2013 AMBER Tutorial with UMP and OMP
For additional Rizzo Lab tutorials see AMBER Tutorials.
In this tutorial, we will learn how to run a molecular dynamics simulation of a protein-ligand complex. We will then post-process that simulation by calculating structural fluctuations (with RMSD) and free energies of binding (MM-GBSA).
Contents
I. Introduction
AMBER
Amber - Assisted Model Building with Energy Refinement - is a suite of about multiple programs for perform macromolecular simulations. Amber11, the current version of Amber, includes newly released functionality such as PMEMD, particle mesh Ewald MD and soft-core Thermodynamics Integration MD. For the tutorial, we are using the newest version AMBER12.
The Amber 12 Manual is the primary resource to get started with Amber12. (Tip: Using Adobe Acrobat to view the file, you can simply search the document for keywords such as the name of a simulation parameter, which saves much time.) In addition, Amber Tools User's Manual serves as another reference while using Amber tools.
Here are some programs in Amber
- LEaP: an preparing program for constructing new or modified systems in Amber. It consists of the functions of prep, link, edit, and parm for earlier version of Amber.
- ANTECHAMBER: in additional to LEap, this main Antechamber suite program is for preparing input files other than standard nucleic acids and proteins.
- SANDER: according to the Amber 12 manual, it is 'a basic energy minimizer and molecular dynamics program' that can be used to minimize, equilibrate and sample molecular conformations. And this is the program we mainly use in this tutorial to generate trajectory files of the molecular system.
- PMEMD: version of SANDER that has improved parallel scaling property and optimized speed.
- PTRAJ: an analysis program for processing trajectory files. One can use ptraj to rotate, translate the structures, evaluate geometrical features and so on.
There is a mailing list you could sign-up for, as an additional resource.
UMP and OMP
For information of the UMP-OMP system, see 2013 DOCK tutorial with Orotodine Monophosphate Decarboxylase.
Organizing Directories
While performing MD simulations, it is convenient to adopt a standard directory structure / naming scheme, so that files are easy to find / identify. For this tutorial, we will use something similar to the following:
~username/AMS536/AMBER-Tutorial/001.CHIMERA.MOL.PREP/ 002.ANTE.TLEAP/ 003.SANDER/ 004.PTRAJ/ 005.MMGBSA/
II. Structural Preparation
Preparation in Chimera
In this AMBER tutorial, we will use the same system with previous DOCK part. To begin with, we need three files under directory 001.CHIMERA.MOL.PREP.
Downloading the PDB file (1LOQ)
Since we need to edit the PDB before we use it in Chimera we should do this manually. Go to PDB homepage (http://www.rcsb.org/pdb/home/home.do ) enter the protein ID (1LOQ) in the search bar, click Download Files in the top-right of the webpage, then select PDB File (text). In the new window, save the file in Downloads.
Preparing the ligand and receptor in Chimera
In this section, we will create three new files and save them in the 001.CHIMERA.MOL.PREP/ folder:
1LOQ.dockprep.mol2 (complete system with hydrogens and charges) 1LOQ.receptor.noH.mol2 (the receptor alone, without hydrogens) 1LOQ.ligand.mol2 (the ligand alone)
To prepare these files, first copy the original PDB file into the 001.CHIMERA.MOL.PREP/ folder and open it with VIM ($ vim 1LOQ.pdb). Because the residue name of the ligand (U) will give us some problems when assigning charges, change the residue name "U" to "LIG" starting at line 2082. Here is an example command that will change all instances of " U" into "LIG", while preserving the correct spacing:
%s/ U/LIG/gc
For this command, g is short for global and c is short for check with the user before making the change.
Next, open up the PDB file (1LOQ.pdb) in Chimera. To delete water molecules and other ligands, click Tools -> Structure Editing -> Dock Prep. Check all boxes and click Okay to the end. Alternatively, the waters can be deleted manually by choosing Select -> Residue -> HOH, then go to Actions -> Atoms/Bonds -> Delete. Hydrogen atoms can be added manually by choosing Tools -> Structure Editing -> Add H.
Next, to add charges to the ligand and receptor, go to Select -> Residue -> LIG, then go to Tools -> Structure Editing -> Add Charge. Choose AMBER ff99SB as the charge model, click Okay, and when prompted chose AM1-BCC charges for the ligand, and make sure the Net Charge is set to -1. (You must consider the chemistry of the ligand when assigning a charge state).
