Esempio n. 1
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    def testProteinLigand(self):
        from htmd.builder.solvate import solvate
        from parameterize.parameterization.fftype import fftype
        from parameterize.parameterization.writers import writeFRCMOD

        # Test protein ligand building with parametrized ligand
        refdir = home(dataDir=join('test-amber-build', 'protLig'))
        tmpdir = os.path.join(self.testDir, 'protLig')
        os.makedirs(tmpdir)

        mol = Molecule(join(refdir, '3ptb_mod.pdb'))
        lig = Molecule(join(refdir, 'benzamidine.pdb'),
                       guess=('bonds', 'angles', 'dihedrals'))
        prm, lig = fftype(lig, method='GAFF2')
        writeFRCMOD(lig, prm, join(tmpdir, 'mol.frcmod'))
        lig.segid[:] = 'L'

        # params =
        newmol = Molecule()
        newmol.append(lig)
        newmol.append(mol)
        smol = solvate(newmol)

        params = defaultParam() + [
            join(tmpdir, 'mol.frcmod'),
        ]

        _ = build(smol, outdir=tmpdir, param=params, ionize=False)

        refdir = home(dataDir=join('test-amber-build', 'protLig', 'results'))
        _TestAmberBuild._compareResultFolders(refdir, tmpdir, '3PTB')
Esempio n. 2
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File: amber.py Progetto: raimis/htmd
    def testProteinLigand(self):
        from htmd.builder.solvate import solvate

        # Test protein ligand building with parametrized ligand
        refdir = home(dataDir=join("test-amber-build", "protLig"))
        tmpdir = os.path.join(self.testDir, "protLig")
        os.makedirs(tmpdir)

        mol = Molecule(join(refdir, "3ptb_mod.pdb"))
        lig = Molecule(join(refdir, "benzamidine.mol2"))
        lig.segid[:] = "L"

        # params =
        newmol = Molecule()
        newmol.append(lig)
        newmol.append(mol)
        smol = solvate(newmol)

        params = defaultParam() + [
            join(refdir, "benzamidine.frcmod"),
        ]

        _ = build(smol, outdir=tmpdir, param=params, ionize=False)

        refdir = home(dataDir=join("test-amber-build", "protLig", "results"))
        _TestAmberBuild._compareResultFolders(refdir, tmpdir, "3PTB")
Esempio n. 3
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    def sampleRegion(
        self, point=None, radius=None, limits=None, nsamples=20, singlemol=False
    ):
        """Samples conformations from a region in the projected space.

        Parameters
        ----------
        point : list or np.ndarray
            A point in the projected space. Undefined dimensions should have None value.
        radius : float
            The radius in around the point in which to sample conformations.
        limits : np.ndarray
            A (2, ndim) dimensional array containing the min (1st row) and max (2nd row) limits for each dimension.
            None values will be interpreted as no limit in that dimension, or min/max value.
        nsamples : int
            The number of conformations to sample.
        singlemol : bool
            If True it will return all samples within a single Molecule instead of a list of Molecules.

        Returns
        -------
        absFrames : list
            A list of the absolute frame indexes sampled
        relFrames : list of tuples
            A list of (trajNum, frameNum) tuples sampled
        mols : Molecule or list of Molecules
            The conformations stored in a Molecule or a list of Molecules

        Examples
        --------
        >>> # Working with 4 dimensional data for example
        >>> abs, rel, mols = data.sampleRegion(point=(0.5, 3, None, None), radius=0.1)  # Point undefined in dim 3, 4
        >>> minlims = [-1, None, None, 4]  # No min limit for 2, 3 dim
        >>> maxlims = [2,     3, None, 7]  # No max limit for 3 dim
        >>> abs, rel, mols = data.sampleRegion(limits=np.array([minlims, maxlims]))
        """
        from scipy.spatial.distance import cdist

