| name | alphagenome-single-variant-analysis |
| description | Analyzes genetic variant effects on gene expression (RNA-seq), chromatin accessibility (DNASE), histone marks (ChIP), and transcription factors using the AlphaGenome API. Use when the user asks about non-coding variant effects, pathogenicity, clinical significance, disease associations, functional effects, gene expression changes, splicing disruption, or regulatory effects in promoters and enhancers. Also use for resolving biological terms to tissue/cell-type ontologies (UBERON/CL) or analyzing variants in chr:pos:ref>alt format.
|
Variant Analysis using AlphaGenome
Prerequisites
-
uv: Read the uv skill and follow its Setup instructions to ensure
uv is installed and on PATH.
-
User Notification: If LICENSE_NOTIFICATION.txt does not already exist in
this skill directory then (1) prominently notify the user to check the terms
at https://deepmind.google.com/science/alphagenome/, then (2) create the
file recording the notification text and timestamp.
-
.env file: Make sure the .env file exists in your home directory.
Create one if it does not exist.
-
ALPHAGENOME_API_KEY: This skill requires an API key to function.
You must ask the user for an API key if this skill looks relevant to their
request and you do not have one in .env. The user can sign up at
https://deepmind.google.com/science/alphagenome/. Do NOT ask the user to
paste their key into the chat (this would leak the key into the agent's
context). Instead, explain that a key is necessary to use AlphaGenome and
give the user this command substituting ENV_FILE with the resolved
literal path to the .env file:
printf "Enter AlphaGenome API key (typing hidden): " && read -s key && echo && echo "ALPHAGENOME_API_KEY=$key" >> "ENV_FILE" && echo "Saved."
The scripts load credentials automatically via dotenv. NEVER read,
print, or inspect the .env file or its variables (e.g. no cat, grep,
echo, printenv, or os.environ.get on keys). Credentials must stay out
of the agent's context.
When running in sandbox, dotenv.load_dotenv() will be a no-op, and instead
the sandbox will read credentials and inject them directly.
Core Rules
- NEVER run
python3 or python3 -c directly. The system Python does not
necessarily have pandas, numpy, and other key dependencies. ALWAYS use uv run to run ALL Python code — including scripts, ad-hoc analysis files, and
one-liners. Do not attempt to pip install or create new venvs — uv
manages an isolated environment automatically.
- Offline Only: NEVER use external APIs (e.g., MyGene.info, Ensembl REST)
for gene/transcript lookup. Use
lookup_gene_info.py with the local GTF. If
it fails, fix the environment/paths, do not switch to external APIs.
- API Key is required:
ALPHAGENOME_API_KEY must be set before running
any script (in sandbox, credentials are injected automatically).
- Notification: If this skill is used, ensure this is mentioned in the
output.
- Report Format: Always use the templates in
docs/report-templates.md
for generating analysis reports, and ensure to include the table of top hits
from the discovery scan.
Environment Setup & Troubleshooting
Python Environment
All scripts must be executed using uv run, which manages an isolated virtual
environment with the correct dependencies via uv.
uv run <script_name> [args...]
For ad-hoc scripts (e.g., inline analysis code saved to a temp file), pass the
full path instead of a short name:
uv run --project $SKILL_DIR /tmp/my_analysis.py --arg1 val1
[!NOTE] The first invocation resolves and installs dependencies (~10s).
Subsequent runs use the cached environment and start instantly. The cache
lives in ~/.cache/uv/.
Common Issues
- Column Names:
tidy_scores and metadata often use gene_name (not
gene_symbol) and output_type (not modality). Always inspect
df.columns before filtering.
- Large Genes: Genes > 500kb (e.g.,
USH2A) break the whole_gene view.
Use --view detail or manual regional windows instead.
- Sashimi Strand Error:
plot_components.Sashimi does NOT accept a
strand argument directly. Filter input tracks instead.
- KeyError: 'ontology_curie': Not all tracks have
ontology_curie. Check
track.metadata.columns before filtering.
- Python Path: If
exec: "python": executable file not found occurs,
ensure you are using uv run instead of bare python/python3.
- NotImplementedError (pandas): "iLocation based boolean indexing on an
integer type is not available". This occurs when using boolean masks with
.iloc on integer-indexed DataFrames in newer pandas versions. Fix:
Convert boolean masks to integer indices using np.flatnonzero(mask).