Finally, save this file as 1LOQ.dockprep.mol2.
Generating the final files
To create the receptor file with no hydrogen atoms: Open 1LOQ.dockprep.mol2, click Select -> Chemistry -> Element -> H, then chose Actions -> Atoms/Bonds -> Delete. Save the file as 1LOQ.receptor.noH.mol2.
To create the ligand file: Open 1LOQ.dockprep.mol2, click Select -> Residue -> LIG, then click Select -> Invert, then chose Actions -> Atoms/Bonds -> Delete. Save the file as 1LOQ.ligand.mol2.
antechamber
The antechamber program itself is the main program of Antechamber package. In most of cases, one should use this program instead of a series of separated programs to do molecular format convertion, atom type assignment and charge generation etc. An antechamber input file requires all the atom names to be unique. So if we use 1LOQ.ligand.mol2 as the input file, it will cause errors. The program can only recognize atom names of 3 characters ( In this case, H5' and H5'' cannot be distinguished from each other. )
22 H5' 40.0697 36.0506 37.6716 H 1 LIG210 0.0761 23 H5 40.6060 37.0416 36.2883 H 1 LIG210 0.0349 24 H4' 38.2510 37.5673 38.1082 H 1 LIG210 0.0967 25 H3' 38.2723 38.5564 35.5613 H 1 LIG210 0.1052 26 H2' 40.3056 39.7322 35.6920 H 1 LIG210 0.1188 27 H1' 39.7587 40.5927 38.4795 H 1 LIG210 0.0753 28 H6 41.3847 41.7815 39.3543 H 1 LIG210 0.0322 29 H5 43.6843 42.3632 39.6188 H 1 LIG210 0.1693 30 H3 44.6515 39.3570 36.8437 H 1 LIG210 0.3481 31 HO3' 36.5607 38.9743 36.9843 H 1 LIG210 0.4373 32 HP3 39.3989 32.7036 35.9199 H 1 LIG210 0.4245 33 HO2' 39.5501 41.7087 35.4449 H 1 LIG210 0.4228
We need to manually rename the atoms.
22 H1 40.0697 36.0506 37.6716 H 1 LIG210 0.0761 23 H2 40.6060 37.0416 36.2883 H 1 LIG210 0.0349 24 H3 38.2510 37.5673 38.1082 H 1 LIG210 0.0967 25 H4 38.2723 38.5564 35.5613 H 1 LIG210 0.1052 26 H5 40.3056 39.7322 35.6920 H 1 LIG210 0.1188 27 H6 39.7587 40.5927 38.4795 H 1 LIG210 0.0753 28 H7 41.3847 41.7815 39.3543 H 1 LIG210 0.0322 29 H8 43.6843 42.3632 39.6188 H 1 LIG210 0.1693 30 H9 44.6515 39.3570 36.8437 H 1 LIG210 0.3481 31 HO1 36.5607 38.9743 36.9843 H 1 LIG210 0.4373 32 HP3 39.3989 32.7036 35.9199 H 1 LIG210 0.4245 33 HO2 39.5501 41.7087 35.4449 H 1 LIG210 0.4228
To begin with, go to 002.ANTE.TLEAP directory. To make sure we have access to the three programs that we want to run (antechamber, parmchk and tleap) and we are using the correct version of amber, we can use the which command, type:
which antechamber which parmchk which tleap
Your results should be similar to this:
/home/wjallen/AMS536/local/amber12/bin/antechamber /home/wjallen/AMS536/local/amber12/bin/parmchk /home/wjallen/AMS536/local/amber12/bin/tleap
Copy parameters of ions to your working directory from the following resource:
cp -r ~lingling/AMS536/AMBER_Tutorial/002.ANTE.TLEAP/rizzo_amber7.ionparms
Then we use antechamber to convert our input mol2 file into files ready for LEaP.Type command:
antechamber -i ../001.CHIMERA.MOL.PREP/1LOQ.lig.mol2 -fi mol2 -o 1LOQ.lig.ante.pdb -fo pdb
Here, -i input file name; -fi input file format; -o output file name; -fo output file format. You will have an output file:1LOQ.lig.ante.pdb
Similarly, we can use antechamber to change the fomat of 1LOQ.lig.mol2 file to prep file:
antechamber -i ../001.CHIMERA.MOL.PREP/1LOQ.lig.mol2 -fi mol2 -o 1LOQ.lig.ante.prep -fo prepi
You will get a set of output files:
ANTECHAMBER_AC.AC ANTECHAMBER_AC.AC0 ANTECHAMBER_BOND_TYPE.AC ANTECHAMBER_BOND_TYPE.AC0 ANTECHAMBER_PREP.AC ANTECHAMBER_PREP.AC0 ATOMTYPE.INF NEWPDB.PDB PREP.INF 1LOQ.lig.ante.prep
parmchk
Parmchk is another program in Antechamber. After running antechamber, we run parmchk to check the parameters. If there are missing parameters after antechamber is finished, the frcmod template generated by parmchk will help us in generating the needed parameters:
parmchk -i 1LOQ.lig.ante.prep -f prepi -o 1LOQ.lig.ante.frcmod
tleaP
Next, we need 3 new input files – “tleap.lig.in”, “tleap.rec.in” and “tleap.com.in”, for the ligand, the receptor, and the complex, respectively. These input files will be used by LEaP to create parameter/topology files and initial coordinate files.
