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GenotypeFormat.py
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GenotypeFormat.py
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from itertools import combinations_with_replacement
from vcf.parser import _Format
from IlluminaBeadArrayFiles import code2genotype
CHANNEL_MAP = {"A": "T", "T": "A", "C": "G", "G": "C"}
def get_expected_ploidy(gender, chrom):
"""
Determine expected ploidy of call based on sample's gender and chromosome. Unknown genders are processed as diploid.
Args:
gender (string): M,F or U
chrom (string): chromosome, PAR values should be represented as XY
Returns
int: value of expected ploidy, currently set at 1 or 2
"""
if (gender == b"M" and chrom == "X") or chrom == "Y" or chrom == "MT":
return 1
return 2
def format_vcf_genotype(vcf_allele1_char, vcf_allele2_char, ploidy):
"""
Create a VCF representation of the genotype based on alleles. Format appropriately if haploid.
Args:
vcf_allele1_char (string): 0,1,2 etc.
vcf_allele2_char (string): 0,1,2, etc.
vcf_record (vcf._Record): Record for the entry analyzed
ploidy(int): Expected ploidy.
Returns
string: String representation of genotype (e.g., "0/1"), adjusted for haploid calls if applicable
"""
assert ploidy < 3
# haploid calls
if ploidy == 1:
if vcf_allele1_char == vcf_allele2_char:
return str(vcf_allele1_char)
vcf_genotype = ""
if vcf_allele2_char < vcf_allele1_char:
vcf_genotype = str(vcf_allele2_char) + "/" + str(vcf_allele1_char)
else:
vcf_genotype = str(vcf_allele1_char) + "/" + str(vcf_allele2_char)
return vcf_genotype
def convert_ab_genotype_to_nucleotide(ab_genotype, plus_strand_alleles):
"""
Convert an integer genotype to nucleotide genotype on the plus strand
Args:
ab_genotype (int): 0 (no call), 1 (homozygous A), 2 (het), or 3 (homozygous B)
plus_strand_alleles (tuple(string)): Tuple of length 2 with assay alleles (e.g., from SNP column of manifest)
Returns
tuple(string): Tuple of length 2 with nucleotide alleles on plus strand (e.g., ('A', 'C')). NC is ('-', '-')
"""
if ab_genotype == 0:
return ('-', '-')
return tuple([plus_strand_alleles[0] if ab_allele == "A" else plus_strand_alleles[1] for ab_allele in code2genotype[ab_genotype]])
def convert_indel_genotype_to_vcf(nucleotide_genotypes, vcf_record, is_deletion, ploidy):
"""
For indel, convert indel SNP genotype (e.g., I/D) into VCF genotype (e.g, 0/1)
Args:
nucleotide_genotypes (string,string): SNP genotype from manifest (e.g., ('D', 'I'))
vcf_record (vcf._Record): Corresponding VCF record (define reference and alternate allele)
is_deletion (bool): Whether the BPM record that produced the nucleotide genotypes is a reference deletion
ploidy (int): Expected ploidy
Returns:
string: VCF genotype (e.g, "0/1")
"""
if not nucleotide_genotypes:
return format_vcf_genotype(".", ".", ploidy)
if len(nucleotide_genotypes) > 1:
for nucleotide_genotype in nucleotide_genotypes:
if nucleotide_genotype != nucleotide_genotypes[0]:
return format_vcf_genotype(".", ".", ploidy)
nucleotide_genotype = nucleotide_genotypes[0]
if is_deletion:
vcf_allele1_char = "0" if nucleotide_genotype[0] == "I" else "1"
vcf_allele2_char = "0" if nucleotide_genotype[1] == "I" else "1"
else:
vcf_allele1_char = "1" if nucleotide_genotype[0] == "I" else "0"
vcf_allele2_char = "1" if nucleotide_genotype[1] == "I" else "0"
vcf_genotype = format_vcf_genotype(
vcf_allele1_char, vcf_allele2_char, ploidy)
return vcf_genotype
def convert_nucleotide_genotype_to_vcf(nucleotide_genotype, vcf_record, ploidy):
"""
Convert a nucleotide genotype (on the plus strand) to a vcf genotype. For indels,
use "convert_indel_genotype_to_vcf"
Args:
nucleotide_genotype (tuple(string)): Tuple of length 2. Each element is nucleotide allele
No call should be represented as ("-", "-")
ploidy(int): value of estimated ploidy.
