dnanexus-integration
$
npx mdskill add K-Dense-AI/scientific-agent-skills/dnanexus-integrationDevelop genomics pipelines on DNAnexus using dxpy and workflow tools.
- Build apps, manage data, and execute workflows for biomedical analysis.
- Integrates with dxpy SDK, FASTQ, BAM, VCF, and DNAnexus account.
- Executes tasks based on app creation, data handling, or workflow needs.
- Delivers results through app deployment, job monitoring, and file processing.
SKILL.md
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---
name: dnanexus-integration
description: DNAnexus cloud genomics platform. Build apps/applets, manage data (upload/download), dxpy Python SDK, run workflows, FASTQ/BAM/VCF, for genomics pipeline development and execution.
license: Unknown
compatibility: Requires a DNAnexus account
metadata:
skill-author: K-Dense Inc.
---
# DNAnexus Integration
## Overview
DNAnexus is a cloud platform for biomedical data analysis and genomics. Build and deploy apps/applets, manage data objects, run workflows, and use the dxpy Python SDK for genomics pipeline development and execution.
## When to Use This Skill
This skill should be used when:
- Creating, building, or modifying DNAnexus apps/applets
- Uploading, downloading, searching, or organizing files and records
- Running analyses, monitoring jobs, creating workflows
- Writing scripts using dxpy to interact with the platform
- Setting up dxapp.json, managing dependencies, using Docker
- Processing FASTQ, BAM, VCF, or other bioinformatics files
- Managing projects, permissions, or platform resources
## Core Capabilities
The skill is organized into five main areas, each with detailed reference documentation:
### 1. App Development
**Purpose**: Create executable programs (apps/applets) that run on the DNAnexus platform.
**Key Operations**:
- Generate app skeleton with `dx-app-wizard`
- Write Python or Bash apps with proper entry points
- Handle input/output data objects
- Deploy with `dx build` or `dx build --app`
- Test apps on the platform
**Common Use Cases**:
- Bioinformatics pipelines (alignment, variant calling)
- Data processing workflows
- Quality control and filtering
- Format conversion tools
**Reference**: See `references/app-development.md` for:
- Complete app structure and patterns
- Python entry point decorators
- Input/output handling with dxpy
- Development best practices
- Common issues and solutions
### 2. Data Operations
**Purpose**: Manage files, records, and other data objects on the platform.
**Key Operations**:
- Upload/download files with `dxpy.upload_local_file()` and `dxpy.download_dxfile()`
- Create and manage records with metadata
- Search for data objects by name, properties, or type
- Clone data between projects
- Manage project folders and permissions
**Common Use Cases**:
- Uploading sequencing data (FASTQ files)
- Organizing analysis results
- Searching for specific samples or experiments
- Backing up data across projects
- Managing reference genomes and annotations
**Reference**: See `references/data-operations.md` for:
- Complete file and record operations
- Data object lifecycle (open/closed states)
- Search and discovery patterns
- Project management
- Batch operations
### 3. Job Execution
**Purpose**: Run analyses, monitor execution, and orchestrate workflows.
**Key Operations**:
- Launch jobs with `applet.run()` or `app.run()`
- Monitor job status and logs
- Create subjobs for parallel processing
- Build and run multi-step workflows
- Chain jobs with output references
**Common Use Cases**:
- Running genomics analyses on sequencing data
- Parallel processing of multiple samples
- Multi-step analysis pipelines
- Monitoring long-running computations
- Debugging failed jobs
**Reference**: See `references/job-execution.md` for:
- Complete job lifecycle and states
- Workflow creation and orchestration
- Parallel execution patterns
- Job monitoring and debugging
- Resource management
### 4. Python SDK (dxpy)
**Purpose**: Programmatic access to DNAnexus platform through Python.
**Key Operations**:
- Work with data object handlers (DXFile, DXRecord, DXApplet, etc.)
- Use high-level functions for common tasks
- Make direct API calls for advanced operations
- Create links and references between objects
- Search and discover platform resources
**Common Use Cases**:
- Automation scripts for data management
- Custom analysis pipelines
- Batch processing workflows
- Integration with external tools
- Data migration and organization
**Reference**: See `references/python-sdk.md` for:
- Complete dxpy class reference
- High-level utility functions
- API method documentation
- Error handling patterns
- Common code patterns
### 5. Configuration and Dependencies
**Purpose**: Configure app metadata and manage dependencies.
**Key Operations**:
- Write dxapp.json with inputs, outputs, and run specs
- Install system packages (execDepends)
- Bundle custom tools and resources
- Use assets for shared dependencies
- Integrate Docker containers
- Configure instance types and timeouts
**Common Use Cases**:
- Defining app input/output specifications
- Installing bioinformatics tools (samtools, bwa, etc.)
