#!/usr/bin/env python3
"""Module containing the MDAnalysis HOLE class and the command line interface."""
import re
import argparse
import numpy as np
from biobb_common.generic.biobb_object import BiobbObject
from biobb_common.configuration import settings
from biobb_common.tools.file_utils import launchlogger
import MDAnalysis as mda
from MDAnalysis.analysis import hole2
[docs]
class MDAHole(BiobbObject):
"""
| biobb_mem MDAHole
| Wrapper of the MDAnalysis HOLE module for analyzing ion channel pores or transporter pathways.
| MDAnalysis HOLE provides an interface to the HOLE suite of tools to analyze pore dimensions and properties along a channel or transporter pathway. The parameter names and defaults follow the `MDAnalysis HOLE <https://docs.mdanalysis.org/stable/documentation_pages/analysis/hole2.html>`_ implementation.
Args:
input_top_path (str): Path to the input structure or topology file. File type: input. `Sample file <https://github.com/bioexcel/biobb_mem/raw/main/biobb_mem/test/data/A01JD/A01JD.pdb>`_. Accepted formats: crd (edam:3878), gro (edam:2033), mdcrd (edam:3878), mol2 (edam:3816), pdb (edam:1476), pdbqt (edam:1476), prmtop (edam:3881), psf (edam:3882), top (edam:3881), tpr (edam:2333), xml (edam:2332), xyz (edam:3887).
input_traj_path (str): Path to the input trajectory to be processed. File type: input. `Sample file <https://github.com/bioexcel/biobb_mem/raw/main/biobb_mem/test/data/A01JD/A01JD.xtc>`_. Accepted formats: arc (edam:2333), crd (edam:3878), dcd (edam:3878), ent (edam:1476), gro (edam:2033), inpcrd (edam:3878), mdcrd (edam:3878), mol2 (edam:3816), nc (edam:3650), pdb (edam:1476), pdbqt (edam:1476), restrt (edam:3886), tng (edam:3876), trr (edam:3910), xtc (edam:3875), xyz (edam:3887).
output_hole_path (str): Path to the output HOLE analysis results. File type: output. `Sample file <https://github.com/bioexcel/biobb_mem/raw/main/biobb_mem/test/reference/mdanalysis_biobb/hole.vmd>`_. Accepted formats: vmd (edam:format_2330).
properties (dic - Python dictionary object containing the tool parameters, not input/output files):
* **start** (*int*) - (None) Starting frame for slicing.
* **stop** (*int*) - (None) Ending frame for slicing.
* **steps** (*int*) - (None) Step for slicing.
* **executable** (*str*) - ("hole") Path to the HOLE executable.
* **select** (*str*) - ("protein") The selection string to create an atom selection that the HOLE analysis is applied to.
* **cpoint** (*list*) - (None) Coordinates of a point inside the pore (Å). If None, tries to guess based on the geometry.
* **cvect** (*list*) - (None) Search direction vector. If None, tries to guess based on the geometry.
* **sample** (*float*) - (0.2) Distance of sample points in Å. This value determines how many points in the pore profile are calculated.
* **end_radius** (*float*) - (22) Radius in Å, which is considered to be the end of the pore.
* **dot_density** (*int*) - (15) [5~35] Density of facets for generating a 3D pore representation.
* **remove_tmp** (*bool*) - (True) [WF property] Remove temporal files.
* **restart** (*bool*) - (False) [WF property] Do not execute if output files exist.
* **sandbox_path** (*str*) - ("./") [WF property] Parent path to the sandbox directory.
Examples:
This is a use example of how to use the building block from Python::
from biobb_mem.mdanalysis_biobb.mda_hole import mda_hole
prop = {
'select': 'protein',
'executable': 'hole'
}
mda_hole(input_top_path='/path/to/myTopology.pdb',
input_traj_path='/path/to/myTrajectory.xtc',
output_hole_path='/path/to/hole_analysis.csv',
properties=prop)
Info:
* wrapped_software:
* name: MDAnalysis
* version: 2.7.0
* license: GNU
* ontology:
* name: EDAM
* schema: http://edamontology.org/EDAM.owl
"""
def __init__(self, input_top_path, input_traj_path, output_hole_path,
properties=None, **kwargs) -> None:
properties = properties or {}
# Call parent class constructor
super().__init__(properties)
self.locals_var_dict = locals().copy()
# Input/Output files
self.io_dict = {
"in": {"input_top_path": input_top_path, "input_traj_path": input_traj_path},
"out": {"output_hole_path": output_hole_path}
}
# Properties specific for MDAHole
self.start = properties.get('start', None)
self.stop = properties.get('stop', None)
self.steps = properties.get('steps', None)
self.executable = properties.get('executable', 'hole')
self.select = properties.get('select', 'protein')
self.cpoint = properties.get('cpoint', None)
self.cvect = properties.get('cvect', None)
self.sample = properties.get('sample', 0.2)
self.end_radius = properties.get('end_radius', 22)
self.dot_density = properties.get('dot_density', 15)
self.properties = properties
# Check the properties
self.check_properties(properties)
self.check_arguments()
[docs]
@launchlogger
def launch(self) -> int:
"""Execute the :class:`MDAHole <mdanalysis_biobb.mda_hole.MDAHole>` class."""