Returns
string: VCF genotype (e.g, "0/1")
"""
assert len(nucleotide_genotype) == 2
if nucleotide_genotype[0] == "-" and nucleotide_genotype[1] == "-":
return format_vcf_genotype(".", ".", ploidy)
try:
vcf_allele1_char = vcf_record.alleles.index(nucleotide_genotype[0])
vcf_allele2_char = vcf_record.alleles.index(nucleotide_genotype[1])
except:
raise Exception(
"Could not index alleles in VCF record " + vcf_record.ID)
vcf_genotype = format_vcf_genotype(
vcf_allele1_char, vcf_allele2_char, ploidy)
return vcf_genotype
class RecordCombiner(object):
"""
Class to take in a group of BPM records and output a combined genotype
"""
def __init__(self, bpm_records, genotypes, logger):
"""
Create new RecordCombiner
Args:
bpm_records (list(BPMRecord)): Group of BPM records for a single site (typically just one)
genotypes (list(genotypes)): List of all genotypes in GTC file as integers
Returns:
RecordCombiner
"""
self._bpm_records = bpm_records
self._genotypes = genotypes
self._logger = logger
def _generate_possible_genotypes(self):
"""
From the alleles in the BPM records, enumerate all possible genotypes
at this site
Args:
None
Returns:
list(list(string)) - A list of lists of length 2. Each inner list represents a possible
genotype at this site in terms of pair of nucleotide alleles on the plus strand
"""
alleles = set()
for record in self._bpm_records:
alleles.update(record.plus_strand_alleles)
return list(combinations_with_replacement(alleles, 2))
def _record_inconsistent_with_genotype(self, record, genotype):
"""Check if a particular BPM record is inconsitent with a given
genotype. Genotype should be tuple of alleles on plus strand.
Args:
record (BPMRecord)
genotype (tuple(string)) : Tuple of length 2 where each element is nucleotide allele
on plus strand
Returns:
bool
"""
# record_genotype is an integer (0 - NC, 1 - AA, 2 - AB, 3 - BB)
record_int_genotype = self._genotypes[record.index_num]
if record_int_genotype == 0:
return False
plus_strand_alleles = record.plus_strand_alleles
record_plus_genotype = convert_ab_genotype_to_nucleotide(
record_int_genotype, plus_strand_alleles)
for allele in record_plus_genotype:
# check for alleles that must be present in a consistent genotype
consistent_alleles = []
consistent_alleles.append(allele)
if record.assay_type == 0: # Inf II
consistent_alleles.append(CHANNEL_MAP[allele])
if not any([consistent_allele in genotype for consistent_allele in consistent_alleles]):
return True
# check for alleles that must be absent in a consistent genotype
absent_alleles = []
if record_int_genotype == 1 or record_int_genotype == 3: # homozygous
# for example, if assay is A/C Inf II and genotype is AA, real
# genotype can not contain C or G
absent_allele = plus_strand_alleles[0] if record_int_genotype == 3 else plus_strand_alleles[1]
absent_alleles.append(absent_allele)
if record.assay_type == 0: # Inf II
absent_alleles.append(CHANNEL_MAP[absent_allele])
if any([absent_allele in genotype for absent_allele in absent_alleles]):
return True
return False
def _filter_inconsistent_genotypes(self, possible_genotypes):
"""Filter the list of possible genotypes to remove
those that are inconsitent with any BPM record in this group
Args
possible_genotypes (list(list(string)) - List of possible genotypes. Each possible genotype is a list of
length 2 where each string is a nucleotide on the plus strand
Returns
