https://github.com/fenderglass/Ragout
Tip revision: 4a0ab26826fa4f123c7a8ecabb71b030efa44cf0 authored by Mikhail Kolmogorov on 22 April 2023, 16:31:58 UTC
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Tip revision: 4a0ab26
chimera_detector.py
#(c) 2013-2014 by Authors
#This file is a part of Ragout program.
#Released under the BSD license (see LICENSE file)
"""
This module tries to detect missassembled adjacencies
in input sequences and breaks them if neccesary
"""
from __future__ import print_function
from __future__ import absolute_import
from __future__ import division
import logging
from collections import defaultdict, namedtuple
from copy import copy, deepcopy
from ragout.six.moves import range
logger = logging.getLogger()
ContigBreak = namedtuple("ContigBreak", ["seq_name", "begin", "end", "good"])
class ChimeraDetector(object):
def __init__(self, breakpoint_graphs, run_stages, target_seqs):
logger.info("Detecting chimeric adjacencies")
self.bp_graphs = breakpoint_graphs
self.run_stages = run_stages
self.target_seqs = target_seqs
self._make_hierarchical_breaks()
def _make_hierarchical_breaks(self):
"""
Determines where and at what synteny blocks scale to break each contig
"""
seq_cuts = defaultdict(lambda : defaultdict(list))
#extracting and grouping by sequence
for stage in self.run_stages:
logger.debug(">>With block size: %d", stage.block_size)
breaks = self._get_contig_breaks(self.bp_graphs[stage])
for br in breaks:
seq_cuts[br.seq_name][stage].append(br)
hierarchical_cuts = defaultdict(lambda : defaultdict(list))
for seq_name in seq_cuts:
for i in range(len(self.run_stages)):
top_stage = self.run_stages[i]
for top_break in seq_cuts[seq_name][top_stage]:
if top_break.good:
continue
adjusted_break = (top_break.begin, top_break.end)
for j in range(i + 1, len(self.run_stages)):
lower_stage = self.run_stages[j]
#check if there is overlapping cut
for lower_break in seq_cuts[seq_name][lower_stage]:
ovlp_left = max(adjusted_break[0], lower_break.begin)
ovlp_right = min(adjusted_break[1], lower_break.end)
#if so, update current and go down
if ovlp_right >= ovlp_left:
adjusted_break = (ovlp_left, ovlp_right)
break
break_pos = self._optimal_break(seq_name, *adjusted_break)
hierarchical_cuts[seq_name][top_stage].append(break_pos)
self.hierarchical_cuts = hierarchical_cuts
def _optimal_break(self, seq_name, break_start, break_end):
"""
Finds the longet run of Ns within given range
"""
seq = self.target_seqs[seq_name]
cur_pos = break_start
cur_len = 0
max_pos = break_start
max_len = 0
for i in range(break_start, break_end):
if seq[i].upper() == "N":
cur_len += 1
if seq[i].upper() != "N" or i == break_end - 1:
if max_len < cur_len:
max_len = cur_len
max_pos = cur_pos
cur_pos = i + 1
cur_len = 0
return max_pos + max_len // 2
def _get_contig_breaks(self, bp_graph):
"""
Detects chimeric adjacencies
"""
seq_cuts = []
subgraphs = bp_graph.connected_components()
num_target_adj = 0
num_unique_adj = 0
num_removed_adj = 0
for subgr in subgraphs:
if len(subgr.bp_graph) > 100:
logger.debug("Processing component of size %d",
len(subgr.bp_graph))
for (u, v, data) in subgr.bp_graph.edges(data=True):
if data["genome_id"] != subgr.target:
continue
num_target_adj += 1
genomes = set(subgr.genomes_support(u, v))
if (genomes != set([bp_graph.target])
and not subgr.is_infinity(u, v)):
continue
num_unique_adj += 1
seq_name, start, end = data["chr_name"], data["start"], data["end"]
if subgr.alternating_cycle(u, v) is not None:
seq_cuts.append(ContigBreak(seq_name, start, end, True))
continue
seq_cuts.append(ContigBreak(seq_name, start, end, False))
num_removed_adj += 1
#bp_graph.debug_output()
logger.debug("Checking %d target adjacencies", num_target_adj)
logger.debug("Found %d target-specific adjacencies, "
"%d broken as chimeric", num_unique_adj, num_removed_adj)
return seq_cuts
def _valid_2break(self, bp_graph, red_edge):
"""
Checks if there is a valid 2-break through the given red edge
"""
assert len(bp_graph) == 4
red_1, red_2 = red_edge
cand_1, cand_2 = tuple(set(bp_graph.nodes) - set(red_edge))
if abs(cand_1) == abs(cand_2):
return False
if bp_graph.has_edge(red_1, cand_1):
if not bp_graph.has_edge(red_2, cand_2):
return False
known_1 = red_1, cand_1
known_2 = red_2, cand_2
elif bp_graph.has_edge(red_1, cand_2):
if not bp_graph.has_edge(red_2, cand_1):
return False
known_1 = red_1, cand_2
known_2 = red_2, cand_1
else:
return False
chr_1 = {}
for data in bp_graph[known_1[0]][known_1[1]].values():
chr_1[data["genome_id"]] = data["chr_name"]
chr_2 = {}
for data in bp_graph[known_2[0]][known_2[1]].values():
chr_2[data["genome_id"]] = data["chr_name"]
common_genomes = set(chr_1.keys()).intersection(list(chr_2.keys()))
for genome in common_genomes:
if chr_1[genome] != chr_2[genome]:
return False
return True
def break_contigs(self, perm_container, block_sizes):
"""
Breaks contigs in inferred cut positions
"""
logger.info("Removing chimeric adjacencies")
new_container = deepcopy(perm_container)
new_target_perms = []
num_breaks = 0
num_chimeras = 0
for perm in new_container.target_perms:
break_points = []
for size in block_sizes:
break_points.extend(self.hierarchical_cuts[perm.chr_name][size])
break_points = list(set(break_points))
num_breaks += len(break_points)
if not break_points:
new_target_perms.append(perm)
else:
num_chimeras += 1
new_target_perms.extend(_break_permutation(perm, break_points))
logger.debug("Chimera Detector: %d cuts made in %d sequences",
num_breaks, num_chimeras)
new_container.target_perms = new_target_perms
return new_container
def _break_permutation(permutation, break_points):
broken_perms = []
cuts_stack = copy(sorted(break_points))
cuts_stack.append(permutation.seq_len)
current_perm = deepcopy(permutation)
current_perm.blocks = []
shift = 0
for block in permutation.blocks:
if block.end <= cuts_stack[0]:
block.start -= shift
block.end -= shift
current_perm.blocks.append(block)
continue
if block.start < cuts_stack[0]:
block.start = cuts_stack[0]
#we have passed the current cut
current_perm.seq_start = shift
current_perm.seq_end = cuts_stack[0]
if current_perm.blocks:
broken_perms.append(current_perm)
shift = cuts_stack[0]
cuts_stack.pop(0)
current_perm = deepcopy(permutation)
block.start -= shift
block.end -= shift
current_perm.blocks = [block]
current_perm.seq_start = shift
current_perm.seq_end = cuts_stack[0]
if current_perm.blocks:
broken_perms.append(current_perm)
return broken_perms
