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| import tensorflow as tf | |
| from keras import regularizers | |
| from keras.layers import Input, Dense, Dropout, Activation, Conv1D | |
| from keras.layers import GlobalAveragePooling1D, AveragePooling1D | |
| from keras.layers import Bidirectional, LSTM | |
| from keras import Model | |
| from keras.metrics import MeanSquaredError | |
| import pandas as pd | |
| import numpy as np | |
| import requests | |
| from functools import reduce | |
| from operator import add | |
| import tabulate | |
| from difflib import SequenceMatcher | |
| import cyvcf2 | |
| import parasail | |
| import re | |
| ntmap = {'A': (1, 0, 0, 0), | |
| 'C': (0, 1, 0, 0), | |
| 'G': (0, 0, 1, 0), | |
| 'T': (0, 0, 0, 1) | |
| } | |
| def get_seqcode(seq): | |
| return np.array(reduce(add, map(lambda c: ntmap[c], seq.upper()))).reshape((1, len(seq), -1)) | |
| def BiLSTM_model(input_shape): | |
| input = Input(shape=input_shape) | |
| conv1 = Conv1D(128, 5, activation="relu")(input) | |
| pool1 = AveragePooling1D(2)(conv1) | |
| drop1 = Dropout(0.1)(pool1) | |
| conv2 = Conv1D(128, 5, activation="relu")(drop1) | |
| pool2 = AveragePooling1D(2)(conv2) | |
| drop2 = Dropout(0.1)(pool2) | |
| lstm1 = Bidirectional(LSTM(128, | |
| dropout=0.1, | |
| activation='tanh', | |
| return_sequences=True, | |
| kernel_regularizer=regularizers.l2(1e-4)))(drop2) | |
| avgpool = GlobalAveragePooling1D()(lstm1) | |
| dense1 = Dense(128, | |
| kernel_regularizer=regularizers.l2(1e-4), | |
| bias_regularizer=regularizers.l2(1e-4), | |
| activation="relu")(avgpool) | |
| drop3 = Dropout(0.1)(dense1) | |
| dense2 = Dense(32, | |
| kernel_regularizer=regularizers.l2(1e-4), | |
| bias_regularizer=regularizers.l2(1e-4), | |
| activation="relu")(drop3) | |
| drop4 = Dropout(0.1)(dense2) | |
| dense3 = Dense(32, | |
| kernel_regularizer=regularizers.l2(1e-4), | |
| bias_regularizer=regularizers.l2(1e-4), | |
| activation="relu")(drop4) | |
| drop5 = Dropout(0.1)(dense3) | |
| output = Dense(1, activation="linear")(drop5) | |
| model = Model(inputs=[input], outputs=[output]) | |
| return model | |
| def fetch_ensembl_transcripts(gene_symbol): | |
| url = f"https://rest.ensembl.org/lookup/symbol/homo_sapiens/{gene_symbol}?expand=1;content-type=application/json" | |
| response = requests.get(url) | |
| if response.status_code == 200: | |
| gene_data = response.json() | |
| if 'Transcript' in gene_data: | |
| return gene_data['Transcript'] | |
| else: | |
| print("No transcripts found for gene:", gene_symbol) | |
| return None | |
| else: | |
| print(f"Error fetching gene data from Ensembl: {response.text}") | |
| return None | |
| def fetch_ensembl_sequence(transcript_id): | |
| url = f"https://rest.ensembl.org/sequence/id/{transcript_id}?content-type=application/json" | |
| response = requests.get(url) | |
| if response.status_code == 200: | |
| sequence_data = response.json() | |
| if 'seq' in sequence_data: | |
| return sequence_data['seq'] | |
| else: | |
| print("No sequence found for transcript:", transcript_id) | |
| return None | |
| else: | |
| print(f"Error fetching sequence data from Ensembl: {response.text}") | |
| return None | |
| def apply_mutation(ref_sequence, offset, ref, alt): | |
| """ | |
| Apply a single mutation to the sequence. | |
