Agent skill
bioinformatics-fundamentals
Core bioinformatics concepts including SAM/BAM format, AGP genome assembly format, sequencing technologies (Hi-C, HiFi, Illumina), quality metrics, and common data processing patterns. Essential for debugging alignment, filtering, pairing issues, and AGP coordinate validation.
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npx add-skill https://github.com/Delphine-L/claude_global/tree/main/skills/bioinformatics/fundamentals
SKILL.md
Bioinformatics Fundamentals
Foundation knowledge for genomics and bioinformatics workflows. Provides essential understanding of file formats, sequencing technologies, and common data processing patterns.
When to Use This Skill
- Working with sequencing data (PacBio HiFi, Hi-C, Illumina)
- Debugging SAM/BAM alignment or filtering issues
- Processing AGP files for genome assembly curation
- Validating AGP coordinate systems and unloc assignments
- Understanding paired-end vs single-end data
- Interpreting quality metrics (MAPQ, PHRED scores)
- Troubleshooting empty outputs or broken read pairs
- Accessing GenomeArk QC data (GenomeScope, BUSCO, Merqury)
- Curating karyotype data or chromosome count analysis
- General bioinformatics data analysis
SAM/BAM Format Essentials
SAM Flags (Bitwise)
Flags are additive - a read can have multiple flags set simultaneously.
Common Flags:
0x0001(1): Read is paired in sequencing0x0002(2): Each segment properly aligned (proper pair)0x0004(4): Read unmapped0x0008(8): Mate unmapped0x0010(16): Read mapped to reverse strand0x0020(32): Mate mapped to reverse strand0x0040(64): First in pair (R1/forward)0x0080(128): Second in pair (R2/reverse)0x0100(256): Secondary alignment0x0400(1024): PCR or optical duplicate0x0800(2048): Supplementary alignment
Flag Combinations:
- Properly paired R1:
99(0x63 = 1 + 2 + 32 + 64) - Properly paired R2:
147(0x93 = 1 + 2 + 16 + 128) - Unmapped read:
4 - Mate unmapped:
8
See
reference.mdfor complete flag tables, CIGAR operations, optional tags, and SAM mandatory fields.
Proper Pair Flag (0x0002)
What "proper pair" means:
- Both R1 and R2 are mapped
- Mapping orientations are correct (typically R1 forward, R2 reverse)
- Insert size is reasonable for the library
- Pair conforms to aligner's expectations
Important: Different aligners have different criteria for proper pairs!
MAPQ (Mapping Quality)
Formula: MAPQ = -10 * log10(P(mapping is wrong))
Common Thresholds:
MAPQ >= 60: High confidence (error probability < 0.0001%)MAPQ >= 30: Good quality (error probability < 0.1%)MAPQ >= 20: Acceptable (error probability < 1%)MAPQ >= 10: Low confidence (error probability < 10%)MAPQ = 0: Multi-mapper or unmapped
Note: MAPQ=0 can mean either unmapped OR equally good multiple mappings.
CIGAR String
Represents alignment between read and reference:
M: Match or mismatch (alignment match)I: Insertion in read vs referenceD: Deletion in read vs referenceS: Soft clipping (bases in read not aligned)H: Hard clipping (bases not in read sequence)N: Skipped region (for RNA-seq splicing)
Example: 100M = perfect 100bp match
Example: 50M5I45M = 50bp match, 5bp insertion, 45bp match
Sequencing Technologies
PacBio HiFi (High Fidelity)
Characteristics:
- Long reads: 10-25 kb typical
- High accuracy: >99.9% (Q20+)
- Circular Consensus Sequencing (CCS)
- Single-end data (though from circular molecules)
- Excellent for de novo assembly
Best Mappers:
- minimap2 presets:
map-pb,map-hifi - BWA-MEM2 can work but optimized for short reads
Typical Use Cases:
- De novo genome assembly
- Structural variant detection
- Isoform sequencing (Iso-Seq)
- Haplotype phasing
Hi-C (Chromatin Conformation Capture)
Characteristics:
- Paired-end short reads (typically 100-150 bp)
- Read pairs capture chromatin interactions
- R1 and R2 often map to different scaffolds/chromosomes
- Requires careful proper pair handling
- Used for scaffolding and 3D genome structure
Best Mappers:
- BWA-MEM2 (paired-end mode)
- BWA-MEM (paired-end mode)
Critical Concept: Hi-C read pairs intentionally map to distant loci. Region filtering can easily break pairs!
