--- name: bio-workflows-fastq-to-variants description: End-to-end DNA sequencing workflow from FASTQ files to variant calls. Covers QC, alignment with BWA, BAM processing, and variant calling with bcftools or GATK HaplotypeCaller. Use when calling variants from raw sequencing reads. tool_type: cli primary_tool: bcftools workflow: true depends_on: - read-qc/fastp-workflow - read-alignment/bwa-alignment - alignment-files/alignment-sorting - alignment-files/duplicate-handling - variant-calling/variant-calling - variant-calling/vcf-filtering qc_checkpoints: - after_qc: "Q30 >85%, adapter content <1%" - after_alignment: "Mapping rate >95%, properly paired >90%" - after_dedup: "Duplication rate <30% for WGS, <50% for exome" - after_calling: "Ti/Tv ratio ~2.1 for WGS, dbSNP overlap >95%" --- # FASTQ to Variants Workflow Complete pipeline from raw DNA sequencing FASTQ files to filtered variant calls. ## Workflow Overview ``` FASTQ files | v [1. QC & Trimming] -----> fastp | v [2. Alignment] ---------> bwa-mem2 | v [3. BAM Processing] ----> sort, markdup, index | v [4. Variant Calling] ---> bcftools (primary) or GATK | v [5. Filtering] ---------> Quality filters | v Filtered VCF ``` ## Primary Path: BWA + bcftools ### Step 1: Quality Control with fastp ```bash # Single sample fastp -i sample_R1.fastq.gz -I sample_R2.fastq.gz \ -o sample_R1.trimmed.fq.gz -O sample_R2.trimmed.fq.gz \ --detect_adapter_for_pe \ --qualified_quality_phred 20 \ --length_required 50 \ --html sample_fastp.html # Batch processing for sample in sample1 sample2 sample3; do fastp -i ${sample}_R1.fastq.gz -I ${sample}_R2.fastq.gz \ -o trimmed/${sample}_R1.fq.gz -O trimmed/${sample}_R2.fq.gz \ --detect_adapter_for_pe \ --html qc/${sample}_fastp.html done ``` **QC Checkpoint 1:** Check fastp reports - Q30 bases >85% (DNA typically higher quality than RNA) - Adapter content <1% - No unusual GC distribution ### Step 2: BWA-MEM2 Alignment ```bash # Index reference (once) bwa-mem2 index reference.fa # Align with read group info for sample in sample1 sample2 sample3; do bwa-mem2 mem -t 8 \ -R "@RG\tID:${sample}\tSM:${sample}\tPL:ILLUMINA\tLB:lib1" \ reference.fa \ trimmed/${sample}_R1.fq.gz \ trimmed/${sample}_R2.fq.gz \ | samtools view -bS - > aligned/${sample}.bam done ``` **QC Checkpoint 2:** Check alignment stats ```bash samtools flagstat aligned/${sample}.bam ``` - Mapped reads >95% - Properly paired >90% ### Step 3: BAM Processing ```bash for sample in sample1 sample2 sample3; do # Sort by coordinate samtools sort -@ 8 -o aligned/${sample}.sorted.bam aligned/${sample}.bam # Mark duplicates (samtools method) samtools fixmate -m aligned/${sample}.sorted.bam - | \ samtools sort -@ 8 - | \ samtools markdup -@ 8 - aligned/${sample}.markdup.bam # Index samtools index aligned/${sample}.markdup.bam # Cleanup intermediate rm aligned/${sample}.bam aligned/${sample}.sorted.bam done ``` **QC Checkpoint 3:** Check duplication rate ```bash samtools flagstat aligned/${sample}.markdup.bam | grep "duplicates" ``` - WGS: <30% duplicates - Exome/targeted: <50% duplicates ### Step 4: Variant Calling with bcftools ```bash # Single sample calling bcftools mpileup -Ou -f reference.fa aligned/sample1.markdup.bam | \ bcftools call -mv -Oz -o variants/sample1.vcf.gz # Multi-sample calling (joint