Difference between revisions of "2022 AMBER tutorial 1 with PDBID 6ME2"
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== '''Generating Simulation Parameters''' == | == '''Generating Simulation Parameters''' == | ||
+ | In order to generate parameters for this tutorial, switch to the following directory: | ||
+ | |||
+ | cd 002_parameters | ||
+ | |||
+ | To generate the parameters, run the following command: | ||
+ | |||
+ | antechamber -i ../001_structure/6me2_lig_wH.mol2 -fi mol2 -o 6me2_ligand_antechamber.mol2 -fo mol2 -at gaff2 -c bcc -rn LIG -nc 0 | ||
+ | |||
+ | Note the -nc flag is set to 0 in the above line; this should correspond to the protonation state of the ligand. If a user is following this tutorial to simulate dynamics on a structure other than 6ME2, be sure to double check and change this value accordingly. | ||
== '''Using TLeap''' == | == '''Using TLeap''' == |
Revision as of 09:15, 3 May 2022
Contents
Introduction
AMBER is a program designed for computing biomolecular simulations. In this tutorial, AMBER will be used to simulate the dynamics between the ligand and receptor of the 6ME2 PDB file.
Directory Setup
For this tutorial, it is recommended to define the following directories to stay organized:
mkdir 001_structure mkdir 002_parameters mkdir 003_leap mkdir 004_equil mkdir 005_production
6ME2 Structure Files
If the 6ME2 DOCK tutorials were followed before this AMBER tutorial, the user has some experience generating and prepping receptor and ligand filed from the original 6ME2 PDB file. However, it is recommended that the user NOT use the files generated in the 6ME2 DOCK tutorials and to instead start from scratch here, as this allows the chance to catch mistakes that may have been made but not recognized while following the initial DOCK tutorials.
To begin this tutorial, search the Protein Data Bank (PDB) website using the code 6ME2, or use the Fetch... button on the home screen of UCSF Chimera for this four-letter code. All the following structures should be saved to the following directory:
cd 001_structure
Receptor File Generation
To generate a fresh copy of the receptor file, open the 6me2.pdb file containing the ligand-receptor complex. Go to Select -> Structure -> protein, which will select the receptor, and then go to Select -> Invert (all models) to select everything other than the receptor in the file. Then, go to Actions -> Atoms/Bonds -> delete which will isolate the receptor. Go to File -> Save Mol2... and save as 6me2_rec.mol2. Close Chimera.
Ligand File Generation
To generate the ligand file, open the 6me2.pdb file again, and go to Select -> Structure -> protein then Actions -> Atoms/Bonds -> delete to delete the receptor. Then, go to Select -> Residue -> HOH, Select -> Residue -> OLA, and Select -> Residue -> PEG to delete everything except for the JEV residue, which is the ligand of interest.
Note: there are problems with the file containing the ligand as-is. In order to proceed properly, it is necessary to make some changed to this file. While the file is still open, go to 'Tools > Structure Editing > Rotamers and change the non-standard YCM residue to the most probable rotamers of CYS.
After this is completed, go to Tools > Structure editing > Add H to add hydrogens to the ligand. Then, go to Tools > Structure editing > Add Charge > (have Amber ff14SB and AM1-BCC selected) -> Ok and then go to File -> Save Mol2... and save as 6me2_lig_dockprep.mol2. Close Chimera.
Generating Simulation Parameters
In order to generate parameters for this tutorial, switch to the following directory:
cd 002_parameters
To generate the parameters, run the following command:
antechamber -i ../001_structure/6me2_lig_wH.mol2 -fi mol2 -o 6me2_ligand_antechamber.mol2 -fo mol2 -at gaff2 -c bcc -rn LIG -nc 0
Note the -nc flag is set to 0 in the above line; this should correspond to the protonation state of the ligand. If a user is following this tutorial to simulate dynamics on a structure other than 6ME2, be sure to double check and change this value accordingly.