hicstuff 3.2.3

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Description:

hicstuff 3.2.3

hicstuff









A lightweight library that generates and handles Hi-C contact maps in either cooler-compatible 2Dbedgraph or instaGRAAL format. It is essentially a merge of the yahcp pipeline, the hicstuff library and extra features illustrated in the 3C tutorial and the DADE pipeline, all packaged together for extra convenience.
The goal is to make generation and manipulation of Hi-C matrices as simple as possible and work for any organism.
Table of contents

Installation

pip
conda
docker


Usage

Full pipeline
Individual components


Library
Connecting the modules
File formats
Contributing

Installation
pip
To install a stable version:
pip3 install -U hicstuff

or, for the latest development version:
pip3 install -e git+https://github.com/koszullab/hicstuff.git@master#egg=hicstuff

bowtie2, bwa and/or minimap2 as well as samtools are required by the pipeline command.
You can install them via the conda package manager:
conda install -c bioconda bowtie2 bwa minimap2 samtools

Alternatively, on ubuntu you can also install them along with additional dependencies through APT:
apt-get install bowtie2 bwa minimap2 samtools libbz2-dev liblzma-dev

Conda
hicstuff is available as a bioconda package. It can be installed, along with all dependencies using:
conda install -c bioconda hicstuff

Docker
A pre-built docker image is made available on quay.io via biocontainers and can be ran using:
docker pull quay.io/biocontainers/hicstuff:<tag>

Usage
The hicstuff command line interface is composed of multiple subcommands. You can always get a summary of all available commands by running:
hicstuff --help

Simple Hi-C pipeline for generating and manipulating contact matrices.

usage:
hicstuff [-hv] <command> [<args>...]

options:
-h, --help shows the help
-v, --version shows the version

The subcommands are:
convert Convert Hi-C data between different formats.
digest Digest genome into a list of fragments.
cutsite Preprocess fastq files by digesting reads at religation site.
distancelaw Analyse and plot distance law.
filter Filters Hi-C pairs to exclude spurious events.
iteralign Iteratively aligns reads to a reference genome.
missview Preview missing Hi-C bins in based on the genome and read length.
pipeline Hi-C pipeline to generate contact matrix from fastq files.
rebin Bin the matrix and regenerate files accordingly.
subsample Bootstrap subsampling of contacts from a Hi-C map.
view Visualize a Hi-C matrix.

Full pipeline
All components of the pipeline can be run at once using the hicstuff pipeline command. This allows to generate a contact matrix from reads in a single command. By default, the output is in GRAAL compatible COO sparse matrix format, but it can be a 2D bedgraph or cool file instead using the --matfmt option. More detailed documentation can be found on the readthedocs website: https://hicstuff.readthedocs.io/en/latest/index.html
usage:
pipeline [--aligner=bowtie2] [--centromeres=FILE] [--circular] [--distance-law]
[--duplicates] [--enzyme=5000] [--filter] [--force] [--mapping=normal]
[--matfmt=graal] [--no-cleanup] [--outdir=DIR] [--plot] [--prefix=PREFIX]
[--quality-min=30] [--read-len=INT] [--remove-centromeres=0] [--size=0]
[--start-stage=fastq] [--threads=1] [--tmpdir=DIR] --genome=FILE <input1> [<input2>]

arguments:
input1: Forward fastq file, if start_stage is "fastq", sam
file for aligned forward reads if start_stage is
"bam", or a .pairs file if start_stage is "pairs".
input2: Reverse fastq file, if start_stage is "fastq", sam
file for aligned reverse reads if start_stage is
"bam", or nothing if start_stage is "pairs".