list(list(string)) - List of genotypes consitent with assay data. Each remaining genotype is a list of
length 2 where each string is a nucleotide on the plus strand
"""
idx2inconsistent = [False] * len(possible_genotypes)
for idx in range(len(possible_genotypes)):
for record in self._bpm_records:
if self._record_inconsistent_with_genotype(record, possible_genotypes[idx]):
idx2inconsistent[idx] = True
break
return [genotype for (genotype, is_inconsistent) in zip(possible_genotypes, idx2inconsistent) if not is_inconsistent]
def combine_genotypes(self):
"""
Generate the combined genotype from all assays at this site
Args:
None
Returns:
(string, string): The combined genotype (on the plus strand) at this site (e.g., ("A", "C") ) No call is ("-", "-")
"""
possible_genotypes = self._generate_possible_genotypes()
# filter any genotypes which may be ambiguous due to the presence of
# InfII assays
allowable_genotypes = self._filter_inconsistent_genotypes(
possible_genotypes)
# if only one consistent genotype, then that is the genotype. Otherwise, the genotype
# is ambiguous (more than 1) or inconsistent (less than 1) and return a
# no-call
if len(allowable_genotypes) == 1:
return allowable_genotypes[0]
return ("-", "-")
def combine_names(self):
"""
Generate the combined name for thi sgroup of records
Args:
None
Returns:
string: The combined names
"""
record_names = []
for record in self._bpm_records:
record_names.append(record.name)
return ",".join(sorted(record_names))
class GenotypeFormat(object):
"""
Generate GT format information for VCF
"""
def __init__(self, logger, gender, genotypes):
self._gender = gender
self._genotypes = genotypes
self._logger = logger
@staticmethod
def get_id():
return "GT"
@staticmethod
def get_description():
return "Genotype"
@staticmethod
def get_format_obj():
return _Format(GenotypeFormat.get_id(), 1, "String", GenotypeFormat.get_description())
def generate_sample_format_info(self, bpm_records, vcf_record, sample_name):
"""
Get the sample genotype
Args:
bpm_records (list(BPMRecord)): List of BPM records
vcf_record (vcf._Record): Corresponding VCF record
sample_name (string): The sample name
Returns:
string: GT sample format string (e.g., "0/1")
"""
# use chrom from bpm_records where PAR chromsomes have not been
# converted
ploidy = get_expected_ploidy(self._gender, bpm_records[0].chromosome)
if any(record.is_indel() for record in bpm_records):
assert all(record.is_indel() for record in bpm_records)
nucleotide_genotypes = []
for record in bpm_records:
int_genotype = self._genotypes[record.index_num]
if int_genotype != 0:
nucleotide_genotypes.append(convert_ab_genotype_to_nucleotide(
int_genotype, record.plus_strand_alleles))
vcf_genotype = convert_indel_genotype_to_vcf(
nucleotide_genotypes, vcf_record, bpm_records[0].is_deletion, ploidy)
else:
if len(bpm_records) > 1:
combiner = RecordCombiner(
bpm_records, self._genotypes, self._logger)
nucleotide_genotype = combiner.combine_genotypes()
vcf_genotype = convert_nucleotide_genotype_to_vcf(
nucleotide_genotype, vcf_record, ploidy)
vcf_record.ID = combiner.combine_names()
else:
sample_genotype = self._genotypes[bpm_records[0].index_num]
if sample_genotype == 0:
nucleotide_genotype = ('-', '-')
else:
nucleotide_genotype = convert_ab_genotype_to_nucleotide(
sample_genotype, bpm_records[0].plus_strand_alleles)
vcf_genotype = convert_nucleotide_genotype_to_vcf(
nucleotide_genotype, vcf_record, ploidy)
return vcf_genotype