arboreto
Infer gene regulatory networks (GRNs) from gene expression data using scalable algorithms (GRNBoost2, GENIE3). Use when analyzing transcriptomics data (bulk RNA-seq, single-cell RNA-seq) to identify transcription factor-target gene relationships and regulatory interactions. Supports distributed computation for large-scale datasets.
Best use case
arboreto is best used when you need a repeatable AI agent workflow instead of a one-off prompt. It is especially useful for teams working in multi. Infer gene regulatory networks (GRNs) from gene expression data using scalable algorithms (GRNBoost2, GENIE3). Use when analyzing transcriptomics data (bulk RNA-seq, single-cell RNA-seq) to identify transcription factor-target gene relationships and regulatory interactions. Supports distributed computation for large-scale datasets.
Infer gene regulatory networks (GRNs) from gene expression data using scalable algorithms (GRNBoost2, GENIE3). Use when analyzing transcriptomics data (bulk RNA-seq, single-cell RNA-seq) to identify transcription factor-target gene relationships and regulatory interactions. Supports distributed computation for large-scale datasets.
Users should expect a more consistent workflow output, faster repeated execution, and less time spent rewriting prompts from scratch.
Practical example
Example input
Use the "arboreto" skill to help with this workflow task. Context: Infer gene regulatory networks (GRNs) from gene expression data using scalable algorithms (GRNBoost2, GENIE3). Use when analyzing transcriptomics data (bulk RNA-seq, single-cell RNA-seq) to identify transcription factor-target gene relationships and regulatory interactions. Supports distributed computation for large-scale datasets.
Example output
A structured workflow result with clearer steps, more consistent formatting, and an output that is easier to reuse in the next run.
When to use this skill
- Use this skill when you want a reusable workflow rather than writing the same prompt again and again.
When not to use this skill
- Do not use this when you only need a one-off answer and do not need a reusable workflow.
- Do not use it if you cannot install or maintain the related files, repository context, or supporting tools.
Installation
Claude Code / Cursor / Codex
Manual Installation
- Download SKILL.md from GitHub
- Place it in
.claude/skills/arboreto/SKILL.mdinside your project - Restart your AI agent — it will auto-discover the skill
How arboreto Compares
| Feature / Agent | arboreto | Standard Approach |
|---|---|---|
| Platform Support | Not specified | Limited / Varies |
| Context Awareness | High | Baseline |
| Installation Complexity | Unknown | N/A |
Frequently Asked Questions
What does this skill do?
Infer gene regulatory networks (GRNs) from gene expression data using scalable algorithms (GRNBoost2, GENIE3). Use when analyzing transcriptomics data (bulk RNA-seq, single-cell RNA-seq) to identify transcription factor-target gene relationships and regulatory interactions. Supports distributed computation for large-scale datasets.
Where can I find the source code?
You can find the source code on GitHub using the link provided at the top of the page.
SKILL.md Source
# Arboreto
## Overview
Arboreto is a computational library for inferring gene regulatory networks (GRNs) from gene expression data using parallelized algorithms that scale from single machines to multi-node clusters.
**Core capability**: Identify which transcription factors (TFs) regulate which target genes based on expression patterns across observations (cells, samples, conditions).
## Quick Start
Install arboreto:
```bash
uv pip install arboreto
```
Basic GRN inference:
```python
import pandas as pd
from arboreto.algo import grnboost2
if __name__ == '__main__':
# Load expression data (genes as columns)
expression_matrix = pd.read_csv('expression_data.tsv', sep='\t')
# Infer regulatory network
network = grnboost2(expression_data=expression_matrix)
# Save results (TF, target, importance)
network.to_csv('network.tsv', sep='\t', index=False, header=False)