        datconcat = np.concatenate(self.dat)
        numdim = datconcat.shape[1]
        if point is not None:
            if radius is None:
                raise RuntimeError("You must define a radius with a point.")
            point = np.array(point)
            if len(point) != numdim:
                raise RuntimeError(
                    "Argument `point` should be same dimensionality as your data ({} dimensions)".format(
                        numdim
                    )
                )
            keepdim = np.array([p is not None for p in point])
            dists = cdist(datconcat[:, keepdim], [point[keepdim]])
            confs = np.where(dists < radius)[0]
        elif limits is not None:
            if limits.shape != (2, numdim):
                raise RuntimeError(
                    "Argument `limits` should be of shape (2, {})".format(numdim)
                )
            mask = np.ones(datconcat.shape[0], dtype=bool)
            for i in range(numdim):
                if limits[0, i] is not None:
                    mask &= datconcat[:, i] > limits[0, i]
                if limits[1, i] is not None:
                    mask &= datconcat[:, i] < limits[1, i]
            confs = np.where(mask)[0]

        if len(confs) > nsamples:
            confs = np.random.choice(confs, nsamples, replace=False)
        sims = self.abs2sim(confs)

        from moleculekit.molecule import Molecule

        if singlemol:
            mol = Molecule(sims[0])
            for i in range(1, len(sims)):
                m = Molecule(sims[i])
                mol.appendFrames(m)
        else:
            mol = []
            for s in sims:
                mol.append(Molecule(s))
        return confs, self.abs2rel(confs), mol
Esempio n. 4
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def tileMembrane(memb, xmin, ymin, xmax, ymax, buffer=1.5):
    """ Tile a membrane in the X and Y dimensions to reach a specific size.

    Parameters
    ----------
    memb : :class:`Molecule <moleculekit.molecule.Molecule>` object
        The membrane to be tiled
    xmin : float
        Minimum x coordinate
    ymin : float
        Minimum y coordinate
    xmax : float
        Maximum x coordinate
    ymax : float
        Maximum y coordinate
    buffer : float
        Buffer distance between tiles

    Returns
    -------
    megamemb :
        A big membrane Molecule
    """
    from tqdm import tqdm
    memb = memb.copy()
    memb.resid = sequenceID(
        (memb.resid, memb.insertion, memb.chain, memb.segid))

    minmemb = np.min(memb.get('coords', 'water'), axis=0).flatten()

    size = np.max(memb.get('coords', 'water'), axis=0) - np.min(
        memb.get('coords', 'water'), axis=0)
    size = size.flatten()
    xreps = int(np.ceil((xmax - xmin) / size[0]))
    yreps = int(np.ceil((ymax - ymin) / size[1]))

    logger.info('Replicating Membrane {}x{}'.format(xreps, yreps))

    from moleculekit.molecule import Molecule
    megamemb = Molecule()
    bar = tqdm(total=xreps * yreps, desc='Replicating Membrane')
    k = 0
    for x in range(xreps):
        for y in range(yreps):
            tmpmemb = memb.copy()
            xpos = xmin + x * (size[0] + buffer)
            ypos = ymin + y * (size[1] + buffer)

            tmpmemb.moveBy(
                [-float(minmemb[0]) + xpos, -float(minmemb[1]) + ypos, 0])
            tmpmemb.remove('same resid as (x > {} or y > {})'.format(
                xmax, ymax),
                           _logger=False)
            if tmpmemb.numAtoms == 0:
                continue

            tmpmemb.set('segid', 'M{}'.format(k), sel='not water')
            tmpmemb.set('segid', 'MW{}'.format(k), sel='water')

            megamemb.append(tmpmemb)
            k += 1
            bar.update(1)
    bar.close()

    # Membranes don't tile perfectly. Need to remove waters that clash with lipids of other tiles
    # Some clashes will still occur between periodic images however
    megamemb.remove('same resid as water and within 1.5 of not water',
                    _logger=False)
    return megamemb
Esempio n. 5
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from htmd.builder.amber import defaultParam, build

