Feature Extraction
Transformers
Safetensors
esmfold2
biology
protein-structure
multimodal-protein-model
custom_code
Instructions to use Synthyra/ESMFold2-Fast with libraries, inference providers, notebooks, and local apps. Follow these links to get started.
- Libraries
- Transformers
How to use Synthyra/ESMFold2-Fast with Transformers:
# Use a pipeline as a high-level helper from transformers import pipeline pipe = pipeline("feature-extraction", model="Synthyra/ESMFold2-Fast", trust_remote_code=True)# Load model directly from transformers import AutoModel model = AutoModel.from_pretrained("Synthyra/ESMFold2-Fast", trust_remote_code=True, dtype="auto") - Notebooks
- Google Colab
- Kaggle
| # Copyright 2025 EvolutionaryScale | |
| # Copyright 2021 AlQuraishi Laboratory | |
| # Copyright 2021 DeepMind Technologies Limited | |
| # | |
| # Licensed under the Apache License, Version 2.0 (the "License"); | |
| # you may not use this file except in compliance with the License. | |
| # You may obtain a copy of the License at | |
| # | |
| # http://www.apache.org/licenses/LICENSE-2.0 | |
| # | |
| # Unless required by applicable law or agreed to in writing, software | |
| # distributed under the License is distributed on an "AS IS" BASIS, | |
| # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. | |
| # See the License for the specific language governing permissions and | |
| # limitations under the License. | |
| """Constants used in AlphaFold.""" | |
| import collections | |
| import functools | |
| from pathlib import Path | |
| from typing import List, Mapping, Tuple | |
| import numpy as np | |
| # import tree | |
| # Internal import (35fd). | |
| # Distance from one CA to next CA [trans configuration: omega = 180]. | |
| ca_ca = 3.80209737096 | |
| # Format: The list for each AA type contains chi1, chi2, chi3, chi4 in | |
| # this order (or a relevant subset from chi1 onwards). ALA and GLY don't have | |
| # chi angles so their chi angle lists are empty. | |
| chi_angles_atoms = { | |
| "ALA": [], | |
| # Chi5 in arginine is always 0 +- 5 degrees, so ignore it. | |
| "ARG": [ | |
| ["N", "CA", "CB", "CG"], | |
| ["CA", "CB", "CG", "CD"], | |
| ["CB", "CG", "CD", "NE"], | |
| ["CG", "CD", "NE", "CZ"], | |
| ], | |
| "ASN": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "OD1"]], | |
| "ASP": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "OD1"]], | |
| "CYS": [["N", "CA", "CB", "SG"]], | |
| "GLN": [ | |
| ["N", "CA", "CB", "CG"], | |
| ["CA", "CB", "CG", "CD"], | |
| ["CB", "CG", "CD", "OE1"], | |
| ], | |
| "GLU": [ | |
| ["N", "CA", "CB", "CG"], | |
| ["CA", "CB", "CG", "CD"], | |
| ["CB", "CG", "CD", "OE1"], | |
| ], | |
| "GLY": [], | |
| "HIS": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "ND1"]], | |
| "ILE": [["N", "CA", "CB", "CG1"], ["CA", "CB", "CG1", "CD1"]], | |
| "LEU": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "CD1"]], | |
| "LYS": [ | |
| ["N", "CA", "CB", "CG"], | |
| ["CA", "CB", "CG", "CD"], | |
| ["CB", "CG", "CD", "CE"], | |
| ["CG", "CD", "CE", "NZ"], | |
| ], | |
| "MET": [ | |
| ["N", "CA", "CB", "CG"], | |
| ["CA", "CB", "CG", "SD"], | |
| ["CB", "CG", "SD", "CE"], | |
| ], | |
| "PHE": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "CD1"]], | |
| "PRO": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "CD"]], | |
| "SER": [["N", "CA", "CB", "OG"]], | |
| "THR": [["N", "CA", "CB", "OG1"]], | |
| "TRP": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "CD1"]], | |
| "TYR": [["N", "CA", "CB", "CG"], ["CA", "CB", "CG", "CD1"]], | |
| "VAL": [["N", "CA", "CB", "CG1"]], | |
| "UNK": [], | |
| } | |
| # If chi angles given in fixed-length array, this matrix determines how to mask | |
| # them for each AA type. The order is as per restype_order (see below). | |
| chi_angles_mask = [ | |
| [0.0, 0.0, 0.0, 0.0], # ALA | |
| [1.0, 1.0, 1.0, 1.0], # ARG | |
| [1.0, 1.0, 0.0, 0.0], # ASN | |
| [1.0, 1.0, 0.0, 0.0], # ASP | |
| [1.0, 0.0, 0.0, 0.0], # CYS | |
| [1.0, 1.0, 1.0, 0.0], # GLN | |
| [1.0, 1.0, 1.0, 0.0], # GLU | |
| [0.0, 0.0, 0.0, 0.0], # GLY | |
| [1.0, 1.0, 0.0, 0.0], # HIS | |
| [1.0, 1.0, 0.0, 0.0], # ILE | |
| [1.0, 1.0, 0.0, 0.0], # LEU | |
| [1.0, 1.0, 1.0, 1.0], # LYS | |
| [1.0, 1.0, 1.0, 0.0], # MET | |
| [1.0, 1.0, 0.0, 0.0], # PHE | |
| [1.0, 1.0, 0.0, 0.0], # PRO | |
| [1.0, 0.0, 0.0, 0.0], # SER | |
| [1.0, 0.0, 0.0, 0.0], # THR | |
| [1.0, 1.0, 0.0, 0.0], # TRP | |
| [1.0, 1.0, 0.0, 0.0], # TYR | |
| [1.0, 0.0, 0.0, 0.0], # VAL | |
| [0.0, 0.0, 0.0, 0.0], # UNK | |
| ] | |
| # The following chi angles are pi periodic: they can be rotated by a multiple | |
| # of pi without affecting the structure. | |
| chi_pi_periodic = [ | |
| [0.0, 0.0, 0.0, 0.0], # ALA | |
| [0.0, 0.0, 0.0, 0.0], # ARG | |
| [0.0, 0.0, 0.0, 0.0], # ASN | |
| [0.0, 1.0, 0.0, 0.0], # ASP | |
| [0.0, 0.0, 0.0, 0.0], # CYS | |
| [0.0, 0.0, 0.0, 0.0], # GLN | |
| [0.0, 0.0, 1.0, 0.0], # GLU | |
| [0.0, 0.0, 0.0, 0.0], # GLY | |
| [0.0, 0.0, 0.0, 0.0], # HIS | |
| [0.0, 0.0, 0.0, 0.0], # ILE | |
| [0.0, 0.0, 0.0, 0.0], # LEU | |
| [0.0, 0.0, 0.0, 0.0], # LYS | |
| [0.0, 0.0, 0.0, 0.0], # MET | |
| [0.0, 1.0, 0.0, 0.0], # PHE | |
| [0.0, 0.0, 0.0, 0.0], # PRO | |
| [0.0, 0.0, 0.0, 0.0], # SER | |
| [0.0, 0.0, 0.0, 0.0], # THR | |
