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A Python package for discovery, annotation, and analysis of gene clusters in genomics or metagenomics data sets.

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Opfi

Documentation Status PyPI Anaconda-Server Badge

A python package for discovery, annotation, and analysis of gene clusters in genomics or metagenomics datasets.

Installation

The recommended way to install Opfi is with Bioconda, which requires the conda package manager. This will install Opfi and all of its dependencies (which you can read more about here).

Currently, Bioconda supports only 64-bit Linux and Mac OS. Windows users can still install Opfi with pip (see below); however, the complete installation procedure has not been fully tested on a Windows system.

Install with conda (Linux and Mac OS only)

First, set up conda and Bioconda following the quickstart guide. Once this is done, run:

conda install -c bioconda opfi

And that's it! Note that this will install Opfi in the conda environment that is currently active. To create a fresh environment with Opfi installed, do:

conda create --name opfi-env -c bioconda opfi
conda activate opfi-env

Install with pip

This method does not automatically install non-Python dependencies, so they will need to be installed separately, following their individual installation instructions. A complete list of required software is available here. Once this step is complete, install Opfi with pip by running:

pip install opfi

For information about installing for development, check out the documentation site.

Gene Finder

Gene Finder iteratively executes homology searches to identify gene clusters of interest. Below is an example script that sets up a search for putative CRISPR-Cas systems in the Rippkaea orientalis PCC 8802 (cyanobacteria) genome. Data inputs are provided in the Opfi tutorial (tutorials/tutorial.ipynb).

from gene_finder.pipeline import Pipeline
import os

genomic_data = "GCF_000024045.1_ASM2404v1_genomic.fna.gz"

p = Pipeline()
p.add_seed_step(db="cas1", name="cas1", e_val=0.001, blast_type="PROT", num_threads=1)
p.add_filter_step(db="cas_all", name="cas_all", e_val=0.001, blast_type="PROT", num_threads=1)
p.add_crispr_step()

# use the input filename as the job id
job_id = os.path.basename(genomic_data)
results = p.run(job_id=job_id, data=genomic_data, min_prot_len=90, span=10000, gzip=True)

Operon Analyzer

Operon Analyzer filters results from Gene Finder, and identifies promising candidate operons according to a given set of criteria. It also contains some tools for visualizing candidates and performing basic statistics.

Please note that the use of the word "operon" throughout this library is somewhat of an artifact from early development. At this time, Opfi does not predict whether a candidate system represents a true operon, that is, a set of genes under the control of a single promoter. Although a candidate gene cluster may certainly qualify as an operon, it is currently up to the user to make that distinction.

Analysis

The analysis module provides tools to identify operons that conform to certain rules, such as requiring that they contain a certain gene, or that two genes are within a given distance of each other (the full list is given below). CSV output is written to stdout, which identifies the outcome of the analysis for each putative operon.

Rules defined with the RuleSet determine whether an operon should be considered a candidate for further analysis. Filters defined with the FilterSet help define which features to consider when evaluating rules. You might, for example, want to exclude any operon containing a particular gene, but if a copy of that gene coincidentally exists 5 kb from the true operon, you might want to ignore it for the purposes of evaluating your rules.

A sample script that performs this task is given here:

import sys
from operon_analyzer.analyze import analyze
from operon_analyzer.rules import RuleSet, FilterSet


rs = RuleSet().require('transposase') \
              .exclude('cas3') \
              .at_most_n_bp_from_anything('transposase', 500) \
              .same_orientation()

fs = FilterSet().pick_overlapping_features_by_bit_score(0.9) \
                .must_be_within_n_bp_of_anything(1000)

if __name__ == '__main__':
    analyze(sys.stdin, rs, fs)

