In this case study, we describe applying DeepTrio to a real WGS trio. Then we
assess the quality of the DeepTrio variant calls with hap.py. In addition we
evaluate a mendelian violation rate for a merged VCF.
To make it faster to run over this case study, we run only on chromosome 20.
Docker will be used to run DeepTrio and hap.py,
We will be using GRCh38 for this case study.
mkdir -p reference
FTPDIR=ftp://ftp.ncbi.nlm.nih.gov/genomes/all/GCA/000/001/405/GCA_000001405.15_GRCh38/seqs_for_alignment_pipelines.ucsc_ids
curl ${FTPDIR}/GCA_000001405.15_GRCh38_no_alt_analysis_set.fna.gz | gunzip > reference/GRCh38_no_alt_analysis_set.fasta
curl ${FTPDIR}/GCA_000001405.15_GRCh38_no_alt_analysis_set.fna.fai > reference/GRCh38_no_alt_analysis_set.fasta.faiWe will benchmark our variant calls against v4.2.1 of the Genome in a Bottle small variant benchmarks for HG002, HG003, and HG004 trio.
mkdir -p benchmark
FTPDIR=ftp://ftp-trace.ncbi.nlm.nih.gov/giab/ftp/release/AshkenazimTrio
curl ${FTPDIR}/HG002_NA24385_son/NISTv4.2.1/GRCh38/HG002_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed > benchmark/HG002_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed
curl ${FTPDIR}/HG002_NA24385_son/NISTv4.2.1/GRCh38/HG002_GRCh38_1_22_v4.2.1_benchmark.vcf.gz > benchmark/HG002_GRCh38_1_22_v4.2.1_benchmark.vcf.gz
curl ${FTPDIR}/HG002_NA24385_son/NISTv4.2.1/GRCh38/HG002_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbi > benchmark/HG002_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbi
curl ${FTPDIR}/HG003_NA24149_father/NISTv4.2.1/GRCh38/HG003_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed > benchmark/HG003_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed
curl ${FTPDIR}/HG003_NA24149_father/NISTv4.2.1/GRCh38/HG003_GRCh38_1_22_v4.2.1_benchmark.vcf.gz > benchmark/HG003_GRCh38_1_22_v4.2.1_benchmark.vcf.gz
curl ${FTPDIR}/HG003_NA24149_father/NISTv4.2.1/GRCh38/HG003_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbi > benchmark/HG003_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbi
curl ${FTPDIR}/HG004_NA24143_mother/NISTv4.2.1/GRCh38/HG004_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed > benchmark/HG004_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed
curl ${FTPDIR}/HG004_NA24143_mother/NISTv4.2.1/GRCh38/HG004_GRCh38_1_22_v4.2.1_benchmark.vcf.gz > benchmark/HG004_GRCh38_1_22_v4.2.1_benchmark.vcf.gz
curl ${FTPDIR}/HG004_NA24143_mother/NISTv4.2.1/GRCh38/HG004_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbi > benchmark/HG004_GRCh38_1_22_v4.2.1_benchmark.vcf.gz.tbiWe'll use HG002, HG003, HG004 Illumina WGS reads publicly available from the PrecisionFDA Truth v2 Challenge.
mkdir -p input
HTTPDIR=https://storage.googleapis.com/deepvariant/case-study-testdata
curl ${HTTPDIR}/HG002.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam > input/HG002.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam
curl ${HTTPDIR}/HG002.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.bai > input/HG002.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.bai
curl ${HTTPDIR}/HG003.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam > input/HG003.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam
curl ${HTTPDIR}/HG003.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.bai > input/HG003.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.bai
curl ${HTTPDIR}/HG004.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam > input/HG004.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam
curl ${HTTPDIR}/HG004.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.bai > input/HG004.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam.baiDeepTrio pipeline consists of 4 steps: make_examples, call_variants,
postprocess_variants and GLnexus merge. It is possible to run DeepTrio with
one command using the run_deepvariant script. GLnexus is run as a separate
command.
mkdir -p output
mkdir -p output/intermediate_results_dir
BIN_VERSION=1.2.0
time sudo docker run \
-v "${PWD}/input":"/input" \
-v "${PWD}/output":"/output" \
-v "${PWD}/reference":"/reference" \
google/deepvariant:deeptrio-"${BIN_VERSION}" \
/opt/deepvariant/bin/deeptrio/run_deeptrio \
--model_type WGS \
--ref /reference/GRCh38_no_alt_analysis_set.fasta \
--reads_child /input/HG002.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam \
--reads_parent1 /input/HG003.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam \
--reads_parent2 /input/HG004.novaseq.pcr-free.35x.dedup.grch38_no_alt.chr20.bam \
--output_vcf_child /output/HG002.output.vcf.gz \
--output_vcf_parent1 /output/HG003.output.vcf.gz \
--output_vcf_parent2 /output/HG004.output.vcf.gz \
--sample_name_child 'HG002' \
--sample_name_parent1 'HG003' \
--sample_name_parent2 'HG004' \
--num_shards $(nproc) \
--regions chr20 \
--intermediate_results_dir /output/intermediate_results_dir \
--output_gvcf_child /output/HG002.g.vcf.gz \
--output_gvcf_parent1 /output/HG003.g.vcf.gz \
--output_gvcf_parent2 /output/HG004.g.vcf.gzBy specifying --model_type WGS, you'll be using a model that is best suited
for Illumina Whole Genome Sequencing data.