| [0.0, 0.0, 0.0, 0.0], # TRP | |
| [0.0, 1.0, 0.0, 0.0], # TYR | |
| [0.0, 0.0, 0.0, 0.0], # VAL | |
| [0.0, 0.0, 0.0, 0.0], # UNK | |
| ] | |
| # Atoms positions relative to the 8 rigid groups, defined by the pre-omega, phi, | |
| # psi and chi angles: | |
| # 0: 'backbone group', | |
| # 1: 'pre-omega-group', (empty) | |
| # 2: 'phi-group', (currently empty, because it defines only hydrogens) | |
| # 3: 'psi-group', | |
| # 4,5,6,7: 'chi1,2,3,4-group' | |
| # The atom positions are relative to the axis-end-atom of the corresponding | |
| # rotation axis. The x-axis is in direction of the rotation axis, and the y-axis | |
| # is defined such that the dihedral-angle-definiting atom (the last entry in | |
| # chi_angles_atoms above) is in the xy-plane (with a positive y-coordinate). | |
| # format: [atomname, group_idx, rel_position] | |
| rigid_group_atom_positions = { | |
| "ALA": [ | |
| ["N", 0, (-0.525, 1.363, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, -0.000, -0.000)], | |
| ["CB", 0, (-0.529, -0.774, -1.205)], | |
| ["O", 3, (0.627, 1.062, 0.000)], | |
| ], | |
| "ARG": [ | |
| ["N", 0, (-0.524, 1.362, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, -0.000, -0.000)], | |
| ["CB", 0, (-0.524, -0.778, -1.209)], | |
| ["O", 3, (0.626, 1.062, 0.000)], | |
| ["CG", 4, (0.616, 1.390, -0.000)], | |
| ["CD", 5, (0.564, 1.414, 0.000)], | |
| ["NE", 6, (0.539, 1.357, -0.000)], | |
| ["NH1", 7, (0.206, 2.301, 0.000)], | |
| ["NH2", 7, (2.078, 0.978, -0.000)], | |
| ["CZ", 7, (0.758, 1.093, -0.000)], | |
| ], | |
| "ASN": [ | |
| ["N", 0, (-0.536, 1.357, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, -0.000, -0.000)], | |
| ["CB", 0, (-0.531, -0.787, -1.200)], | |
| ["O", 3, (0.625, 1.062, 0.000)], | |
| ["CG", 4, (0.584, 1.399, 0.000)], | |
| ["ND2", 5, (0.593, -1.188, 0.001)], | |
| ["OD1", 5, (0.633, 1.059, 0.000)], | |
| ], | |
| "ASP": [ | |
| ["N", 0, (-0.525, 1.362, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.527, 0.000, -0.000)], | |
| ["CB", 0, (-0.526, -0.778, -1.208)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ["CG", 4, (0.593, 1.398, -0.000)], | |
| ["OD1", 5, (0.610, 1.091, 0.000)], | |
| ["OD2", 5, (0.592, -1.101, -0.003)], | |
| ], | |
| "CYS": [ | |
| ["N", 0, (-0.522, 1.362, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.524, 0.000, 0.000)], | |
| ["CB", 0, (-0.519, -0.773, -1.212)], | |
| ["O", 3, (0.625, 1.062, -0.000)], | |
| ["SG", 4, (0.728, 1.653, 0.000)], | |
| ], | |
| "GLN": [ | |
| ["N", 0, (-0.526, 1.361, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, 0.000, 0.000)], | |
| ["CB", 0, (-0.525, -0.779, -1.207)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ["CG", 4, (0.615, 1.393, 0.000)], | |
| ["CD", 5, (0.587, 1.399, -0.000)], | |
| ["NE2", 6, (0.593, -1.189, -0.001)], | |
| ["OE1", 6, (0.634, 1.060, 0.000)], | |
| ], | |
| "GLU": [ | |
| ["N", 0, (-0.528, 1.361, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, -0.000, -0.000)], | |
| ["CB", 0, (-0.526, -0.781, -1.207)], | |
| ["O", 3, (0.626, 1.062, 0.000)], | |
| ["CG", 4, (0.615, 1.392, 0.000)], | |
| ["CD", 5, (0.600, 1.397, 0.000)], | |
| ["OE1", 6, (0.607, 1.095, -0.000)], | |
| ["OE2", 6, (0.589, -1.104, -0.001)], | |
| ], | |
| "GLY": [ | |
| ["N", 0, (-0.572, 1.337, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.517, -0.000, -0.000)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ], | |
| "HIS": [ | |
| ["N", 0, (-0.527, 1.360, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, 0.000, 0.000)], | |
| ["CB", 0, (-0.525, -0.778, -1.208)], | |
| ["O", 3, (0.625, 1.063, 0.000)], | |
| ["CG", 4, (0.600, 1.370, -0.000)], | |
| ["CD2", 5, (0.889, -1.021, 0.003)], | |
| ["ND1", 5, (0.744, 1.160, -0.000)], | |
| ["CE1", 5, (2.030, 0.851, 0.002)], | |
| ["NE2", 5, (2.145, -0.466, 0.004)], | |
| ], | |
| "ILE": [ | |
| ["N", 0, (-0.493, 1.373, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.527, -0.000, -0.000)], | |
| ["CB", 0, (-0.536, -0.793, -1.213)], | |
| ["O", 3, (0.627, 1.062, -0.000)], | |
| ["CG1", 4, (0.534, 1.437, -0.000)], | |
| ["CG2", 4, (0.540, -0.785, -1.199)], | |
| ["CD1", 5, (0.619, 1.391, 0.000)], | |
| ], | |
| "LEU": [ | |
| ["N", 0, (-0.520, 1.363, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, -0.000, -0.000)], | |
| ["CB", 0, (-0.522, -0.773, -1.214)], | |
| ["O", 3, (0.625, 1.063, -0.000)], | |
| ["CG", 4, (0.678, 1.371, 0.000)], | |
| ["CD1", 5, (0.530, 1.430, -0.000)], | |
| ["CD2", 5, (0.535, -0.774, 1.200)], | |
| ], | |
| "LYS": [ | |
| ["N", 0, (-0.526, 1.362, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, 0.000, 0.000)], | |
| ["CB", 0, (-0.524, -0.778, -1.208)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ["CG", 4, (0.619, 1.390, 0.000)], | |
| ["CD", 5, (0.559, 1.417, 0.000)], | |
| ["CE", 6, (0.560, 1.416, 0.000)], | |
| ["NZ", 7, (0.554, 1.387, 0.000)], | |
| ], | |
| "MET": [ | |
| ["N", 0, (-0.521, 1.364, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, 0.000, 0.000)], | |
| ["CB", 0, (-0.523, -0.776, -1.210)], | |
| ["O", 3, (0.625, 1.062, -0.000)], | |
| ["CG", 4, (0.613, 1.391, -0.000)], | |
| ["SD", 5, (0.703, 1.695, 0.000)], | |
| ["CE", 6, (0.320, 1.786, -0.000)], | |
| ], | |
| "PHE": [ | |