Copy parameters of ions to your working directory from the following resource:
cp ~lingling/AMS536/AMBER_Tutorial/002.ANTE.TLEAP/tleap.lig.in cp ~lingling/AMS536/AMBER_Tutorial/002.ANTE.TLEAP/tleap.rec.in cp ~lingling/AMS536/AMBER_Tutorial/002.ANTE.TLEAP/tleap.com.in
Use leap command:
tleap -s -f tleap.lig.in > tleap.lig.out tleap -s -f tleap.rec.in > tleap.rec.out tleap -s -f tleap.com.in > tleap.com.out
You will see the following output files: 1LOQ.com.gas.leap.prm7 1LOQ.com.wat.leap.prm7 1LOQ.lig.ante.frcmod 1LOQ.lig.ante.prep 1LOQ.lig.gas.leap.rst7 1LOQ.lig.wat.leap.rst7 1LOQ.rec.gas.leap.rst7 1LOQ.rec.wat.leap.rst7 1LOQ.com.gas.leap.rst7 1LOQ.com.wat.leap.rst7 1LOQ.lig.ante.pdb 1LOQ.lig.gas.leap.prm7 1LOQ.lig.wat.leap.prm7 1LOQ.rec.gas.leap.prm7 1LOQ.rec.wat.leap.prm7 tleap.lig.out tleap.rec.out tleap.com.out leap.log
Visualization in VMD
Visualization is an important step in AMBER molecular dynamics simulation as it allows for the viewing of molecules and molecule movements within a specified field of view. Several files prepared in the previous two steps will be required for the visualization of the ligand and its movement in the protein binding pocket. The first step that must be completed is the copying of all necessary information from Seawulf to Herbie.
Before exiting Seawulf, you can type:
scp -r ~/AMS536/AMBER_Tutorial/002.ANTE.TLEAP username@herbie.mathlab.sunysb.edu:~/AMS536/AMBER_Tutorial/
Then, when in Herbie, type the command vmd in any directory and the program VMD will open on the computer. In the "VMD Main" window, click File > New Molecule. Now in the new window titled "Molecule File Browser" a few files must be selected and loaded. To select and load a file follow these steps:
1. Click Browse... and select the file that you desire. 2. Click the down button in the "Determine file type:" field and select the proper file type. 3. Click Load and view the molecule/system in the original "VMD 1.8.5 OpenGL Display" window.
We can now visualize several files: the protein-ligand complex in the gas or water phase, and the ligand in the gas or water phase. Viewing the protein-ligand complex in the gas phase we select 1LOQ.com.gas.leap.prm7 and the file type AMBER7 Parm. Next you need to select and load the file 1LOQ.com.gas.leap.rst7 and the file type AMBER7 Restart. This can be done for the complex or ligand for either the gas or the water phase by selecting and loading the corresponding .parm7 files and .rst7 files.
Next, you can choose to edit the structure shown for better visualization. By clicking Graphics > Representations... a new window "Graphical Representations" will open, in which you can create new representations of the protein-ligand complex. It is possible to choose the entire complex or simply the protein or ligand, to color the structure in various ways, and to choose how it is best represented (e.g. lines, thicker bonds, full surface).
