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charmm_forcefield.py
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## \example atom/charmm_forcefield.py
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## In this example, a PDB file is read in and scored using the CHARMM forcefield. For more control over the setup of the forcefield, see the 'charmm_forcefield_verbose.py' example.
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##
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import
IMP.atom
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import
IMP.container
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# Create an IMP model and add a heavy atom-only protein from a PDB file
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m =
IMP.Model
()
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prot =
IMP.atom.read_pdb
(
IMP.atom.get_example_path
(
"example_protein.pdb"
), m,
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IMP.atom.NonWaterNonHydrogenPDBSelector
())
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# Read in the CHARMM heavy atom topology and parameter files
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ff =
IMP.atom.get_heavy_atom_CHARMM_parameters
()
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# Using the CHARMM libraries, determine the ideal topology (atoms and their
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# connectivity) for the PDB file's primary sequence
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topology = ff.create_topology(prot)
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# Typically this modifies the C and N termini of each chain in the protein by
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# applying the CHARMM CTER and NTER patches. Patches can also be manually
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# applied at this point, e.g. to add disulfide bridges.
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topology.apply_default_patches()
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# Make the PDB file conform with the topology; i.e. if it contains extra
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# atoms that are not in the CHARMM topology file, remove them; if it is
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# missing atoms (e.g. sidechains, hydrogens) that are in the CHARMM topology,
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# add them and construct their Cartesian coordinates from internal coordinate
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# information.
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topology.setup_hierarchy(prot)
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# Set up and evaluate the stereochemical part (bonds, angles, dihedrals,
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# impropers) of the CHARMM forcefield
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r =
IMP.atom.CHARMMStereochemistryRestraint
(prot, topology)
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m.add_restraint(r)
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# Add non-bonded interaction (in this case, Lennard-Jones). This needs to
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# know the radii and well depths for each atom, so add them from the forcefield
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# (they can also be assigned manually using the XYZR or LennardJones
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# decorators):
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ff.add_radii(prot)
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ff.add_well_depths(prot)
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# Get a list of all atoms in the protein, and put it in a container
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atoms =
IMP.atom.get_by_type
(prot, IMP.atom.ATOM_TYPE)
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cont =
IMP.container.ListSingletonContainer
(atoms)
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# Add a restraint for the Lennard-Jones interaction. This is built from
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# a collection of building blocks. First, a ClosePairContainer maintains a list
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# of all pairs of Particles that are close. Next, all 1-2, 1-3 and 1-4 pairs
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# from the stereochemistry created above are filtered out.
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# Then, a LennardJonesPairScore scores a pair of atoms with the Lennard-Jones
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# potential. Finally, a PairsRestraint is used which simply applies the
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# LennardJonesPairScore to each pair in the ClosePairContainer.
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nbl =
IMP.container.ClosePairContainer
(cont, 4.0)
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nbl.add_pair_filter(r.get_pair_filter())
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sf =
IMP.atom.ForceSwitch
(6.0, 7.0)
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ps =
IMP.atom.LennardJonesPairScore
(sf)
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m.add_restraint(
IMP.container.PairsRestraint
(ps, nbl))
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# it gets awfully slow with internal checks
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IMP.base.set_check_level
(IMP.base.USAGE)
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# Finally, evaluate the score of the whole system (without derivatives)
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print
m.evaluate(
False
)