| ["N", 0, (-0.518, 1.363, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.524, 0.000, -0.000)], | |
| ["CB", 0, (-0.525, -0.776, -1.212)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ["CG", 4, (0.607, 1.377, 0.000)], | |
| ["CD1", 5, (0.709, 1.195, -0.000)], | |
| ["CD2", 5, (0.706, -1.196, 0.000)], | |
| ["CE1", 5, (2.102, 1.198, -0.000)], | |
| ["CE2", 5, (2.098, -1.201, -0.000)], | |
| ["CZ", 5, (2.794, -0.003, -0.001)], | |
| ], | |
| "PRO": [ | |
| ["N", 0, (-0.566, 1.351, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.527, -0.000, 0.000)], | |
| ["CB", 0, (-0.546, -0.611, -1.293)], | |
| ["O", 3, (0.621, 1.066, 0.000)], | |
| ["CG", 4, (0.382, 1.445, 0.0)], | |
| # ['CD', 5, (0.427, 1.440, 0.0)], | |
| ["CD", 5, (0.477, 1.424, 0.0)], # manually made angle 2 degrees larger | |
| ], | |
| "SER": [ | |
| ["N", 0, (-0.529, 1.360, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, -0.000, -0.000)], | |
| ["CB", 0, (-0.518, -0.777, -1.211)], | |
| ["O", 3, (0.626, 1.062, -0.000)], | |
| ["OG", 4, (0.503, 1.325, 0.000)], | |
| ], | |
| "THR": [ | |
| ["N", 0, (-0.517, 1.364, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, 0.000, -0.000)], | |
| ["CB", 0, (-0.516, -0.793, -1.215)], | |
| ["O", 3, (0.626, 1.062, 0.000)], | |
| ["CG2", 4, (0.550, -0.718, -1.228)], | |
| ["OG1", 4, (0.472, 1.353, 0.000)], | |
| ], | |
| "TRP": [ | |
| ["N", 0, (-0.521, 1.363, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.525, -0.000, 0.000)], | |
| ["CB", 0, (-0.523, -0.776, -1.212)], | |
| ["O", 3, (0.627, 1.062, 0.000)], | |
| ["CG", 4, (0.609, 1.370, -0.000)], | |
| ["CD1", 5, (0.824, 1.091, 0.000)], | |
| ["CD2", 5, (0.854, -1.148, -0.005)], | |
| ["CE2", 5, (2.186, -0.678, -0.007)], | |
| ["CE3", 5, (0.622, -2.530, -0.007)], | |
| ["NE1", 5, (2.140, 0.690, -0.004)], | |
| ["CH2", 5, (3.028, -2.890, -0.013)], | |
| ["CZ2", 5, (3.283, -1.543, -0.011)], | |
| ["CZ3", 5, (1.715, -3.389, -0.011)], | |
| ], | |
| "TYR": [ | |
| ["N", 0, (-0.522, 1.362, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.524, -0.000, -0.000)], | |
| ["CB", 0, (-0.522, -0.776, -1.213)], | |
| ["O", 3, (0.627, 1.062, -0.000)], | |
| ["CG", 4, (0.607, 1.382, -0.000)], | |
| ["CD1", 5, (0.716, 1.195, -0.000)], | |
| ["CD2", 5, (0.713, -1.194, -0.001)], | |
| ["CE1", 5, (2.107, 1.200, -0.002)], | |
| ["CE2", 5, (2.104, -1.201, -0.003)], | |
| ["OH", 5, (4.168, -0.002, -0.005)], | |
| ["CZ", 5, (2.791, -0.001, -0.003)], | |
| ], | |
| "VAL": [ | |
| ["N", 0, (-0.494, 1.373, -0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.527, -0.000, -0.000)], | |
| ["CB", 0, (-0.533, -0.795, -1.213)], | |
| ["O", 3, (0.627, 1.062, -0.000)], | |
| ["CG1", 4, (0.540, 1.429, -0.000)], | |
| ["CG2", 4, (0.533, -0.776, 1.203)], | |
| ], | |
| # Assume alanine positions for unknown AA | |
| "UNK": [ | |
| ["N", 0, (-0.525, 1.363, 0.000)], | |
| ["CA", 0, (0.000, 0.000, 0.000)], | |
| ["C", 0, (1.526, -0.000, -0.000)], | |
| ], | |
| } | |
| # A list of atoms (excluding hydrogen) for each AA type. PDB naming convention. | |
| residue_atoms = { | |
| "ALA": ["C", "CA", "CB", "N", "O"], | |
| "ARG": ["C", "CA", "CB", "CG", "CD", "CZ", "N", "NE", "O", "NH1", "NH2"], | |
| "ASP": ["C", "CA", "CB", "CG", "N", "O", "OD1", "OD2"], | |
| "ASN": ["C", "CA", "CB", "CG", "N", "ND2", "O", "OD1"], | |
| "CYS": ["C", "CA", "CB", "N", "O", "SG"], | |
| "GLU": ["C", "CA", "CB", "CG", "CD", "N", "O", "OE1", "OE2"], | |
| "GLN": ["C", "CA", "CB", "CG", "CD", "N", "NE2", "O", "OE1"], | |
| "GLY": ["C", "CA", "N", "O"], | |
| "HIS": ["C", "CA", "CB", "CG", "CD2", "CE1", "N", "ND1", "NE2", "O"], | |
| "ILE": ["C", "CA", "CB", "CG1", "CG2", "CD1", "N", "O"], | |
| "LEU": ["C", "CA", "CB", "CG", "CD1", "CD2", "N", "O"], | |
| "LYS": ["C", "CA", "CB", "CG", "CD", "CE", "N", "NZ", "O"], | |
| "MET": ["C", "CA", "CB", "CG", "CE", "N", "O", "SD"], | |
| "PHE": ["C", "CA", "CB", "CG", "CD1", "CD2", "CE1", "CE2", "CZ", "N", "O"], | |
| "PRO": ["C", "CA", "CB", "CG", "CD", "N", "O"], | |
| "SER": ["C", "CA", "CB", "N", "O", "OG"], | |
| "THR": ["C", "CA", "CB", "CG2", "N", "O", "OG1"], | |
| "TRP": [ | |
| "C", | |
| "CA", | |
| "CB", | |
| "CG", | |
| "CD1", | |
| "CD2", | |
| "CE2", | |
| "CE3", | |
| "CZ2", | |
| "CZ3", | |
| "CH2", | |
| "N", | |
| "NE1", | |
| "O", | |
| ], | |
| "TYR": ["C", "CA", "CB", "CG", "CD1", "CD2", "CE1", "CE2", "CZ", "N", "O", "OH"], | |
| "VAL": ["C", "CA", "CB", "CG1", "CG2", "N", "O"], | |
| "UNK": ["C", "CA", "N"], | |
| } | |
| # Naming swaps for ambiguous atom names. | |
| # Due to symmetries in the amino acids the naming of atoms is ambiguous in | |
| # 4 of the 20 amino acids. | |
| # (The LDDT paper lists 7 amino acids as ambiguous, but the naming ambiguities | |
| # in LEU, VAL and ARG can be resolved by using the 3d constellations of | |
| # the 'ambiguous' atoms and their neighbours) | |
| # TODO: ^ interpret this | |
| residue_atom_renaming_swaps = { | |
| "ASP": {"OD1": "OD2"}, | |
| "GLU": {"OE1": "OE2"}, | |
| "PHE": {"CD1": "CD2", "CE1": "CE2"}, | |
| "TYR": {"CD1": "CD2", "CE1": "CE2"}, | |
| } | |
| # Van der Waals radii [Angstroem] of the atoms (from Wikipedia) | |
| van_der_waals_radius = {"C": 1.7, "N": 1.55, "O": 1.52, "S": 1.8} | |
| Bond = collections.namedtuple("Bond", ["atom1_name", "atom2_name", "length", "stddev"]) | |