III. Simulation using sander
Minimization
Energy minimization is first performed on the stucture before the equilibration and production runs may be performed. Model building often creates unwanted structural artifacts that must be removed before a molecular dynamics simulation is performed.
To begin, create four files for minimization steps 1,3,4 and 5.
vim 01mi.in
and follow the naming according to minimization run number, i.e. 03mi.in
All "#mi.in" file content will be identical except the last parameter, the restraint weight (restraint_wt). This restraint will decrease with increasing minimization runs. Run number 1,3,4,and 5 has restraint weight 5,2,0.1,and 0.05 respectively.
An example of minimization code for 01mi.in:
01mi.in: equilibration &cntrl imin = 1, maxcyc = 1000, ntmin = 2, ntx = 1, ntc = 1, ntf = 1, ntb = 1, ntp = 0, ntwx = 1000, ntwe = 0, ntpr = 1000, ntr = 1, restraintmask = ':1-210 & !@H=', restraint_wt=5.0,
The following parameters are defined as follows:
imin:specifies minimization not molecular dynamics
maxcyc:total number of minimization cycles to be performed
ntmin:how many cycles will use a deepest decent method, the remaining cycles use an approximation of this called the conjugate gradient method.
ntx:only coordinates and not velocities are to be read from previous step
ntc:indicates level of constraint on bonds. if =1, SHAKE algorithm is off so no bonds are constrained. If =2, constrains any bonds with H atoms. If =3, constrains all bonds.
ntf:=1, all parts of the potential must be evaluated
ntb:periodic boundary to keep system at constant volume
ntp:=0, NO constant pressure applied
The frequencies at which the program records data are in controlled by the paramenters ntwx, ntwe, and ntpr.
ntwx:=1000, atom coordinates saved into .trj file every 1000 cycles
ntwe:=0, no .en file is generated
ntpr:=1000, energy readins are written as .out and .info files every 1000 steps
ntr:=1, positional restraint method applied
restraintmask= ':1-119 & !@H : position of atom within residues 1-119 that is not a H atom is being restrained
restraint_wt: restraint weight indicating how strong the restraint on the atoms is
Equilibration
To further prepare our complex for the molecular dynamic simulations, the subsequent step of energy minimization is equilibrate the system at some certain temperatures. We repeat the process of minimization and equilibration for twice in our case, of course with varied parameters and restraints put on our system.
Right after the first 1000 steps of minimization, we perform a 50000 steps(nstlim = 50000) X the step length of 1 fs(dt = 0.001) (that is 50 ps in total) equilibration at the temperature 298.15K(temp0 = 298.15, tempi = 298.15), contining putting on the weight (in kcal/mol) of 5.0 for the positional restraints on all non hydrogen atoms(restraintmask = ':1-210 & !@H=', restraint_wt = 5.0).
02md.in: equilibration (50ps) &cntrl imin = 0, ntx = 1, irest = 0, nstlim = 50000, temp0 = 298.15, tempi = 298.15, ntc = 2, ntf = 1, ntt = 1, dt = 0.001, ntb = 2, ntp = 1, tautp = 1.0, taup = 1.0, ntwx = 1000, ntwe = 0, ntwr = 1000, ntpr = 1000, ntr = 1, nscm = 100, iwrap = 1, cut = 8.0, restraintmask = ':1-210 & !@H=', restraint_wt = 5.0, /
- Notice that some flags used in minimization have been changed:
imin = 1 indicates that we are doing an MD simulation instead of doing energy minimization.
ntc = 2 indicates that all bonds involving H bonds are constrained by the SHAKE algorithm to eliminate high frequency oscillations in the system.
ntb = 2 and ntp = 1 indicate that constant pressure instead of constant volume is applied.
- Some flags (including those explained above) are newly added;
ntx = 1 means coordinates, but no velocities, will be read.
irest = 0 irest is a flag to restart a simulation, we always start from running a new simulation until the production part, so it is 0 from 02md.in, 06md.in to 09md.in.
ntt = 1 switch the temperature scaling, 1 means constant temperature, using the weak-coupling algorithm.
tautp = 1.0 and taup = 1.0 defines the time constant (in ps) and the pressure relaxation time (in ps), respectively.
iwrap = 1 indicate that the coordinates written to the .rst7 and .trj files will be wrapped into a primary box. This reduces the amount of coordinate output, thus preventing overflowing and making visualization more convenient.
cut = 8.0 set the the non-bonded cutoff distance at 8.0 Angstroms.
