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esm3-conformational-sampling / app.py

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add decorators to visualizers instead of main function

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	import spaces
	import gradio as gr
	import py3Dmol
	import io
	import numpy as np
	import os
	import traceback
	from esm.sdk import client
	from esm.sdk.api import ESM3InferenceClient, ESMProtein, GenerationConfig, ESMProteinError
	from esm.utils.structure.protein_chain import ProteinChain
	from Bio.Data import PDBData
	import biotite.structure as bs
	from biotite.structure.io import pdb
	from esm.utils import residue_constants as RC
	import requests
	from dotenv import load_dotenv
	import torch
	import json
	import time
	from Bio.PDB import PDBParser
	import itertools

	howtouse = """
	## How to use
	1. Upload a PDB file using the file uploader.
	2. Adjust the number of prediction runs per frame using the slider.
	3. Set the noise level to add random perturbations to the structure.
	4. Choose the number of MD frames to simulate.
	5. Click the "Run Prediction" button to start the process.
	6. The 3D visualization will show the original structure (grey) and the best predicted structure (green).
	7. The alignment result will display the best cRMSD (lower is better).
	8. Total and Normalized (per atom) steric clashes (lower is better)
	"""
	about = """ ## Background

	- 3D protein structures typically come from crystal structures, which are densely packed and lack flexibility.
	- Different proteins require varying levels of noise to achieve overlap in conformational space.
	- We've developed an adaptability model that predicts the appropriate noise level for each protein.

	## Our Approach

	1. Adaptability Model: Trained on Molecular Dynamics (MD) data, our model predicts flexibility at the atomic level.
	2. Correlation: The adaptability predictions correlate well with the RMSD (Root Mean Square Deviation) from ESM3 sampling.
	3. Noise Application: We apply noise to simulate protein flexibility, mimicking MD-like behavior.
	"""
	about1 = """
	## About
	This demo uses the ESM3 model to predict protein structures from PDB files.
	It runs multiple predictions with added noise and simulated MD frames, displaying the best result based on the lowest cRMSD.
	"""

	load_dotenv()

	API_URL = "https://forge.evolutionaryscale.ai/api/v1"
	MODEL = "esm3-open-2024-03"
	API_TOKEN = os.environ.get("ESM_API_TOKEN")
	if not API_TOKEN:
	raise ValueError("ESM_API_TOKEN environment variable is not set")

	model = client(
	model=MODEL,
	url=API_URL,
	token="2x0lifRJCpo8klurAJtRom"
	)

	amino3to1 = {
	'ALA': 'A', 'CYS': 'C', 'ASP': 'D', 'GLU': 'E', 'PHE': 'F',
	'GLY': 'G', 'HIS': 'H', 'ILE': 'I', 'LYS': 'K', 'LEU': 'L',
	'MET': 'M', 'ASN': 'N', 'PRO': 'P', 'GLN': 'Q', 'ARG': 'R',
	'SER': 'S', 'THR': 'T', 'VAL': 'V', 'TRP': 'W', 'TYR': 'Y'
	}


	# Covalent radii dictionary
	COVALENT_RADIUS = {
	"H": 0.31, "HE": 0.28, "LI": 1.28, "BE": 0.96, "B": 0.84, "C": 0.76, "N": 0.71, "O": 0.66, "F": 0.57, "NE": 0.58,
	"NA": 1.66, "MG": 1.41, "AL": 1.21, "SI": 1.11, "P": 1.07, "S": 1.05, "CL": 1.02, "AR": 1.06, "K": 2.03,
	"CA": 1.76, "SC": 1.7, "TI": 1.6, "V": 1.53, "CR": 1.39, "MN": 1.5, "FE": 1.42, "CO": 1.38, "NI": 1.24,
	"CU": 1.32, "ZN": 1.22, "GA": 1.22, "GE": 1.2, "AS": 1.19, "SE": 1.2, "BR": 1.2, "KR": 1.16, "RB": 2.2,
	"SR": 1.95, "Y": 1.9, "ZR": 1.75, "NB": 1.64, "MO": 1.54, "TC": 1.47, "RU": 1.46, "RH": 1.42, "PD": 1.39,
	"AG": 1.45, "CD": 1.44, "IN": 1.42, "SN": 1.39, "SB": 1.39, "TE": 1.38, "I": 1.39, "XE": 1.4, "CS": 2.44,
	"BA": 2.15, "LA": 2.07, "CE": 2.04, "PR": 2.03, "ND": 2.01, "PM": 1.99, "SM": 1.98, "EU": 1.98, "GD": 1.96,
	"TB": 1.94, "DY": 1.92, "HO": 1.92, "ER": 1.89, "TM": 1.9, "YB": 1.87, "LU": 1.87, "HF": 1.75, "TA": 1.7,
	"W": 1.62, "RE": 1.51, "OS": 1.44, "IR": 1.41, "PT": 1.36, "AU": 1.36, "HG": 1.32, "TL": 1.45, "PB": 1.46,
	"BI": 1.48, "PO": 1.4, "AT": 1.5, "RN": 1.5, "FR": 2.6, "RA": 2.21, "AC": 2.15, "TH": 2.06, "PA": 2.0,
	"U": 1.96, "NP": 1.9, "PU": 1.87, "AM": 1.8, "CM": 1.69, "BK": 2.0, "CF": 2.0, "ES": 2.0, "FM": 2.0,
	"MD": 2.0, "NO": 2.0, "LR": 2.0, "RF": 2.0, "DB": 2.0, "SG": 2.0, "BH": 2.0, "HS": 2.0, "MT": 2.0,
	"DS": 2.0, "RG": 2.0, "CN": 2.0, "UUT": 2.0, "UUQ": 2.0, "UUP": 2.0, "UUH": 2.0, "UUS": 2.0, "UUO": 2.0
	}