| BondAngle = collections.namedtuple( | |
| "BondAngle", ["atom1_name", "atom2_name", "atom3name", "angle_rad", "stddev"] | |
| ) | |
| def load_stereo_chemical_props() -> ( | |
| Tuple[ | |
| Mapping[str, List[Bond]], | |
| Mapping[str, List[Bond]], | |
| Mapping[str, List[BondAngle]], | |
| ] | |
| ): | |
| """Load stereo_chemical_props.txt into a nice structure. | |
| Load literature values for bond lengths and bond angles and translate | |
| bond angles into the length of the opposite edge of the triangle | |
| ("residue_virtual_bonds"). | |
| Returns: | |
| residue_bonds: dict that maps resname --> list of Bond tuples | |
| residue_virtual_bonds: dict that maps resname --> list of Bond tuples | |
| residue_bond_angles: dict that maps resname --> list of BondAngle tuples | |
| """ | |
| stereo_chemical_props = Path( | |
| "evolutionaryscale/structure/stereo_chemical_props.txt" | |
| ).read_text() | |
| lines_iter = iter(stereo_chemical_props.splitlines()) | |
| # Load bond lengths. | |
| residue_bonds = {} | |
| next(lines_iter) # Skip header line. | |
| for line in lines_iter: | |
| if line.strip() == "-": | |
| break | |
| bond, resname, length, stddev = line.split() | |
| atom1, atom2 = bond.split("-") | |
| if resname not in residue_bonds: | |
| residue_bonds[resname] = [] | |
| residue_bonds[resname].append(Bond(atom1, atom2, float(length), float(stddev))) | |
| residue_bonds["UNK"] = [] | |
| # Load bond angles. | |
| residue_bond_angles = {} | |
| next(lines_iter) # Skip empty line. | |
| next(lines_iter) # Skip header line. | |
| for line in lines_iter: | |
| if line.strip() == "-": | |
| break | |
| bond, resname, angle_degree, stddev_degree = line.split() | |
| atom1, atom2, atom3 = bond.split("-") | |
| if resname not in residue_bond_angles: | |
| residue_bond_angles[resname] = [] | |
| residue_bond_angles[resname].append( | |
| BondAngle( | |
| atom1, | |
| atom2, | |
| atom3, | |
| float(angle_degree) / 180.0 * np.pi, | |
| float(stddev_degree) / 180.0 * np.pi, | |
| ) | |
| ) | |
| residue_bond_angles["UNK"] = [] | |
| def make_bond_key(atom1_name, atom2_name): | |
| """Unique key to lookup bonds.""" | |
| return "-".join(sorted([atom1_name, atom2_name])) | |
| # Translate bond angles into distances ("virtual bonds"). | |
| residue_virtual_bonds = {} | |
| for resname, bond_angles in residue_bond_angles.items(): | |
| # Create a fast lookup dict for bond lengths. | |
| bond_cache = {} | |
| for b in residue_bonds[resname]: | |
| bond_cache[make_bond_key(b.atom1_name, b.atom2_name)] = b | |
| residue_virtual_bonds[resname] = [] | |
| for ba in bond_angles: | |
| bond1 = bond_cache[make_bond_key(ba.atom1_name, ba.atom2_name)] | |
| bond2 = bond_cache[make_bond_key(ba.atom2_name, ba.atom3name)] | |
| # Compute distance between atom1 and atom3 using the law of cosines | |
| # c^2 = a^2 + b^2 - 2ab*cos(gamma). | |
| gamma = ba.angle_rad | |
| length = np.sqrt( | |
| bond1.length**2 | |
| + bond2.length**2 | |
| - 2 * bond1.length * bond2.length * np.cos(gamma) | |
| ) | |
| # Propagation of uncertainty assuming uncorrelated errors. | |
| dl_outer = 0.5 / length | |
| dl_dgamma = (2 * bond1.length * bond2.length * np.sin(gamma)) * dl_outer | |
| dl_db1 = (2 * bond1.length - 2 * bond2.length * np.cos(gamma)) * dl_outer | |
| dl_db2 = (2 * bond2.length - 2 * bond1.length * np.cos(gamma)) * dl_outer | |
| stddev = np.sqrt( | |
| (dl_dgamma * ba.stddev) ** 2 | |
| + (dl_db1 * bond1.stddev) ** 2 | |
| + (dl_db2 * bond2.stddev) ** 2 | |
| ) | |
| residue_virtual_bonds[resname].append( | |
| Bond(ba.atom1_name, ba.atom3name, length, stddev) | |
| ) | |
| return (residue_bonds, residue_virtual_bonds, residue_bond_angles) | |
| # Between-residue bond lengths for general bonds (first element) and for Proline | |
| # (second element). | |
| between_res_bond_length_c_n = [1.329, 1.341] | |
| between_res_bond_length_stddev_c_n = [0.014, 0.016] | |
| # Between-residue cos_angles. | |
| between_res_cos_angles_c_n_ca = [-0.5203, 0.0353] # degrees: 121.352 +- 2.315 | |
| between_res_cos_angles_ca_c_n = [-0.4473, 0.0311] # degrees: 116.568 +- 1.995 | |
| # This mapping is used when we need to store atom data in a format that requires | |
| # fixed atom data size for every residue (e.g. a numpy array). | |
| atom_types = [ | |
| "N", | |
| "CA", | |
| "C", | |
| "CB", | |
| "O", | |
| "CG", | |
| "CG1", | |
| "CG2", | |
| "OG", | |
| "OG1", | |
| "SG", | |
| "CD", | |
| "CD1", | |
| "CD2", | |
| "ND1", | |
| "ND2", | |
| "OD1", | |
| "OD2", | |
| "SD", | |
| "CE", | |
| "CE1", | |
| "CE2", | |
| "CE3", | |
| "NE", | |
| "NE1", | |
| "NE2", | |
| "OE1", | |
| "OE2", | |
| "CH2", | |
| "NH1", | |
| "NH2", | |
| "OH", | |
| "CZ", | |
| "CZ2", | |
| "CZ3", | |
| "NZ", | |
| "OXT", | |
| ] | |
| atom_order = {atom_type: i for i, atom_type in enumerate(atom_types)} | |
| atom_type_num = len(atom_types) # := 37. | |
| # A compact atom encoding with 14 columns | |
| # pylint: disable=line-too-long | |
| # pylint: disable=bad-whitespace | |
| restype_name_to_atom14_names = { | |
| "ALA": ["N", "CA", "C", "O", "CB", "", "", "", "", "", "", "", "", ""], | |
| "ARG": [ | |
| "N", | |
| "CA", | |
| "C", | |
| "O", | |
| "CB", | |
| "CG", | |
