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prot_lig_openmm_10ns.py
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prot_lig_openmm_10ns.py
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# This script is written by Quantao/quantaosun@gmail.com or Github:quantaosun for OpenMM simulation,2023.
from openmm import *
from openmm.app import *
from openmm.unit import *
from sys import stdout
from openmm.app import PDBFile # for final frame pdb generation
# Input Files
prmtop = AmberPrmtopFile('SYS_gaff2.prmtop')
inpcrd = AmberInpcrdFile('SYS_gaff2.crd')
# System Configuration
nonbondedMethod = PME
nonbondedCutoff = 1.0*nanometers
ewaldErrorTolerance = 0.0005
constraints = HBonds
rigidWater = True
constraintTolerance = 0.000001
# Integration Options
dt = 0.002*picoseconds
temperature = 300*kelvin
friction = 1.0/picosecond
pressure = 1.0*atmospheres
barostatInterval = 25
# Simulation Options
# long simulation (default)
#minimizationSteps = 10000
#productionSteps = 50000000 # 100 ns
#equilibrationSteps = 20000000 # 20 ns
###################################################
# medium simulation
#minimizationSteps = 10000
#productionSteps = 25000000 # 50 ns
#equilibrationSteps = 10000000 # 10 ns
###################################################
# short simulation
minimizationSteps = 10000
productionSteps = 5000000 # 10 ns
equilibrationSteps = 1000000 # 2 ns
##################################################
platform = Platform.getPlatformByName('CUDA')
platformProperties = {'Precision': 'single'}
dcdReporter = DCDReporter('prot_lig_prod.dcd', 10000)
minimizationDataReporter = StateDataReporter('stdout', 100, totalSteps=minimizationSteps,
step=True, time=True, speed=True, progress=True, remainingTime=True, potentialEnergy=True, temperature=True, separator='\t')
equilibrationDataReporter = StateDataReporter(stdout, 5000, totalSteps=equilibrationSteps,
step=True, time=True, speed=True, progress=True, remainingTime=True, potentialEnergy=True, temperature=True, separator='\t')
productionReporter = StateDataReporter(stdout, 5000, totalSteps=productionSteps,
step=True, time=True, speed=True, progress=True, remainingTime=True, temperature=True, separator='\t')
dataReporter = StateDataReporter('prot_lig_prod.log', 1000, totalSteps=productionSteps,
step=True, time=True, speed=True, progress=True, remainingTime=True, potentialEnergy=True, temperature=True, separator='\t')
# Prepare the Simulation
print('Starting molecular dynamics simulaiton......')
print('############################################################################')
print('## This script was written by Quantao Sun based on official OpenMM documentation. You can visit Github:quantaosun for more insight. Please cite OpenMM paper, and consider cite my github repo link if used in any publications ####')
print('Initialising molecular dynamics....')
print('############################################################################')
print ('With GPU like RTX3080 or above, the simulation speed for a typical kinase protein should be greater than 200 ns/day')
print('############################################################################')
import time
# Sleep for 10 seconds
time.sleep(20)
print('############################################################################')
print('Building system...')
topology = prmtop.topology
positions = inpcrd.positions
system = prmtop.createSystem(nonbondedMethod=nonbondedMethod, nonbondedCutoff=nonbondedCutoff,
constraints=constraints, rigidWater=rigidWater, ewaldErrorTolerance=ewaldErrorTolerance)
system.addForce(MonteCarloBarostat(pressure, temperature, barostatInterval))
integrator = LangevinIntegrator(temperature, friction, dt)
integrator.setConstraintTolerance(constraintTolerance)
simulation = Simulation(topology, system, integrator, platform, platformProperties)
simulation.context.setPositions(positions)
if inpcrd.boxVectors is not None:
simulation.context.setPeriodicBoxVectors(*inpcrd.boxVectors)
#########################################################
content = """
# Simulation Options
###################################################
# medium simulation
minimizationSteps = 10000
productionSteps = 25000000 # 50 ns
equilibrationSteps = 10000000 # 10 ns
###################################################
##################################################
If you wish to change the simulation time, please modify
these three parameters inside the .py file
#############################################################
If you have not changed anything the default setting is 10000
steps of minimisation, followed by 10 ns of equilibration and
then 50 ns of production.
##############################################################
At the end of this simulation, the final frame will be saved as
###############################################################
########## prot_lig_1.pdb ##############
the trajectory will be saved as
########### prot_lig.dcd ##############
##################################################################
You can view the trajectory with Pymol by loading
########### SYS_gaff2.prmtop ##################
and the trajectory file.
# # # # ###### # # # #
# # ## # # # # # #
# # # # # ###### # # # #
# # # ## # # #
##### # # ####### # #
"""
print(content)
# Minimize and Equilibrate
print('Performing energy minimization...')
#simulation.minimizeEnergy()
simulation.minimizeEnergy(maxIterations=minimizationSteps)
simulation.reporters.clear()
print('##############################################')
print('Starting Equilibrating...')
simulation.context.setVelocitiesToTemperature(temperature)
simulation.reporters.append(equilibrationDataReporter)
simulation.step(equilibrationSteps)
simulation.reporters.clear()
# Production Simulate
print('##############################################')
print('Production Simulating...')
simulation.reporters.append(productionReporter) # on screen display.
simulation.reporters.append(dcdReporter)
simulation.reporters.append(dataReporter)
simulation.currentStep = 0
simulation.step(productionSteps)
print('##############################################')
# Write the last frame as a PDB file
print('Saving the last frame as PDB file...')
positions = simulation.context.getState(getPositions=True).getPositions()
PDBFile.writeFile(topology, positions, open('prod_lig_1.pdb', 'w'))