# Test protein ligand building with parametrized ligand
refdir = home(dataDir=join('test-amber-build', 'protLig'))
tmpdir = './protLig'

mol = Molecule(join(refdir, '3ptb_mod.pdb'))
mol.center()
lig = Molecule(join(refdir, 'benzamidine.pdb'),
               guess=('bonds', 'angles', 'dihedrals'))
prm, lig = fftype(lig, method='GAFF2')
writeFRCMOD(lig, prm, join(tmpdir, 'mol.frcmod'))
lig.segid[:] = 'L'
lig.center()

from moleculekit.util import maxDistance
D = maxDistance(mol, 'all')
D += 6
lig.moveBy([0, 0, D])

newmol = Molecule()
newmol.append(lig)
newmol.append(mol)
smol = solvate(newmol, posz=3)

params = defaultParam() + [
    join(tmpdir, 'mol.frcmod'),
]

_ = build(smol, outdir=tmpdir, param=params, ionize=False)
Esempio n. 6
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def generateCrystalPacking(pdbid, hexagonal=False, visualize=False, viewerhandle=None):
    """
    Generates the crystal packing of a PDB protein.

    It is possible to inspect it immediately with the visualize option. It can only be generated if there is
    crystallographic information in the PDB entry.

    Parameters
    ----------
    pdbid : str
        ID from the Protein Databank
    hexagonal : bool
        # TODO: Undocumented
    visualize : bool
        If True, this function also visualizes the crystal packing
    viewerhandle : :class:`VMD <moleculekit.vmdviewer.VMD>` object, optional
        A specific viewer in which to visualize the molecule. If None it will use the current default viewer.
    Returns
    -------
    mol : :class:`Molecule`
        Molecule object with the crystal packing
    """

    if not isinstance(pdbid, str):
        raise ValueError('pdbid should be a string')

    filename, _ = _getPDB(pdbid)

    mol = Molecule(filename)

    if viewerhandle is not None and not visualize:
        logger.warning('A viewerhandle was passed. Setting visualize to True.')
        visualize = True
    if visualize and viewerhandle is None:
        from moleculekit.vmdviewer import getCurrentViewer
        viewerhandle = getCurrentViewer()

    if mol.crystalinfo is None or 'numcopies' not in mol.crystalinfo:
        raise RuntimeError('No crystallography data found in Molecule.')
    ci = mol.crystalinfo

    alpha, beta, gamma, a, b, c = ci['alpha'], ci['beta'], ci['gamma'], ci['a'], ci['b'], ci['c']
    alpha = np.deg2rad(float(alpha))
    beta = np.deg2rad(float(beta))
    gamma = np.deg2rad(float(gamma))

    caux = (np.cos(alpha) - np.cos(beta) * np.cos(gamma)) / np.sin(gamma)
    axes = np.array([[a, 0, 0], [b * np.cos(gamma), b * np.sin(gamma), 0], [c * np.cos(beta), c * caux,
                    c * np.sqrt(1 - np.cos(beta) ** 2 - caux ** 2)]])
    size = np.array([axes[0][0], axes[1][1], axes[2][2]])

    molunit = Molecule()

    # Creates copies of the molecule and places them correctly inside the complete Unit Cell
    hexagonal_molunit = None
    for i in tqdm(range(ci['numcopies']), desc='Generating symmetry mates'):
        molecule = mol.copy()
        molecule.segid[:] = str(i+1)
        # apply SMTRY (Crystal Symmetry) operations
        molecule.rotateBy(ci['rotations'][i])
        molecule.moveBy(ci['translations'][i])
        # apply translation to inside of same Unit Cell.
        _place_crystal(molecule, size, [alpha, beta, gamma], axes)
        # pack copies to target Unit Cell
        molunit.append(molecule)
    if ci['sGroup'][0] == 'H' and hexagonal:
        hexagonal_molunit = Molecule()
        _build_hexagon(molunit, hexagonal_molunit)

    if hexagonal_molunit is not None:
        if visualize:
            hexagonal_molunit.view(style='NewCartoon', viewerhandle=viewerhandle)
        else:
            return hexagonal_molunit
    else:
        if visualize:
            molunit.view(style='NewCartoon', viewerhandle=viewerhandle)
        else:
            return molunit

    if visualize:
        _draw_cell(axes, ci['sGroup'], viewerhandle, hexagonal=hexagonal)