| "CD", | |
| "NE", | |
| "CZ", | |
| "NH1", | |
| "NH2", | |
| "", | |
| "", | |
| "", | |
| ], | |
| "ASN": ["N", "CA", "C", "O", "CB", "CG", "OD1", "ND2", "", "", "", "", "", ""], | |
| "ASP": ["N", "CA", "C", "O", "CB", "CG", "OD1", "OD2", "", "", "", "", "", ""], | |
| "CYS": ["N", "CA", "C", "O", "CB", "SG", "", "", "", "", "", "", "", ""], | |
| "GLN": ["N", "CA", "C", "O", "CB", "CG", "CD", "OE1", "NE2", "", "", "", "", ""], | |
| "GLU": ["N", "CA", "C", "O", "CB", "CG", "CD", "OE1", "OE2", "", "", "", "", ""], | |
| "GLY": ["N", "CA", "C", "O", "", "", "", "", "", "", "", "", "", ""], | |
| "HIS": [ | |
| "N", | |
| "CA", | |
| "C", | |
| "O", | |
| "CB", | |
| "CG", | |
| "ND1", | |
| "CD2", | |
| "CE1", | |
| "NE2", | |
| "", | |
| "", | |
| "", | |
| "", | |
| ], | |
| "ILE": ["N", "CA", "C", "O", "CB", "CG1", "CG2", "CD1", "", "", "", "", "", ""], | |
| "LEU": ["N", "CA", "C", "O", "CB", "CG", "CD1", "CD2", "", "", "", "", "", ""], | |
| "LYS": ["N", "CA", "C", "O", "CB", "CG", "CD", "CE", "NZ", "", "", "", "", ""], | |
| "MET": ["N", "CA", "C", "O", "CB", "CG", "SD", "CE", "", "", "", "", "", ""], | |
| "PHE": [ | |
| "N", | |
| "CA", | |
| "C", | |
| "O", | |
| "CB", | |
| "CG", | |
| "CD1", | |
| "CD2", | |
| "CE1", | |
| "CE2", | |
| "CZ", | |
| "", | |
| "", | |
| "", | |
| ], | |
| "PRO": ["N", "CA", "C", "O", "CB", "CG", "CD", "", "", "", "", "", "", ""], | |
| "SER": ["N", "CA", "C", "O", "CB", "OG", "", "", "", "", "", "", "", ""], | |
| "THR": ["N", "CA", "C", "O", "CB", "OG1", "CG2", "", "", "", "", "", "", ""], | |
| "TRP": [ | |
| "N", | |
| "CA", | |
| "C", | |
| "O", | |
| "CB", | |
| "CG", | |
| "CD1", | |
| "CD2", | |
| "NE1", | |
| "CE2", | |
| "CE3", | |
| "CZ2", | |
| "CZ3", | |
| "CH2", | |
| ], | |
| "TYR": [ | |
| "N", | |
| "CA", | |
| "C", | |
| "O", | |
| "CB", | |
| "CG", | |
| "CD1", | |
| "CD2", | |
| "CE1", | |
| "CE2", | |
| "CZ", | |
| "OH", | |
| "", | |
| "", | |
| ], | |
| "VAL": ["N", "CA", "C", "O", "CB", "CG1", "CG2", "", "", "", "", "", "", ""], | |
| "UNK": ["N", "CA", "C", "", "", "", "", "", "", "", "", "", "", ""], | |
| } | |
| # pylint: enable=line-too-long | |
| # pylint: enable=bad-whitespace | |
| # This is the standard residue order when coding AA type as a number. | |
| # Reproduce it by taking 3-letter AA codes and sorting them alphabetically. | |
| restypes = [ | |
| "A", | |
| "R", | |
| "N", | |
| "D", | |
| "C", | |
| "Q", | |
| "E", | |
| "G", | |
| "H", | |
| "I", | |
| "L", | |
| "K", | |
| "M", | |
| "F", | |
| "P", | |
| "S", | |
| "T", | |
| "W", | |
| "Y", | |
| "V", | |
| ] | |
| restype_order = {restype: i for i, restype in enumerate(restypes)} | |
| restype_num = len(restypes) # := 20. | |
| unk_restype_index = restype_num # Catch-all index for unknown restypes. | |
| restypes_with_x = restypes + ["X"] | |
| restype_order_with_x = {restype: i for i, restype in enumerate(restypes_with_x)} | |
| bb_atoms = ["N", "CA", "C", "O"] | |
| # Hydrophobicity by residue (positive values are hydrophobic). Derived from Black & Mould (1991), normalized by subtracting 0.5. | |
| hydrophobicity = { | |
| "ALA": 0.116, | |
| "ARG": -0.5, | |
| "ASN": -0.264, | |
| "ASP": -0.472, | |
| "CYS": 0.18, | |
| "GLN": -0.249, | |
| "GLU": -0.457, | |
| "GLY": 0.001, | |
| "HIS": -0.335, | |
| "ILE": 0.443, | |
| "LEU": 0.443, | |
| "LYS": -0.217, | |
| "MET": 0.238, | |
| "PHE": 0.5, | |
| "PRO": 0.211, | |
| "SER": -0.141, | |
| "THR": -0.05, | |
| "TRP": 0.378, | |
| "TYR": 0.38, | |
| "VAL": 0.325, | |
| } | |
| # Side chain max accessible surface area in Ala-X-Ala tripeptide (from Chennamsetty et al. 2010). | |
| side_chain_asa = { | |
| "ALA": 64.7809, | |
| "ARG": 210.02, | |
| "ASN": 113.187, | |
| "ASP": 110.209, | |
| "CYS": 95.2439, | |
| "GLN": 147.855, | |
| "GLU": 143.924, | |
| "GLY": 23.1338, | |
| "HIS": 146.449, | |
| "ILE": 151.242, | |
| "LEU": 139.524, | |
| "LYS": 177.366, | |
| "MET": 164.674, | |
| "PHE": 186.7, | |
| "PRO": 111.533, | |
| "SER": 81.2159, | |
| "THR": 111.597, | |
| "TRP": 229.619, | |
| "TYR": 200.306, | |
| "VAL": 124.237, | |
| } | |
| # Approximate Volumes of amino acids in cubic angstroms. | |
| # https://www.imgt.org/IMGTeducation/Aide-memoire/_UK/aminoacids/abbreviation.html | |
| amino_acid_volumes = { | |
| "A": 88.6, # Alanine | |
| "R": 173.4, # Arginine | |
| "N": 114.1, # Asparagine | |
| "D": 111.1, # Aspartic acid | |
| "C": 108.5, # Cysteine | |
| "Q": 143.8, # Glutamine | |
| "E": 138.4, # Glutamic acid | |
| "G": 60.1, # Glycine | |
| "H": 153.2, # Histidine | |
| "I": 166.7, # Isoleucine | |
| "L": 166.7, # Leucine | |
| "K": 168.6, # Lysine | |
| "M": 162.9, # Methionine | |
| "F": 189.9, # Phenylalanine | |
| "P": 112.7, # Proline | |
| "S": 89.0, # Serine | |
| "T": 116.1, # Threonine | |
| "W": 227.8, # Tryptophan | |
| "Y": 193.6, # Tyrosine | |
| "V": 140.0, # Valine | |
| "X": 88.6, # Unknown, use Alanine as approximation | |
| } | |
| def sequence_to_onehot( | |
| sequence: str, mapping: Mapping[str, int], map_unknown_to_x: bool = False | |
| ) -> np.ndarray: | |
| """Maps the given sequence into a one-hot encoded matrix. | |
| Args: | |
| sequence: An amino acid sequence. | |
| mapping: A dictionary mapping amino acids to integers. | |