Continuing 4 simulations are carried out after the fourth minimization, there are only little differents in these input files:
06md.in: equilibration (50ps) &cntrl imin = 0, ntx = 1, irest = 0, nstlim = 50000, temp0 = 298.15, tempi = 298.15, ig = 71287, ntc = 2, ntf = 1, ntt = 1, dt = 0.001, ntb = 2, ntp = 1, tautp = 1.0, taup = 1.0, ntwx = 1000, ntwe = 0, ntwr = 1000, ntpr = 1000, ntr = 1, nscm = 100, iwrap = 1, cut = 8.0, restraintmask = ':1-210 & !@H=', restraint_wt = 1.0, /
- As we can see in 06md.in file, the only changes are setting ig as 71287 and reducing restraint_wt value from 5.0 to 1.0.
ig is the seed for the pseudo-random number generator which the MD starting velocity depend on.
To further reduce the restraint put on the whole system, we vary restraint_wt value to be 0.05, 0.1, 0.1, respectively in 07md, 08md and 09md input files.
- Note that starting from 08md to 09md simulations, the restraintmask = ':1-210 & !@H=' has been changed to restraintmask = ':1-209 & !@H=' which means not at all restrains are put on the ligand atoms.
Production
Before the production runs (10 and 11), first we need to generate the input files 10md.in and 11md.in (as shown below).
10md.in: production (500000 = 1ns) &cntrl imin = 0, ntx = 5, irest = 1, nstlim = 500000, temp0 = 298.15, tempi = 298.15, ig = 71287, ntc = 2, ntf = 1, ntt = 1, dt = 0.002, ntb = 2, ntp = 1, tautp = 1.0, taup = 1.0, ntwx = 500, ntwe = 0, ntwr = 500, ntpr = 500, ntr = 1, nscm = 100, iwrap = 1, cut = 8.0, restraintmask = ':1-209@CA,C,N', restraint_wt = 0.1, /
11md.in: production (500000 = 1ns) &cntrl imin = 0, ntx = 5, irest = 1, nstlim = 500000, temp0 = 298.15, tempi = 298.15, ig = 71287, ntc = 2, ntf = 1, ntt = 1, dt = 0.002, ntb = 2, ntp = 1, tautp = 1.0, taup = 1.0, ntwx = 500, ntwe = 0, ntwr = 500, ntpr = 500, ntr = 1, nscm = 100, iwrap = 1, cut = 8.0, restraintmask = ':1-209@CA,C,N', restraint_wt = 0.1, /
Explanation for some of the parameter values:
ntx = 5, irest = 1 #using velocity information from the previous restart file# nstlim = 500000 #running for 500,000 steps# temp0 = 298.15 #the target temperature is 298.15 K (the default is 300 K)# tempi = 298.15 #the initial temperature is 298.15 K# dt = 0.002 #the time step dt is 0.002 ps (2 fs)# ntwr = 500 #to print energy output every 500 steps# ntb = 2 #the constant pressure is switched on#
To run the production, we need to create a c-shell file named "run.production.csh" of which the contents are shown below:
#! /bin/tcsh #-l nodes=4:ppn=2 #PBS -l walltime=720:00:00 #PBS -o zzz.qsub.prod.out #PBS -e zzz.qsub.prod.err #PBS -V set workdir = "~<username>/AMS536/amber-tutorial/03.sander" cd ${workdir} cat $PBS_NODEFILE | sort | uniq mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 10md.in -o 10md.out -p ../02.ante.tleap/1LOQ.com.wat.leap.prm7 \ -c 09md.rst7 -ref 09md.rst7 -x 10md.trj -inf 10md.info -r 10md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 11md.in -o 11md.out -p ../02.ante.tleap/1LOQ.com.wat.leap.prm7 \ -c 10md.rst7 -ref 10md.rst7 -x 11md.trj -inf 11md.info -r 11md.rst7 exit
The last step of a production run is to submit the c-shell file to the queue:
qsub zzz.production.csh
It will take almost 24 hour to finish the production run. To check the status of your job, type:
qstat -u <username>
After the production run, 10 new files should be created:
10md.info 10md.out 10md.rst7 10md.trj 11md.info 11md.out 11md.rst7 11md.trj zzz.qsub.prod.err (should be empty if nothing is wrong) zzz.qsub.prod.out
Running jobs on the queue
To run equilibration and production, Write the tcsh file equil.produc.qsub.csh:
#! /bin/tcsh #PBS -l nodes=4:ppn=2 #PBS -l walltime=720:00:00 #PBS -o zzz.qsub.out #PBS -e zzz.qsub.err #PBS -V set workdir = "~lingling/AMS536/AMBER_Tutorial/003.SANDER" cd ${workdir} cat $PBS_NODEFILE | sort | uniq mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 01mi.in -o 01mi.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c ../002.ANTE.TLEAP/1LOQ.com.wat.leap.rst7 -ref ../002.ANTE.TLEAP/1LOQ.com.wat.leap.rst7 \ -x 01mi.trj -inf 01mi.info -r 01mi.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 02md.in -o 02md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 01mi.rst7 -ref 01mi.rst7 -x 02md.trj -inf 02md.info -r 02md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 03mi.in -o 03mi.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 02md.rst7 -ref 02md.rst7 -x 03mi.trj -inf 03mi.info -r 03mi.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 04mi.in -o 04mi.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 03mi.rst7 -ref 03mi.rst7 -x 04mi.trj -inf 04mi.info -r 04mi.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 05mi.in -o 05mi.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 04mi.rst7 -ref 04mi.rst7 -x 05mi.trj -inf 05mi.info -r 05mi.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 06md.in -o 06md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 05mi.rst7 -ref 05mi.rst7 -x 06md.trj -inf 06md.info -r 06md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 07md.in -o 07md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 06md.rst7 -ref 06md.rst7 -x 07md.trj -inf 07md.info -r 07md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 08md.in -o 08md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 07md.rst7 -ref 07md.rst7 -x 08md.trj -inf 08md.info -r 08md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 09md.in -o 09md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 08md.rst7 -ref 08md.rst7 -x 09md.trj -inf 09md.info -r 09md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 10md.in -o 10md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 09md.rst7 -ref 09md.rst7 -x 10md.trj -inf 10md.info -r 10md.rst7 mpirun -n 8 /nfs/user03/wjallen/local/amber12/bin/sander.MPI -O -i 11md.in -o 11md.out -p ../002.ANTE.TLEAP/1LOQ.com.wat.leap.prm7 \ -c 10md.rst7 -ref 09md.rst7 -x 11md.trj -inf 11md.info -r 11md.rst7 exit
Note in the above script that for each run, the .rst7, .trj and .info files generated from the previous run provides the initial state to start from. The .prm7 file generated for the hydrated complex by TLEAP provides the force parameters.
Submit the file to the queue and monitor progress.
IV. Simulation Analysis
Ptraj
You should create another work directory for this step (004.PTRAJ, for example), if you don't have one. There will be five runs of analysis, each of which will require different input files, though the running process is absolutely same.
1. At first we want to concatenate the two 1ns trajectories together, stripping off the waters, and creating a .strip-file as an output. Below is the input file which will allow us to do so.
ptraj.1.in
trajin ../003.SANDER/10md.trj 1 1000 1 trajin ../003.SANDER/11md.trj 1 1000 1 trajout 1LOQ.trj.strip nobox strip :WAT
The two sets of numbers 1 1000 1 give the input information about which frames are used for the Ptraj. The first two numbers 1 and 1000 specify the starting and ending snapshots from the trajectory file. The ending number of the snapshot doesn't need to be accurate because if you actually don't have enough snapshots in your trajectory file, Ptraj will read up to the last one you have. The last number 1 specifies the frequency of the snapshot saved, in this case, we are saving every frame of the trajectory file. And the last line of the input file will take away all the water molecules.
Running this step:
ptraj ../002.ANTE.TLEAP/1DF8.com.wat.leap.parm ptraj.1.in > ptraj.1.log
As the output you will obtain 1LOQ.trj.strip file which contains 2000 snapshots of the trajectory.
2.
