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Claude-skill-registry-data microbiome-cancer-agent

name: microbiome-cancer-agent

install
source · Clone the upstream repo
git clone https://github.com/majiayu000/claude-skill-registry-data
Claude Code · Install into ~/.claude/skills/
T=$(mktemp -d) && git clone --depth=1 https://github.com/majiayu000/claude-skill-registry-data "$T" && mkdir -p ~/.claude/skills && cp -r "$T/data/microbiome-cancer-agent" ~/.claude/skills/majiayu000-claude-skill-registry-data-microbiome-cancer-agent && rm -rf "$T"
manifest: data/microbiome-cancer-agent/SKILL.md
source content

---name: microbiome-cancer-agent description: AI-powered analysis of microbiome-cancer interactions including tumor microbiome profiling, immunotherapy response prediction, and microbiome-targeted therapeutic opportunities. license: MIT metadata: author: AI Group version: "1.0.0" created: "2026-01-19" compatibility:

  • system: Python 3.10+ allowed-tools:
  • run_shell_command
  • read_file
  • write_file

keywords:

  • microbiome-cancer-agent
  • automation
  • biomedical measurable_outcome: execute task with >95% success rate. ---"

Microbiome-Cancer Interaction Agent

The Microbiome-Cancer Interaction Agent analyzes relationships between the microbiome and cancer, including tumor-associated bacteria, gut microbiome effects on immunotherapy, and microbiome-targeted therapeutic strategies.

When to Use This Skill

  • When analyzing tumor microbiome composition from sequencing data.
  • To predict immunotherapy response based on gut microbiome profiles.
  • For identifying microbiome-based biomarkers in cancer.
  • When assessing antibiotic impact on cancer treatment efficacy.
  • To design microbiome-modulating therapeutic interventions.

Core Capabilities

  1. Tumor Microbiome Analysis: Profile intratumoral bacteria from tumor sequencing data.

  2. Gut-Cancer Axis: Analyze fecal microbiome associations with cancer outcomes.

  3. ICI Response Prediction: Predict checkpoint inhibitor response from microbiome.

  4. Metabolite Profiling: Link microbial metabolites to cancer phenotypes.

  5. Antibiotic Impact: Model antibiotic effects on treatment efficacy.

  6. FMT/Probiotic Design: Support microbiome-modulating interventions.

Microbiome-Cancer Associations

Cancer TypeKey BacteriaAssociation
ColorectalFusobacterium nucleatumPromotion, poor prognosis
ColorectalBacteroides fragilis (ETBF)Carcinogenesis
GastricHelicobacter pyloriEstablished carcinogen
PancreaticGammaproteobacteriaDrug metabolism
BreastFusobacteriumMetastasis
OralPorphyromonas gingivalisOral SCC

Workflow

  1. Input: 16S/shotgun metagenomics, tumor sequencing, clinical data.

  2. Taxonomy Profiling: Identify bacterial composition at genus/species level.

  3. Diversity Analysis: Calculate alpha and beta diversity metrics.

  4. Association Testing: Correlate microbiome with outcomes.

  5. Functional Prediction: Infer metabolic potential (PICRUSt2, HUMAnN).

  6. Prediction Modeling: Build response prediction models.

  7. Output: Microbiome profile, associations, predictions, interventions.

Example Usage

User: "Analyze gut microbiome from melanoma patients and predict anti-PD-1 response."

Agent Action:

python3 Skills/Microbiome/Microbiome_Cancer_Agent/microbiome_cancer.py \
    --metagenomics fecal_shotgun.fastq.gz \
    --tumor_data melanoma_rnaseq.tsv \
    --clinical treatment_outcomes.csv \
    --analysis ici_response \
    --reference metaphlan_db \
    --output microbiome_report/

ICI Response and Microbiome

Favorable Microbiome:

  • Akkermansia muciniphila
  • Faecalibacterium prausnitzii
  • Bifidobacterium spp.
  • Ruminococcaceae family
  • High diversity

Unfavorable Microbiome:

  • Bacteroidales (in some studies)
  • Low diversity
  • Post-antibiotic dysbiosis

Microbial Metabolites in Cancer

MetaboliteSourceEffect
ButyrateClostridiaAnti-inflammatory, anti-tumor
InosineAkkermansiaEnhanced ICI response
TMAOVariousPro-tumorigenic
Secondary bile acidsVariousVariable, context-dependent
LPSGram-negativeInflammation, mixed effects

AI/ML Components

Response Prediction:

  • Random forest on microbiome features
  • Neural networks for metagenomic profiles
  • Integration with host factors

Microbiome-Metabolite Linking:

  • Genome-scale metabolic models
  • Correlation networks
  • Causal inference methods

Intervention Design:

  • FMT donor selection
  • Probiotic consortium optimization
  • Antibiotic avoidance recommendations

Tumor Microbiome Analysis

Challenges:

  • Low bacterial biomass in tumors
  • Contamination from reagents/environment
  • Batch effects
  • Need for stringent controls

Best Practices:

  • Negative controls (extraction, PCR)
  • Decontamination algorithms (decontam, SCRuB)
  • Multiple validation methods
  • Orthogonal confirmation (FISH, culture)

Clinical Implications

  1. Biomarker Development: Microbiome-based response prediction
  2. Intervention Timing: Avoid antibiotics pre-ICI
  3. FMT Trials: Responder microbiome transfer
  4. Probiotics: Rationally designed consortia
  5. Prebiotics: Fiber to support beneficial bacteria

Prerequisites

  • Python 3.10+
  • QIIME2, Metaphlan, HUMAnN
  • R (phyloseq, vegan)
  • ML frameworks

Related Skills

  • Metagenomics - For general microbiome analysis
  • Immune_Checkpoint_Combination_Agent - For ICI optimization
  • Metabolomics - For metabolite analysis

Research Frontiers

  1. Intratumoral bacteria: Direct tumor effects
  2. Phage therapy: Targeting pathobionts
  3. Engineered probiotics: Drug-producing bacteria
  4. Diet interventions: Modulating microbiome for therapy

Author

AI Group - Biomedical AI Platform