Metadata-Version: 2.1
Name: gnomonicus
Version: 2.5.5
Summary: Python code to integrate results of tb-pipeline and provide an antibiogram, mutations and variants
Home-page: https://github.com/oxfordmmm/gnomonicus
Author: Philip W Fowler, Jeremy Westhead
Author-email: philip.fowler@ndm.ox.ac.uk
License: University of Oxford License, see LICENSE
Keywords: gnomonicus,piezo,lodestone,clockwork,TB
Classifier: Programming Language :: Python :: 3
Requires-Python: >=3.10
Description-Content-Type: text/markdown
License-File: LICENSE
Requires-Dist: gumpy>=1.2.7
Requires-Dist: piezo>=0.8.2
Requires-Dist: numpy
Requires-Dist: pandas
Requires-Dist: recursive_diff

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# gnomonicus
Python code to integrate results of tb-pipeline and provide an antibiogram, mutations and variations

Provides a library of functions for use within scripts, as well as a CLI tool for linking the functions together to produce output

## Documentation
API reference for developers, and CLI instructions can be found here: https://oxfordmmm.github.io/gnomonicus/ 
## Usage
```
usage: gnomonicus [-h] --vcf_file VCF_FILE --genome_object GENOME_OBJECT [--catalogue_file CATALOGUE_FILE] [--ignore_vcf_filter] [--progress] [--output_dir OUTPUT_DIR] [--json] [--fasta FASTA] [--minor_populations MINOR_POPULATIONS]

options:
  -h, --help            show this help message and exit
  --vcf_file VCF_FILE   the path to a single VCF file
  --genome_object GENOME_OBJECT
                        the path to a compressed gumpy Genome object or a genbank file
  --catalogue_file CATALOGUE_FILE
                        the path to the resistance catalogue
  --ignore_vcf_filter   whether to ignore the FILTER field in the vcf (e.g. necessary for some versions of Clockwork VCFs)
  --progress            whether to show progress using tqdm
  --output_dir OUTPUT_DIR
                        Directory to save output files to. Defaults to wherever the script is run from.
  --json                Flag to create a single JSON output as well as the CSVs
  --fasta FASTA         Use to output a FASTA file of the resultant genome. Specify either 'fixed' or 'variable' for fixed length and variable length FASTA respectively.
  --minor_populations MINOR_POPULATIONS
                        Path to a line separated file containing genome indices of minor populations.
```

## Helper usage
As the main script can utilise pickled `gumpy.Genome` objects, there is a supplied helper script. This converts a Genbank file into a pickled gumpy.Genome for significant time saving.
Due to the security implications of the pickle module, **DO NOT SEND/RECEIVE PICKLES**. This script should be used on a host VM before running nextflow to avoid reinstanciation.
Supports gzip compression to reduce file size significantly (using the `--compress` flag).
```
usage: gbkToPkl FILENAME [--compress]
```

## Install
Simple install using pip for the latest release
```
pip install gnomonicus
```

Install from source
```
git clone https://github.com/oxfordmmm/gnomonicus.git
cd gnomonicus
pip install -e .
```

## Docker
A Docker image should be built on releases. To open a shell with gnomonicus installed:
```
docker run -it oxfordmmm/gnomonicus:latest
```

## Updating
If a `gnomonicus` update changes the version of `gumpy` used, an `OutdatedGumpyException` will be thrown if using a pickled `Genome` object which was instantiated with the old version. This can be fixed by simply re-instantiating the `Genome` object by passing a genbank file once.

## Notes
When generating mutations, in cases of synonymous amino acid mutation, the nucelotides changed are also included. This can lead to a mix of nucleotides and amino acids for coding genes, but these are excluded from generating effects unless specified in the catalogue. This means that the default rule of `gene@*= --> S` is still in place regardless of the introduced `gene@*?` which would otherwise take precedence. For example:
```
  'MUTATIONS': [
      {
          'MUTATION': 'F2F',
          'GENE': 'S',
          'GENE_POSITION': 2
      },
      {
          'MUTATION': 't6c',
          'GENE': 'S',
          'GENE_POSITION': 6
      },
  ],
  'EFFECTS': {
      'AAA': [
          {
              'GENE': 'S',
              'MUTATION': 'F2F',
              'PREDICTION': 'S'
          },
          {
              'PHENOTYPE': 'S'
          }
      ],
```
The nucelotide variation is included in the the `MUTATIONS`, but explictly removed from the `EFFECTS` unless it is specified within the catalogue.
In order for this variation to be included, a line in the catalogue of `S@F2F&S@t6c` would have to be present.

## User stories

1. As a bioinformatician, I want to be able to run `gnomonicus` on the command line, passing it (i) a GenBank file (or pickled `gumpy.Genome` object), (ii) a resistance catalogue and (iii) a VCF file, and get back `pandas.DataFrames` of the genetic variants, mutations, effects and predictions/antibiogram. The latter is for all the drugs described in the passed resistance catalogue.

2. As a GPAS developer, I want to be able to embed `gnomonicus` in a Docker image/NextFlow pipeline that consumes the outputs of [tb-pipeline](https://github.com/Pathogen-Genomics-Cymru/tb-pipeline) and emits a structured, well-designed `JSON` object describing the genetic variants, mutations, effects and predictions/antibiogram.

3. In general, I would also like the option to output fixed- and variable-length FASTA files (the latter takes into account insertions and deletions described in any input VCF file).

## Unit testing

For speed, rather than use NC_000962.3 (i.e. H37Rv *M. tuberculosis*), we shall use SARS-CoV-2 and have created a fictious drug resistance catalogue, along with some `vcf` files and the expected outputs in `tests/`.

These can be run with `pytest -vv`