- Managing Python package dependencies
- Using Docker images for complex environments
- Selecting computational resources
**Reference**: See `references/configuration.md` for:
- Complete dxapp.json specification
- Dependency management strategies
- Docker integration patterns
- Regional and resource configuration
- Example configurations
## Quick Start Examples
### Upload and Analyze Data
```python
import dxpy
# Upload input file
input_file = dxpy.upload_local_file("sample.fastq", project="project-xxxx")
# Run analysis
job = dxpy.DXApplet("applet-xxxx").run({
"reads": dxpy.dxlink(input_file.get_id())
})
# Wait for completion
job.wait_on_done()
# Download results
output_id = job.describe()["output"]["aligned_reads"]["$dnanexus_link"]
dxpy.download_dxfile(output_id, "aligned.bam")
```
### Search and Download Files
```python
import dxpy
# Find BAM files from a specific experiment
files = dxpy.find_data_objects(
classname="file",
name="*.bam",
properties={"experiment": "exp001"},
project="project-xxxx"
)
# Download each file
for file_result in files:
file_obj = dxpy.DXFile(file_result["id"])
filename = file_obj.describe()["name"]
dxpy.download_dxfile(file_result["id"], filename)
```
### Create Simple App
```python
# src/my-app.py
import dxpy
import subprocess
@dxpy.entry_point('main')
def main(input_file, quality_threshold=30):
# Download input
dxpy.download_dxfile(input_file["$dnanexus_link"], "input.fastq")
# Process
subprocess.check_call([
"quality_filter",
"--input", "input.fastq",
"--output", "filtered.fastq",
"--threshold", str(quality_threshold)
])
# Upload output
output_file = dxpy.upload_local_file("filtered.fastq")
return {
"filtered_reads": dxpy.dxlink(output_file)
}
dxpy.run()
```
## Workflow Decision Tree
When working with DNAnexus, follow this decision tree:
1. **Need to create a new executable?**
- Yes → Use **App Development** (references/app-development.md)
- No → Continue to step 2
2. **Need to manage files or data?**
- Yes → Use **Data Operations** (references/data-operations.md)
- No → Continue to step 3
3. **Need to run an analysis or workflow?**
- Yes → Use **Job Execution** (references/job-execution.md)
- No → Continue to step 4
4. **Writing Python scripts for automation?**
- Yes → Use **Python SDK** (references/python-sdk.md)
- No → Continue to step 5
5. **Configuring app settings or dependencies?**
- Yes → Use **Configuration** (references/configuration.md)
Often you'll need multiple capabilities together (e.g., app development + configuration, or data operations + job execution).
## Installation and Authentication
### Install dxpy
```bash
uv pip install dxpy
```
### Login to DNAnexus
```bash
dx login
```
This authenticates your session and sets up access to projects and data.
### Verify Installation
```bash
dx --version
dx whoami
```
## Common Patterns
### Pattern 1: Batch Processing
Process multiple files with the same analysis:
```python
# Find all FASTQ files
files = dxpy.find_data_objects(
classname="file",
name="*.fastq",
project="project-xxxx"
)
# Launch parallel jobs
jobs = []
for file_result in files:
job = dxpy.DXApplet("applet-xxxx").run({
"input": dxpy.dxlink(file_result["id"])
})
jobs.append(job)
# Wait for all completions
for job in jobs:
job.wait_on_done()
```
### Pattern 2: Multi-Step Pipeline
Chain multiple analyses together:
```python
# Step 1: Quality control
qc_job = qc_applet.run({"reads": input_file})
# Step 2: Alignment (uses QC output)
align_job = align_applet.run({
"reads": qc_job.get_output_ref("filtered_reads")
})
# Step 3: Variant calling (uses alignment output)
variant_job = variant_applet.run({
"bam": align_job.get_output_ref("aligned_bam")
})
```
### Pattern 3: Data Organization
Organize analysis results systematically:
```python
# Create organized folder structure
dxpy.api.project_new_folder(
"project-xxxx",
{"folder": "/experiments/exp001/results", "parents": True}
)
# Upload with metadata
result_file = dxpy.upload_local_file(
"results.txt",
project="project-xxxx",
folder="/experiments/exp001/results",
properties={
"experiment": "exp001",
"sample": "sample1",
"analysis_date": "2025-10-20"
},
tags=["validated", "published"]
)
```
## Best Practices
1. **Error Handling**: Always wrap API calls in try-except blocks
2. **Resource Management**: Choose appropriate instance types for workloads
3. **Data Organization**: Use consistent folder structures and metadata
4. **Cost Optimization**: Archive old data, use appropriate storage classes
5. **Documentation**: Include clear descriptions in dxapp.json
6. **Testing**: Test apps with various input types before production use
7. **Version Control**: Use semantic versioning for apps
8. **Security**: Never hardcode credentials in source code
9. **Logging**: Include informative log messages for debugging
10. **Cleanup**: Remove temporary files and failed jobs
## Resources
This skill includes detailed reference documentation:
### references/
- **app-development.md** - Complete guide to building and deploying apps/applets
- **data-operations.md** - File management, records, search, and project operations
- **job-execution.md** - Running jobs, workflows, monitoring, and parallel processing
- **python-sdk.md** - Comprehensive dxpy library reference with all classes and functions
- **configuration.md** - dxapp.json specification and dependency management
Load these references when you need detailed information about specific operations or when working on complex tasks.
## Getting Help
- Official documentation: https://documentation.dnanexus.com/
- API reference: http://autodoc.dnanexus.com/
- GitHub repository: https://github.com/dnanexus/dx-toolkit
- Support: support@dnanexus.com
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