| """ | |
| if len(ref) == len(alt) and alt != "*": # SNP | |
| mutated_seq = ref_sequence[:offset] + alt + ref_sequence[offset+len(alt):] | |
| elif len(ref) < len(alt): # Insertion | |
| mutated_seq = ref_sequence[:offset] + alt + ref_sequence[offset+1:] | |
| elif len(ref) == len(alt) and alt == "*": # Deletion | |
| mutated_seq = ref_sequence[:offset] + ref_sequence[offset+1:] | |
| elif len(ref) > len(alt) and alt != "*": # Deletion | |
| mutated_seq = ref_sequence[:offset] + alt + ref_sequence[offset+len(ref):] | |
| elif len(ref) > len(alt) and alt == "*": # Deletion | |
| mutated_seq = ref_sequence[:offset] + ref_sequence[offset+len(ref):] | |
| return mutated_seq | |
| def construct_combinations(sequence, mutations): | |
| """ | |
| Construct all combinations of mutations. | |
| mutations is a list of tuples (position, ref, [alts]) | |
| """ | |
| if not mutations: | |
| return [sequence] | |
| # Take the first mutation and recursively construct combinations for the rest | |
| first_mutation = mutations[0] | |
| rest_mutations = mutations[1:] | |
| offset, ref, alts = first_mutation | |
| sequences = [] | |
| for alt in alts: | |
| mutated_sequence = apply_mutation(sequence, offset, ref, alt) | |
| sequences.extend(construct_combinations(mutated_sequence, rest_mutations)) | |
| return sequences | |
| def needleman_wunsch_alignment(query_seq, ref_seq): | |
| """ | |
| Use Needleman-Wunsch alignment to find the maximum alignment position in ref_seq | |
| Use this position to represent the position of target sequence with mutations | |
| """ | |
| # Needleman-Wunsch alignment | |
| alignment = parasail.nw_trace(query_seq, ref_seq, 10, 1, parasail.blosum62) | |
| # extract CIGAR object | |
| cigar = alignment.cigar | |
| cigar_string = cigar.decode.decode("utf-8") | |
| # record ref_pos | |
| ref_pos = 0 | |
| matches = re.findall(r'(\d+)([MIDNSHP=X])', cigar_string) | |
| max_num_before_equal = 0 | |
| max_equal_index = -1 | |
| total_before_max_equal = 0 | |
| for i, (num_str, op) in enumerate(matches): | |
| num = int(num_str) | |
| if op == '=': | |
| if num > max_num_before_equal: | |
| max_num_before_equal = num | |
| max_equal_index = i | |
| total_before_max_equal = sum(int(matches[j][0]) for j in range(max_equal_index)) | |
| ref_pos = total_before_max_equal | |
| return ref_pos | |
| def find_gRNA_with_mutation(ref_sequence, exon_chr, start, end, strand, transcript_id, | |
| exon_id, gene_symbol, vcf_reader, pam="TTTN", target_length=34): | |
| # initialization | |
| mutated_sequences = [ref_sequence] | |
| # find mutations within interested region | |
| mutations = vcf_reader(f"{exon_chr}:{start}-{end}") | |
| if mutations: | |
| # find mutations | |
| mutation_list = [] | |
| for mutation in mutations: | |
| offset = mutation.POS - start | |
| ref = mutation.REF | |
| alts = mutation.ALT[:-1] | |
| mutation_list.append((offset, ref, alts)) | |
| # replace reference sequence of mutation | |
| mutated_sequences = construct_combinations(ref_sequence, mutation_list) | |
| # find gRNA in ref_sequence or all mutated_sequences | |
| targets = [] | |
| for seq in mutated_sequences: | |
| len_sequence = len(seq) | |
| dnatorna = {'A': 'A', 'T': 'U', 'C': 'C', 'G': 'G'} | |
| for i in range(len_sequence - target_length + 1): | |
