Monday, November 18, 2013

IBD pipeline

There are a lot of interesting analyses that segments inherited identical-by-descent (IBD) can be informative for. However, it takes some steps to setup a fully functional IBD pipeline. Here is a basic one that will work with any dataset in binary plink format. It will first phase the data with hapi-ur, then detect IBD segments using beagle, and finally detect clusters of IBD individuals using dash.

To begin with, you need to setup a few variables:
hpr="%DIRECTORY WITH HAPI-UR BINARY FILES%"
gmp="%DIRECTORY WITH GENETIC MAP FILES%"
bgl="%DIRECTORY WITH BEAGLE BINARY FILE%"
dsh="%DIRECTORY WITH DASH BINARY FILE%"
set="%PLINK DATASET PREFIX%"

And have a couple of programs pre-installed on your Linux machine:
# install plink
sudo apt-get install plink

# install hapi-ur
wget https://hapi-ur.googlecode.com/files/hapi-ur-1.01.tgz
tar xzvf hapi-ur-1.01.tgz
mkdir -p $hpr
/bin/cp hapi-ur-1.01/hapi-ur hapi-ur-1.01/insert-map.pl $hpr/

# install genetic maps
wget http://mathgen.stats.ox.ac.uk/impute/genetic_maps_b37.tgz
tar xzvf genetic_maps_b37.tgz
mkdir -p $gmp
for i in {1..22} X_PAR1 X_nonPAR X_PAR2; do gzip -c genetic_maps_b37/genetic_map_chr${i}_combined_b37.txt > $gmp/chr$i.gmap.gz; done

# install beagle
mkdir -p $bgl
wget http://faculty.washington.edu/browning/beagle/b4.r1196.jar -P $bgl/

# install dash
wget http://www1.cs.columbia.edu/~gusev/dash/dash-1-1.tar.gz
tar xzvf dash-1-1.tar.gz
mkdir -p $dsh
/bin/cp dash-1-1/bin/dash_cc $dsh/

The following pipeline will run the analysis independently on each autosome:
# perform IBD and DASH analysis separately for each autosome
for i in {1..22}; do
  # create a directory
  mkdir -p chr$i

  # extract autosome of interest
  p-link --noweb --bfile $set --chr $i --make-bed --out chr$i/$set

  # generate marker file with genetic distance
  zcat $gmp/chr$i.gmap.gz | $hpr/insert-map.pl chr$i/$set.bim - | awk -v OFS="\t" \
    'length($5)>1 || $6=="-" {$5="I"; $6="D"} $5=="-" || length($6)>1 {$5="D"; $6="I"} {print $1,$2,$3,$4,$5,$6}' > chr$i/$set.gmap.bim

  # clean up just in case
  /bin/rm chr$i/$set.sample chr$i/$set.haps

  # phase haplotypes using hapi-ur
  $hpr/hapi-ur -g chr$i/$set.bed -s chr$i/$set.gmap.bim -i chr$i/$set.fam -w 73 --impute -o chr$i/$set

  # convert hapi-ur output for use with beagle
  (echo "##fileformat=VCFv4.1";
  echo "##FORMAT=";
  echo -en "#CHROM\tPOS\tID\tREF\tALT\tQUAL\tFILTER\tINFO\tFORMAT\t";
  awk 'NR>2 {printf $1"."$2"\t"}' chr$i/$set.sample | sed 's/\t$/\n/g';
  awk -v c=$i '{printf c"\t"$3"\t"$2"\t"$4"\t"$5"\t.\tPASS\t.\tGT";
    for (i=6; i<NF; i+=2) printf "\t"$i"|"$(i+1); printf "\n"}' chr$i/$set.haps) |
    java -Xmx3g -jar $bgl/b4.r1185.jar ibd=true gt=/dev/stdin usephase=true burnin-its=0 phase-its=0 out=chr$i/$set

  # convert beagle output for use with DASH
  awk '{sub("\\\."," ",$1); sub("\\\."," ",$3); print $1"."$2-1,$3"."$4-1,$6,$7}' chr$i/$set.hbd chr$i/$set.ibd |
    $dsh/dash_cc chr$i/$set.fam chr$i/$set

  # create map file with IBD clusters
  cut -f1-5 chr$i/$set.clst | awk -v c=$i '{ print c,c"_"$1,$2,$3,$4,$5 }' > chr$i/$set.cmap

  # create map file with IBD clusters for use with plink
  awk -v c=$i '{ print c,$2,0,int(($3+$4)/2) }' chr$i/$set.cmap > chr$i/$set.map

  # convert output to plink binary format
  p-link --maf 0.001 --file chr$i/$set --make-bed --recode --out chr$i/$set
done

You can then join the results in a single plink binary file using the code discussed in a previous post:
# join separate autosome outputs into a single plink binary file
for i in {1..22}; do cat chr$i/$set.cmap; done > $set.dash.cmap
cp $set.fam $set.dash.fam
for i in {1..22}; do cat chr$i/$set.bim; done > $set.dash.bim
(echo -en "\x6C\x1B\x01"; for i in {1..22}; do tail -c +4 chr$i/$set.bed; done) > $set.dash.bed

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