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ABySS

ABySS is a de novo sequence assembler intended for short paired-end reads and genomes of all sizes.

Please cite our papers.

Contents

Installation

Install ABySS using Conda (recommended)

If you have the Conda package manager (Linux, MacOS) installed, run:

conda install -c bioconda -c conda-forge abyss

Or you can install ABySS in a dedicated environment:

conda create -n abyss-env
conda activate abyss-env
conda install -c bioconda -c conda-forge abyss

Install ABySS using Homebrew

If you have the Homebrew package manager (Linux, MacOS) installed, run:

brew install abyss

Install ABySS on Windows

Install Windows Subsystem for Linux from which you can run Conda or Homebrew installation.

Dependencies

Dependencies for linked reads

These can be installed through Conda:

conda install -c bioconda arcs tigmint

Or Homebrew:

brew install brewsci/bio/arcs brewsci/bio/links-scaffolder

Optional dependencies

Conda:

conda install -c bioconda samtools
conda install -c conda-forge pigz zsh

Homebrew:

brew install pigz samtools zsh

Compiling ABySS from source

When compiling ABySS from source the following tools are required:

ABySS requires a C++ compiler that supports OpenMP such as GCC.

The following libraries are required:

Conda:

conda install -c conda-forge boost openmpi
conda install -c bioconda google-sparsehash btllib

It is also helpful to install the compilers Conda package that automatically passes the correct compiler flags to use the available Conda packages:

conda install -c conda-forge compilers

Homebrew:

brew install boost open-mpi google-sparsehash

ABySS will receive an error when compiling with Boost 1.51.0 or 1.52.0 since they contain a bug. Later versions of Boost compile without error.

To compile, run the following:

./autogen.sh
mkdir build
cd build
../configure --prefix=/path/to/abyss
make
make install

You may also pass the following flags to configure script:

--with-boost=PATH
--with-mpi=PATH
--with-sqlite=PATH
--with-sparsehash=PATH
--with-btllib=PATH

Where PATH is the path to the directory containing the corresponding dependencies. This should only be necessary if configure doesn't find the dependencies by default. If you are using Conda, PATH would be the path to the Conda installation. SQLite and MPI are optional dependencies.

The above steps install ABySS at the provided path, in this case /path/to/abyss. Not specifying --prefix would install in /usr/local, which requires sudo privileges when running make install.

ABySS requires a modern compiler such as GCC 6 or greater. If you have multiple versions of GCC installed, you can specify a different compiler:

../configure CC=gcc-10 CXX=g++-10

While OpenMPI is assumed by default you can switch to LAM/MPI or MPICH using:

    ../configure --enable-lammpi
    ../configure --enable-mpich

The default maximum k-mer size is 192 and may be decreased to reduce memory usage or increased at compile time. This value must be a multiple of 32 (i.e. 32, 64, 96, 128, etc):

../configure --enable-maxk=160

If you encounter compiler warnings that are not critical, you can allow the compilation to continue:

../configure --disable-werror

To run ABySS, its executables should be found in your PATH environment variable. If you installed ABySS in /opt/abyss, add /opt/abyss/bin to your PATH:

PATH=/opt/abyss/bin:$PATH

Before starting an assembly

ABySS stores temporary files in TMPDIR, which is /tmp by default on most systems. If your default temporary disk volume is too small, set TMPDIR to a larger volume, such as /var/tmp or your home directory.

export TMPDIR=/var/tmp

Modes

Bloom filter mode

The recommended mode of running ABySS is the Bloom filter mode. Specifying the Bloom filter memory budget with the B parameter enables this mode, which can reduce memory consumption by ten-fold compared to the MPI mode. B may be specified with unit suffixes 'k' (kilobytes), 'M' (megabytes), 'G' (gigabytes). If no units are specified bytes are assumed. Internally, the Bloom filter assembler allocates the entire memory budget (B * 8/9) to a Counting Bloom filter, and an additional (B/9) memory to another Bloom filter that is used to track k-mers that have previously been included in contigs.

A good value for B depends on a number of factors, but primarily on the genome being assembled. A general guideline is:

P. glauca (~20Gbp): B=500G H. sapiens (~3.1Gbp): B=50G C. elegans (~101Mbp): B=2G

For other genome sizes, the value for B can be interpolated. Note that there is no downside to using larger than necessary B value, except for the memory required. To make sure you have selected a correct B value, inspect the standard error log of the assembly process and ensure that the reported FPR value under Counting Bloom filter stats is 5% or less. This requires using verbosity level 1 with v=-v option.

