882 |
|
\] |
883 |
|
|
884 |
|
\section{\label{introSection:molecularDynamics}Molecular Dynamics} |
885 |
– |
|
886 |
– |
As a special discipline of molecular modeling, Molecular dynamics |
887 |
– |
has proven to be a powerful tool for studying the functions of |
888 |
– |
biological systems, providing structural, thermodynamic and |
889 |
– |
dynamical information. |
885 |
|
|
886 |
< |
One of the principal tools for modeling proteins, nucleic acids and |
887 |
< |
their complexes. Stability of proteins Folding of proteins. |
888 |
< |
Molecular recognition by:proteins, DNA, RNA, lipids, hormones STP, |
889 |
< |
etc. Enzyme reactions Rational design of biologically active |
890 |
< |
molecules (drug design) Small and large-scale conformational |
891 |
< |
changes. determination and construction of 3D structures (homology, |
892 |
< |
Xray diffraction, NMR) Dynamic processes such as ion transport in |
893 |
< |
biological systems. |
894 |
< |
|
895 |
< |
Macroscopic properties are related to microscopic behavior. |
886 |
> |
As one of the principal tools of molecular modeling, Molecular |
887 |
> |
dynamics has proven to be a powerful tool for studying the functions |
888 |
> |
of biological systems, providing structural, thermodynamic and |
889 |
> |
dynamical information. The basic idea of molecular dynamics is that |
890 |
> |
macroscopic properties are related to microscopic behavior and |
891 |
> |
microscopic behavior can be calculated from the trajectories in |
892 |
> |
simulations. For instance, instantaneous temperature of an |
893 |
> |
Hamiltonian system of $N$ particle can be measured by |
894 |
> |
\[ |
895 |
> |
T(t) = \sum\limits_{i = 1}^N {\frac{{m_i v_i^2 }}{{fk_B }}} |
896 |
> |
\] |
897 |
> |
where $m_i$ and $v_i$ are the mass and velocity of $i$th particle |
898 |
> |
respectively, $f$ is the number of degrees of freedom, and $k_B$ is |
899 |
> |
the boltzman constant. |
900 |
|
|
901 |
< |
Time dependent (and independent) microscopic behavior of a molecule |
902 |
< |
can be calculated by molecular dynamics simulations. |
903 |
< |
|
904 |
< |
\subsection{\label{introSec:mdInit}Initialization} |
901 |
> |
A typical molecular dynamics run consists of three essential steps: |
902 |
> |
\begin{enumerate} |
903 |
> |
\item Initialization |
904 |
> |
\begin{enumerate} |
905 |
> |
\item Preliminary preparation |
906 |
> |
\item Minimization |
907 |
> |
\item Heating |
908 |
> |
\item Equilibration |
909 |
> |
\end{enumerate} |
910 |
> |
\item Production |
911 |
> |
\item Analysis |
912 |
> |
\end{enumerate} |
913 |
> |
These three individual steps will be covered in the following |
914 |
> |
sections. Sec.~\ref{introSec:initialSystemSettings} deals with the |
915 |
> |
initialization of a simulation. Sec.~\ref{introSec:production} will |
916 |
> |
discusses issues in production run, including the force evaluation |
917 |
> |
and the numerical integration schemes of the equations of motion . |
918 |
> |
Sec.~\ref{introSection:Analysis} provides the theoretical tools for |
919 |
> |
trajectory analysis. |
920 |
|
|
921 |
< |
\subsection{\label{introSec:forceEvaluation}Force Evaluation} |
921 |
> |
\subsection{\label{introSec:initialSystemSettings}Initialization} |
922 |
> |
|
923 |
> |
\subsubsection{Preliminary preparation} |
924 |
> |
|
925 |
> |
When selecting the starting structure of a molecule for molecular |
926 |
> |
simulation, one may retrieve its Cartesian coordinates from public |
927 |
> |
databases, such as RCSB Protein Data Bank \textit{etc}. Although |
928 |
> |
thousands of crystal structures of molecules are discovered every |
929 |
> |
year, many more remain unknown due to the difficulties of |
930 |
> |
purification and crystallization. Even for the molecule with known |
931 |
> |
structure, some important information is missing. For example, the |
932 |
> |
missing hydrogen atom which acts as donor in hydrogen bonding must |
933 |
> |
be added. Moreover, in order to include electrostatic interaction, |
934 |
> |
one may need to specify the partial charges for individual atoms. |
935 |
> |
Under some circumstances, we may even need to prepare the system in |
936 |
> |
a special setup. For instance, when studying transport phenomenon in |
937 |
> |
membrane system, we may prepare the lipids in bilayer structure |
938 |
> |
instead of placing lipids randomly in solvent, since we are not |
939 |
> |
interested in self-aggregation and it takes a long time to happen. |
