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Fig8_methyl_frames.py
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Fig8_methyl_frames.py
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#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Copyright 2021 Albert Smith-Penzel
This file is part of Frames Theory Archive (FTA).
FTA is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
FTA is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with FTA. If not, see <https://www.gnu.org/licenses/>.
Questions, contact me at:
albert.smith-penzel@medizin.uni-leipzig.de
Created on Tue Jul 13 13:42:37 2021
@author: albertsmith
"""
import numpy as np
import pyDIFRATE as DR
import matplotlib.pyplot as plt
import matplotlib
from scipy.optimize import least_squares
font = {'family' : 'normal',
'weight' : 'normal',
'size' : 8}
matplotlib.rc('font', **font)
"This loads the MD trajectory into pyDIFRATE"
mol=DR.molecule('HETs_ILE254.pdb','HETs_ILE254.xtc')
#%% Define the frames
"We store the frames in a list, and then later load them into the frame analysis"
frames=list()
"""
'Type': Name of the function used for generating the frame
(see pyDIFRATE/Struct/frames.py, pyDIFRATE/Struct/special_frames.py)
'Nuc': Shortcut for selecting a particular pair of nuclei.
ivlal selects one group on every Ile, Val, Leu, Ala
'resids': List of residues to include (not required here – only one residue in trajectory)
'segids': List of segments to include (not required here – only one segment in trajectory)
'sigma': Time constant for post-processing (averaging of frame direction with Gaussian)
'n_bonds': Number of bonds away from methyl C–C group to define frame
"""
"Frames without post-process smoothing"
frames.append({'Type':'methylCC','Nuc':'ivlal','sigma':0})
frames.append({'Type':'side_chain_chi','Nuc':'ivlal','n_bonds':1,'sigma':0})
frames.append({'Type':'side_chain_chi','Nuc':'ivlal','n_bonds':2,'sigma':0})
"Frames with post-process smoothing"
frames.append({'Type':'hops_3site','Nuc':'ivlal','sigma':5})
frames.append({'Type':'methylCC','Nuc':'ivlal','sigma':5})
frames.append({'Type':'chi_hop','Nuc':'ivlal','n_bonds':1,'sigma':50})
frames.append({'Type':'side_chain_chi','Nuc':'ivlal','n_bonds':1,'sigma':50})
frames.append({'Type':'chi_hop','Nuc':'ivlal','n_bonds':2,'sigma':50})
frames.append({'Type':'side_chain_chi','Nuc':'ivlal','n_bonds':2,'sigma':50})
#%% Create a figure for plotting
titles=[['Methyl rot.',r'$\chi_2$ rot.',r'$\chi_1$ rot.',r'C$\alpha$-C$\beta$ motion','Total'],
['Methyl rot.',r'$\chi_2$ rot.',r'$\chi_1$ rot.',r'C$\alpha$-C$\beta$ motion','Total'],
['Methyl lib.','Methyl hop.',r'$\chi_2$ lib.',r'$\chi_2$ hop.',
r'$\chi_1$ lib.',r'$\chi_1$ hop.',r'C$\alpha$-C$\beta$ motion','Total']]
fig=plt.figure('Methyl Dynamics')
fig.clear()
fig.set_size_inches([10.27, 9.03])
ax=[]
ax.append([fig.add_subplot(5,3,k+1) for k in range(0,15,3)])
ax.append([fig.add_subplot(5,3,k+1) for k in range(1,15,3)])
ax.append([fig.add_subplot(5,6,k+1) for k in [4,5,10,11,16,17,22]])
ax[-1].append(fig.add_subplot(5,3,15))
for a0,t0 in zip(ax,titles):
for a,t in zip(a0,t0):
a.set_title(t)
#%% Analyze with just one frame
tf=200000
mol.select_atoms(Nuc='ivlal') #Select 1 methyl group from all isoleucine, valine, leucine, and alanine residues
"""We could also specify the residue, but the provided trajectory just has one residue
A selection command populates mol.sel1 and mol.sel2 with atom groups, where sel1 and sel2
then define a list of bonds
"""
fr_obj=DR.frames.FrameObj(mol) #This creates a frame object based on the above molecule object
fr_obj.tensor_frame(sel1=1,sel2=2) #Here we specify to use the same bonds that were selected above in mol.select_atoms
#1,2 means we use for the first atom selection 1 in mol and for the second atom the second selection in mol
for f in frames:fr_obj.new_frame(**f) #This defines all frames in the frame object
#(arguments were previously stored in the frames list)
fr_obj.load_frames(tf=tf,n=-1) #This sweeps through the trajectory and collects the directions of all frames at each time point
fr_obj.post_process() #This applies post processing to the frames where it is defined (i.e. sigma!=0)
"""
For each calculation, we only include some of the 9 frames that were defined above.
1) 3 rotational frames without post procesing (frames 0-2)
2) 3 rotational frames with averaging (frames 4,6,8)
3) 6 frames (rotational+hopping frames, frames 3-8)
"""
include=np.zeros([3,9],dtype=bool)
include[0][:3]=True #Only methylCC,side_chain_chi frames without post processing
include[1][[4,6,8]]=True #Only methylCC,side_chain_chi frames with post processing
include[2][3:]=True #All frames with post processing
t=np.arange(int(tf/2))*.005 #Only plot the first half of the correlation function, where noise is lower
for inc,ax0 in zip(include,ax):
out=fr_obj.frames2ct(include=inc,mode='full')
for ct,a in zip(out['ct_finF'],ax0):
a.cla()
a.plot(t,ct.mean(0)[:int(tf/2)])
a.set_ylim([0,1.05])
S2=ct.mean(0)[int(tf/4):int(tf/2)].mean()
b=np.argwhere(ct.mean(0)-S2<0)[0,0]
# tc0=np.max([.001,((ct.mean(0)[:b]-S2)/(1-S2)).sum()*.005])
tc0=t[np.argmin(np.abs((ct.mean(0)[:b]-S2)/(1-S2)-np.exp(-1)))]
fun=lambda x:(((x[0]+(1-x[0])*np.exp(-t[:b]/x[1]))-ct.mean(0)[:b])**2).sum()
S2,tc=least_squares(fun,[S2,tc0]).x
a.plot(t,S2+(1-S2)*np.exp(-t/tc),color='grey',linestyle=':')
a.set_xlim([0,np.min([10*tc,fr_obj.t[int(tf/2)]])])
ax0[-1].semilogx(out['t'][:int(tf/2)],out['ct'].mean(0)[:int(tf/2)])
ax0[-1].semilogx(out['t'][:int(tf/2)],out['ct_prod'].mean(0)[:int(tf/2)])
ax0[-1].set_ylim([0,.5])
fig.set_size_inches([180/25.4,220/25.4])
plt.show()