Ejemplo n.º 1
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 def test_hbond(self):
     """Calculates real-life coordinates"""
     vec1 = Vector([33.48, 142.73, -25.44])
     vec2 = Vector([33.24, 142.49, -24.16])
     vec3 = Vector([33.00, 141.24, -23.75])
     vec4 = build_coord(vec1, vec2, vec3, 1.1, 120.0, 33.0)
     self.assertEqual(str(vec4), '<Vector 33.49, 140.39, -24.25>')
Ejemplo n.º 2
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 def minimize_atoms(self):
     """Performs crude random minimization of dihedral angles."""
     epsilon = 0.02
     i = 0
     maxcyc = 50
     step = 120
     delta = 100 + epsilon
     MAX_J = 5
     MAX_K = 5
     tor1, tor2 = 0.0, 0.0
     matrix1 = get_ref_matrix(self.c4v, self.c3v, self.o3v)
     while delta > epsilon and i < maxcyc:
         old = (self.p.coord, self.o5.coord, tor1, tor2)
         # generate and check candidate positions
         j = 0
         while j < MAX_J:
             # construct P atom
             t1 = self.get_random_torsion(tor1, step)
             d = build_coord(self.c4v, self.c3v, self.o3v, O3_P_DIST, A1,
                             t1, matrix1)
             self.p.coord = array((d[0], d[1], d[2]))
             self.pv = self.p.get_vector()
             matrix2 = get_ref_matrix(self.c3v, self.o3v, self.pv)
             k = 0
             while k < MAX_K:
                 # construct O5 atom
                 t2 = self.get_random_torsion(tor2, step)
                 d = build_coord(self.c3v, self.o3v, self.pv, P_O5_DIST, A2,
                                 t2, matrix2)
                 self.o5.coord = array((d[0], d[1], d[2]))
                 self.o5v = self.o5.get_vector()
                 # evaluate the candidate atoms
                 score = self.get_score(delta)
                 if score < delta:
                     delta = score
                     tor1, tor2 = t1, t2
                     j = MAX_J
                     k = MAX_K
                 k += 1
             j += 1
         if j == MAX_J:
             # old position is better
             self.p.coord, self.o5.coord, tor1, tor2 = old
             step = step * 0.5
         i += 1
Ejemplo n.º 3
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 def _test_coord_samples(self, coord, examples):
     """
     Runs the coord building on a set of
     dist, angle, torsion values.
     """
     for dis, ang, tor in examples:
         vec1, vec2, vec3 = coord
         vec4 = build_coord(vec1, vec2, vec3, dis, ang, tor)
         result = self._measure(vec1, vec2, vec3, vec4)
         self.assertDistance(result, dis)
         self.assertAngle(result, ang)
         self.assertTorsion(result, tor)
Ejemplo n.º 4
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 def create_resi_from_torsions(self, torsions):
     """Creates residue with backbone atoms in different positions."""
     resi2_copy = RNAResidue(self.resi2, \
             alphabet_entry=self.resi2.alphabet_entry)
     epsilon, zeta, alpha, beta, gamma, delta = torsions
     c4c3 = self.resi2["C4'"] - self.resi2["C3'"]
     c3c2 = self.resi2["C3'"] - self.resi2["C2'"]
     at_p = build_coord(self.resi1["C4'"].get_vector(), \
             self.resi1["C3'"].get_vector(), \
             self.resi1["O3'"].get_vector(), O3_P_DIST, 109.0,epsilon)
     at_o5 = build_coord(self.resi1["C3'"].get_vector(), \
             self.resi1["O3'"].get_vector(), \
             at_p, P_O5_DIST, 109.0, zeta)
     at_c5 = build_coord(self.resi1["O3'"].get_vector(), \
             at_p, at_o5, O5_C5_DIST, 109.0, alpha)
     at_c4 = build_coord(at_p, at_o5, at_c5, C5_C4_DIST, 109.0, beta)
     at_c3 = build_coord(at_o5, at_c5, at_c4, c4c3, 109.0, gamma)
     at_c2 = build_coord(at_c5, at_c4, at_c3, c3c2, 109.0, delta)
     resi2_copy['P'].coord = array((at_p[0], at_p[1], at_p[2]))
     resi2_copy["O5'"].coord = array((at_o5[0], at_o5[1], at_o5[2]))
     resi2_copy["C5'"].coord = array((at_c5[0], at_c5[1], at_c5[2]))
     resi2_copy["C4'"].coord = array((at_c4[0], at_c4[1], at_c4[2]))
     resi2_copy["C3'"].coord = array((at_c3[0], at_c3[1], at_c3[2]))
     resi2_copy["C2'"].coord = array((at_c2[0], at_c2[1], at_c2[2]))
     return resi2_copy
Ejemplo n.º 5
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 def __get_phosphate_atoms(self, beta):
     """
     Creates atoms (P, OP1, OP2, OP3) based on values from given resi and given B angle.
     Returns list of 4 created atoms.
     """
     p_coord = build_coord(self.c4v, self.c5v, self.o5v, P_O5_DIST, A3,
                           beta)
     at_P = self.create_atom("P", "P", p_coord.get_array())
     pv = at_P.get_vector()
     op1_coord = build_coord(self.c5v, self.o5v, pv, P_OP_DIST, P_OP_ANGLE,
                             OP1_TORSION)
     op2_coord = build_coord(self.c5v, self.o5v, pv, P_OP_DIST, P_OP_ANGLE,
                             OP2_TORSION)
     op3_coord = build_coord(self.c5v, self.o5v, pv, P_OP_DIST, P_OP_ANGLE,
                             OP3_TORSION)
     at_OP1 = self.create_atom("OP1", "O", op1_coord.get_array())
     at_OP2 = self.create_atom("OP2", "O", op2_coord.get_array())
     at_OP3 = self.create_atom("OP3", "O", op3_coord.get_array())
     # might be usful here?
     # from Bio.PDB import calc_angle, calc_dihedral
     # angle = calc_angle(at1.get_vector(), at2.get_vector(), at3.get_vector())
     # dihedral = calc_dihedral(at1.get_vector(), at2.get_vector(), at3.get_vector(), at4.get_vector())
     return [at_P, at_OP1, at_OP2, at_OP3]
Ejemplo n.º 6
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    def get_donor_hydrogens(self, donor):
        """
        Returns a list of coord records of hypothetical hydrogen positions.
        If the donor has two neighbors, this will be a single position, if
        it has only one, a rotation will be performed in 10 degree steps.
        Atoms with 3 or more neighbors will be rejected.
        """
        # TODO: refactor this out.
        if donor.name in self._donor_hydrogens:
            return self._donor_hydrogens[donor.name]

