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get_gene_structures.cgi
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#!/usr/bin/python3
import base64
import cgi
import json
import urllib.request
from PIL import Image, ImageDraw
print('Access-Control-Allow-Origin: *')
print('Content-Type: application/json\n') # HTML is following
# ----- CONSTANTS -----
EXON_IMG_WIDTH = 450
EXON_IMG_HEIGHT = 8
# ----- VARIABLES -----
exon_and_CDS = {"start": [], "end": []}
mRNA = {"start": [], "end": []}
expression_score = []
variants = []
variant_count = 0
# ----- GET THE LOCUS OF INTEREST -----
gene_id = cgi.FieldStorage().getvalue('locus')
# ----- GETS MAPPING INFO FOR THE GENE ID -----
map_info = json.loads(urllib.request.urlopen(
"https://bar.utoronto.ca/webservices/bar_araport/gene_structure_by_locus.php?locus=" + gene_id).read())
printout = ""
printout = printout + "{"
printout = printout + "\"locus\" : \"" + gene_id + "\", "
printout = printout + "\"locus_start\" : \"" + str(map_info['features'][0]['start']) + "\", "
printout = printout + "\"locus_end\" : \"" + str(map_info['features'][0]['end']) + "\", "
printout = printout + "\"splice_variants\" : ["
# Get start/end of the LOCUS
start = int(map_info['features'][0]['start'])
end = int(map_info['features'][0]['end'])
strand = int(map_info['features'][0]['strand'])
i = 0
for subfeature in map_info['features'][0]['subfeatures']:
# Need a comma if it is not the first element
if i == 0:
printout = printout + "{"
else:
printout = printout + ", {"
# To return a count of the number of variants returned by Araport
variant_count = variant_count + 1
# Extract variant
variants.append(subfeature['subfeatures'])
# Return all exons' coordinates
printout = printout + "\"exon_coordinates\" : ["
# Define the colours
white = (255, 255, 255)
black = (0, 0, 0)
red = (220, 20, 60)
orange = (255, 140, 0)
blue = (0, 0, 255)
# TO DO: Fix the green and dark green shades...
green = (166, 220, 166)
darkgreen = (0, 125, 0)
# Generate gene structure image based on the information in map_info.
# Create an image for gene structure
exon_graph_image = Image.new("RGB", (EXON_IMG_WIDTH, EXON_IMG_HEIGHT), white)
exongraph = ImageDraw.Draw(exon_graph_image)
count = 0 # Need a comma if it is not the first element...
for region in variants[i]:
# We want to return regions marked as type = exons and type = CDS
if region['type'] == 'exon' or region['type'] == 'CDS':
exon_and_CDS["start"].append(int(region['start']))
exon_and_CDS["end"].append(int(region['end']))
if count == 0:
printout = printout + "{" + "\"exon_start\" : " + str(int(region['start'])) + ", \"exon_end\" : " + str(
int(region['end'])) + "}"
else:
printout = printout + ", {" + "\"exon_start\" : " + str(
int(region['start'])) + ", \"exon_end\" : " + str(int(region['end'])) + "}"
count = count + 1 # To add a comma only...
# We want to graph all types of features in the gene structure image
if region['type'] == 'exon':
exongraph.rectangle((
(int(float(region['start'] - start) / (end - start) * EXON_IMG_WIDTH), 0),
(int(float(region['end'] - start) / (end - start) * EXON_IMG_WIDTH), EXON_IMG_HEIGHT)), darkgreen)
elif region['type'] == 'CDS':
exongraph.rectangle((
(int(float(region['start'] - start) / (end - start) * EXON_IMG_WIDTH), 0),
(int(float(region['end'] - start) / (end - start) * EXON_IMG_WIDTH), EXON_IMG_HEIGHT)), darkgreen)
elif region['type'] == 'five_prime_UTR':
exongraph.rectangle((
(int(float(region['start'] - start) / (end - start) * EXON_IMG_WIDTH), 0),
(int(float(region['end'] - start) / (end - start) * EXON_IMG_WIDTH), EXON_IMG_HEIGHT)), green)
elif region['type'] == 'three_prime_UTR':
exongraph.rectangle((
(int(float(region['start'] - start) / (end - start) * EXON_IMG_WIDTH), 0),
(int(float(region['end'] - start) / (end - start) * EXON_IMG_WIDTH), EXON_IMG_HEIGHT)), green)
# Nucleotide padding
nucleotidePadding = 100
exongraph.rectangle(((0, 0), ((EXON_IMG_WIDTH / nucleotidePadding), EXON_IMG_HEIGHT)), white)
exongraph.rectangle((((EXON_IMG_WIDTH - (EXON_IMG_WIDTH / nucleotidePadding)), 0),
(EXON_IMG_WIDTH, EXON_IMG_HEIGHT)), white)
# Line in the middle
exongraph.rectangle(((0, EXON_IMG_HEIGHT / 2), (EXON_IMG_WIDTH, EXON_IMG_HEIGHT / 2)), black)
# Insert appropriate arrows to indicate direction of the gene
if strand == -1:
exongraph.polygon(
((0, EXON_IMG_HEIGHT / 2), (3, EXON_IMG_HEIGHT - (EXON_IMG_HEIGHT - 1)), (3, EXON_IMG_HEIGHT - 1)), black)
elif strand == +1:
exongraph.polygon(((EXON_IMG_WIDTH, EXON_IMG_HEIGHT / 2),
(EXON_IMG_WIDTH - 3, EXON_IMG_HEIGHT - (EXON_IMG_HEIGHT - 1)),
(EXON_IMG_WIDTH - 3, EXON_IMG_HEIGHT - 1)), black)
f = open("get_exon_base64_exongraph.png", "wb")
exon_graph_image.save(f)
f.close()
printout = printout + "], " + "\"start\" : " + str(start) + ", " + "\"end\" : " + str(
end) + ", " + "\"gene_structure\" : "
printout = printout + "\""
with open("get_exon_base64_exongraph.png", "rb") as fl:
printout = printout + base64.b64encode(fl.read()).decode("utf-8")
printout = printout + "\""
fl.close()
i = i + 1
printout = printout + "}"
printout = printout + "]" + ", \"variant_count\" : \"" + str(variant_count) + "\"" + "}"
print(printout.replace('\n', ' '))