MPI mode (legacy)

This mode is legacy and we do not recommend running ABySS with it. To run ABySS in the MPI mode, you need to specify the np parameter, which specifies the number of processes to use for the parallel MPI job. Without any MPI configuration, this will allow you to use multiple cores on a single machine. To use multiple machines for assembly, you must create a hostfile for mpirun, which is described in the mpirun man page.

Do not run mpirun -np 8 abyss-pe. To run ABySS with 8 threads, use abyss-pe np=8. The abyss-pe driver script will start the MPI process, like so: mpirun -np 8 ABYSS-P.

The paired-end assembly stage is multithreaded, but must run on a single machine. The number of threads to use may be specified with the parameter j. The default value for j is the value of np.

Examples

Assemble a small synthetic data set

wget http://www.bcgsc.ca/platform/bioinfo/software/abyss/releases/1.3.4/test-data.tar.gz
tar xzvf test-data.tar.gz
abyss-pe k=25 name=test B=1G \
	in='test-data/reads1.fastq test-data/reads2.fastq'

Calculate assembly contiguity statistics:

abyss-fac test-unitigs.fa test-contigs.fa test-scaffolds.fa

Assembling a paired-end library

To assemble paired reads in two files named reads1.fa and reads2.fa into contigs in a file named ecoli-contigs.fa, run the command:

abyss-pe name=ecoli k=96 B=2G in='reads1.fa reads2.fa'

The parameter in specifies the input files to read, which may be in FASTA, FASTQ, qseq, export, SRA, SAM or BAM format and compressed with gz, bz2 or xz and may be tarred. The assembled contigs will be stored in ${name}-contigs.fa and the scaffolds will be stored in ${name}-scaffolds.fa.

A pair of reads must be named with the suffixes /1 and /2 to identify the first and second read, or the reads may be named identically. The paired reads may be in separate files or interleaved in a single file.

Reads without mates should be placed in a file specified by the parameter se (single-end). Reads without mates in the paired-end files will slow down the paired-end assembler considerably during the abyss-fixmate stage.

Assembling multiple libraries

The distribution of fragment sizes of each library is calculated empirically by aligning paired reads to the contigs produced by the single-end assembler, and the distribution is stored in a file with the extension .hist, such as ecoli-3.hist. The N50 of the single-end assembly must be well over the fragment-size to obtain an accurate empirical distribution.

Here's an example scenario of assembling a data set with two different fragment libraries and single-end reads. Note that the names of the libraries (pea and peb) are arbitrary.

The command line to assemble this example data set is:

abyss-pe k=96 B=2G name=ecoli lib='pea peb' \
	pea='pea_1.fa pea_2.fa' peb='peb_1.fa peb_2.fa' \
	se='se1.fa se2.fa'

The empirical distribution of fragment sizes will be stored in two files named pea-3.hist and peb-3.hist. These files may be plotted to check that the empirical distribution agrees with the expected distribution. The assembled contigs will be stored in ${name}-contigs.fa and the scaffolds will be stored in ${name}-scaffolds.fa.

Scaffolding

Long-distance mate-pair libraries may be used to scaffold an assembly. Specify the names of the mate-pair libraries using the parameter mp. The scaffolds will be stored in the file ${name}-scaffolds.fa. Here's an example of assembling a data set with two paired-end libraries and two mate-pair libraries. Note that the names of the libraries (pea, peb, mpa, mpb) are arbitrary.

abyss-pe k=96 B=2G name=ecoli lib='pea peb' mp='mpc mpd' \
	pea='pea_1.fa pea_2.fa' peb='peb_1.fa peb_2.fa' \
	mpc='mpc_1.fa mpc_2.fa' mpd='mpd_1.fa mpd_2.fa'

The mate-pair libraries are used only for scaffolding and do not contribute towards the consensus sequence.

Scaffolding with linked reads

ABySS can scaffold using linked reads from 10x Genomics Chromium. The barcodes must first be extracted from the read sequences and added to the BX:Z tag of the FASTQ header, typically using the longranger basic command of Long Ranger or EMA preproc. The linked reads are used to correct assembly errors, which requires that Tigmint. The linked reads are also used for scaffolding, which requires ARCS. See Dependencies for installation instructions.