        hydrogens = []
        neighbors = self.get_neighbors(donor)
        don_vec = donor.get_vector()
        sup_vec1 = None  # coordinates next to donor
        sup_vec2 = None  # coordinates to calc torsion

        if len(neighbors) == 1:
            sup_vec1 = neighbors[0].get_vector()
            neighbors2 = self.get_neighbors(neighbors[0])
            sup_vec2 = None
            while neighbors2 and sup_vec2 is None:
                next = neighbors2.pop()
                if next != donor:
                    sup_vec2 = next.get_vector()
            # bad case: no neighbors to construct 2nd support vec
            if sup_vec2 is None:
                sup_vec2 = (don_vec**sup_vec1)
            angle = H_ANGLE_ONE
            torsions = H_GENERATE_TORSIONS

        elif len(neighbors) == 2:
            sup_vec1 = neighbors[0].get_vector()
            sup_vec2 = neighbors[1].get_vector()
            angle = H_ANGLE_TWO
            torsions = [180.0]

        if sup_vec1 is not None and sup_vec2 is not None:
            # create hydrogen positions
            for torsion in torsions:
                h_pos = build_coord(sup_vec2, sup_vec1, don_vec,
                                    H_COVALENT_BOND, angle, torsion)
                h_pos = array([h_pos[0], h_pos[1], h_pos[2]])
                hydrogens.append(h_pos)

        self._donor_hydrogens[donor.name] = hydrogens
        # self.write_hydrogens(hydrogens)
        return hydrogens
Ejemplo n.º 7
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 def test_build_coord(self):
     """Checks whether the P+O5' atoms are constructed."""
     vec1, vec2, vec3 = self.sample_coord
     vec4 = build_coord(vec1, vec2, vec3, 1.0, 90.0, 0)
     self.assertTrue(isinstance(vec4, Vector))
Ejemplo n.º 8
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 def test_dihedral(self):
     """Checks whether the torsion angle is OK."""
     vec1, vec2, vec3 = self.sample_coord
     vec4 = build_coord(vec1, vec2, vec3, 1.0, 90.0, 90.0)
     result = self._measure(vec1, vec2, vec3, vec4)
     self.assertTorsion(result, 90.0)
Ejemplo n.º 9
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 def test_angle(self):
     """Checks whether the angle is OK."""
     vec1, vec2, vec3 = self.sample_coord
     vec4 = build_coord(vec1, vec2, vec3, 1.0, 90.0, 0.0)
     result = self._measure(vec1, vec2, vec3, vec4)
     self.assertAngle(result, 90.0)
Ejemplo n.º 10
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 def test_distance(self):
     """Checks whether the distance is OK."""
     vec1, vec2, vec3 = self.sample_coord
     vec4 = build_coord(vec1, vec2, vec3, 2.34, 90.0, 0.0)
     result = self._measure(vec1, vec2, vec3, vec4)
     self.assertDistance(result, 2.34)