation}{4.56c}) was introduced into our field\citep{dudko03,hyeon03}.%TODO -By the mid 2000's, the full-blown double-integral form of Kramer's model (\xref{hanggi90}{equation}{4.56b}) was in use\citep{schlierf06}.%TODO - -There have been some tangential attempts towards even fancier models. -\citet{dudko03} attempted to reduce the restrictions of the single-unfolding-path model. -\citet{hyeon03} attempted to measure the local roughness using temperature dependent unfolding. - -\subsection{History of simulations} - There is a long history of protein unfolding and unbinding simulations. Early work by \citet{grubmuller96} and \citet{izrailev97} focused on molecular dynamics (MD) simulations of @@ -797,14 +774,31 @@ validate their results. physical motion of atoms and molecules by numerically solving Newton's equations.} -\subsection{History of experimental AFM unfolding experiments} - -\begin{itemize} - \item \citet{rief97a}: -\end{itemize} - -\subsection{History of experimental laser tweezer unfolding experiments} +Within the Monte Carlo simulation approach, there are two main models +for protein domain unfolding under tension: Bell's and +Kramers'\citep{schlierf06,hummer03,dudko06}. Bell introduced his +model in the context of cell adhesion\citep{bell78}, but it has been +widely used to model mechanical unfolding in +proteins\citep{rief97a,carrion-vazquez99b,schlierf06} due to its +simplicity and ease of use\citep{hummer03}. Kramers introduced his +theory in the context of thermally activated barrier crossings, which +is how we use it here. -\begin{itemize} - \item \citet{izrailev97}: -\end{itemize} +Evans introduced the saddle-point Kramers' approximation in a protein +unfolding context in 1997 (\xref{evans97}{equation}{3}). However, +early work on mechanical unfolding focused on the simpler Bell +model\citep{rief97a}. In the early 2000's, the +saddle-point/steepest-descent approximation to Kramer's model +(\xref{hanggi90}{equation}{4.56c}) was introduced into our +field\citep{dudko03,hyeon03}. By the mid 2000's, the full-blown +double-integral form of Kramer's model +(\xref{hanggi90}{equation}{4.56b}) was in use\citep{schlierf06}. + +There have been some tangential attempts towards even fancier models: +\citet{dudko03} attempted to reduce the restrictions of the +single-unfolding-path model and \citet{hyeon03} attempted to measure +the local roughness using temperature dependent unfolding. However, +further work on these lines has been slow, because the Bell model fits +the data well despite its simplicity. For more complicated models to +gain ground, we need larger, more detailed datasets that expose +features which the Bell model doesn't capture. -- 2.26.2