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GenotypeTRcorrection.py
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GenotypeTRcorrection.py
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### import libraries ###
import sys
import collections, math
import heapq
### basic function ###
def stop_err(msg):
sys.stderr.write(msg)
sys.exit()
def averagelist(a,b,expectedlevelofminor):
product=[]
for i in range(len(a)):
product.append((1-expectedlevelofminor)*a[i]+expectedlevelofminor*b[i])
return product
def complement_base(read):
collect=''
for i in read:
if i.upper()=='A':
collect+='T'
elif i.upper()=='T':
collect+='A'
elif i.upper()=='C':
collect+='G'
elif i.upper()=='G':
collect+='C'
return collect
def makeallpossible(read):
collect=[]
for i in range(len(read)):
tmp= read[i:]+read[:i]
collect.append(tmp)
collect.append(complement_base(tmp))
return collect
def motifsimplify(base):
'''str--> str
'''
motiflength=len(base)
temp=list(set(ALLMOTIF[motiflength]).intersection(set(makeallpossible(base))))
return temp[0]
def majorallele(seq):
binseq=list(set(seq))
binseq.sort(reverse=True) # highly mutate mode
#binseq.sort() # majority mode
storeform=''
storevalue=0
for i in binseq:
if seq.count(i)>storevalue:
storeform=i
storevalue=seq.count(i)
return int(storeform)
### decide global parameter ###
COORDINATECOLUMN=1
ALLELECOLUMN=2
MOTIFCOLUMN=3
##(0.01-0.5)
MINIMUMMUTABLE=1.2*(1.0/(10**8)) #http://www.ncbi.nlm.nih.gov/pubmed/22914163 Kong et al 2012
## Fixed global variable
inputname=sys.argv[1]
errorprofile=sys.argv[2]
Genotypingcorrected=sys.argv[3]
EXPECTEDLEVELOFMINOR=float(sys.argv[4])
if EXPECTEDLEVELOFMINOR >0.5:
try:
expected_contribution_of_minor_allele=int('expected_contribution_of_minor_allele')
except Exception, eee:
print eee
stop_err("Expected contribution of minor allele must be at least 0 and not more than 0.5")
ALLREPEATTYPE=[1,2,3,4]
ALLREPEATTYPENAME=['mono','di','tri','tetra']
monomotif=['A','C']
dimotif=['AC','AG','AT','CG']
trimotif=['AAC','AAG','AAT','ACC','ACG','ACT','AGC','AGG','ATC','CCG']
tetramotif=['AAAC','AAAG','AAAT','AACC','AACG','AACT','AAGC','AAGG','AAGT','AATC','AATG','AATT',\
'ACAG','ACAT','ACCC','ACCG','ACCT','ACGC','ACGG','ACGT','ACTC','ACTG','AGAT','AGCC','AGCG','AGCT',\
'AGGC','AGGG','ATCC','ATCG','ATGC','CCCG','CCGG','AGTC']
ALLMOTIF={1:monomotif,2:dimotif,3:trimotif,4:tetramotif}
monorange=range(5,60)
dirange=range(6,60)
trirange=range(9,60)
tetrarange=range(12,80)
ALLRANGE={1:monorange,2:dirange,3:trirange,4:tetrarange}
#########################################
######## Prob calculation sector ########
#########################################
def multinomial_prob(majorallele,STRlength,motif,probdatabase):
'''int,int,str,dict-->int
### get prob for each STRlength to be generated from major allele
'''
#print (majorallele,STRlength,motif)
prob=probdatabase[len(motif)][motif][majorallele][STRlength]
return prob
################################################
######## error model database sector ###########
################################################
## structure generator
errormodeldatabase={1:{},2:{},3:{},4:{}}
sumbymajoralleledatabase={1:{},2:{},3:{},4:{}}
for repeattype in ALLREPEATTYPE:
for motif in ALLMOTIF[repeattype]:
errormodeldatabase[repeattype][motif]={}
sumbymajoralleledatabase[repeattype][motif]={}
for motifsize1 in ALLRANGE[repeattype]:
errormodeldatabase[repeattype][motif][motifsize1]={}
sumbymajoralleledatabase[repeattype][motif][motifsize1]=0
for motifsize2 in ALLRANGE[repeattype]:
errormodeldatabase[repeattype][motif][motifsize1][motifsize2]=MINIMUMMUTABLE
#print errormodeldatabase
## read database
## get read count for each major allele
fd=open(errorprofile)
lines=fd.readlines()
for line in lines:
temp=line.strip().split('\t')
t_major=int(temp[0])
t_count=int(temp[2])
motif=temp[3]
sumbymajoralleledatabase[len(motif)][motif][t_major]+=t_count
fd.close()
##print sumbymajoralleledatabase
## get probability
fd=open(errorprofile)
lines=fd.readlines()