| map_unknown_to_x: If True, any amino acid that is not in the mapping will be | |
| mapped to the unknown amino acid 'X'. If the mapping doesn't contain | |
| amino acid 'X', an error will be thrown. If False, any amino acid not in | |
| the mapping will throw an error. | |
| Returns: | |
| A numpy array of shape (seq_len, num_unique_aas) with one-hot encoding of | |
| the sequence. | |
| Raises: | |
| ValueError: If the mapping doesn't contain values from 0 to | |
| num_unique_aas - 1 without any gaps. | |
| """ | |
| num_entries = max(mapping.values()) + 1 | |
| if sorted(set(mapping.values())) != list(range(num_entries)): | |
| raise ValueError( | |
| "The mapping must have values from 0 to num_unique_aas-1 " | |
| "without any gaps. Got: %s" % sorted(mapping.values()) | |
| ) | |
| one_hot_arr = np.zeros((len(sequence), num_entries), dtype=np.int32) | |
| for aa_index, aa_type in enumerate(sequence): | |
| if map_unknown_to_x: | |
| if aa_type.isalpha() and aa_type.isupper(): | |
| aa_id = mapping.get(aa_type, mapping["X"]) | |
| else: | |
| raise ValueError(f"Invalid character in the sequence: {aa_type}") | |
| else: | |
| aa_id = mapping[aa_type] | |
| one_hot_arr[aa_index, aa_id] = 1 | |
| return one_hot_arr | |
| restype_1to3 = { | |
| "A": "ALA", | |
| "R": "ARG", | |
| "N": "ASN", | |
| "D": "ASP", | |
| "C": "CYS", | |
| "Q": "GLN", | |
| "E": "GLU", | |
| "G": "GLY", | |
| "H": "HIS", | |
| "I": "ILE", | |
| "L": "LEU", | |
| "K": "LYS", | |
| "M": "MET", | |
| "F": "PHE", | |
| "P": "PRO", | |
| "S": "SER", | |
| "T": "THR", | |
| "W": "TRP", | |
| "Y": "TYR", | |
| "V": "VAL", | |
| "X": "UNK", | |
| } | |
| # NB: restype_3to1 differs from Bio.PDB.protein_letters_3to1 by being a simple | |
| # 1-to-1 mapping of 3 letter names to one letter names. The latter contains | |
| # many more, and less common, three letter names as keys and maps many of these | |
| # to the same one letter name (including 'X' and 'U' which we don't use here). | |
| restype_3to1 = {v: k for k, v in restype_1to3.items()} | |
| # Define a restype name for all unknown residues. | |
| unk_restype = "UNK" | |
| resnames = [restype_1to3[r] for r in restypes] + [unk_restype] | |
| resname_to_idx = {resname: i for i, resname in enumerate(resnames)} | |
| hydrophobic_resnames = {"VAL", "ILE", "LEU", "PHE", "MET", "TRP"} | |
| # The mapping here uses hhblits convention, so that B is mapped to D, J and O | |
| # are mapped to X, U is mapped to C, and Z is mapped to E. Other than that the | |
| # remaining 20 amino acids are kept in alphabetical order. | |
| # There are 2 non-amino acid codes, X (representing any amino acid) and | |
| # "-" representing a missing amino acid in an alignment. The id for these | |
| # codes is put at the end (20 and 21) so that they can easily be ignored if | |
| # desired. | |
| HHBLITS_AA_TO_ID = { | |
| "A": 0, | |
| "B": 2, | |
| "C": 1, | |
| "D": 2, | |
| "E": 3, | |
| "F": 4, | |
| "G": 5, | |
| "H": 6, | |
| "I": 7, | |
| "J": 20, | |
| "K": 8, | |
| "L": 9, | |
| "M": 10, | |
| "N": 11, | |
| "O": 20, | |
| "P": 12, | |
| "Q": 13, | |
| "R": 14, | |
| "S": 15, | |
| "T": 16, | |
| "U": 1, | |
| "V": 17, | |
| "W": 18, | |
| "X": 20, | |
| "Y": 19, | |
| "Z": 3, | |
| "-": 21, | |
| } | |
| # Partial inversion of HHBLITS_AA_TO_ID. | |
| ID_TO_HHBLITS_AA = { | |
| 0: "A", | |
| 1: "C", # Also U. | |
| 2: "D", # Also B. | |
| 3: "E", # Also Z. | |
| 4: "F", | |
| 5: "G", | |
| 6: "H", | |
| 7: "I", | |
| 8: "K", | |
| 9: "L", | |
| 10: "M", | |
| 11: "N", | |
| 12: "P", | |
| 13: "Q", | |
| 14: "R", | |
| 15: "S", | |
| 16: "T", | |
| 17: "V", | |
| 18: "W", | |
| 19: "Y", | |
| 20: "X", # Includes J and O. | |
| 21: "-", | |
| } | |
| restypes_with_x_and_gap = restypes + ["X", "-"] | |
| MAP_HHBLITS_AATYPE_TO_OUR_AATYPE = tuple( | |
| restypes_with_x_and_gap.index(ID_TO_HHBLITS_AA[i]) | |
| for i in range(len(restypes_with_x_and_gap)) | |
| ) | |
| def _make_standard_atom_mask() -> np.ndarray: | |
| """Returns [num_res_types, num_atom_types] mask array.""" | |
| # +1 to account for unknown (all 0s). | |
| mask = np.zeros([restype_num + 1, atom_type_num], dtype=np.int32) | |
| for restype, restype_letter in enumerate(restypes): | |
| restype_name = restype_1to3[restype_letter] | |
| atom_names = residue_atoms[restype_name] | |
| for atom_name in atom_names: | |
| atom_type = atom_order[atom_name] | |
| mask[restype, atom_type] = 1 | |
| return mask | |
| STANDARD_ATOM_MASK = _make_standard_atom_mask() | |
| # A one hot representation for the first and second atoms defining the axis | |
| # of rotation for each chi-angle in each residue. | |
| def chi_angle_atom(atom_index: int) -> np.ndarray: | |
| """Define chi-angle rigid groups via one-hot representations.""" | |
| chi_angles_index = {} | |
| one_hots = [] | |
| for k, v in chi_angles_atoms.items(): | |
| indices = [atom_types.index(s[atom_index]) for s in v] | |
| indices.extend([-1] * (4 - len(indices))) | |
| chi_angles_index[k] = indices | |
| for r in restypes: | |
| res3 = restype_1to3[r] | |
| one_hot = np.eye(atom_type_num)[chi_angles_index[res3]] | |
| one_hots.append(one_hot) | |
| one_hots.append(np.zeros([4, atom_type_num])) # Add zeros for residue `X`. | |
