viewer3d

Display PackedPose objects, Pose objects, or .pdb files within a Jupyter notebook and Google Colab.

Description

The viewer3d macromolecular viewer quickly renders .pdb files, dynamically instantiating Pose objects if required for certain visualization modules (matching the name viewer3d.set*). So when adding visualization modules to the viewer or using presets, passing Pose or PackedPose objects to the viewer is suggested for quicker rendering. If a Pose object or list, tuple, or set of Pose objects are provided to the viewer, the Pose(s) pointer location(s) in memory remain fixed, and so the viewer can dynamically update upon Pose conformational changes by calling the following methods:

update_viewer(index=None, model=None, add_objects=True, remove_objects=True)

add_pose(pose, index=None, update_viewer=True)

add_pdbstring(pdbstring, index=None, update_viewer=True)

remove_pose(index=None, model=None, update_viewer=True)

remove_pdbstring(index=None, model=None, update_viewer=True)

update_pose(pose, index=None, model=None, update_viewer=True)

update_pdbstring(pdbstring, index=None, model=None, update_viewer=True)

update_poses(poses, index=None, update_viewer=True)

update_pdbstrings(pdbstrings, index=None, update_viewer=True)

For adding/removing visualization modules in the widget update function, either initialize the viewer with viewer3d.init(modules=[...]) or call the set_modules() method to overwrite the current list of modules. Otherwise, call the clear() method then add the new modules. After pose conformational changes and setting the viewer modules, call the update_viewer() method if the pose's pointer in memory remains the same, otherwise call the update_pose(pose) method to update the pose and viewer.

See docstrings for more information. The viewer applies visualization modules in the same order they are added (from left to right), so layering different styles (and ResidueSelectors) on top of one another becomes possible. The user must have already initialized PyRosetta providing .params files for any ligands and non-canonical residues in the input molecule(s), otherwise pyrosetta.distributed automatically initializes PyRosetta with default command line options.

Contributing

Please open a pull request with an updated unit test from a custom branch.

Unit Tests

python -m unittest

Installation

conda env create -f environment.yml

PyPI Releases

Update version number in setup.py
pip install --user --upgrade setuptools wheel twine
rm -rf dist/*
python setup.py sdist bdist_wheel
python -m twine upload dist/*

Usage Examples:

import viewer3d

Example Jupyter notebook commands:

v = viewer3d.init("path/to/pdbfile.pdb")
v.show()

import logging
logging.basicConfig(level=logging.WARNING)
import pyrosetta
pyrosetta.init("-mute all")

pose = pyrosetta.toolbox.rcsb.pose_from_rcsb("5BVL")

view = viewer3d.init(pose, window_size=(800, 600), backend="nglview")
view() # Equivalent to view.show()

poses = [pyrosetta.toolbox.rcsb.pose_from_rcsb(pdbid) for pdbid in ["5BVL", "6MSR", "1QCQ"]]

view = viewer3d.init(poses) \
+ viewer3d.setStyle(colorscheme="lightgreyCarbon") \
+ viewer3d.setHydrogenBonds()
view()

import pyrosetta.distributed.io as io
packed_pose = io.to_packed(pyrosetta.toolbox.pose_from_rcsb("2FD7"))
polar_residue_selector = pyrosetta.rosetta.core.select.residue_selector.ResiduePropertySelector(
    pyrosetta.rosetta.core.chemical.ResidueProperty(52)
)

view = viewer3d.init(packed_pose)
view.add(viewer3d.setStyle(radius=0.1))
view.add(viewer3d.setStyle(residue_selector=polar_residue_selector, colorscheme="whiteCarbon", radius=0.25, label=False))
view.add(viewer3d.setHydrogens(color="white", polar_only=True, radius=0.1))
view.add(viewer3d.setHydrogenBonds(color="black"))
view.add(viewer3d.setDisulfides(radius=0.1))
view()

view = sum(
    [
        viewer3d.init(packed_pose),
        viewer3d.setStyle(cartoon=False, style="sphere", radius=1.5, colorscheme="darkgreyCarbon"),
        viewer3d.setZoom(factor=1.5)
    ]
)
view.show()

from pyrosetta.rosetta.core.select.residue_selector import ChainSelector
pose = pyrosetta.toolbox.rcsb.pose_from_rcsb("6MSR")
chA = ChainSelector("A")
chB = ChainSelector("B")

view = sum(
    [
        viewer3d.init(pose, backend=1, gui=True),
        viewer3d.setStyle(cartoon_color="lightgrey", radius=0.25),
        viewer3d.setSurface(residue_selector=chA, colorscheme="greenCarbon", opacity=0.65, surface_type="VDW"),
        viewer3d.setSurface(residue_selector=chB, color="blue", opacity=1.0, surface_type="SAS"),
        viewer3d.setDisulfides(radius=0.25),
        viewer3d.setZoom(factor=1.5)
    ]
)
view()

import pyrosetta.distributed.io as io
import viewer3d
from pyrosetta.rosetta.core.select.residue_selector import (
    LayerSelector,
    ChainSelector,
)

poses = [io.pose_from_sequence("TEST" * i) for i in range(1, 6)]
core_selector = LayerSelector()
core_selector.set_layers(True, False, False)
boundary_selector = LayerSelector()
boundary_selector.set_layers(False, True, False)
surface_selector = LayerSelector()
surface_selector.set_layers(False, False, True)
view = (
    viewer3d.init(poses, (1200, 800.01), delay=0, backend=1) \
    + viewer3d.setStyle()  #residue_selector=surface_selector, style="stick", colorscheme="element", label=False) #+ viewer3d.setSurface(opacity=0.5)
    + viewer3d.setDisulfides() \
    + viewer3d.setBackgroundColor(color="lightgray")
    + viewer3d.setHydrogenBonds()
    + viewer3d.setHydrogens(polar_only=True, color="white")
    + viewer3d.setZoomTo(ChainSelector("A")) \
    + viewer3d.setZoom(-1) \
)
view.show()