For example, to run the pipeline with minimap2 using 8 threads and generate a matrix in instagraal format in the directory out:
hicstuff pipeline -t 8 -a minimap2 -e DpnII -o out/ -g genome.fa reads_for.fq reads_rev.fq

If you have already aligned your reads, hicstuff pipeline can also take bam files as input. For example,
to generate a matrix in cool format with a fixed bin size of 5kb:
# Note the bam files have to be name-sorted, this can be done using samtools
samtools sort -n aligned_for.bam -o namesorted_for.bam
samtools sort -n aligned_rev.bam -o namesorted_rev.bam
hicstuff pipeline -S bam -e 5000 -M cool -o out/ -g genome.fa namesorted_for.bam namesorted_rev.bam

The pipeline can also be run from python, using the hicstuff.pipeline submodule. For example, this would run the pipeline with bowtie2 (default) using cutsiste alignment and keep all intermediate files. For more examples using the API, see the API demo
from hicstuff import pipeline as hpi

hpi.full_pipeline(
'genome.fa',
'end1.fq',
'end2.fq',
no_cleanup=True
mapping='cutsite',
out_dir='out',
enzyme="DpnII")

The general steps of the pipeline are as follows:

Individual components
For more advanced usage, different scripts can be used independently on the command line to perform individual parts of the pipeline. This readme contains quick descriptions and example usages. To obtain detailed instructions on any subcommand, one can use hicstuff <subcommand> --help.
Digestion of the reads
Generates new gzipped fastq files from original fastq. The function will cut the reads at their religation sites and creates new pairs of reads with the different fragments obtained after cutting at the digestion sites.
usage:
cutsite --forward=FILE --reverse=FILE --prefix=STR --enzyme=STR
[--mode=for_vs_rev] [--seed-size=20] [--threads=1]

Iterative alignment
Truncate reads from a fastq file to 20 basepairs and iteratively extend and re-align the unmapped reads to optimize the proportion of uniquely aligned reads in a 3C library.
usage:
iteralign [--aligner=bowtie2] [--threads=1] [--min-len=20] [--read-len=INT]
[--tempdir=DIR] --out-bam=FILE --genome=FILE <reads.fq>

Digestion of the genome
Digests a fasta file into fragments based on a restriction enzyme or a
fixed chunk size. Generates two output files into the target directory
named "info_contigs.txt" and "fragments_list.txt"
usage:
digest [--plot] [--figdir=FILE] [--force] [--circular] [--size=0]
[--outdir=DIR] --enzyme=ENZ <fasta>

For example, to digest the yeast genome with MaeII and HinfI and show histogram of fragment lengths:
hicstuff digest --plot --outdir output_dir --enzyme MaeII,HinfI Sc_ref.fa
Filtering of 3C events
Filters spurious 3C events such as loops and uncuts from the library based on a minimum distance threshold automatically estimated from the library by default. Can also plot 3C library statistics. This module takes a pairs file with 9 columns as input (readID, chr1, pos1, chr2, pos2, strand1, strand2, frag1, frag2) and filters it.
usage:
filter [--interactive | --thresholds INT-INT] [--plot]
[--figdir FILE] [--prefix STR] <input> <output>

Viewing the contact map
Visualize a Hi-C matrix file as a heatmap of contact frequencies. Allows to
tune visualisation by binning and normalizing the matrix, and to save the
output image to disk. If no output is specified, the output is displayed.
usage:
view [--binning=1] [--despeckle] [--frags FILE] [--trim INT] [--n-mad 3.0] [--lines]
[--normalize] [--min=0] [--max=99%] [--output=IMG] [--cmap=Reds] [--dpi=300]
[--transform=STR] [--circular] [--region=STR] <contact_map> [<contact_map2>]

arguments:
contact_map Sparse contact matrix in bg2, cool or graal format
contact_map2 Sparse contact matrix in bg2, cool or graal format,
if given, the log ratio of contact_map/contact_map2
will be shown.