| one_hot = np.stack(one_hots, axis=0) | |
| one_hot = np.transpose(one_hot, [0, 2, 1]) | |
| return one_hot | |
| chi_atom_1_one_hot = chi_angle_atom(1) | |
| chi_atom_2_one_hot = chi_angle_atom(2) | |
| # An array like chi_angles_atoms but using indices rather than names. | |
| chi_angles_atom_indices = [chi_angles_atoms[restype_1to3[r]] for r in restypes] | |
| # chi_angles_atom_indices = tree.map_structure( | |
| # lambda atom_name: atom_order[atom_name], chi_angles_atom_indices | |
| # ) | |
| chi_angles_atom_indices = np.array( | |
| [ | |
| chi_atoms + ([[0, 0, 0, 0]] * (4 - len(chi_atoms))) | |
| for chi_atoms in chi_angles_atom_indices | |
| ] | |
| ) | |
| # Mapping from (res_name, atom_name) pairs to the atom's chi group index | |
| # and atom index within that group. | |
| chi_groups_for_atom = collections.defaultdict(list) | |
| for res_name, chi_angle_atoms_for_res in chi_angles_atoms.items(): | |
| for chi_group_i, chi_group in enumerate(chi_angle_atoms_for_res): | |
| for atom_i, atom in enumerate(chi_group): | |
| chi_groups_for_atom[(res_name, atom)].append((chi_group_i, atom_i)) | |
| chi_groups_for_atom = dict(chi_groups_for_atom) | |
| def _make_rigid_transformation_4x4(ex, ey, translation): | |
| """Create a rigid 4x4 transformation matrix from two axes and transl.""" | |
| # Normalize ex. | |
| ex_normalized = ex / np.linalg.norm(ex) | |
| # make ey perpendicular to ex | |
| ey_normalized = ey - np.dot(ey, ex_normalized) * ex_normalized | |
| ey_normalized /= np.linalg.norm(ey_normalized) | |
| # compute ez as cross product | |
| eznorm = np.cross(ex_normalized, ey_normalized) | |
| m = np.stack([ex_normalized, ey_normalized, eznorm, translation]).transpose() | |
| m = np.concatenate([m, [[0.0, 0.0, 0.0, 1.0]]], axis=0) | |
| return m | |
| # create an array with (restype, atomtype) --> rigid_group_idx | |
| # and an array with (restype, atomtype, coord) for the atom positions | |
| # and compute affine transformation matrices (4,4) from one rigid group to the | |
| # previous group | |
| restype_atom37_to_rigid_group = np.zeros([21, 37], dtype=int) | |
| restype_atom37_mask = np.zeros([21, 37], dtype=np.float32) | |
| restype_atom37_rigid_group_positions = np.zeros([21, 37, 3], dtype=np.float32) | |
| restype_atom14_to_rigid_group = np.zeros([21, 14], dtype=int) | |
| restype_atom14_mask = np.zeros([21, 14], dtype=np.float32) | |
| restype_atom14_rigid_group_positions = np.zeros([21, 14, 3], dtype=np.float32) | |
| restype_rigid_group_default_frame = np.zeros([21, 8, 4, 4], dtype=np.float32) | |
| def _make_rigid_group_constants(): | |
| """Fill the arrays above.""" | |
| for restype, restype_letter in enumerate(restypes_with_x): | |
| resname = restype_1to3[restype_letter] | |
| for atomname, group_idx, atom_position in rigid_group_atom_positions[resname]: | |
| atomtype = atom_order[atomname] | |
| restype_atom37_to_rigid_group[restype, atomtype] = group_idx | |
| restype_atom37_mask[restype, atomtype] = 1 | |
| restype_atom37_rigid_group_positions[restype, atomtype, :] = atom_position | |
| atom14idx = restype_name_to_atom14_names[resname].index(atomname) | |
| restype_atom14_to_rigid_group[restype, atom14idx] = group_idx | |
| restype_atom14_mask[restype, atom14idx] = 1 | |
| restype_atom14_rigid_group_positions[restype, atom14idx, :] = atom_position | |
| for restype, restype_letter in enumerate(restypes_with_x): | |
| resname = restype_1to3[restype_letter] | |
| atom_positions = { | |
| name: np.array(pos) for name, _, pos in rigid_group_atom_positions[resname] | |
| } | |
| # backbone to backbone is the identity transform | |
| restype_rigid_group_default_frame[restype, 0, :, :] = np.eye(4) | |
| # pre-omega-frame to backbone (currently dummy identity matrix) | |
| restype_rigid_group_default_frame[restype, 1, :, :] = np.eye(4) | |
| # phi-frame to backbone | |
| mat = _make_rigid_transformation_4x4( | |
| ex=atom_positions["N"] - atom_positions["CA"], | |
| ey=np.array([1.0, 0.0, 0.0]), | |
| translation=atom_positions["N"], | |
| ) | |
| restype_rigid_group_default_frame[restype, 2, :, :] = mat | |
| # psi-frame to backbone | |
| mat = _make_rigid_transformation_4x4( | |
| ex=atom_positions["C"] - atom_positions["CA"], | |
| ey=atom_positions["CA"] - atom_positions["N"], | |
| translation=atom_positions["C"], | |
| ) | |
| restype_rigid_group_default_frame[restype, 3, :, :] = mat | |
| # chi1-frame to backbone | |
| if chi_angles_mask[restype][0]: | |
| base_atom_names = chi_angles_atoms[resname][0] | |
| base_atom_positions = [atom_positions[name] for name in base_atom_names] | |
| mat = _make_rigid_transformation_4x4( | |
| ex=base_atom_positions[2] - base_atom_positions[1], | |
| ey=base_atom_positions[0] - base_atom_positions[1], | |
| translation=base_atom_positions[2], | |
| ) | |
| restype_rigid_group_default_frame[restype, 4, :, :] = mat | |
| # chi2-frame to chi1-frame | |
| # chi3-frame to chi2-frame | |
| # chi4-frame to chi3-frame | |
| # luckily all rotation axes for the next frame start at (0,0,0) of the | |
| # previous frame | |
| for chi_idx in range(1, 4): | |
| if chi_angles_mask[restype][chi_idx]: | |
| axis_end_atom_name = chi_angles_atoms[resname][chi_idx][2] | |
| axis_end_atom_position = atom_positions[axis_end_atom_name] | |