--intermediate_results_dir flag is optional. By specifying it, the
intermediate outputs of make_examples and call_variants stages can be found
in the directory. After the command, you can find these files in the directory:
call_variants_output_child.tfrecord.gz
call_variants_output_parent1.tfrecord.gz
call_variants_output_parent2.tfrecord.gz
gvcf_child.tfrecord-?????-of-?????.gz
gvcf_parent1.tfrecord-?????-of-?????.gz
gvcf_parent2.tfrecord-?????-of-?????.gz
make_examples_child.tfrecord-?????-of-?????.gz
make_examples_parent1.tfrecord-?????-of-?????.gz
make_examples_parent2.tfrecord-?????-of-?????.gz
For running on GPU machines, or using Singularity instead of Docker, see Quick Start.
At this step we take all 3 VCFs generated in the previous step and merge them using GLnexus.
# bcftools and bgzip are now included in our docker images.
# You can also install them separately.
sudo docker run \
-v "${PWD}/output":"/output" \
quay.io/mlin/glnexus:v1.2.7 \
/usr/local/bin/glnexus_cli \
--config DeepVariant_unfiltered \
/output/HG002.g.vcf.gz \
/output/HG003.g.vcf.gz \
/output/HG004.g.vcf.gz \
| sudo docker run -i google/deepvariant:deeptrio-"${BIN_VERSION}" \
bcftools view - \
| sudo docker run -i google/deepvariant:deeptrio-"${BIN_VERSION}" \
bgzip -c > output/HG002_trio_merged.vcf.gzAfter completion of GLnexus command we should have a new merged VCF file in the output directory.
HG002_trio_merged.vcf.gz
sudo docker run \
-v "${PWD}/input":"/input" \
-v "${PWD}/reference":"/reference" \
realtimegenomics/rtg-tools format \
-o /reference/GRCh38_no_alt_analysis_set.sdf "/reference/GRCh38_no_alt_analysis_set.fasta"
FILE="reference/trio.ped"
cat <<EOM >$FILE
#PED format pedigree
#
#fam-id/ind-id/pat-id/mat-id: 0=unknown
#sex: 1=male; 2=female; 0=unknown
#phenotype: -9=missing, 0=missing; 1=unaffected; 2=affected
#
#fam-id ind-id pat-id mat-id sex phen
1 HG002 HG003 HG004 1 0
1 HG003 0 0 1 0
1 HG004 0 0 2 0
EOM
sudo docker run \
-v "${PWD}/input":"/input" \
-v "${PWD}/reference":"/reference" \
-v "${PWD}/output":"/output" \
realtimegenomics/rtg-tools mendelian \
-i "/output/HG002_trio_merged.vcf.gz" \
-o "/output/HG002_trio_annotated.output.vcf.gz" \
--pedigree=/reference/trio.ped \
-t /reference/GRCh38_no_alt_analysis_set.sdf \
| tee output/deepvariant.input_rtg_output.txtAs a result we should get the following output:
Checking: /output/HG002_trio_merged.vcf.gz
Family: [HG003 + HG004] -> [HG002]
88 non-pass records were skipped
Concordance HG002: F:137408/138897 (98.93%) M:137499/139053 (98.88%) F+M:134869/137469 (98.11%)
Sample HG002 has less than 99.0 concordance with both parents. Check for incorrect pedigree or sample mislabelling.