ABySS can combine paired-end, mate-pair, and linked-read libraries. The pe and lr libraries will be used to build the de Bruijn graph. The mp libraries will be used for paired-end/mate-pair scaffolding. The lr libraries will be used for misassembly correction using Tigmint and scaffolding using ARCS.

abyss-pe k=96 B=2G name=hsapiens \
	pe='pea' pea='lra.fastq.gz' \
	mp='mpa' mpa='lra.fastq.gz' \
	lr='lra' lra='lra.fastq.gz'

ABySS performs better with a mixture of paired-end, mate-pair, and linked reads, but it is possible to assemble only linked reads using ABySS, though this mode of operation is experimental.

abyss-pe k=96 name=hsapiens lr='lra' lra='lra.fastq.gz'

Rescaffolding with long sequences

Long sequences such as RNA-Seq contigs can be used to rescaffold an assembly. Sequences are aligned using BWA-MEM to the assembled scaffolds. Additional scaffolds are then formed between scaffolds that can be linked unambiguously when considering all BWA-MEM alignments.

Similar to scaffolding, the names of the datasets can be specified with the long parameter. These scaffolds will be stored in the file ${name}-long-scaffs.fa. The following is an example of an assembly with PET, MPET and an RNA-Seq assembly. Note that the names of the libraries are arbitrary.

abyss-pe k=96 B=2G name=ecoli lib='pe1 pe2' mp='mp1 mp2' long='longa' \
	pe1='pe1_1.fa pe1_2.fa' pe2='pe2_1.fa pe2_2.fa' \
	mp1='mp1_1.fa mp1_2.fa' mp2='mp2_1.fa mp2_2.fa' \
	longa='longa.fa'

Assembling using a paired de Bruijn graph

Assemblies may be performed using a paired de Bruijn graph instead of a standard de Bruijn graph. In paired de Bruijn graph mode, ABySS uses k-mer pairs in place of k-mers, where each k-mer pair consists of two equal-size k-mers separated by a fixed distance. A k-mer pair is functionally similar to a large k-mer spanning the breadth of the k-mer pair, but uses less memory because the sequence in the gap is not stored. To assemble using paired de Bruijn graph mode, specify both individual k-mer size (K) and k-mer pair span (k). For example, to assemble E. coli with a individual k-mer size of 16 and a k-mer pair span of 96:

abyss-pe name=ecoli K=16 k=96 in='reads1.fa reads2.fa'

In this example, the size of the intervening gap between k-mer pairs is 64 bp (96 - 2*16). Note that the k parameter takes on a new meaning in paired de Bruijn graph mode. k indicates kmer pair span in paired de Bruijn graph mode (when K is set), whereas k indicates k-mer size in standard de Bruijn graph mode (when K is not set).

Assembling a strand-specific RNA-Seq library

Strand-specific RNA-Seq libraries can be assembled such that the resulting unitigs, contigs and scaffolds are oriented correctly with respect to the original transcripts that were sequenced. In order to run ABySS in strand-specific mode, the SS parameter must be used as in the following example:

abyss-pe name=SS-RNA B=2G k=96 in='reads1.fa reads2.fa' SS=--SS

The expected orientation for the read sequences with respect to the original RNA is RF. i.e. the first read in a read pair is always in reverse orientation.

Optimizing the parameters k and kc

It is standard practice when running ABySS to run multiple assemblies to find the optimal values for the k and kc parameters. k determines the k-mer size in the de Bruijn Graph, and kc is the k-mer minimum coverage multiplicity cutoff, which filters out erroneous k-mers. The range in which k should be tested depends on the read size and read coverage.

A rough indicator is, for 2x150bp reads and 40x coverage, the right k value is often around 70 to 90. For 2x250bp reads and 40x coverage, the right value might be around 110 to 140.

For kc, 2 is most often a good value, but can go as high as 4.

The following shell snippet will assemble for k values 2 and 3, and every eighth value of k from 50 to 90. In the end, we calculate the contiguity statistics, as a proxy for identifying the optimal assembly. Other metrics can be used, as needed.

for kc in 2 3; do
	for k in `seq 50 8 90`; do
		mkdir k${k}-kc${kc}
		abyss-pe -C k${k}-kc${kc} name=ecoli B=2G k=$k kc=$kc in=../reads.fa
	done
done
abyss-fac k*/ecoli-scaffolds.fa

The default maximum value for k is 192. This limit may be changed at compile time using the --enable-maxk option of configure. It may be decreased to 32 to decrease memory usage or increased to larger values.