Typical Use Cases:
- Genome scaffolding (connecting contigs)
- 3D chromatin structure analysis
- Haplotype phasing
- Assembly quality assessment
Illumina Short Reads
Characteristics:
- Short reads: 50-300 bp
- Paired-end or single-end
- High throughput
- Well-established quality scores
Best Mappers:
- BWA-MEM2, BWA-MEM (general purpose)
- Bowtie2 (fast, local alignment)
- STAR (RNA-seq spliced alignment)
See
reference.mdfor detailed technical specs, error profiles, and quality metrics per technology.
Common Tools and Their Behaviors
samtools view
Purpose: Filter, convert, and view SAM/BAM files
Key Flags:
-b: Output BAM format-h: Include header-f INT: Require flags (keep reads WITH these flags)-F INT: Filter flags (remove reads WITH these flags)-q INT: Minimum MAPQ threshold-L FILE: Keep reads overlapping regions in BED file
Important Behavior:
-L(region filtering) checks each read individually, not pairs- Can break read pairs if mates map to different regions
- Flag filters (
-f,-F) are applied before region filters (-L)
Example - Proper pairs in regions (correct order):
samtools view -b -f 2 -L regions.bed input.bam > proper_pairs_in_regions.bam
bamtools filter
Purpose: Advanced filtering with complex criteria
Common Filters:
isPaired: true- Read is from paired-end sequencingisProperPair: true- Read is part of proper pairisMapped: true- Read is mappedmapQuality: >=30- Mapping quality threshold
Important Difference from samtools:
isProperPairis more strict than samtools-f 2- Checks pair validity more thoroughly
samtools fastx
Purpose: Convert SAM/BAM to FASTQ/FASTA
Critical: Use appropriate filters to ensure R1/R2 files match!
See
reference.mdfor complete tool command reference with all options and examples.
Common Patterns and Best Practices
Pattern 1: Filtering Paired-End Data by Regions
WRONG WAY (breaks pairs):
# Region filter first -> breaks pairs when mates are in different regions
samtools view -b -L regions.bed input.bam | bamtools filter -isPaired -isProperPair
# Result: Empty output (all pairs broken)
RIGHT WAY (preserves pairs):
# Proper pair filter FIRST, then region filter
samtools view -b -f 2 -L regions.bed input.bam > output.bam
Pattern 2: Extracting FASTQ from Filtered BAM
For Paired-End:
samtools fastx -1 R1.fq.gz -2 R2.fq.gz \
--i1-flags 2 \ # Require proper pair
input.bam
For Single-End:
samtools fastx -0 output.fq.gz input.bam
Pattern 3: Quality Filtering
Conservative (high quality):
samtools view -b -q 30 -f 2 -F 256 -F 2048 input.bam
# MAPQ >= 30, proper pairs, no secondary/supplementary
Permissive (for low-coverage data):
samtools view -b -q 10 -F 4 input.bam
# MAPQ >= 10, mapped reads
Common Issues Summary
Issue 1: Empty Output After Region Filtering (Hi-C Data)
Region filter (samtools view -L) breaks read pairs. One mate in region, other outside. Proper pair flag lost. Apply proper pair filter BEFORE region filtering:
samtools view -b -f 2 -L regions.bed input.bam > output.bam
Issue 2: R1 and R2 Files Have Different Read Counts
Improper filtering broke some pairs. Require proper pairs during extraction:
samtools fastx -1 R1.fq -2 R2.fq --i1-flags 2 input.bam
Issue 3: Low Mapping Rate for Hi-C Data
This is normal for Hi-C due to chimeric reads. Use Hi-C-specific pipelines (HiC-Pro, Juicer). Don't filter too aggressively on MAPQ.
Issue 4: Proper Pairs Lost After Mapping
Check insert size distribution, reference mismatch, or incorrect orientation flags.
samtools stats input.bam | grep "insert size"
samtools flagstat input.bam
See
common-issues.mdfor comprehensive troubleshooting with detailed solutions, including AGP processing issues, HiFi-specific problems, and diagnostic commands.