Now we will compare the file received to our reference file 1LOQ.com.gas.leap.rst7, the input file for this step is presented below.
ptraj.2.in
trajin 1LOQ.trj.strip 1 2000 1 trajout 1LOQ.com.trj.stripfit reference ../002.ANTE.TLEAP/1LOQ.com.gas.leap.rst7 rms reference out 1LOQ.rmsd.CA.txt :1-209@CA
Running this step:
ptraj ../002.ANTE.TLEAP/1DF8.com.gas.leap.parm ptraj.2.in > ptraj.2.log
3.
ptraj.3.in
trajin 1LOQ.com.trj.stripfit 1 2000 1 reference ../002.ANTE.TLEAP/1LOQ.com.gas.leap.rst7 rms reference out 1LOQ.lig.rmsd.txt :210@C*,N*,O*,S* nofit
And then run this step:
ptraj ../002.ANTE.TLEAP/1DF8.com.gas.leap.parm ptraj.3.in > ptraj.3.log
4. At this step we consider receptor only. The input file is provided below:
ptraj.4.in
trajin 1LOQ.com.trj.stripfit 1 2000 1 trajout 1LOQ.rec.trj.stripfit strip :210
And then run this step:
ptraj ../002.ANTE.TLEAP/1DF8.com.gas.leap.parm ptraj.4.in > ptraj.4.log
5. At the last step we work with ligand only, with the following input file:
ptraj.5.in
trajin 1LOQ.com.trj.stripfit 1 2000 1 trajout 1LOQ.lig.trj.stripfit strip :1-209
And then run this step:
ptraj ../002.ANTE.TLEAP/1DF8.com.gas.leap.parm ptraj.5.in > ptraj.5.log
RMSD Plots
Measuring h-bond distances
MM-GBSA Energy Calculation
MM/GBSA is the acronym for Molecular Mechanics/Generalized Born Surface Area. This part of AMBER combines molecular mechanics (MM) with both the electrostatic (PB) and nonpolar (SA) contribution to solvation . Topology files are needed for the receptor, ligand, and receptor-ligand complex. The trajectory files generate the coordinates. Therefore, molecular dynamics is used to generate a set of snapshots taken at fixed intervals from the trajectories. These snapshots are processed to remove solvent and generate the free energy of binding.
In the AMBER_Tutorial directory, create a new directory:
mkdir 005.MMGBSA
In this new directory, create the file gb.rescore.in containing:
Single point GB energy calc &cntrl ntf = 1, ntb = 0, ntc = 2, idecomp= 0, igb = 5, saltcon= 0.00, gbsa = 2, surften= 1.0, offset = 0.09, extdiel= 78.5, cut = 99999.0, nsnb = 99999, imin = 5, maxcyc = 1, ncyc = 0, /
Then create a csh script, run.sander.rescore.csh, that contains the following lines of command:
#! /bin/csh #PBS -l nodes=1:ppn=2 #PBS -l walltime=24:00:00 #PBS -o zzz.qsub.out #PBS -e zzz.qsub.err #PBS -V set workdir = "/nfs/user03/yechen1/AMBER-Tutorial/005.MMGBSA" set sander = "/nfs/user03/wjallen/local/amber12/bin/sander" cd ${workdir} $sander -O -i gb.rescore.in -o gb.rescore.out.com -p ../002.ANTE.TLEAP /1LOQ.com.gas.leap.prm7 \ -c ../002.ANTE.TLEAP/1LOQ.com.gas.leap.rst7 -y ../004.PTRAJ/1LOQ.com.trj.stripfit \ -r restrt.com -ref ../002.ANTE.TLEAP/1LOQ.com.gas.leap.rst7 -x mdcrd.com -inf mdinfo.com $sander -O -i gb.rescore.in -o gb.rescore.out.lig -p ../002.ANTE.TLEAP/1LOQ.lig.gas.leap.prm7 \ -c ../002.ANTE.TLEAP/1LOQ.lig.gas.leap.rst7 -y ../004.PTRAJ/1LOQ.lig.trj.stripfit \ -r restrt.lig -ref ../002.ANTE.TLEAP/1LOQ.lig.gas.leap.rst7 -x mdcrd.lig -inf mdinfo.lig $sander -O -i gb.rescore.in -o gb.rescore.out.rec -p ../002.ANTE.TLEAP/1LOQ.rec.gas.leap.prm7 \ -c ../002.ANTE.TLEAP/1LOQ.rec.gas.leap.rst7 -y ../004.PTRAJ/1LOQ.rec.trj.stripfit \ -r restrt.rec -ref ../002.ANTE.TLEAP/1LOQ.rec.gas.leap.rst7 -x mdcrd.rec -inf mdinfo.rec exit
~ ~ ~ ~