Running ABySS on a cluster

ABySS integrates well with cluster job schedulers, such as:

For example, to submit an array of jobs to assemble every eighth value of k between 50 and 90 using 64 processes for each job:

qsub -N ecoli -pe openmpi 64 -t 50-90:8 \
	<<<'mkdir k$SGE_TASK_ID && abyss-pe -C k$SGE_TASK_ID in=/data/reads.fa'

Using the DIDA alignment framework

ABySS supports the use of DIDA (Distributed Indexing Dispatched Alignment), an MPI-based framework for computing sequence alignments in parallel across multiple machines. The DIDA software must be separately downloaded and installed from http://www.bcgsc.ca/platform/bioinfo/software/dida. In comparison to the standard ABySS alignment stages which are constrained to a single machine, DIDA offers improved performance and the ability to scale to larger targets. Please see the DIDA section of the abyss-pe man page (in the doc subdirectory) for details on usage.

Assembly Parameters

Parameters of the driver script, abyss-pe

Environment variables

abyss-pe configuration variables may be set on the command line or from the environment, for example with export k=96. It can happen that abyss-pe picks up such variables from your environment that you had not intended, and that can cause trouble. To troubleshoot that situation, use the abyss-pe env command to print the values of all the abyss-pe configuration variables:

abyss-pe env [options]

ABySS programs

abyss-pe is a driver script implemented as a Makefile. Any option of make may be used with abyss-pe. Particularly useful options are:

abyss-pe uses the following programs, which must be found in your PATH:

This flowchart shows the ABySS assembly pipeline and its intermediate files.

Export to SQLite Database

ABySS has a built-in support for SQLite database to export log values into a SQLite file and/or .csv files at runtime.

Database parameters

Of abyss-pe:

For example, to export data of species 'Ecoli', strain 'O121' and library 'pea' into your SQLite database repository named '/abyss/test.sqlite':

abyss-pe db=/abyss/test.sqlite species=Ecoli strain=O121 library=pea [other options]

Helper programs

Found in your path:

Usage:

abyss-db-txt /your/repository
abyss-db-csv /your/repository program(s)

For example,

abyss-db-txt repo.sqlite
abyss-db-csv repo.sqlite DistanceEst
abyss-db-csv repo.sqlite DistanceEst abyss-scaffold
abyss-db-csv repo.sqlite --all

Citation

ABySS 2.0

Shaun D Jackman, Benjamin P Vandervalk, Hamid Mohamadi, Justin Chu, Sarah Yeo, S Austin Hammond, Golnaz Jahesh, Hamza Khan, Lauren Coombe, René L Warren, and Inanc Birol (2017). ABySS 2.0: Resource-efficient assembly of large genomes using a Bloom filter. Genome research, 27(5), 768-777. doi:10.1101/gr.214346.116

ABySS

Simpson, Jared T., Kim Wong, Shaun D. Jackman, Jacqueline E. Schein, Steven JM Jones, and Inanc Birol (2009). ABySS: a parallel assembler for short read sequence data. Genome research, 19(6), 1117-1123. doi:10.1101/gr.089532.108

Related Publications

RResolver

Vladimir Nikolić, Amirhossein Afshinfard, Justin Chu, Johnathan Wong, Lauren Coombe, Ka Ming Nip, René L. Warren & Inanç Birol (2022). RResolver: efficient short-read repeat resolution within ABySS. BMC Bioinformatics 23, Article number: 246 (2022). doi:10.1186/s12859-022-04790-z

Trans-ABySS

Robertson, Gordon, Jacqueline Schein, Readman Chiu, Richard Corbett, Matthew Field, Shaun D. Jackman, Karen Mungall, et al (2010). De novo assembly and analysis of RNA-seq data. Nature methods, 7(11), 909-912. doi:10.1038/10.1038/nmeth.1517

ABySS-Explorer

Nielsen, Cydney B., Shaun D. Jackman, Inanc Birol, and Steven JM Jones (2009). ABySS-Explorer: visualizing genome sequence assemblies. IEEE Transactions on Visualization and Computer Graphics, 15(6), 881-888. doi:10.1109/TVCG.2009.116

Support

Create a new issue on GitHub.

Ask a question on Biostars.

Subscribe to the ABySS mailing list, abyss-users@googlegroups.com.

For questions related to transcriptome assembly, contact the Trans-ABySS mailing list, trans-abyss@googlegroups.com.

Authors

Supervised by Dr. Inanc Birol.

Copyright 2016-present Canada's Michael Smith Genome Sciences Centre