| mat = _make_rigid_transformation_4x4( | |
| ex=axis_end_atom_position, | |
| ey=np.array([-1.0, 0.0, 0.0]), | |
| translation=axis_end_atom_position, | |
| ) | |
| restype_rigid_group_default_frame[restype, 4 + chi_idx, :, :] = mat | |
| _make_rigid_group_constants() | |
| def make_atom14_dists_bounds(overlap_tolerance=1.5, bond_length_tolerance_factor=15.0): | |
| """compute upper and lower bounds for bonds to assess violations.""" | |
| restype_atom14_bond_lower_bound = np.zeros([21, 14, 14], np.float32) | |
| restype_atom14_bond_upper_bound = np.zeros([21, 14, 14], np.float32) | |
| restype_atom14_bond_stddev = np.zeros([21, 14, 14], np.float32) | |
| residue_bonds, residue_virtual_bonds, _ = load_stereo_chemical_props() | |
| for restype, restype_letter in enumerate(restypes): | |
| resname = restype_1to3[restype_letter] | |
| atom_list = restype_name_to_atom14_names[resname] | |
| # create lower and upper bounds for clashes | |
| for atom1_idx, atom1_name in enumerate(atom_list): | |
| if not atom1_name: | |
| continue | |
| atom1_radius = van_der_waals_radius[atom1_name[0]] | |
| for atom2_idx, atom2_name in enumerate(atom_list): | |
| if (not atom2_name) or atom1_idx == atom2_idx: | |
| continue | |
| atom2_radius = van_der_waals_radius[atom2_name[0]] | |
| lower = atom1_radius + atom2_radius - overlap_tolerance | |
| upper = 1e10 | |
| restype_atom14_bond_lower_bound[restype, atom1_idx, atom2_idx] = lower | |
| restype_atom14_bond_lower_bound[restype, atom2_idx, atom1_idx] = lower | |
| restype_atom14_bond_upper_bound[restype, atom1_idx, atom2_idx] = upper | |
| restype_atom14_bond_upper_bound[restype, atom2_idx, atom1_idx] = upper | |
| # overwrite lower and upper bounds for bonds and angles | |
| for b in residue_bonds[resname] + residue_virtual_bonds[resname]: | |
| atom1_idx = atom_list.index(b.atom1_name) | |
| atom2_idx = atom_list.index(b.atom2_name) | |
| lower = b.length - bond_length_tolerance_factor * b.stddev | |
| upper = b.length + bond_length_tolerance_factor * b.stddev | |
| restype_atom14_bond_lower_bound[restype, atom1_idx, atom2_idx] = lower | |
| restype_atom14_bond_lower_bound[restype, atom2_idx, atom1_idx] = lower | |
| restype_atom14_bond_upper_bound[restype, atom1_idx, atom2_idx] = upper | |
| restype_atom14_bond_upper_bound[restype, atom2_idx, atom1_idx] = upper | |
| restype_atom14_bond_stddev[restype, atom1_idx, atom2_idx] = b.stddev | |
| restype_atom14_bond_stddev[restype, atom2_idx, atom1_idx] = b.stddev | |
| return { | |
| "lower_bound": restype_atom14_bond_lower_bound, # shape (21,14,14) | |
| "upper_bound": restype_atom14_bond_upper_bound, # shape (21,14,14) | |
| "stddev": restype_atom14_bond_stddev, # shape (21,14,14) | |
| } | |
| restype_atom14_ambiguous_atoms = np.zeros((21, 14), dtype=np.float32) | |
| restype_atom14_ambiguous_atoms_swap_idx = np.tile(np.arange(14, dtype=int), (21, 1)) | |
| def _make_atom14_ambiguity_feats(): | |
| for res, pairs in residue_atom_renaming_swaps.items(): | |
| res_idx = restype_order[restype_3to1[res]] | |
| for atom1, atom2 in pairs.items(): | |
| atom1_idx = restype_name_to_atom14_names[res].index(atom1) | |
| atom2_idx = restype_name_to_atom14_names[res].index(atom2) | |
| restype_atom14_ambiguous_atoms[res_idx, atom1_idx] = 1 | |
| restype_atom14_ambiguous_atoms[res_idx, atom2_idx] = 1 | |
| restype_atom14_ambiguous_atoms_swap_idx[res_idx, atom1_idx] = atom2_idx | |
| restype_atom14_ambiguous_atoms_swap_idx[res_idx, atom2_idx] = atom1_idx | |
| _make_atom14_ambiguity_feats() | |
| def aatype_to_str_sequence(aatype): | |
| return "".join([restypes_with_x[aatype[i]] for i in range(len(aatype))]) | |
| # NOTE(thayes): These are computed based on the average CA->C and CA->N norm from rigid_group_atom_positions | |
| CA_TO_N_NORM = 1.4591 | |
| CA_TO_C_NORM = 1.5252 | |
| def _make_restype_atom37_to_atom14(): | |
| """Map from atom37 to atom14 per residue type.""" | |
| restype_atom37_to_atom14 = [] # mapping (restype, atom37) --> atom14 | |
| for rt in restypes: | |
| atom_names = restype_name_to_atom14_names[restype_1to3[rt]] | |
| atom_name_to_idx14 = {name: i for i, name in enumerate(atom_names)} | |
| restype_atom37_to_atom14.append( | |
| [ | |
| (atom_name_to_idx14[name] if name in atom_name_to_idx14 else 0) | |
| for name in atom_types | |
| ] | |
| ) | |
| restype_atom37_to_atom14.append([0] * 37) | |
| restype_atom37_to_atom14 = np.array(restype_atom37_to_atom14, dtype=np.int32) | |
| return restype_atom37_to_atom14 | |
| def _make_restype_atom14_to_atom37(): | |
| """Map from atom14 to atom37 per residue type.""" | |
| restype_atom14_to_atom37 = [] # mapping (restype, atom14) --> atom37 | |
| for rt in restypes: | |
| atom_names = restype_name_to_atom14_names[restype_1to3[rt]] | |
| restype_atom14_to_atom37.append( | |
| [(atom_order[name] if name else 0) for name in atom_names] | |
| ) | |
| # Add dummy mapping for restype 'UNK' | |
| restype_atom14_to_atom37.append([0] * 14) | |
| restype_atom14_to_atom37 = np.array(restype_atom14_to_atom37, dtype=np.int32) | |
| return restype_atom14_to_atom37 | |
| RESTYPE_ATOM14_TO_ATOM37 = _make_restype_atom14_to_atom37() | |
| RESTYPE_ATOM37_TO_ATOM14 = _make_restype_atom37_to_atom14() | |
| CHAIN_BREAK_TOKEN = "|" | |