- GTF Feather Case Sensitivity: The AlphaGenome GTF Feather file uses
Capitalized column names (
Feature, Start, End, Strand) unlike
standard GTF files. Always check df.columns if getting KeyErrors.
score_variant ontology filtering: score_variant does NOT accept
ontology_terms as an argument. You must filter the returned AnnData
objects manually by inspecting adata.var columns. In contrast,
predict_variant DOES accept ontology_terms directly.
- Sashimi Zoom Logic: To ensure "skipping" arcs are visible, expand the
zoom to include the flanking exons rather than relying on junction
overlap alone.
- Junction Scores: Raw
Junction objects from prediction may be simple
Intervals. Use junction_data.get_junctions_to_plot(predictions=..., name=...) to retrieve objects with the .k (abundance/score) attribute.
uv Not Found: If exec: uv: not found, follow the installation
instructions in Prerequisites.
- Registry Authentication Error (401): If
uv fails with 401 Unauthorized
for a private registry, set UV_INDEX_URL=https://pypi.org/simple before
running the script.
References
Code Patterns
Broad Discovery Scan
Use score_variant across differential scorers only to discover unexpected
tissue effects.
from alphagenome.models import dna_client
from alphagenome.models import variant_scorers
from alphagenome.data import genome
import os
import pandas as pd
dna_model = dna_client.create(api_key=os.environ.get('ALPHAGENOME_API_KEY'),
address='dns:///gdmscience.googleapis.com:443')
variant_str = "chr2:1234:A>C"
chrom, pos_str, ref_alt = variant_str.split(':')
ref, alt = ref_alt.split('>')
pos = int(pos_str)
SEQ_LENGTH = 2**20
interval = genome.Interval(chrom, pos - SEQ_LENGTH // 2, pos + SEQ_LENGTH // 2)
variant = genome.Variant(chrom, pos, ref, alt)
scorers = [
variant_scorers.RECOMMENDED_VARIANT_SCORERS[m]
for m in variant_scorers.RECOMMENDED_VARIANT_SCORERS
if "ACTIVE" not in m and "CAGE" not in m and "PROCAP" not in m
]
print(f"Scoring variant {variant_str}...")
scores_list = dna_model.score_variant(interval=interval, variant=variant, variant_scorers=scorers)
all_dfs = []
for score_adata in scores_list:
df = variant_scorers.tidy_scores([score_adata], match_gene_strand=True)
if df is not None:
all_dfs.append(df)
if all_dfs:
df = pd.concat(all_dfs)
significant = df[df['quantile_score'].abs() > 0.995]
ranked = significant.sort_values('raw_score', key=abs, ascending=False)
print("Top Significant Hits:")
print(ranked[['biosample_name', 'gene_name', 'output_type', 'quantile_score', 'raw_score']])
Extended Search for Disease-Relevant Tissues
disease_keywords = ["liver", "hepatocyte"]
mask = df['biosample_name'].str.contains('|'.join(disease_keywords), case=False, na=False)
relevant_hits = df[mask].sort_values('raw_score', key=abs, ascending=False)
print(f"\n--- Extended Analysis (Keywords: {disease_keywords}) ---")
print(relevant_hits.head(20)[['biosample_name', 'output_type', 'raw_score', 'quantile_score']])
Workflow Checklist
Variant Analysis Progress:
- [ ] Step 0: Review Golden Examples (MANDATORY)
- [ ] Step 1: Create Output Folder and Setup
- [ ] Step 2: Parse User Query & Research
- [ ] Step 3: Resolve Tissues & Modalities
- [ ] Step 4: Visualize & Save Plots
- [ ] Step 5: Analyze Predictions (view plots, no code). MANDATORY: Read [interpretation-guide.md](docs/interpretation-guide.md) before interpreting results.
- [ ] Step 6: Write Report, save it as `report.md` (MANDATORY)
- [ ] Step 7: Self-Critique (view `report.md` to verify links & claims)
- [ ] Step 8: Make artifact out of `report.md`
Multi-Variant Workflow
If multiple variants are specified, spawn sub-agents to run each variant
analysis and then synthesize each report.md into a single report.
Script Reference
| Script | Purpose |
|---|
lookup_gene_info | Comprehensive gene and transcript lookup using |
| : : GTF data : | |
resolve_ontology_terms | Biological terms → UBERON/CL/EFO IDs |
visualize_variant_effects | REF/ALT visualization (expression, regulatory, |
| : : splicing) : | |
analyze_ism | In-Silico Mutagenesis SeqLogo generation |
interpret_splicing | Quantitative splicing analysis (delta scores, |
| : : junctions) : | |
visualize_genome_tracks | Genomic track visualization for a region |