```
**Critical**: Always use `if __name__ == '__main__':` guard because Dask spawns new processes.
## Core Capabilities
### 1. Basic GRN Inference
For standard GRN inference workflows including:
- Input data preparation (Pandas DataFrame or NumPy array)
- Running inference with GRNBoost2 or GENIE3
- Filtering by transcription factors
- Output format and interpretation
**See**: `references/basic_inference.md`
**Use the ready-to-run script**: `scripts/basic_grn_inference.py` for standard inference tasks:
```bash
python scripts/basic_grn_inference.py expression_data.tsv output_network.tsv --tf-file tfs.txt --seed 777
```
### 2. Algorithm Selection
Arboreto provides two algorithms:
**GRNBoost2 (Recommended)**:
- Fast gradient boosting-based inference
- Optimized for large datasets (10k+ observations)
- Default choice for most analyses
**GENIE3**:
- Random Forest-based inference
- Original multiple regression approach
- Use for comparison or validation
Quick comparison:
```python
from arboreto.algo import grnboost2, genie3
# Fast, recommended
network_grnboost = grnboost2(expression_data=matrix)
# Classic algorithm
network_genie3 = genie3(expression_data=matrix)
```
**For detailed algorithm comparison, parameters, and selection guidance**: `references/algorithms.md`
### 3. Distributed Computing
Scale inference from local multi-core to cluster environments:
**Local (default)** - Uses all available cores automatically:
```python
network = grnboost2(expression_data=matrix)
```
**Custom local client** - Control resources:
```python
from distributed import LocalCluster, Client
local_cluster = LocalCluster(n_workers=10, memory_limit='8GB')
client = Client(local_cluster)
network = grnboost2(expression_data=matrix, client_or_address=client)
client.close()
local_cluster.close()
```
**Cluster computing** - Connect to remote Dask scheduler:
```python
from distributed import Client
client = Client('tcp://scheduler:8786')
network = grnboost2(expression_data=matrix, client_or_address=client)
```
**For cluster setup, performance optimization, and large-scale workflows**: `references/distributed_computing.md`
## Installation
```bash
uv pip install arboreto
```
**Dependencies**: scipy, scikit-learn, numpy, pandas, dask, distributed
## Common Use Cases
### Single-Cell RNA-seq Analysis
```python
import pandas as pd
from arboreto.algo import grnboost2
if __name__ == '__main__':
# Load single-cell expression matrix (cells x genes)
sc_data = pd.read_csv('scrna_counts.tsv', sep='\t')
# Infer cell-type-specific regulatory network
network = grnboost2(expression_data=sc_data, seed=42)
# Filter high-confidence links
high_confidence = network[network['importance'] > 0.5]
high_confidence.to_csv('grn_high_confidence.tsv', sep='\t', index=False)
```
### Bulk RNA-seq with TF Filtering
```python
from arboreto.utils import load_tf_names
from arboreto.algo import grnboost2
if __name__ == '__main__':
# Load data
expression_data = pd.read_csv('rnaseq_tpm.tsv', sep='\t')
tf_names = load_tf_names('human_tfs.txt')
# Infer with TF restriction
network = grnboost2(
expression_data=expression_data,
tf_names=tf_names,
seed=123
)
network.to_csv('tf_target_network.tsv', sep='\t', index=False)
```
### Comparative Analysis (Multiple Conditions)
```python
from arboreto.algo import grnboost2
if __name__ == '__main__':
# Infer networks for different conditions
conditions = ['control', 'treatment_24h', 'treatment_48h']
for condition in conditions:
data = pd.read_csv(f'{condition}_expression.tsv', sep='\t')
network = grnboost2(expression_data=data, seed=42)
network.to_csv(f'{condition}_network.tsv', sep='\t', index=False)
```
## Output Interpretation
Arboreto returns a DataFrame with regulatory links:
| Column | Description |
|--------|-------------|
| `TF` | Transcription factor (regulator) |
| `target` | Target gene |
| `importance` | Regulatory importance score (higher = stronger) |
**Filtering strategy**:
- Top N links per target gene
- Importance threshold (e.g., > 0.5)
- Statistical significance testing (permutation tests)
## Integration with pySCENIC
Arboreto is a core component of the SCENIC pipeline for single-cell regulatory network analysis:
```python
# Step 1: Use arboreto for GRN inference
from arboreto.algo import grnboost2
network = grnboost2(expression_data=sc_data, tf_names=tf_list)
# Step 2: Use pySCENIC for regulon identification and activity scoring
# (See pySCENIC documentation for downstream analysis)
```
## Reproducibility
Always set a seed for reproducible results:
```python
network = grnboost2(expression_data=matrix, seed=777)
```
Run multiple seeds for robustness analysis:
```python
from distributed import LocalCluster, Client
if __name__ == '__main__':
client = Client(LocalCluster())
seeds = [42, 123, 777]
networks = []
for seed in seeds:
net = grnboost2(expression_data=matrix, client_or_address=client, seed=seed)
networks.append(net)
# Combine networks and filter consensus links
consensus = analyze_consensus(networks)
```
## Troubleshooting
**Memory errors**: Reduce dataset size by filtering low-variance genes or use distributed computing
**Slow performance**: Use GRNBoost2 instead of GENIE3, enable distributed client, filter TF list
**Dask errors**: Ensure `if __name__ == '__main__':` guard is present in scripts
**Empty results**: Check data format (genes as columns), verify TF names match gene namesRelated Skills
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