# Setup Biobb
if self.check_restart():
return 0
self.stage_files()
# Load the universe
u = mda.Universe(self.stage_io_dict["in"]["input_top_path"],
self.stage_io_dict["in"]["input_traj_path"])
# Create HoleAnalysis object
hole = hole2.HoleAnalysis(
universe=u,
select=self.select,
cpoint=self.cpoint,
cvect=self.cvect,
sample=self.sample,
executable=self.executable
)
# Run the analysis with step parameter
hole.run(
start=self.start,
stop=self.stop,
step=self.steps
)
hole.create_vmd_surface(
self.stage_io_dict["out"]["output_hole_path"],
dot_density=self.dot_density
)
hole.delete_temporary_files()
# Copy files to host
self.copy_to_host()
# remove temporary folder(s)
self.tmp_files.extend([
self.stage_io_dict.get("unique_dir")
])
self.remove_tmp_files()
self.check_arguments(output_files_created=True, raise_exception=False)
return self.return_code
[docs]
def mda_hole(input_top_path: str, input_traj_path: str, output_hole_path: str = None, properties: dict = None, **kwargs) -> int:
"""Execute the :class:`MDAHole <mdanalysis_biobb.mda_hole.MDAHole>` class and
execute the :meth:`launch() <mdanalysis_biobb.mda_hole.MDAHole.launch>` method."""
return MDAHole(input_top_path=input_top_path,
input_traj_path=input_traj_path,
output_hole_path=output_hole_path,
properties=properties, **kwargs).launch()
[docs]
def main():
"""Command line execution of this building block. Please check the command line documentation."""
parser = argparse.ArgumentParser(description="Analyze ion channel pores or transporter pathways.", formatter_class=lambda prog: argparse.RawTextHelpFormatter(prog, width=99999))
parser.add_argument('--config', required=False, help='Configuration file')
# Specific args of each building block
required_args = parser.add_argument_group('required arguments')
required_args.add_argument('--input_top_path', required=True, help='Path to the input structure or topology file. Accepted formats: crd, gro, mdcrd, mol2, pdb, pdbqt, prmtop, psf, top, tpr, xml, xyz.')
required_args.add_argument('--input_traj_path', required=True, help='Path to the input trajectory to be processed. Accepted formats: arc, crd, dcd, ent, gro, inpcrd, mdcrd, mol2, nc, pdb, pdbqt, restrt, tng, trr, xtc, xyz.')
required_args.add_argument('--output_hole_path', required=True, help='Path to the output HOLE analysis results. Accepted formats: vmd.')
args = parser.parse_args()
args.config = args.config or "{}"
properties = settings.ConfReader(config=args.config).get_prop_dic()
# Specific call of each building block
mda_hole(input_top_path=args.input_top_path,
input_traj_path=args.input_traj_path,
output_hole_path=args.output_hole_path,
properties=properties)
[docs]
def display_hole(input_top_path: str, output_hole_path: str = 'hole.vmd',
frame: int = 0, opacity: float = 0.9):
"""
Visualize a channel using NGLView from a VMD file.
Args:
input_top_path (str): Path to the input topology file.
output_hole_path (str, optional): Path to the VMD file containing the channel data. Default is 'hole.vmd'.
frame (int, optional): Frame index to visualize. Default is 0.
opacity (float, optional): Opacity of the visualization. Default is 0.9.
Returns:
nglview.NGLWidget: NGLView widget for visualizing the channel.
"""
try:
import nglview as nv
except ImportError:
raise ImportError('Please install the nglview package to visualize the channel.')
# Read the VMD file and parse triangles
with open(output_hole_path, 'r') as f:
lines = f.readlines()
# Find lines with triangle coordinates
trinorms = []
for i, line in enumerate(lines):
if i > 3 and 'set triangle' in line:
vmd_set = re.sub(r'set triangles\(\d+\)', '', line) # Remove set triangles(i)
vmd_set = re.sub(r'\{(\s*-?\d[^\s]*)(\s*-?\d[^\s]*)(\s*-?\d[^}]*)\}', r'[\1,\2,\3]', vmd_set) # Convert { x y z } to [x,y,z]
vmd_set = vmd_set.replace('{', '[').replace('}', ']') # Convert { to [ and } to ]
vmd_set = re.sub(r'\]\s*\[', '], [', vmd_set) # Add commas between brackets
vmd_set = eval(vmd_set.strip()) # Evaluate string as list
# different hole colors
trinorms.append(vmd_set)
colors = np.array([[1, 0, 0], # red
[0, 1, 0], # green
[0, 0, 1]]) # blue
poss, cols, nors = [], [], []
for i, color in enumerate(colors):
if len(trinorms[frame][i]) > 0:
col_dat = np.array(trinorms[frame][i])
poss.append(col_dat[:, :3, :].flatten())
cols.append((np.zeros(col_dat.shape[0]*18).reshape(-1, 3) + color).flatten())
nors.append(col_dat[:, 3:, :].flatten())
poss = np.concatenate(poss)
cols = np.concatenate(cols)
nors = np.concatenate(nors)
# Create NGLView widget
view = nv.show_file(input_top_path)
# view.clear_representations()
mesh = ('mesh', poss, cols)
view._add_shape([mesh], name='my_shape')
view.update_representation(component=1, repr_index=0, opacity=opacity)
return view
if __name__ == '__main__':
main()