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Studer Gabriel authored
This commit doesn't make OpenStructure work with Python 3. The goal of this commit was to perform an automated port of the Python code and make it compile. The performed steps: - Edited CMakeLists.txt to search for Python with 3.6 as min version 3.6 is the Python version shipped by default with Ubuntu 18.04 LTS - Add version 3.6 to cmake_support/FindPython.cmake - Adapt setup_boost macro in cmake_support/OST.cmake to prefer versioned libraries and not first check for boost_python.so. In the example of Ubuntu 18.04, libboost_python.so is specific for Python 2 but libboost_python3.so is the one we want. - apply the following command: 2to3-2.7 -n -w <OST_DIR> - adapt base/pymod/wrap_base.cc, gui/pymod/wrap_gui.cc and gui/pymod/export_message_widget.cc as PyString functionalities do not exist anymore in the Python 3 interpreter (replaced by PyUnicode) - adapt gui/src/python_shell/python_interpreter_worker.hh to resolve issue discussed in https://stackoverflow.com/questions/23068700/embedding-python3-in-qt-5 Long story short: Qt does a typedef for "slots" which causes trouble with other headers that are pulled in from the Python interpreter
Studer Gabriel authoredThis commit doesn't make OpenStructure work with Python 3. The goal of this commit was to perform an automated port of the Python code and make it compile. The performed steps: - Edited CMakeLists.txt to search for Python with 3.6 as min version 3.6 is the Python version shipped by default with Ubuntu 18.04 LTS - Add version 3.6 to cmake_support/FindPython.cmake - Adapt setup_boost macro in cmake_support/OST.cmake to prefer versioned libraries and not first check for boost_python.so. In the example of Ubuntu 18.04, libboost_python.so is specific for Python 2 but libboost_python3.so is the one we want. - apply the following command: 2to3-2.7 -n -w <OST_DIR> - adapt base/pymod/wrap_base.cc, gui/pymod/wrap_gui.cc and gui/pymod/export_message_widget.cc as PyString functionalities do not exist anymore in the Python 3 interpreter (replaced by PyUnicode) - adapt gui/src/python_shell/python_interpreter_worker.hh to resolve issue discussed in https://stackoverflow.com/questions/23068700/embedding-python3-in-qt-5 Long story short: Qt does a typedef for "slots" which causes trouble with other headers that are pulled in from the Python interpreter
helix_kinks.py 6.84 KiB
"""
Functions to calculate helix kinks: bend, face shift and wobble angles
Author: Niklaus Johner
"""
import os
import ost
def __FindProline(sele,proline):
if not sele.IsValid():
print('selection is not valid')
raise RuntimeError
if proline==False:
proline=sele.Select('rname=PRO')
if not proline.GetResidueCount()==1:
print(proline.GetResidueCount(),'prolines in the selection. One proline is needed')
raise RuntimeError
proline=proline.residues[0]
proline_ca=proline.FindAtom('CA')
if not proline_ca.IsValid():
print('proline has no CA atom')
raise RuntimeError
return (proline,proline_ca)
proline.GetNumber().num
def __SelectPreAndPostProline(sele,proline_num):
pre_proline=sele.Select('rnum<'+str(proline_num))
post_proline=sele.Select('rnum>'+str(proline_num))
print('pre-proline residues')
for res in pre_proline.residues:
print(res)
print('post-proline residues')
for res in post_proline.residues:
print(res)
if pre_proline.GetResidueCount()<4 or post_proline.GetResidueCount()<4:
print('pre and post proline helices should be at least 4 residues long, 7 for better stability')
raise RuntimeError
return (pre_proline,post_proline)
def __FindCa3AndCa4(sele,proline_ca,proline_num):
ca_3=sele.FindAtom(proline_ca.GetHandle().GetChain().GetName(),proline_num-3,'CA')
ca_4=sele.FindAtom(proline_ca.GetHandle().GetChain().GetName(),proline_num-4,'CA')
if not (ca_3.IsValid() and ca_4.IsValid()):
print('CA not found in (i-4) or (i-3) residue')
raise RuntimeError
return (ca_3,ca_4)
def __CalculateBendAngle(pre_proline_axis,post_proline_axis):
return ost.geom.Angle(pre_proline_axis,post_proline_axis)
def __CalculateWobbleAngle(pre_proline_axis,post_proline_axis,post_proline_centers,proline_pos):
p1=proline_pos-post_proline_centers
n1=p1-ost.geom.Dot(p1,post_proline_axis)*post_proline_axis
p2=-pre_proline_axis
n2=p2-ost.geom.Dot(p2,post_proline_axis)*post_proline_axis
sign=ost.geom.Dot(ost.geom.Cross(pre_proline_axis,n2),n2-n1)
sign=sign/abs(sign)
return sign*ost.geom.Angle(n1,n2)
def __CalculateFaceShift(pre_proline_axis,post_proline_axis,pre_proline_centers,post_proline_centers,proline_pos,ca3_pos,ca4_pos,bend_angle):
p1=proline_pos-post_proline_centers
n1=p1-ost.geom.Dot(p1,post_proline_axis)*post_proline_axis
p2=(ca3_pos+ca4_pos)/2.0-pre_proline_centers
n2=p2-ost.geom.Dot(p2,pre_proline_axis)*pre_proline_axis
#Here we want to apply a rotation to n1, to align the post-proline axis on the pre-proline axis
R=ost.geom.AxisRotation(ost.geom.Cross(post_proline_axis,pre_proline_axis),bend_angle)
n1=R*n1
#We also need to determine the sign of the angle
sign=ost.geom.Dot(ost.geom.Cross(pre_proline_axis,n2),n2-n1)
sign=sign/abs(sign)
return sign*ost.geom.Angle(n1,n2)
def AnalyzeHelixKink(t, sele, proline=False):
"""
This function calculates the bend, wobble and face-shift angles in an alpha-
helix over a trajectory. The determination is more stable if there are at
least 4 residues on each side (8 is even better) of the proline around which
the helix is kinked. The selection should contain all residues in the correct
order and with no gaps and no missing C-alphas.
