ngs-analysis

Analyze deep sequencing of complex libraries


Keywords
NGS, library, variant, barcode
License
MIT
Install
pip install ngs-analysis==0.0.6

Documentation

ngs-analysis

Convenient analysis of sequencing reads that span multiple DNA or protein parts. For instance, given a library of protein variants linked to DNA barcodes, this tool can answer questions like:

  • How accurate are the variant sequences, at the DNA or protein level?
  • How frequently is the same barcode linked to two different variants?
  • Which reads contain parts required for function (e.g., a kozak start sequence, or a fused protein tag)?

This kind of analysis often involves parsing raw sequencing reads for DNA and/or protein sub-sequences (parts), then mapping the parts to a reference of anticipated part combinations. Here the workflow is:

  1. Define how to parse reads into parts using plain text expressions (no code)
  2. Parse your anticipated DNA sequences to generate a reference
  3. Parse a batch of sequencing samples
  4. Map the parts found in each read to the reference

It’s been tested with Illumina paired-end reads and Oxford Nanopore long reads. Under the hood it uses NGmerge to merge paired reads and MMseqs2 for sequencing mapping. It is moderately performant: 1 million paired-end reads can be mapped to a reference of 100,000 variant-barcode pairs in ~1 minute.

Workflow

A cartoon example with two reference sequences, each consisting of a variant linked to a barcode:

sequences

Here's the analysis workflow and outputs:

analysis workflow

Note that in the last two columns, the parsed variant is mapped to a reference variant defined by the barcode present in the same read, rather than all possible reference variants. Check out the example notebook for paired end reads for details.

TL;DR

Run ngs-analysis --help to see available commands.

  1. Make an empty directory, add config.yaml and samples.csv based on the example.
  2. Add reference_dna.csv with anticipated DNA sequences (including adapters).
  3. Run ngs-analysis setup. Add --clean to start the analysis from scratch.
  4. Check that designs.csv is accurate; if not, fix config.yaml.
    • If you have paired-end data, put it in 0_paired_reads/ and run ngs-analysis merge_read_pairs <sample>.
    • If you have single-end data (e.g., nanopore), put it in 1_reads/.
  5. Run ngs-analysis parse_reads <sample>. Check that 2_parsed/<sample>.parsed.pq looks alright (with pandas, use pd.read_parquet)
  6. Run ngs-analysis map_parsed_reads <sample>. Results are in 3_mapped/<sample>.mapped.csv

Simulation mode

Debugging complex read structures and experimental layouts can be tricky. For example, your config.yaml might parse reference sequences incorrectly, or samples might map to the reference in an unexpected way (e.g., if the same barcode is attached to different variants).

Before running an analysis (or designing an experiment), you can simulate the results by defining sample_plan.csv and running simulate_single_reads or simulate_paired_reads, which have options to add simple random mutations and variable coverage per subpool.

Here's sample_plan.csv from the paired read example. Note that "source" refers to the optional "source" column in reference_DNA.csv.

sample source coverage
sample_A pool1 50
sample_B pool2 50
sample_C pool1 50
sample_C pool2 20
sample_D pool3 50

To analyze the simulated data, just add the --simulate flag to merge_read_pairs, parse_reads, map_parsed_reads, and plot. Results will be saved to {step}/simulate/{sample} rather than {step}/{sample}.

Install

pip install ngs-analysis

Make sure that the mmseqs and NGmerge executables are available (NGmerge is only needed for paired reads).

On Linux and Intel-based MacOS, you can use conda install -c bioconda -c conda-forge mmseqs2 ngmerge. On Apple Silicon mmseqs can be installed via Homebrew with brew install mmseqs2, and NGmerge can be installed from source, or via brew install brewsci/bio/ngmerge.

Tested on Linux and MacOS (Apple Silicon).