ReddRadar
Agent skill
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.
Install this agent skill to your Project
npx add-skill https://github.com/K-Dense-AI/claude-scientific-skills/tree/main/scientific-skills/arboreto
Metadata
Additional technical details for this skill
- skill author
- K-Dense Inc.
SKILL.md
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:
uv pip install arboreto
Basic GRN inference:
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:
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:
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:
network = grnboost2(expression_data=matrix)
Custom local client - Control resources:
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:
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
uv pip install arboreto
Dependencies: scipy, scikit-learn, numpy, pandas, dask, distributed
Common Use Cases
Single-Cell RNA-seq Analysis
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
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)
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:
# 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:
network = grnboost2(expression_data=matrix, seed=777)
Run multiple seeds for robustness analysis:
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 names
Recommended Agent Skills
Expand your agent's capabilities with these related and highly-rated skills.
K-Dense-AI/claude-scientific-skills
pufferlib
High-performance reinforcement learning framework optimized for speed and scale. Use when you need fast parallel training, vectorized environments, multi-agent systems, or integration with game environments (Atari, Procgen, NetHack). Achieves 2-10x speedups over standard implementations. For quick prototyping or standard algorithm implementations with extensive documentation, use stable-baselines3 instead.
K-Dense-AI/claude-scientific-skills
fluidsim
Framework for computational fluid dynamics simulations using Python. Use when running fluid dynamics simulations including Navier-Stokes equations (2D/3D), shallow water equations, stratified flows, or when analyzing turbulence, vortex dynamics, or geophysical flows. Provides pseudospectral methods with FFT, HPC support, and comprehensive output analysis.
K-Dense-AI/claude-scientific-skills
geniml
This skill should be used when working with genomic interval data (BED files) for machine learning tasks. Use for training region embeddings (Region2Vec, BEDspace), single-cell ATAC-seq analysis (scEmbed), building consensus peaks (universes), or any ML-based analysis of genomic regions. Applies to BED file collections, scATAC-seq data, chromatin accessibility datasets, and region-based genomic feature learning.
K-Dense-AI/claude-scientific-skills
astropy
Comprehensive Python library for astronomy and astrophysics. This skill should be used when working with astronomical data including celestial coordinates, physical units, FITS files, cosmological calculations, time systems, tables, world coordinate systems (WCS), and astronomical data analysis. Use when tasks involve coordinate transformations, unit conversions, FITS file manipulation, cosmological distance calculations, time scale conversions, or astronomical data processing.
K-Dense-AI/claude-scientific-skills
pyhealth
Comprehensive healthcare AI toolkit for developing, testing, and deploying machine learning models with clinical data. This skill should be used when working with electronic health records (EHR), clinical prediction tasks (mortality, readmission, drug recommendation), medical coding systems (ICD, NDC, ATC), physiological signals (EEG, ECG), healthcare datasets (MIMIC-III/IV, eICU, OMOP), or implementing deep learning models for healthcare applications (RETAIN, SafeDrug, Transformer, GNN).
K-Dense-AI/claude-scientific-skills
research-lookup
Look up current research information using the Parallel Chat API (primary) or Perplexity sonar-pro-search (academic paper searches). Automatically routes queries to the best backend. Use for finding papers, gathering research data, and verifying scientific information.
Didn't find tool you were looking for?