	# Function to get the covalent radius of an atom
	def get_covalent_radius(atom):
	element = atom.element.upper()
	return COVALENT_RADIUS.get(element, 2.0) # Default to 2.0 Å if element is not in the dictionary

	def calculate_clashes_for_pdb(pdb_file):
	parser = PDBParser(QUIET=True)
	structure = parser.get_structure("protein", pdb_file)
	atoms = list(structure.get_atoms())
	steric_clash_count = 0

	num_atoms = len(atoms)

	# Check atom pairs for steric clashes
	for atom1, atom2 in itertools.combinations(atoms, 2):
	covalent_radius_sum = get_covalent_radius(atom1) + get_covalent_radius(atom2)
	distance = atom1 - atom2 # Distance between atom1 and atom2

	# Check if the distance is less than the sum of covalent radii
	if distance + 0.5 < covalent_radius_sum:
	steric_clash_count += 1

	# Normalize steric clashes per number of atoms
	norm_ster_clash_count = steric_clash_count / num_atoms
	return f"{steric_clash_count}", f"{norm_ster_clash_count}"

	def read_pdb_io(pdb_file):
	if isinstance(pdb_file, io.StringIO):
	pdb_content = pdb_file.getvalue()
	elif hasattr(pdb_file, 'name'):
	with open(pdb_file.name, 'r') as f:
	pdb_content = f.read()
	else:
	raise ValueError("Unsupported file type")

	if not pdb_content.strip():
	raise ValueError("The PDB file is empty.")

	pdb_io = io.StringIO(pdb_content)
	return pdb_io, pdb_content

	def get_protein(pdb_file) -> ESMProtein:
	try:
	pdb_io, content = read_pdb_io(pdb_file)

	if not content.strip():
	raise ValueError("The PDB file is empty")

	# Parse the PDB file using biotite
	pdb_file = pdb.PDBFile.read(pdb_io)
	structure = pdb_file.get_structure()

	# Check if the structure contains any atoms
	if structure.array_length() == 0:
	raise ValueError("The PDB file does not contain any valid atoms")

	# Filter for amino acids and create a sequence
	valid_residues = []
	for res in bs.residue_iter(structure):
	res_name = res.res_name
	if isinstance(res_name, np.ndarray):
	res_name = res_name[0] # Take the first element if it's an array
	if res_name in amino3to1:
	valid_residues.append(res)

	if not valid_residues:
	raise ValueError("No valid amino acid residues found in the PDB file")

	sequence = ''.join(amino3to1.get(res.res_name[0] if isinstance(res.res_name, np.ndarray) else res.res_name, 'X') for res in valid_residues)

	# Handle res_id as a potential sequence
	residue_indices = []
	for res in valid_residues:
	if isinstance(res.res_id, (list, tuple, np.ndarray)):
	residue_indices.append(res.res_id[0]) # Take the first element if it's a sequence
	else:
	residue_indices.append(res.res_id)

	# Create a ProteinChain object
	protein_chain = ProteinChain(
	id="test",
	sequence=sequence,
	chain_id="A",
	entity_id=None,
	residue_index=np.array(residue_indices, dtype=int),
	insertion_code=np.full(len(sequence), "", dtype="<U4"),
	atom37_positions=np.full((len(sequence), 37, 3), np.nan),
	atom37_mask=np.zeros((len(sequence), 37), dtype=bool),
	confidence=np.ones(len(sequence), dtype=np.float32)
	)