0/144316 (0.00%) records did not conform to expected call ploidy
141761/144316 (98.23%) records were variant in at least 1 family member and checked for Mendelian constraints
3781/141761 (2.67%) records had indeterminate consistency status due to incomplete calls
2973/141761 (2.10%) records contained a violation of Mendelian constraintsmkdir -p happy
sudo docker pull jmcdani20/hap.py:v0.3.12
sudo docker run \
-v "${PWD}/benchmark":"/benchmark" \
-v "${PWD}/input":"/input" \
-v "${PWD}/output":"/output" \
-v "${PWD}/reference":"/reference" \
-v "${PWD}/happy:/happy" \
jmcdani20/hap.py:v0.3.12 /opt/hap.py/bin/hap.py \
/benchmark/HG002_GRCh38_1_22_v4.2.1_benchmark.vcf.gz \
/output/HG002.output.vcf.gz \
-f /benchmark/HG002_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed \
-r /reference/GRCh38_no_alt_analysis_set.fasta \
-o /happy/HG002.output \
--engine=vcfeval \
--pass-only \
-l chr20
sudo docker run \
-v "${PWD}/benchmark":"/benchmark" \
-v "${PWD}/input":"/input" \
-v "${PWD}/output":"/output" \
-v "${PWD}/reference":"/reference" \
-v "${PWD}/happy:/happy" \
jmcdani20/hap.py:v0.3.12 /opt/hap.py/bin/hap.py \
/benchmark/HG003_GRCh38_1_22_v4.2.1_benchmark.vcf.gz \
/output/HG003.output.vcf.gz \
-f /benchmark/HG003_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed \
-r /reference/GRCh38_no_alt_analysis_set.fasta \
-o /happy/HG003.output \
--engine=vcfeval \
--pass-only \
-l chr20
sudo docker run \
-v "${PWD}/benchmark":"/benchmark" \
-v "${PWD}/input":"/input" \
-v "${PWD}/output":"/output" \
-v "${PWD}/reference":"/reference" \
-v "${PWD}/happy:/happy" \
jmcdani20/hap.py:v0.3.12 /opt/hap.py/bin/hap.py \
/benchmark/HG004_GRCh38_1_22_v4.2.1_benchmark.vcf.gz \
/output/HG004.output.vcf.gz \
-f /benchmark/HG004_GRCh38_1_22_v4.2.1_benchmark_noinconsistent.bed \
-r /reference/GRCh38_no_alt_analysis_set.fasta \
-o /happy/HG004.output \
--engine=vcfeval \
--pass-only \
-l chr20Benchmarking Summary for HG002:
Type Filter TRUTH.TOTAL TRUTH.TP TRUTH.FN QUERY.TOTAL QUERY.FP QUERY.UNK FP.gt FP.al METRIC.Recall METRIC.Precision METRIC.Frac_NA METRIC.F1_Score TRUTH.TOTAL.TiTv_ratio QUERY.TOTAL.TiTv_ratio TRUTH.TOTAL.het_hom_ratio QUERY.TOTAL.het_hom_ratio
INDEL ALL 11256 11209 47 21263 16 9608 10 5 0.995824 0.998627 0.451865 0.997224 NaN NaN 1.561710 2.080149
INDEL PASS 11256 11209 47 21263 16 9608 10 5 0.995824 0.998627 0.451865 0.997224 NaN NaN 1.561710 2.080149
SNP ALL 71333 71064 269 87387 28 16241 4 3 0.996229 0.999606 0.185851 0.997915 2.314904 2.051794 1.715978 1.714224
SNP PASS 71333 71064 269 87387 28 16241 4 3 0.996229 0.999606 0.185851 0.997915 2.314904 2.051794 1.715978 1.714224
Benchmarking Summary for HG003:
Type Filter TRUTH.TOTAL TRUTH.TP TRUTH.FN QUERY.TOTAL QUERY.FP QUERY.UNK FP.gt FP.al METRIC.Recall METRIC.Precision METRIC.Frac_NA METRIC.F1_Score TRUTH.TOTAL.TiTv_ratio QUERY.TOTAL.TiTv_ratio TRUTH.TOTAL.het_hom_ratio QUERY.TOTAL.het_hom_ratio
INDEL ALL 10628 10585 43 21048 17 9989 13 4 0.995954 0.998463 0.474582 0.997207 NaN NaN 1.748961 2.252744
INDEL PASS 10628 10585 43 21048 17 9989 13 4 0.995954 0.998463 0.474582 0.997207 NaN NaN 1.748961 2.252744
SNP ALL 70166 69928 238 85200 46 15188 18 1 0.996608 0.999343 0.178263 0.997974 2.296566 2.068887 1.883951 1.875224
SNP PASS 70166 69928 238 85200 46 15188 18 1 0.996608 0.999343 0.178263 0.997974 2.296566 2.068887 1.883951 1.875224
Benchmarking Summary for HG004:
Type Filter TRUTH.TOTAL TRUTH.TP TRUTH.FN QUERY.TOTAL QUERY.FP QUERY.UNK FP.gt FP.al METRIC.Recall METRIC.Precision METRIC.Frac_NA METRIC.F1_Score TRUTH.TOTAL.TiTv_ratio QUERY.TOTAL.TiTv_ratio TRUTH.TOTAL.het_hom_ratio QUERY.TOTAL.het_hom_ratio
INDEL ALL 11000 10952 48 21460 23 9999 17 4 0.995636 0.997993 0.465937 0.996813 NaN NaN 1.792709 2.324350
INDEL PASS 11000 10952 48 21460 23 9999 17 4 0.995636 0.997993 0.465937 0.996813 NaN NaN 1.792709 2.324350
SNP ALL 71659 71426 233 86296 46 14774 12 5 0.996748 0.999357 0.171201 0.998051 2.310073 2.070677 1.878340 1.772242
SNP PASS 71659 71426 233 86296 46 14774 12 5 0.996748 0.999357 0.171201 0.998051 2.310073 2.070677 1.878340 1.772242