List of available rules

  • exclude(feature_name: str): Forbid the presence of a particular feature.
  • require(feature_name: str): Require the presence of a particular feature.
  • max_distance(feature1_name: str, feature2_name: str, distance_bp: int): The two given features must be no further than distance_bp base pairs apart. Requires exactly one of each feature to be present.
  • at_least_n_bp_from_anything(feature_name: str, distance_bp: int): Requires that a feature be at least distance_bp base pairs away from any other feature. This is mostly useful for eliminating overlapping features.
  • at_most_n_bp_from_anything(feature_name: str, distance_bp: int): A given feature must be within distance_bp base pairs of another feature. Requires exactly one matching feature to be present. Returns False if the given feature is the only feature.
  • same_orientation(exceptions: Optional[List[str]] = None): All features in the operon must have the same orientation.
  • contains_any_set_of_features(sets: List[List[str]]): Returns True if the operon contains features with all of the names in at least one of the lists. Useful for determining if an operon contains all of the essential genes for a particular system, for example.
  • contains_exactly_one_of(feature1_name: str, feature2_name: str): An exclusive-or of the presence of two features. That is, one of the features must be present and the other must not.
  • contains_at_least_n_features(feature_names: List[str], feature_count: int, count_multiple_copies: bool = False): The operon must contain at least feature_count features in the list. By default, a matching feature that appears multiple times in the operon will only be counted once; to count multiple copies of the same feature, set count_multiple_copies=True.
  • contains_group(self, feature_names: List[str], max_gap_distance_bp: int, require_same_orientation: bool): The operon must contain a contiguous set of features (in any order) separated by no more than max_gap_distance_bp. Optionally, the user may require that the features must all have the same orientation.
  • maximum_size(self, feature_name: str, max_bp: int, all_matching_features_must_pass: bool = False, regex: bool = False): The operon must contain at least one feature with feature_name with a size (in base pairs) of max_bp or smaller. If all_matching_features_must_pass is True, every matching Feature must be at least max_bp long.
  • minimum_size(self, feature_name: str, min_bp: int, all_matching_features_must_pass: bool = False, regex: bool = False): The operon must contain at least one feature with feature_name with a size (in base pairs) of min_bp or larger. If all_matching_features_must_pass is True, every matching Feature must be at least min_bp long.
  • custom(rule: 'Rule'): Add a rule with a user-defined function.

List of available filters

  • must_be_within_n_bp_of_anything(distance_bp: int): If a feature is very far away from anything it's probably not part of an operon.
  • must_be_within_n_bp_of_feature(feature_name: str, distance_bp: int): There may be situations where two features always appear near each other in functional operons.
  • pick_overlapping_features_by_bit_score(minimum_overlap_threshold: float): If two features overlap by more than minimum_overlap_threshold, the one with the lower bit score is ignored.
  • custom(filt: 'Filter'): Add a filter with a user-defined function.

Analysis Output

Each line of the CSV will contain an accession ID and the path to the file that contains it, the contig coordinates, and whether it passed or failed the given rules. If it passed, the last column will contain the word pass only. Otherwise it will start with fail followed by a comma-delimited list of the serialized rules that it failed to adhere to (with the name and parameters that were passed to the method).

Visualization

Interesting operons can be visualized with a simple gene diagram. It is up to the user to decide how to define this, though this sample script below creates diagrams for all operons that passed all given rules:

import sys
from operon_analyzer.analyze import load_analyzed_operons
from operon_analyzer.visualize import build_operon_dictionary, plot_operons

analysis_csv, pipeline_csv, image_directory = sys.argv[1:]
good_operons = []

with open(pipeline_csv) as f:
    operons = build_operon_dictionary(f)
with open(analysis_csv) as f:
    for contig, filename, start, end, result in load_analyzed_operons(f):
        if result[0] != 'pass':
            continue
        op = operons.get((contig, filename, start, end))
        if op is None:
            continue
        good_operons.append(op)
plot_operons(good_operons, image_directory)

Overview Statistics

Some basic tools are provided to inspect the nature of operons that did not pass all given rules. The intent here is to help researchers determine if their filtering is too aggressive (or not aggressive enough), and to get an overall better feel for the data.

Simple bar plots can be produced as follows:

import sys
import matplotlib.pyplot as plt
from operon_analyzer.analyze import load_analyzed_operons
from operon_analyzer.overview import load_counts


def plot_bar_chart(filename, title, data, rotate=True):
    fig, ax = plt.subplots()
    x = [str(d[0]).replace(":", "\n") for d in data]
    y = [d[1] for d in data]
    ax.bar(x, y, edgecolor='k')
    if rotate:
        plt.xticks(rotation=90)
    ax.set_ylabel("Count")
    ax.set_title(title)
    plt.savefig("%s.png" % filename, bbox_inches='tight')
    plt.close()


if __name__ == '__main__':
    unique_rule_violated, failed_rule_occurrences, rule_failure_counts = load_counts(sys.stdin)
    plot_bar_chart("sole-failure.png", "Number of times that each rule\nwas the only one that failed", sorted(unique_rule_violated.items()))
    plot_bar_chart("total-failures", "Total number of rule failures", sorted(failed_rule_occurrences.items()))
    plot_bar_chart("failures-at-each-contig", "Number of rules failed at each contig", sorted(rule_failure_counts.items()), rotate=False)

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A Python package for discovery, annotation, and analysis of gene clusters in genomics or metagenomics data sets.

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