Then this script should be sent to the queue, i.e., qsub the script using the commands:
qsub run.sander.rescore.csh
You can monitor your progress by typing
qstat -u username
When the job is complete, you will obtain the following output files: gb.rescore.out.com, gb.rescore.out.lig, and gb.rescore.out.rec In these files, the single point energy calculation results will be written for each individual frame. It will be found in the results section and the output file will have an infrastrucutre that is similar to the following:
FINAL RESULTS NSTEP ENERGY RMS GMAX NAME NUMBER 1 3.6269E+03 1.8737E+01 1.0472E+02 CB 585 BOND = 580.2786 ANGLE = 1563.7704 DIHED = 2161.5659 VDWAALS = -1684.2762 EEL = -13809.8494 EGB = -2953.6681 1-4 VDW = 756.7767 1-4 EEL = 7260.2823 RESTRAINT = 0.0000 ESURF = 9752.0291 minimization completed, ENE= 0.36269092E+04 RMS= 0.187371E+02 TRAJENE: Trajectory file ended TRAJENE: Trajene complete.
In the command line, type:
grep VDWAALS gb.rescore.out.com > vdw.com.txt. grep ESURF gb.rescore.out.com > surf.com.txt.
You can take these text files, import them into Excel, and do the rest of your modifications there.
Equations for analysis
Remember that to obtain the Gvdw term, you need to take the SASA (which is ESURF) and input into equation 1:
ΔGnonpolar = SASA*0.00542 + 0.92
Also, the mmgbsa of a given system can be determined by equation 2:
ΔGmmgbsa = ΔGvdw + ΔGcoul + ΔGpolar + ΔGnonpolar
From the output file:
VDWAALS = ΔGvdw
EELS = ΔGcoul
EGB = ΔGpolar
You can then easily calculate the ΔΔGbind by using equation 3:
ΔΔGbind = ΔGmmgbsa,complex – (ΔGmmgbsa,lig + ΔGmmgbsa,rec) You will want to careful when doing your analysis that the results from frame 1 for the receptor and ligand are subtracted from the results from frame 1 for your complex. By doing this in excel, you should have 2000 frames for each, and the values should cleanly line up. Finally, you will want to plot your ΔΔGbind and examine if you see corresponding changes in the ligand position and the ΔΔGbind. Also, you should determine the mean and standard deviation for your ΔΔGbind.
Plotting Energy
When your rescoring calculation finishes, you have the following three output files: "gb.rescore.out.com", "gb.rescore.out.lig", and "gb.rescore.out.rec".
Use the following script, entitled get.mmgbsa.bash, to extract data and calculate MMGBSA energy for each snap shot.
#! /bin/bash # by Haoquan echo com lig rec > namelist LIST=`cat namelist` for i in $LIST ; do grep VDWAALS gb.rescore.out.$i | awk '{print $3}' > $i.vdw grep VDWAALS gb.rescore.out.$i | awk '{print $9}' > $i.polar grep VDWAALS gb.rescore.out.$i | awk '{print $6}' > $i.coul grep ESURF gb.rescore.out.$i | awk '{print $3 * 0.00542 + 0.92}' > $i.surf paste -d " " $i.vdw $i.polar $i.surf $i.coul | awk '{print $1 + $2 + $3 + $4}' > data.$i rm $i.* done paste -d " " data.com data.lig data.rec | awk '{print $1 - $2 - $3}' > data.all for ((j=1; j<=`wc -l data.all | awk '{print $1}'`; j+=1)) do echo $j , >> time done paste -d " " time data.all > MMGBSA_vs_time.dat rm namelist time data.*
To run this script do:
bash get.mmgbsa.sh
This will create a text file called MMGBSA_vs_time.dat with x and y values separated by a space and comma. These values can be imported to Excel or Origin or to XMGRACE if you are using Linux:
xmgrace MMGBSA_vs_time.dat