	# Fill in atom positions and mask
	for i, res in enumerate(valid_residues):
	for atom in res:
	atom_name = atom.atom_name
	if isinstance(atom_name, np.ndarray):
	atom_name = atom_name[0] # Take the first element if it's an array
	if atom_name in RC.atom_order:
	idx = RC.atom_order[atom_name]
	coord = atom.coord
	if coord.ndim > 1:
	coord = coord[0] # Take the first coordinate set if multiple are present
	protein_chain.atom37_positions[i, idx] = coord
	protein_chain.atom37_mask[i, idx] = True

	protein = ESMProtein.from_protein_chain(protein_chain)
	return protein
	except Exception as e:
	print(f"Error processing PDB file: {str(e)}")
	raise ValueError(f"Unable to process the PDB file: {str(e)}")

	def add_noise_to_coordinates(protein: ESMProtein, noise_level: float) -> ESMProtein:
	"""Add Gaussian noise to the atom positions of the protein."""
	coordinates = protein.coordinates
	noise = np.random.randn(coordinates.shape) noise_level
	noisy_coordinates = coordinates + noise
	return ESMProtein(sequence=protein.sequence, coordinates=noisy_coordinates)

	def run_structure_prediction(protein: ESMProtein, temperature: float, num_steps: int) -> ESMProtein:
	structure_prediction_config = GenerationConfig(
	track="structure",
	num_steps=num_steps,
	temperature=temperature,
	)
	try:
	response = model.generate(protein, structure_prediction_config)

	if isinstance(response, ESMProtein):
	return response
	elif isinstance(response, ESMProteinError):
	print(f"ESMProteinError during structure prediction: {response.error_msg}")
	return None
	else:
	raise ValueError(f"Unexpected response type: {type(response)}")
	except Exception as e:
	print(f"Error during structure prediction: {str(e)}")
	return None

	@spaces.GPU
	def align_after_prediction(protein: ESMProtein, structure_prediction: ESMProtein) -> tuple[ESMProtein, float]:
	if structure_prediction is None:
	return None, float('inf')

	try:
	structure_prediction_chain = structure_prediction.to_protein_chain()
	protein_chain = protein.to_protein_chain()

	# Ensure both chains have the same length
	min_length = min(len(structure_prediction_chain.sequence), len(protein_chain.sequence))
	structure_indices = np.arange(0, min_length)

	# Perform alignment
	aligned_chain = structure_prediction_chain.align(
	protein_chain,
	mobile_inds=structure_indices,
	target_inds=structure_indices
	)

	# Calculate RMSD
	crmsd = structure_prediction_chain.rmsd(
	protein_chain,
	mobile_inds=structure_indices,
	target_inds=structure_indices
	)

	return ESMProtein.from_protein_chain(aligned_chain), crmsd
	except AttributeError as e:
	print(f"Error during alignment: {str(e)}")
	print(f"Structure prediction type: {type(structure_prediction)}")
	print(f"Structure prediction attributes: {dir(structure_prediction)}")
	return None, float('inf')
	except Exception as e:
	print(f"Unexpected error during alignment: {str(e)}")
	return None, float('inf')

	@spaces.GPU
	def visualize_after_pred(protein: ESMProtein, aligned: ESMProtein):
	if aligned is None:
	return None

	view = py3Dmol.view(width=800, height=600)
	view.addModel(protein_to_pdb(protein), "pdb")
	view.setStyle({"cartoon": {"color": "lightgrey"}})
	view.addModel(protein_to_pdb(aligned), "pdb")
	view.setStyle({"model": -1}, {"cartoon": {"color": "lightgreen"}})
	view.zoomTo()

	return view

	def protein_to_pdb(protein: ESMProtein):
	pdb_str = ""
	for i, (aa, coords) in enumerate(zip(protein.sequence, protein.coordinates)):
	for j, atom in enumerate(RC.atom_types):
	if not torch.isnan(coords[j][0]):
	x, y, z = coords[j].tolist()
	pdb_str += f"ATOM {i*37+j+1:5d} {atom:3s} {aa:3s} A{i+1:4d} {x:8.3f}{y:8.3f}{z:8.3f}\n"
	return pdb_str