:param t: The trajectory to be analyzed
:type t: :class:`~ost.mol.CoordGroup`
:param sele: A selection containing the alpha helix to be analyzed
:type sele: :class:`~ost.mol.EntityView`
:param proline: A selection containing only the proline (or another residue)
around which the helix is kinked. If False, the proline will
be searched for automatically
:type proline: :class:`ost.mol.EntityView`
:return: A tuple (bend_angle, face_shift, wobble_angle).
:rtype: (FloatList, FLoatList, FloatList)
"""
n_frames=t.GetFrameCount()
(proline,proline_ca)=__FindProline(sele,proline)
proline_num=proline.GetNumber().num
(pre_proline,post_proline)=__SelectPreAndPostProline(sele,proline_num)
(ca_3,ca_4)=__FindCa3AndCa4(sele,proline_ca,proline_num)
#Here we extract the necessary information from the trajectory
pre_proline_axis=ost.geom.Vec3List()
post_proline_axis=ost.geom.Vec3List()
pre_proline_centers=ost.geom.Vec3List()
post_proline_centers=ost.geom.Vec3List()
ost.mol.alg.AnalyzeAlphaHelixAxis(t,pre_proline,pre_proline_axis,pre_proline_centers)
ost.mol.alg.AnalyzeAlphaHelixAxis(t,post_proline,post_proline_axis,post_proline_centers)
proline_pos=ost.mol.alg.AnalyzeAtomPos(t,proline_ca.GetHandle())
ca3_pos=ost.mol.alg.AnalyzeAtomPos(t,ca_3.GetHandle())
ca4_pos=ost.mol.alg.AnalyzeAtomPos(t,ca_4.GetHandle())
#Now we calculate the bend angle
bend_angle=ost.FloatList()
face_shift=ost.FloatList()
wobble_angle=ost.FloatList()
for i in range(n_frames):
bend_angle.append(__CalculateBendAngle(pre_proline_axis[i],post_proline_axis[i]))
face_shift.append(__CalculateFaceShift(pre_proline_axis[i],post_proline_axis[i],pre_proline_centers[i],post_proline_centers[i],proline_pos[i],ca3_pos[i],ca4_pos[i],bend_angle[i]))
wobble_angle.append(__CalculateWobbleAngle(pre_proline_axis[i],post_proline_axis[i],post_proline_centers[i],proline_pos[i]))
return (bend_angle,face_shift,wobble_angle)
def CalculateHelixKink(sele, proline=False):
"""
This function calculates the bend, wobble and face-shift angles in an alpha-
helix of an EntityView. The determination is more stable if there are at least
4 residues on each side (8 is even better) of the proline around which the
helix is kinked. The selection should contain all residues in the correct
order and with no gaps and no missing C-alphas.
:param sele: A selection containing the alpha helix to be analyzed
:type sele: :class:`~ost.mol.EntityView`
:param proline: A selection containing only the proline (or another residue)
around which the helix is kinked. If False, the proline will
be searched for automatically
:type proline: :class:`ost.mol.EntityView`
:return: A tuple (bend_angle, face_shift, wobble_angle).
:rtype: (float, float, float)
"""
(proline,proline_ca)=__FindProline(sele,proline)
proline_num=proline.GetNumber().num
(pre_proline,post_proline)=__SelectPreAndPostProline(sele,proline_num)
(ca_3,ca_4)=__FindCa3AndCa4(sele,proline_ca,proline_num)
#Here we extract the necessary information from the structure
pre_proline_axis=ost.mol.alg.structure_analysis.CalculateHelixAxis(pre_proline)
post_proline_axis=ost.mol.alg.structure_analysis.CalculateHelixAxis(post_proline)
prepa=pre_proline_axis.GetDirection()
prepc=pre_proline_axis.GetOrigin()
postpa=post_proline_axis.GetDirection()
postpc=post_proline_axis.GetOrigin()
#calculate the angles
bend=__CalculateBendAngle(prepa,postpa)
wobble=__CalculateWobbleAngle(prepa,postpa,postpc,proline_ca.pos)
shift=__CalculateFaceShift(prepa,postpa,prepc,postpc,proline_ca.pos,ca_3.pos,ca_4.pos,bend)
return (bend,shift,wobble)