Difference between revisions of "2018 AMBER tutorial with 2nnq"
From Rizzo_Lab
(→Equilibration) |
(→Equilibration) |
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= Equilibration = | = Equilibration = | ||
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+ | Create the following input files for the equilibration of the system. | ||
+ | vim 01.min.mdin | ||
+ | |||
+ | Minmize all the hydrogens | ||
+ | &cntrl | ||
+ | imin=1, ! Minimize the initial structure | ||
+ | maxcyc=5000, ! Maximum number of cycles for minimization | ||
+ | ntb=1, ! Constant volume | ||
+ | ntp=0, ! No pressure scaling | ||
+ | ntf=1, ! Complete force evaluation | ||
+ | ntwx= 1000, ! Write to trajectory file every ntwx steps | ||
+ | ntpr= 1000, ! Print to mdout every ntpr steps | ||
+ | ntwr= 1000, ! Write a restart file every ntwr steps | ||
+ | cut= 8.0, ! Nonbonded cutoff in Angstroms | ||
+ | ntr=1, ! Turn on restraints | ||
+ | restraintmask=":1-131 & !@H=", ! atoms to be restrained | ||
+ | restraint_wt=5.0, ! force constant for restraint | ||
+ | ntxo=1, ! Write coordinate file in ASCII format | ||
+ | ioutfm=0, ! Write trajectory file in ASCII format | ||
+ | / | ||
+ | |||
Create a submission script to equilibrate the biological system | Create a submission script to equilibrate the biological system |
Revision as of 14:53, 23 March 2018
2nnq with an explicit solvent model
Prepare the files
Convert 2nnq.lig.withH.charged.mol2 to pdb in chimera
Convert 2nnq.rec.withH.charged.mol2 to pdb in chimera
Copy into zzz.master
Parameters
Move into 000.programs
Paramaterize the ligand
antechamber -i ../zzz.master/2nnq.lig.withH.charged.pdb -fi pdb -o 2nnq_lig.am1bcc.mol2 -fo mol2 -at gaff2 -c bcc -rn LIG -nc 1
Check for missing force field parameters
parmchk2 -i 2nnq_lig.am1bcc.mol2 -f mol2 -o 2nnq_lig.am1bcc.frcmod
TLeap
Move into 001.tleap_build
Create tleap.build.in file
#!/usr/bin/sh ###Load Protein force field source leaprc.protein.ff14SB ###Load GAFF force field (for our ligand) source leaprc.gaff ###Load TIP3P (water) force field source leaprc.water.tip3p ####Load Ions frcmod for the tip3p model loadamberparams frcmod.ionsjc_tip3p ###Needed so we can use igb=8 model set default PBradii mbondi3 ###Load Protein pdb file rec=loadpdb ../zzz.master/2nnq.rec.withH.charged.pdb ###Load Ligand frcmod/mol2 loadamberparams ../000.parameters/2nnq_lig.am1bcc.frcmod lig=loadmol2 ../000.parameters/2nnq_lig.am1bcc.mol2 ###Create gas-phase complex gascomplex= combine {rec lig} ###Write gas-phase pdb savepdb gascomplex 2nnq.gas.complex.pdb ###Write gas-phase toplogy and coord files for MMGBSA calc saveamberparm gascomplex 2nnq.gas.complex.prmtop 2nnq.gas.complex.rst7 saveamberparm rec 2nnq.gas.receptor.prmtop 2nnq.gas.receptor.rst7 saveamberparm lig 2nnq.gas.ligand.prmtop 2nnq.gas.ligand.rst7 ###Create solvated complex (albeit redundant) solvcomplex= combine {rec lig} ###Solvate the system solvateoct solvcomplex TIP3PBOX 12.0 ###Neutralize system (it will add either Na or Cl depending on net charge) addions solvcomplex Cl- 0 addions solvcomplex Na+ 0 ###Write solvated pdb file ###Create solvated complex (albeit redundant) solvcomplex= combine {rec lig} ###Solvate the system solvateoct solvcomplex TIP3PBOX 12.0 ###Neutralize system (it will add either Na or Cl depending on net charge) addions solvcomplex Cl- 0 addions solvcomplex Na+ 0 ###Write solvated pdb file
Create Amber topology and coordinates files for the MD simulation
tleap -f tleap.build.in
Equilibration
Create the following input files for the equilibration of the system.
vim 01.min.mdin
Minmize all the hydrogens &cntrl imin=1, ! Minimize the initial structure maxcyc=5000, ! Maximum number of cycles for minimization ntb=1, ! Constant volume ntp=0, ! No pressure scaling ntf=1, ! Complete force evaluation ntwx= 1000, ! Write to trajectory file every ntwx steps ntpr= 1000, ! Print to mdout every ntpr steps ntwr= 1000, ! Write a restart file every ntwr steps cut= 8.0, ! Nonbonded cutoff in Angstroms ntr=1, ! Turn on restraints restraintmask=":1-131 & !@H=", ! atoms to be restrained restraint_wt=5.0, ! force constant for restraint ntxo=1, ! Write coordinate file in ASCII format ioutfm=0, ! Write trajectory file in ASCII format
/
Create a submission script to equilibrate the biological system
#!/bin/sh #PBS -N 2nnq_equilibration #PBS -l walltime=04:00:00 #PBS -l nodes=2:ppn=28 #PBS -j oe #PBS -q long cd $PBS_O_WORKDIR echo "Started Equilibration on `date` " do_parallel="sander" prmtop="../001.tleap_build/2nnq.wet.complex.prmtop" coords="../001.tleap_build/2nnq.wet.complex" MDINPUTS=(01.min 02.equil 03.min 04.min 05.min 06.equil 07.equil 08.equil 09.equil) for input in ${MDINPUTS[@]}; do $do_parallel -O -i ${input}.mdin -o ${input}.mdout -p $prmtop -c ${coords}.rst7 -ref ${coords}.rst7 -x ${input}.trj -inf ${input}.info -r ${input}.rst7 coords=$input done echo "Finished Equilibration on `date` "
Submit the job
qsub md.equilibration.sh