for line in lines:
temp=line.strip().split('\t')
t_major=int(temp[0])
t_read=int(temp[1])
t_count=int(temp[2])
motif=temp[3]
if sumbymajoralleledatabase[len(motif)][motif][t_major]>0:
errormodeldatabase[len(motif)][motif][t_major][t_read]=t_count/(sumbymajoralleledatabase[len(motif)][motif][t_major]*1.0)
#errormodeldatabase[repeattype][motif][t_major][t_read]=math.log(t_count/(sumbymajorallele[t_major]*1.0))
#else:
# errormodeldatabase[repeattype][motif][t_major][t_read]=0
fd.close()
#########################################
######## input reading sector ###########
#########################################
fdout=open(Genotypingcorrected,'w')
fd = open(inputname)
lines=fd.xreadlines()
for line in lines:
i_read=[]
i2_read=[]
temp=line.strip().split('\t')
i_coordinate=temp[COORDINATECOLUMN-1]
i_motif=motifsimplify(temp[MOTIFCOLUMN-1])
i_read=temp[ALLELECOLUMN-1].split(',')
i_read=map(int,i_read)
coverage=len(i_read)
### Evaluate 1 major allele ###
i_all_allele=list(set(i_read))
i_major_allele=majorallele(i_read)
f_majorallele=i_read.count(i_major_allele)
### Evaluate 2 major allele ###
if len(i_all_allele)>1:
i2_read=filter(lambda a: a != i_major_allele, i_read)
i_major2_allele=majorallele(i2_read)
f_majorallele2=i_read.count(i_major2_allele)
### Evaluate 3 major allele ###
if len(i_all_allele)>2:
i3_read=filter(lambda a: a != i_major2_allele, i2_read)
i_major3_allele=majorallele(i3_read)
f_majorallele3=i_read.count(i_major3_allele)
### No 3 major allele ###
elif len(i_all_allele)==2:
i_major3_allele=i_major2_allele
### No 2 major allele ###
elif len(i_all_allele)==1:
#i_major2_allele=majorallele(i_read)
i_major2_allele=i_major_allele+len(i_motif)
i_major3_allele=i_major2_allele
#print line.strip()+'\t'+'\t'.join(['homo','only',str(i_major_allele),str(i_major_allele),'NA'])
#continue
else:
print("no allele is reading")
sys.exit()
## scope filter
#########################################
######## prob calculation sector ########
#########################################
homozygous_collector=0
heterozygous_collector=0
alist=[multinomial_prob(i_major_allele,x,i_motif,errormodeldatabase)for x in i_read]
blist=[multinomial_prob(i_major2_allele,x,i_motif,errormodeldatabase)for x in i_read]
clist=[multinomial_prob(i_major3_allele,x,i_motif,errormodeldatabase)for x in i_read]
ablist=averagelist(alist,blist,EXPECTEDLEVELOFMINOR)
bclist=averagelist(blist,clist,EXPECTEDLEVELOFMINOR)
aclist=averagelist(alist,clist,EXPECTEDLEVELOFMINOR)
#print alist,blist,clist
majora=sum([math.log(i,10) for i in alist])
majorb=sum([math.log(i,10) for i in blist])
majorc=sum([math.log(i,10) for i in clist])
homozygous_collector=max(majora,majorb,majorc)
homomajor1=max([(majora,i_major_allele),(majorb,i_major2_allele),(majorc,i_major3_allele)])[1]
homomajordict={i_major_allele:majora,i_major2_allele:majorb,i_major3_allele:majorc}
majorab=sum([math.log(i,10) for i in ablist])
majorbc=sum([math.log(i,10) for i in bclist])
majorac=sum([math.log(i,10) for i in aclist])
heterozygous_collector=max(majorab,majorbc,majorac)
bothheteromajor=max([(majorab,(i_major_allele,i_major2_allele)),(majorbc,(i_major2_allele,i_major3_allele)),(majorac,(i_major_allele,i_major3_allele))])[1]
##heteromajor1=max(bothheteromajor)
##heteromajor2=min(bothheteromajor)
pre_heteromajor1=bothheteromajor[0]
pre_heteromajor2=bothheteromajor[1]
heteromajor1=max((homomajordict[pre_heteromajor1],pre_heteromajor1),(homomajordict[pre_heteromajor2],pre_heteromajor2))[1]
heteromajor2=min((homomajordict[pre_heteromajor1],pre_heteromajor1),(homomajordict[pre_heteromajor2],pre_heteromajor2))[1]
logratio_homo=homozygous_collector-heterozygous_collector
if logratio_homo>0:
fdout.writelines(line.strip()+'\t'+'\t'.join(['homo',str(logratio_homo),str(homomajor1),str(heteromajor1),str(heteromajor2)])+'\n')
elif logratio_homo<0:
fdout.writelines(line.strip()+'\t'+'\t'.join(['hetero',str(logratio_homo),str(homomajor1),str(heteromajor1),str(heteromajor2)])+'\n')
fd.close()
fdout.close()