	@spaces.GPU
	def prediction_visualization(pdb_file, num_runs: int, noise_level: float, num_frames: int, temperature: float, num_steps: int, progress=gr.Progress()):
	protein = get_protein(pdb_file)
	runs = []

	total_iterations = num_frames * num_runs
	progress(0, desc="Starting predictions")

	for frame in progress.tqdm(range(num_frames), desc="Processing frames"):
	noisy_protein = add_noise_to_coordinates(protein, noise_level)

	for i in range(num_runs):
	progress((frame * num_runs + i + 1) / total_iterations, desc=f"Frame {frame+1}, Run {i+1}")
	structure_prediction = run_structure_prediction(noisy_protein, temperature, num_steps)
	if structure_prediction is not None:
	aligned, crmsd = align_after_prediction(protein, structure_prediction)
	if aligned is not None:
	runs.append((crmsd, aligned))
	time.sleep(0.1) # Small delay to allow for UI updates

	if not runs:
	return None, "No successful predictions"

	best_aligned = sorted(runs, key=lambda x: x[0])[0]
	view_data = visualize_after_pred(protein, best_aligned[1])
	return view_data, f"Best cRMSD: {best_aligned[0]:.4f}"

	def run_prediction(pdb_file, num_runs, noise_level, num_frames, temperature, num_steps, progress=gr.Progress()):
	try:
	if pdb_file is None:
	return "Please upload a PDB file.", "No file uploaded", "", ""

	progress(0, desc="Starting prediction")
	view, crmsd_text = prediction_visualization(pdb_file, num_runs, noise_level, num_frames, temperature, num_steps, progress)
	steric_clash_text, norm_steric_clash_text = calculate_clashes_for_pdb(pdb_file)
	if view is None:
	return "No successful predictions were made. Try adjusting the parameters or check the PDB file.", crmsd_text, steric_clash_text, norm_steric_clash_text

	progress(0.9, desc="Rendering visualization")

	# Convert the py3Dmol view to HTML
	view_html = view._make_html().replace("'", '"')
	html_content = f"""
	<iframe style="width: 100%; height: 600px;" name="result" allow="midi; geolocation; microphone; camera;
	display-capture; encrypted-media;" sandbox="allow-modals allow-forms
	allow-scripts allow-same-origin allow-popups
	allow-top-navigation-by-user-activation allow-downloads" allowfullscreen=""
	allowpaymentrequest="" frameborder="0" srcdoc='<!DOCTYPE html><html>{view_html}</html>'></iframe>
	"""

	progress(1.0, desc="Completed")
	return html_content, crmsd_text, steric_clash_text, norm_steric_clash_text
	except Exception as e:
	error_message = str(e)
	stack_trace = traceback.format_exc()
	return f"""
	<div style='color: red;'>
	<h3>Error:</h3>
	<p>{error_message}</p>
	<h4>Stack Trace:</h4>
	<pre>{stack_trace}</pre>
	</div>
	""", "Error occurred", "", ""

	def create_demo():
	with gr.Blocks() as demo:
	gr.Markdown("# Protein Structure Prediction and Visualization with Noise and MD Frames")
	with gr.Accordion(label='learn more about MISATO ESM3 conformational sampling', open=False):
	with gr.Row():
	with gr.Column():
	gr.Markdown(about)
	with gr.Column():
	gr.Markdown(howtouse)
	with gr.Row():
	gr.Markdown(about1)
	with gr.Accordion(label="watch presentation video", open=False):
	with gr.Row():
	gr.Video(value="demovideo/demo.mp4", label="MISATO Video Submission")
	with gr.Row():
	with gr.Column(scale=1):
	pdb_file = gr.File(label="Upload PDB file")
	num_runs = gr.Slider(minimum=1, maximum=10, step=1, value=3, label="Number of runs per frame")
	noise_level = gr.Slider(minimum=0, maximum=1, step=0.1, value=0.1, label="Noise level")
	num_frames = gr.Slider(minimum=1, maximum=10, step=1, value=1, label="Number of MD frames")
	temperature = gr.Slider(minimum=0.1, maximum=1.0, step=0.05, value=0.7, label="Temperature")
	num_steps = gr.Slider(minimum=1, maximum=10, step=1, value=10, label="Number of steps")
	run_button = gr.Button("Run Prediction")

	with gr.Column(scale=2):
	visualization = gr.HTML(label="3D Visualization")
	alignment_result = gr.Textbox(label="Alignment Result")
	steric_clash_result = gr.Textbox(label="Steric Clash Result")
	norm_steric_clash_result = gr.Textbox(label="Normalized Steric Clash Result")

	run_button.click(
	fn=run_prediction,
	inputs=[pdb_file, num_runs, noise_level, num_frames, temperature, num_steps],
	outputs=[visualization, alignment_result, steric_clash_result, norm_steric_clash_result]
	)
	gr.Examples(
	examples=[
	["examples/1ywi.pdb"],
	["examples/5awl.pdb"],
	["examples/11gs.pdb"],
	],
	inputs=[pdb_file],
	outputs=[visualization, alignment_result, steric_clash_result, norm_steric_clash_result],
	fn=run_prediction,
	cache_examples=False,
	)

	return demo

	if __name__ == "__main__":
	demo = create_demo()
	demo.queue()
	demo.launch()