ReddRadar
Agent skill
bio-metagenomics-metaphlan
Marker gene-based taxonomic profiling using MetaPhlAn 4. Provides accurate species-level relative abundances using clade-specific markers. Use when accurate taxonomic profiling is needed and computational resources are limited, or for comparison with HMP/other MetaPhlAn studies.
Install this agent skill to your Project
npx add-skill https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills/tree/main/skills/bio-metagenomics-metaphlan
SKILL.md
Version Compatibility
Reference examples tested with: Bowtie2 2.5.3+, MetaPhlAn 4.1+, minimap2 2.26+, pandas 2.2+, scanpy 1.10+
Before using code patterns, verify installed versions match. If versions differ:
- Python:
pip show <package>thenhelp(module.function)to check signatures - CLI:
<tool> --versionthen<tool> --helpto confirm flags
If code throws ImportError, AttributeError, or TypeError, introspect the installed package and adapt the example to match the actual API rather than retrying.
MetaPhlAn 4 Profiling
"Profile the species composition of my metagenome" → Determine species-level relative abundances from shotgun metagenomic reads using clade-specific marker gene alignment.
- CLI:
metaphlan sample.fastq --input_type fastq -o profile.txt
MetaPhlAn 4 uses ~5M clade-specific markers from 26,970 species-level genome bins. Supports both short reads (bowtie2) and long reads (minimap2).
Basic Profiling
# Profile single sample
metaphlan sample.fastq.gz \
--input_type fastq \
--output_file profile.txt
Paired-End Reads
# MetaPhlAn processes PE as single file or concatenated
metaphlan reads_R1.fastq.gz,reads_R2.fastq.gz \
--input_type fastq \
--output_file profile.txt \
--mapout sample.map.bz2
Save Mapping Output for Reuse
# First run - save intermediate mapping
metaphlan sample.fastq.gz \
--input_type fastq \
--mapout sample.map.bz2 \
--output_file profile.txt
# Rerun with different settings without realigning
metaphlan sample.map.bz2 \
--input_type mapout \
--output_file profile_v2.txt
Long-Read Support (MetaPhlAn 4+)
# Long reads automatically use minimap2 instead of bowtie2
metaphlan long_reads.fastq.gz \
--input_type fastq \
--output_file profile.txt
Common Options
metaphlan sample.fastq.gz \
--input_type fastq \
--nproc 8 \ # CPU threads
--tax_lev s \ # Taxonomic level (k,p,c,o,f,g,s,t)
--min_cu_len 2000 \ # Min total nucleotide length
--stat_q 0.2 \ # Quantile for robust average
--output_file profile.txt \
--mapout sample.map.bz2
Install Database
# Download database (done automatically on first run)
metaphlan --install
# Or specify database location
metaphlan --install --db_dir /path/to/db
Analysis Types
# Relative abundances (default)
metaphlan sample.fastq.gz --input_type fastq -t rel_ab
# Relative abundances with read counts
metaphlan sample.fastq.gz --input_type fastq -t rel_ab_w_read_stats
# Marker presence/absence
metaphlan sample.fastq.gz --input_type fastq -t marker_pres_table
# Marker abundances
metaphlan sample.fastq.gz --input_type fastq -t marker_ab_table
Multiple Samples
# Process each sample
for fq in samples/*.fastq.gz; do
sample=$(basename $fq .fastq.gz)
metaphlan $fq \
--input_type fastq \
--nproc 4 \
--output_file profiles/${sample}_profile.txt \
--mapout mapout/${sample}.map.bz2
done
# Merge profiles
merge_metaphlan_tables.py profiles/*_profile.txt > merged_abundance.txt
Filter by Taxonomic Level
# Species only
metaphlan sample.fastq.gz --input_type fastq --tax_lev s -o species.txt
# Genus only
metaphlan sample.fastq.gz --input_type fastq --tax_lev g -o genus.txt
# All levels (default)
metaphlan sample.fastq.gz --input_type fastq --tax_lev a -o all_levels.txt
Output Format
#SampleID sample
#clade_name relative_abundance
k__Bacteria 100.0
k__Bacteria|p__Proteobacteria 65.23
k__Bacteria|p__Proteobacteria|c__Gammaproteobacteria 62.15
k__Bacteria|p__Proteobacteria|c__Gammaproteobacteria|o__Enterobacterales 58.42
k__Bacteria|p__Proteobacteria|c__Gammaproteobacteria|o__Enterobacterales|f__Enterobacteriaceae 55.21
k__Bacteria|p__Proteobacteria|c__Gammaproteobacteria|o__Enterobacterales|f__Enterobacteriaceae|g__Escherichia 52.33
k__Bacteria|p__Proteobacteria|c__Gammaproteobacteria|o__Enterobacterales|f__Enterobacteriaceae|g__Escherichia|s__Escherichia_coli 52.33
Parse Output in Python
import pandas as pd
profile = pd.read_csv('profile.txt', sep='\t', comment='#', header=None,
names=['clade', 'abundance'])
species = profile[profile['clade'].str.contains('\\|s__')]
species['species'] = species['clade'].str.split('|').str[-1].str.replace('s__', '')
species.sort_values('abundance', ascending=False).head(20)
Extract SGBs (Strain-level)
# Include strain-level genomic bins
metaphlan sample.fastq.gz \
--input_type fastq \
--tax_lev t \ # Include t__ level (SGBs)
--output_file profile_with_sgb.txt
Sample Metadata in Output
# Add sample ID to output
metaphlan sample.fastq.gz \
--input_type fastq \
--sample_id sample_name \
--output_file profile.txt
Key Parameters
| Parameter | Default | Description |
|---|---|---|
| --input_type | fastq | Input format (fastq, mapout) |
| --nproc | 4 | CPU threads |
| --tax_lev | a | Taxonomic level (a=all) |
| --stat_q | 0.2 | Quantile value |
| --min_cu_len | 2000 | Min clade length |
| -t | rel_ab | Analysis type |
| --mapout | none | Save mapping output |
| --db_dir | default | Database directory |
Note: Unknown species estimation is now enabled by default in MetaPhlAn 4.2+
Analysis Types (-t)
| Type | Description |
|---|---|
| rel_ab | Relative abundances (%) |
| rel_ab_w_read_stats | With read statistics |
| marker_pres_table | Marker presence/absence |
| marker_ab_table | Marker abundances |
| clade_specific_strain_tracker | Strain tracking |
Related Skills
- kraken-classification - Alternative k-mer based classification
- abundance-estimation - Bracken for Kraken2 abundances
- metagenome-visualization - Visualize profiles
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