calling) bcftools mpileup -Ou -f reference.fa \ aligned/sample1.markdup.bam \ aligned/sample2.markdup.bam \ aligned/sample3.markdup.bam | \ bcftools call -mv -Oz -o variants/cohort.vcf.gz bcftools index variants/cohort.vcf.gz ``` ### Step 5: Variant Filtering ```bash # Basic quality filter bcftools filter -Oz \ -e 'QUAL<20 || DP<10 || MQ<30' \ -o variants/cohort.filtered.vcf.gz \ variants/cohort.vcf.gz # More stringent filter bcftools filter -Oz \ -e 'QUAL<30 || DP<10 || DP>200 || MQ<40 || MQB<0.1' \ -s "LowQual" \ -o variants/cohort.filtered.vcf.gz \ variants/cohort.vcf.gz # Stats bcftools stats variants/cohort.filtered.vcf.gz > variants/vcf_stats.txt ``` **QC Checkpoint 4:** Check variant stats - Ti/Tv ratio ~2.1 for whole genome - Ti/Tv ratio ~2.8-3.0 for exome - >95% overlap with dbSNP for known sites ## Alternative Path: BWA + GATK HaplotypeCaller ### Step 4 Alternative: GATK Variant Calling ```bash # Create sequence dictionary (once) gatk CreateSequenceDictionary -R reference.fa # Index reference (once) samtools faidx reference.fa # Base Quality Score Recalibration (BQSR) gatk BaseRecalibrator \ -R reference.fa \ -I aligned/sample1.markdup.bam \ --known-sites dbsnp.vcf.gz \ -O recal_data.table gatk ApplyBQSR \ -R reference.fa \ -I aligned/sample1.markdup.bam \ --bqsr-recal-file recal_data.table \ -O aligned/sample1.recal.bam # HaplotypeCaller (per-sample GVCF mode) gatk HaplotypeCaller \ -R reference.fa \ -I aligned/sample1.recal.bam \ -O variants/sample1.g.vcf.gz \ -ERC GVCF # Joint genotyping (for multiple samples) gatk GenomicsDBImport \ -V variants/sample1.g.vcf.gz \ -V variants/sample2.g.vcf.gz \ -V variants/sample3.g.vcf.gz \ --genomicsdb-workspace-path genomicsdb \ -L intervals.bed gatk GenotypeGVCFs \ -R reference.fa \ -V gendb://genomicsdb \ -O variants/cohort.vcf.gz ``` ### Step 5 Alternative: GATK Variant Filtering ```bash # Hard filtering (for small cohorts) gatk VariantFiltration \ -R reference.fa \ -V variants/cohort.vcf.gz \ --filter-expression "QD < 2.0" --filter-name "LowQD" \ --filter-expression "FS > 60.0" --filter-name "HighFS" \ --filter-expression "MQ < 40.0" --filter-name "LowMQ" \ --filter-expression "MQRankSum < -12.5" --filter-name "LowMQRS" \ --filter-expression "ReadPosRankSum < -8.0" --filter-name "LowRPRS" \ -O variants/cohort.filtered.vcf.gz # VQSR (for large cohorts >30 samples) gatk VariantRecalibrator \ -R reference.fa \ -V variants/cohort.vcf.gz \ --resource:hapmap,known=false,training=true,truth=true,prior=15.0 hapmap.vcf.gz \ --resource:omni,known=false,training=true,truth=false,prior=12.0 omni.vcf.gz \ --resource:1000G,known=false,training=true,truth=false,prior=10.0 1000G.vcf.gz \ --resource:dbsnp,known=true,training=false,truth=false,prior=2.0 dbsnp.vcf.gz \ -an QD -an MQ -an MQRankSum -an ReadPosRankSum -an FS -an SOR \ -mode SNP \ -O cohort.snp.recal \ --tranches-file cohort.snp.tranches gatk ApplyVQSR \ -R reference.fa \ -V variants/cohort.vcf.gz \ -O variants/cohort.vqsr.vcf.gz \ --recal-file cohort.snp.recal \ --tranches-file cohort.snp.tranches \ -mode SNP \ --truth-sensitivity-filter-level 99.5 ``` ## Parameter Recommendations | Step | Parameter | WGS | Exome/Targeted | |------|-----------|-----|----------------| | bwa-mem2 | -t | 8-16 | 8 | | samtools markdup | - | Required | Required | | bcftools mpileup | -d | 250 (default) | 1000 | | bcftools mpileup | -q | 20 | 20 | | bcftools filter | QUAL | >20 | >30 | | bcftools filter | DP | >10, <2x mean | >20 | | GATK | intervals | - | Target BED | ## Choosing Between bcftools and GATK | Criterion | bcftools | GATK | |-----------|----------|------| | Speed | Faster | Slower | | Memory | Lower | Higher | | Best for | Germline SNPs/indels | Germline, somatic | | Cohort size | Any | Scales well | | BQSR | Not supported | Recommended | | VQSR | Not supported | For large cohorts | ## Troubleshooting | Issue | Likely Cause | Solution | |-------|--------------|----------| | Low mapping rate | Wrong reference, contamination | Verify reference genome version | | High duplication | PCR over-amplification, low input | Check library prep, may need more input DNA | | Low Ti/Tv | False positives | Increase quality filters | | Missing variants | Too stringent filters, low depth | Relax filters, check coverage | | Many indels at homopolymers | Sequencing errors | Filter homopolymer regions | ## Complete Pipeline Script ```bash #!/bin/bash set -e # Configuration THREADS=8 REF="reference.fa" SAMPLES="sample1 sample2 sample3" OUTDIR="results" mkdir -p ${OUTDIR}/{trimmed,aligned,variants,qc} echo "=== Step 1: QC with fastp ===" for sample in $SAMPLES; do fastp -i ${sample}_R1.fastq.gz -I ${sample}_R2.fastq.gz \ -o ${OUTDIR}/trimmed/${sample}_R1.fq.gz \ -O ${OUTDIR}/trimmed/${sample}_R2.fq.gz \ --detect_adapter_for_pe \ --html ${OUTDIR}/qc/${sample}_fastp.html \ -w ${THREADS} done echo "=== Step 2: Alignment with bwa-mem2 ===" for sample in $SAMPLES; do bwa-mem2 mem -t ${THREADS} \ -R "@RG\tID:${sample}\tSM:${sample}\tPL:ILLUMINA" \ ${REF} \ ${OUTDIR}/trimmed/${sample}_R1.fq.gz \ ${OUTDIR}/trimmed/${sample}_R2.fq.gz | \ samtools view -@ ${THREADS} -bS - > ${OUTDIR}/aligned/${sample}.bam done echo "=== Step 3: BAM Processing ===" for sample in $SAMPLES; do samtools fixmate -@ ${THREADS} -m ${OUTDIR}/aligned/${sample}.bam - | \ samtools sort -@ ${THREADS} - | \ samtools markdup -@ ${THREADS} - ${OUTDIR}/aligned/${sample}.markdup.bam samtools index ${OUTDIR}/aligned/${sample}.markdup.bam rm ${OUTDIR}/aligned/${sample}.bam done echo "=== Step 4: Joint Variant Calling ===" bcftools mpileup -Ou -f ${REF} ${OUTDIR}/aligned/*.markdup.bam | \ bcftools call -mv -Oz -o ${OUTDIR}/variants/cohort.vcf.gz bcftools index ${OUTDIR}/variants/cohort.vcf.gz echo "=== Step 5: Filtering ===" bcftools filter -Oz \ -e 'QUAL<20 || DP<10 || MQ<30' \ -o ${OUTDIR}/variants/cohort.filtered.vcf.gz \ ${OUTDIR}/variants/cohort.vcf.gz bcftools index ${OUTDIR}/variants/cohort.filtered.vcf.gz echo "=== Stats ===" bcftools stats ${OUTDIR}/variants/cohort.filtered.vcf.gz > ${OUTDIR}/variants/stats.txt echo "=== Pipeline Complete ===" echo "Filtered VCF: ${OUTDIR}/variants/cohort.filtered.vcf.gz" ``` ## Related Skills - read-qc/fastp-workflow - Detailed QC options - read-alignment/bwa-alignment - BWA-MEM2 parameters - alignment-files/duplicate-handling - Duplicate marking details - variant-calling/variant-calling - bcftools calling options - variant-calling/gatk-variant-calling - GATK HaplotypeCaller details - variant-calling/vcf-filtering - Advanced filtering strategies - variant-calling/variant-annotation - Annotate variants with VEP