from pyrosetta.rosetta.core.select.residue_selector import SecondaryStructureSelector
helix_selector = SecondaryStructureSelector("H")
sheet_selector = SecondaryStructureSelector("E")
loop_selector = SecondaryStructureSelector("L")

modules = [
    viewer3d.setBackgroundColor(color="grey"),
    viewer3d.setStyle(residue_selector=helix_selector, cartoon_color="blue", label=False, radius=0),
    viewer3d.setStyle(residue_selector=sheet_selector, cartoon_color="red", label=False, radius=0),
    viewer3d.setStyle(residue_selector=loop_selector, cartoon_color="white", label=False, radius=0)
]

view = viewer3d.init(poses, window_size=(1200, 600), modules=modules, continuous_update=True)
view()

view.clear() # Subtract all visualization modules previously added to the Viewer
view()

View a live trajectory:

pose = pyrosetta.toolbox.pose_from_rcsb("2FD7")
v = viewer3d.init(pose, delay=0.1) + viewer3d.setStyle(radius=0.1) + viewer3d.setDisulfides(radius=0.1)
backrub = pyrosetta.rosetta.protocols.backrub.BackrubMover()
minimize = pyrosetta.rosetta.protocols.minimization_packing.MinMover()

for _ in range(100):
    backrub.apply(pose)
    minimize.apply(pose)
    v.update_pose(pose)

Display preset custom viewers for routine visualizations:

viewer3d.presets.coreBoundarySurface(poses, window_size=(800, 600), continuous_update=True)

view = viewer3d.presets.makeBundle(backend=1)
view.show()

Visualize the residue 1 psi-space of a 20-residue polyvaline extended peptide:

from bokeh.palettes import Viridis
n = 11 # 256
v = viewer3d.init(backend=1)
pose = pyrosetta.io.pose_from_sequence("V" * 20)
for i, hex_str in enumerate(Viridis[n]):
    v.set_modules(viewer3d.setStyle(cartoon_color=hex_str, radius=0))
    pose.set_psi(1, i * 360 / n)
    v.add_pose(pose)

Overlay multiple poses:

pose1 = pyrosetta.toolbox.rcsb.pose_from_rcsb("6V67")
pose2 = pyrosetta.toolbox.rcsb.pose_from_rcsb("1ATP")
v = viewer3d.init()
v += viewer3d.setStyle(colorscheme='redCarbon')
v += viewer3d.setSurface()
v.add_pose(pose1) # Automatically updates the viewer with the currently set modules
v.reset() # Subtract all modules
v += viewer3d.setStyle(colorscheme='blueCarbon')
v.add_pose(pose2)

View different sets of different overlaid poses:

pose = pyrosetta.toolbox.pose_from_rcsb("2FD7")
v = viewer3d.init(pose, delay=0, backend=1)
backrub = pyrosetta.rosetta.protocols.backrub.BackrubMover()
minimize = pyrosetta.rosetta.protocols.minimization_packing.MinMover()
v.set_modules([viewer3d.setStyle(), viewer3d.setDisulfides()])

for h in range(5):
    for i in range(5):
        for j in range(5):
            backrub.apply(pose)
            minimize.apply(pose)
        v.add_pose(pose.clone(), index=h, update_viewer=False)
v.show()

Overlay all poses or PDB strings:

v.overlay()

Color residues by PerResidueRealMetrics:

scorefxn = pyrosetta.create_score_function("ref2015")
minimize = pyrosetta.rosetta.protocols.minimization_packing.MinMover()
e = (
    pyrosetta.rosetta.core.simple_metrics.per_residue_metrics.PerResidueEnergyMetric()
)
e.set_scorefunction(scorefxn)
v = viewer3d.init(backend=backend, gui=True)
palette = list(bokeh.palettes.Greens256) + list(
    reversed(bokeh.palettes.Reds256)
)
v += viewer3d.setStyle(radius=0)
v += viewer3d.setPerResidueRealMetric(
    scoretype="res_energy", vmin=-10, vmax=10, radius=0.2, log=10, palette=palette
)
v += viewer3d.setHydrogens(polar_only=True, color="lightgray")
v += viewer3d.setHydrogenBonds()
v += viewer3d.setDisulfides()
for h in range(10):
    _pose = pose.clone()
    _pose.scores.clear()
    for i in range(20):
        minimize.apply(_pose)
    e.apply(_pose)
    v.add_pose(_pose, index=h, update_viewer=False)
v.show()

Color residues by per-residue total score:

v = viewer3d.presets.perResidueEnergyMetric(pose)
v.show()

Color residues by per-residue clash score:

v = viewer3d.presets.perResidueClashMetric(poses, backend=0)
v.show()

Color residues by per-residue SASA score:

v = viewer3d.presets.perResidueSasaMetric(pose, backend=1)
v.show()

Color residues by per-residue satisfied backbone hydrogen bonds:

v = viewer3d.presets.unsatSelector(pose)
v.show()

Visualize multiple Rosetta analyses:

v = viewer3d.presets.rosettaViewer(poses, backend=1)
v.show()

RosettaCommons / pyrosetta_viewer3d