940 |
|
|
941 |
< |
\subsection{\label{introSection:mdIntegration} Integration of the Equations of Motion} |
941 |
> |
\subsubsection{Minimization} |
942 |
|
|
943 |
+ |
It is quite possible that some of molecules in the system from |
944 |
+ |
preliminary preparation may be overlapped with each other. This |
945 |
+ |
close proximity leads to high potential energy which consequently |
946 |
+ |
jeopardizes any molecular dynamics simulations. To remove these |
947 |
+ |
steric overlaps, one typically performs energy minimization to find |
948 |
+ |
a more reasonable conformation. Several energy minimization methods |
949 |
+ |
have been developed to exploit the energy surface and to locate the |
950 |
+ |
local minimum. While converging slowly near the minimum, steepest |
951 |
+ |
descent method is extremely robust when systems are far from |
952 |
+ |
harmonic. Thus, it is often used to refine structure from |
953 |
+ |
crystallographic data. Relied on the gradient or hessian, advanced |
954 |
+ |
methods like conjugate gradient and Newton-Raphson converge rapidly |
955 |
+ |
to a local minimum, while become unstable if the energy surface is |
956 |
+ |
far from quadratic. Another factor must be taken into account, when |
957 |
+ |
choosing energy minimization method, is the size of the system. |
958 |
+ |
Steepest descent and conjugate gradient can deal with models of any |
959 |
+ |
size. Because of the limit of computation power to calculate hessian |
960 |
+ |
matrix and insufficient storage capacity to store them, most |
961 |
+ |
Newton-Raphson methods can not be used with very large models. |
962 |
+ |
|
963 |
+ |
\subsubsection{Heating} |
964 |
+ |
|
965 |
+ |
Typically, Heating is performed by assigning random velocities |
966 |
+ |
according to a Gaussian distribution for a temperature. Beginning at |
967 |
+ |
a lower temperature and gradually increasing the temperature by |
968 |
+ |
assigning greater random velocities, we end up with setting the |
969 |
+ |
temperature of the system to a final temperature at which the |
970 |
+ |
simulation will be conducted. In heating phase, we should also keep |
971 |
+ |
the system from drifting or rotating as a whole. Equivalently, the |
972 |
+ |
net linear momentum and angular momentum of the system should be |
973 |
+ |
shifted to zero. |
974 |
+ |
|
975 |
+ |
\subsubsection{Equilibration} |
976 |
+ |
|
977 |
+ |
The purpose of equilibration is to allow the system to evolve |
978 |
+ |
spontaneously for a period of time and reach equilibrium. The |
979 |
+ |
procedure is continued until various statistical properties, such as |
980 |
+ |
temperature, pressure, energy, volume and other structural |
981 |
+ |
properties \textit{etc}, become independent of time. Strictly |
982 |
+ |
speaking, minimization and heating are not necessary, provided the |
983 |
+ |
equilibration process is long enough. However, these steps can serve |
984 |
+ |
as a means to arrive at an equilibrated structure in an effective |
985 |
+ |
way. |
986 |
+ |
|
987 |
+ |
\subsection{\label{introSection:production}Production} |
988 |
+ |
|
989 |
+ |
\subsubsection{\label{introSec:forceCalculation}The Force Calculation} |
990 |
+ |
|
991 |
+ |
\subsubsection{\label{introSection:integrationSchemes} Integration |
992 |
+ |
Schemes} |
993 |
+ |
|
994 |
+ |
\subsection{\label{introSection:Analysis} Analysis} |
995 |
+ |
|
996 |
|
\section{\label{introSection:rigidBody}Dynamics of Rigid Bodies} |
997 |
|
|
998 |
|
Rigid bodies are frequently involved in the modeling of different |
1241 |
|
e^{\Delta tR_1 } \approx (1 - \Delta tR_1 )^{ - 1} (1 + \Delta tR_1 |
1242 |
|
) |
1243 |
|
\] |
1244 |
< |
|
1160 |
< |
The flow maps for $T_2^r$ and $T_2^r$ can be found in the same |
1244 |
> |
The flow maps for $T_2^r$ and $T_3^r$ can be found in the same |
1245 |
|
manner. |
1246 |
|
|
1247 |
|
In order to construct a second-order symplectic method, we split the |
1564 |
|
coefficient $\xi _0$ can either be calculated from spectral density |
1565 |
|
or be determined by Stokes' law for regular shaped particles.A |
1566 |
|
briefly review on calculating friction tensor for arbitrary shaped |
1567 |
< |
particles is given in section \ref{introSection:frictionTensor}. |
1567 |
> |
particles is given in Sec.~\ref{introSection:frictionTensor}. |
1568 |
|
|
1569 |
|
\subsubsection{\label{introSection:secondFluctuationDissipation}The Second Fluctuation Dissipation Theorem} |
1570 |
|
|