For example, to view a 1Mb region of chromosome 1 from a full genome Hi-C matrix rebinned at 10kb:
hicstuff view --normalize --binning 10kb --region chr1:10,000,000-11,000,000 --frags fragments_list.txt contact_map.tsv

Library
All components of the hicstuff program can be used as python modules. See the documentation on reathedocs. The expected contact map format for the library is a simple CSV file, and the objects handled by the library are simple numpy arrays. The various submodules of hicstuff contain various utilities.
import hicstuff.cutsite # Functions to digest fastq librairies
import hicstuff.digest # Functions to work with restriction fragments
import hicstuff.iteralign # Functions related to iterative alignment
import hicstuff.hicstuff # Contains utilities to modify and operate on contact maps as numpy arrays
import hicstuff.filter # Functions for filtering 3C events by type (uncut, loop)
import hicstuff.view # Utilities to visualise contact maps
import hicstuff.io # Reading and writing hicstuff files
import hicstuff.pipeline # Generation and processing of files to generate matrices.

Connecting the modules
All the steps described here are handled automatically when running the hicstuff pipeline. But if you want to connect the different modules manually, the intermediate input and output files can be processed using some python scripting.
Aligning the reads
You can generate SAM files independently using your favorite read mapping software, use the command line utility hicstuff iteralign, or use the helper function align_reads in the submodule hicstuff.pipeline. For example, to perform iterative alignment using bwa (instead of bowtie2 by default):
Using the python function:
from hicstuff import pipeline as hpi

hpi.align_reads("end1.fastq", "genome.fasta", "end1.bam", iterative=True, aligner='bwa')

Using the command line tool:
hicstuff iteralign --aligner bwa --genome genome.fasta --out-bam end1.bam end1.fastq

Extracting contacts from the alignment
The output from hicstuff iteralign is a BAM file. In order to retrieve Hi-C pairs, you need to run iteralign separately on the two fastq files and process the resulting alignment files into a name-sorted BAM file as follows using the pipeline submodules of hicstuff.
from hicstuff import pipeline as hpi
import pysam as ps
# Sort alignments by read names and get into BAM format
ps.sort("-n", "-O", "BAM", "-o", "end1.bam.sorted", "end1.bam")
ps.sort("-n", "-O", "BAM", "-o", "end2.bam.sorted", "end2.bam")
# Combine BAM files
hpi.bam2pairs("end1.sorted.bam", "end2.sorted.bam", "output.pairs", "info_contigs.txt", min_qual=30)

This will generate a "pairs" file containing all read pairs where both reads have been aligned with a mapping quality of at least 30.
Attributing each read to a restriction fragment
To build a a contact matrix, we need to attribute each read to a fragment in the genome. This is done under the hood by performing a binary search for each read position against the list of restriction sites in the genome.
from hicstuff import digest as hcd
from Bio import SeqIO

# Build a list of restriction sites for each chromosome
restrict_table = {}
for record in SeqIO.parse("genome.fasta", "fasta"):
# Get chromosome restriction table
restrict_table[record.id] = hcd.get_restriction_table(
record.seq, enzyme, circular=circular
)

# Add fragment index to pairs (readID, chr1, pos1, chr2,
# pos2, strand1, strand2, frag1, frag2)
hcd.attribute_fragments("output.pairs", "output_indexed.pairs", restrict_table)

Filtering pairs
The resulting pairs file can then be filtered, either in the command line using the hicstuff filter command, or in python using the hicstuff.filter submodule. Otherwise, the matrix can be built directly from the unfiltered pairs.
Filtering on the command line:
hicstuff filter output_indexed.pairs output_filtered.pairs

Filtering in python:
from hicstuff import filter as hcf

uncut_thr, loop_thr = hcf.get_thresholds("output_indexed.pairs")
hcf.filter_events("output_indexed.pairs", "output_filtered.pairs", uncut_thr, loop_thr)

Note that both the command and the python function have various options to generate figure or tweak the filtering thresholds. These options can be displayed using hicstuff filter -h
Matrix generation
A Hi-C sparse contact matrix can then be generated using the python submodule hicstuff.pipeline. The matrix can be generated in GRAAL-compatible COO format, bedgraph2 or cool format.
from hicstuff import pipeline as hpi

n_frags = sum(1 for line in open(fragments_list, "r")) - 1
hpi.pairs2matrix("output_filtered.pairs", "abs_fragments_contacts_weighted.txt", 'fragments_list.txt', mat_fmt="GRAAL")