| target_seq = seq[i:i + target_length] | |
| if target_seq[4:7] == 'TTT': | |
| pos = ref_sequence.find(target_seq) | |
| if pos != -1: | |
| is_mut = False | |
| if strand == -1: | |
| tar_start = end - pos - target_length + 1 | |
| else: | |
| tar_start = start + pos | |
| else: | |
| is_mut = True | |
| nw_pos = needleman_wunsch_alignment(target_seq, ref_sequence) | |
| if strand == -1: | |
| tar_start = str(end - nw_pos - target_length + 1) + '*' | |
| else: | |
| tar_start = str(start + nw_pos) + '*' | |
| gRNA = ''.join([dnatorna[base] for base in target_seq[8:28]]) | |
| targets.append([target_seq, gRNA, exon_chr, str(strand), str(tar_start), transcript_id, exon_id, gene_symbol, is_mut]) | |
| # filter duplicated targets | |
| unique_targets_set = set(tuple(element) for element in targets) | |
| unique_targets = [list(element) for element in unique_targets_set] | |
| return unique_targets | |
| def format_prediction_output_with_mutation(targets, model_path): | |
| Crispr_BiLSTM = BiLSTM_model(input_shape=(34, 4)) | |
| Crispr_BiLSTM.load_weights(model_path) | |
| formatted_data = [] | |
| for target in targets: | |
| # Predict | |
| encoded_seq = get_seqcode(target[0]) | |
| prediction = float(list(Crispr_BiLSTM.predict(encoded_seq, verbose=0)[0])[0]) | |
| if prediction > 100: | |
| prediction = 100 | |
| # Format output | |
| gRNA = target[1] | |
| exon_chr = target[2] | |
| strand = target[3] | |
| tar_start = target[4] | |
| transcript_id = target[5] | |
| exon_id = target[6] | |
| gene_symbol = target[7] | |
| is_mut = target[8] | |
| formatted_data.append([gene_symbol, exon_chr, strand, tar_start, transcript_id, exon_id, target[0], gRNA, prediction, is_mut]) | |
| return formatted_data | |
| def process_gene(gene_symbol, vcf_reader, model_path): | |
| transcripts = fetch_ensembl_transcripts(gene_symbol) | |
| results = [] | |
| all_exons = [] # To accumulate all exons | |
| all_gene_sequences = [] # To accumulate all gene sequences | |
| if transcripts: | |
| for transcript in transcripts: | |
| Exons = transcript['Exon'] | |
| all_exons.extend(Exons) # Add all exons from this transcript to the list | |
| transcript_id = transcript['id'] | |
| for Exon in Exons: | |
| exon_id = Exon['id'] | |
| gene_sequence = fetch_ensembl_sequence(exon_id) # Reference exon sequence | |
| if gene_sequence: | |
| all_gene_sequences.append(gene_sequence) # Add this gene sequence to the list | |
| exon_chr = Exon['seq_region_name'] | |
| start = Exon['start'] | |
| end = Exon['end'] | |
| strand = Exon['strand'] | |
| targets = find_gRNA_with_mutation(gene_sequence, exon_chr, start, end, strand, transcript_id, exon_id, gene_symbol, vcf_reader) | |
| if targets: | |
| # Predict on-target efficiency for each gRNA site | |
| formatted_data = format_prediction_output_with_mutation(targets, model_path) | |
| results.extend(formatted_data) # Flatten the results | |
| else: | |
| print(f"Failed to retrieve gene sequence for exon {exon_id}.") | |
| else: | |
| print("Failed to retrieve transcripts.") | |
| # Sort results based on prediction score (assuming score is at the 8th index) | |
| sorted_results = sorted(results, key=lambda x: x[8], reverse=True) | |
| # Return the sorted output, combined gene sequences, and all exons | |
| return sorted_results, all_gene_sequences, all_exons | |