Quality Metrics
N50 and Related Metrics
N50: Length of the shortest contig at which 50% of total assembly is contained in contigs of that length or longer
Related Metrics:
- L50: Number of contigs needed to reach N50
- N90: More stringent than N50 (90% coverage)
- NG50: N50 relative to genome size (better for comparisons)
Coverage and Depth
Coverage: Percentage of reference bases covered by at least one read Depth: Average number of reads covering each base
Recommended Depths:
- Genome assembly (HiFi): 30-50x
- Variant calling: 30x minimum
- RNA-seq: 20-40 million reads
- Hi-C scaffolding: 50-100x genomic coverage
See
reference.mdfor complete coverage calculations, BUSCO interpretation, QV scores, and assembly quality metrics.
File Format Quick Reference
FASTA
>sequence_id description
ATCGATCGATCG
- Header line starts with
> - No quality scores
FASTQ
@read_id
ATCGATCGATCG
+
IIIIIIIIIIII
- Four lines per read
- Quality scores (Phred+33 encoding typical)
BED
chr1 1000 2000 feature_name score +
- 0-based coordinates
- Half-open interval [start, end)
AGP
chr1 1 5000 1 W contig_1 1 5000 +
chr1 5001 5100 2 U 100 scaffold yes proximity_ligation
- Tab-delimited genome assembly format
- 1-based closed coordinates [start, end]
- Object and component lengths must match:
obj_end - obj_beg + 1 == comp_end - comp_beg + 1
See
reference.mdfor complete AGP specification, coordinate systems, validation rules, and processing patterns. Seecommon-issues.mdfor AGP coordinate debugging and unloc processing issues.
Coordinate Systems
1-based (SAM, VCF, GFF, AGP): First base is position 1. Interval [2,5] includes positions 2,3,4,5. 0-based (BED, BAM binary): First base is position 0. Interval [2,5) includes positions 2,3,4 (excludes 5).
Conversion: BED_start = SAM_start - 1; BED_end = SAM_end.
Best Practices
General
- Always check data type: Paired-end vs single-end determines filtering strategy
- Understand your sequencing technology: Hi-C behaves differently than HiFi
- Filter in the right order: Proper pairs BEFORE region filtering
- Validate outputs: Check file sizes, read counts, flagstat
- Use appropriate MAPQ thresholds: Too stringent = lost data, too permissive = noise
For Hi-C Data
- Expect distant read pairs: Don't be surprised by different scaffolds
- Preserve proper pairs: Critical for downstream scaffolding
- Use paired-aware tools: Standard filters may break pairs
- Don't over-filter on MAPQ: Hi-C often has lower MAPQ than DNA-seq
For HiFi Data
- Single-end processing: No pair concerns
- High quality expected: Can use strict filters
- Use appropriate presets: minimap2
map-hifiormap-pb - Consider read length distribution: HiFi reads vary in length
For Tool Testing
- Create self-contained datasets: Both mates in selected region
- Maintain proper pairs: Essential for realistic testing
- Use representative data: Subsample proportionally, not randomly
- Verify file sizes: Too small = overly filtered
Related Skills
- vgp-pipeline - VGP workflows process Hi-C and HiFi data
- galaxy-tool-wrapping - Galaxy tools work with SAM/BAM and sequencing data formats
- galaxy-workflow-development - Workflows process sequencing data
Supporting Documentation
- reference.md: Detailed format specifications (SAM/BAM complete reference, CIGAR operations, AGP format, FASTQ encoding, tool command reference, sequencing technology specs, assembly quality metrics, coverage calculations, coordinate systems)
- common-issues.md: Comprehensive troubleshooting guide (empty outputs, paired-end issues, quality/mapping problems, format conversion, Hi-C and HiFi specific issues, AGP processing errors, diagnostic commands)
- genomeark-data-access.md: GenomeArk AWS S3 data access patterns (directory structure evolution, QC data locations for GenomeScope/BUSCO/Merqury, fetching strategies, path normalization, assembly date extraction)
- genomic-analysis-patterns.md: Domain-specific analysis patterns (karyotype data curation, haploid vs diploid chromosome counts, phylogenetic tree species mapping, BED/telomere analysis, NCBI data integration strategies)
Version History
- v1.2.0: Split into SKILL.md + supporting files for maintainability; moved GenomeArk access, karyotype/chromosome analysis, phylogenetic mapping, AGP details, and telomere/NCBI patterns to supporting files
- v1.1.1: Added BED file processing patterns for telomere analysis and NCBI data integration strategies
- v1.1.0: Added comprehensive AGP format documentation including coordinate validation, unloc processing, and common error patterns
- v1.0.0: Initial release with SAM/BAM, Hi-C, HiFi, common filtering patterns
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