File formats

pairs files: This format is used for all intermediate files in the pipeline and is also used by hicstuff filter. It is a tab-separated format holding informations about Hi-C pairs. It has an official specification defined by the 4D Nucleome data coordination and integration center.
2D bedgraph: This is an optional output format of hicstuff pipeline for the sparse matrix. It has two fragment per line, and the number of times they are found together. It has the following fields: chr1, start1, end1, chr2, start2, end2, occurences

Those files can be loaded by cooler using cooler load -f bg2 <chrom.sizes>:<binsize> in.bg2.gz out.cool where chrom.sizes is a tab delimited file with chromosome names and length on each line, and binsize is the size of bins in the matrix.


GRAAL sparse matrix: This is a simple tab-separated file with 3 columns: frag1, frag2, contacts. The id columns correspond to the absolute id of the restriction fragments (0-indexed). The first row is a header containing the number of rows, number of columns and number of nonzero entries in the matrix. Example:

564 564 6978
0 0 3
1 2 4
1 3 3



fragments_list.txt: This tab separated file provides information about restriction fragments positions, size and GC content. Note the coordinates are 0 point basepairs, unlike the pairs format, which has 1 point basepairs. Example:

id: 1 based restriction fragment index within chromosome.
chrom: Chromosome identifier. Order should be the same as in info_contigs.txt or pairs files.
start_pos: 0-based start of fragment, in base pairs.
end_pos: 0-based end of fragment, in base pairs.
size: Size of fragment, in base pairs.
gc_content: Proportion of G and C nucleotide in the fragment.



id chrom start_pos end_pos size gc_content
1 seq1 0 21 21 0.5238095238095238
2 seq1 21 80 59 0.576271186440678
3 seq1 80 328 248 0.5201612903225806


info_contigs.txt: This tab separated file gives information on contigs, such as number of restriction fragments and size. Example:

contig: Chromosome identified. Order should be the same in pairs files or fragments_list.txt.
length: Chromosome length, in base pairs.
n_frags: Number of restriction fragments in chromosome.
cumul_length: Cumulative length of previous chromosome, in base pairs.



contig length n_frags cumul_length
seq1 60000 409 0
seq2 20000 155 409

Contributing
All contributions are welcome, in the form of bug reports, suggestions, documentation or pull requests.
We use the numpy standard for docstrings when documenting functions.
The code formatting standard we use is black, with --line-length=79 to follow PEP8 recommendations. We use pytest with the pytest-doctest and pytest-pylint plugins as our testing framework. Ideally, new functions should have associated unit tests, placed in the tests folder.
To test the code, you can run:
pytest --doctest-modules --pylint --pylint-error-types=EF --pylint-rcfile=.pylintrc hicstuff tests

Citation
Please cite hicstuff using the official DOI as follows:
Cyril Matthey-Doret, Lyam Baudry, Amaury Bignaud, Axel Cournac, Remi-Montagne, Nadège Guiglielmoni, Théo Foutel Rodier and Vittore F. Scolari. 2020. hicstuff: Simple library/pipeline to generate and handle Hi-C data . Zenodo. http://doi.org/10.5281/zenodo.4066363
Bibtex entry:
@software{cyril_matthey_doret_2020_4066351,
author = {Cyril Matthey-Doret and
Lyam Baudry and
Amaury Bignaud and
Axel Cournac and
Remi-Montagne and
Nadège Guiglielmoni and
Théo Foutel-Rodier and
Vittore F. Scolari},
title = {hicstuff: Simple library/pipeline to generate and handle Hi-C data },
month = oct,
year = 2020,
publisher = {Zenodo},
version = {v2.3.1},
doi = {10.5281/zenodo.4066351},
url = {http://doi.org/10.5281/zenodo.4066363}
}

License

For personal and professional use. You cannot resell or redistribute these repositories in their original state.

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