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GraphMap2 - A highly sensitive and accurate mapper for long, error-prone reads

Current Version: 0.6.3
Release date: 15 November 2019

Cigar string different from read length bug fixed. Segmentation fault in ksw2 fixed. Version bumped.

Previous Version: 0.6.1
Release date: 30 July 2019

Version, containing tuning of alignments specific for long RNA reads.

Mapping RNA-seq reads

To activate spliced alignments mode, specify -x rnaseq alongside to other command line parameters. Install and compile in the testing mode as such:

git clone https://github.com/lbcb-sci/graphmap2  
cd graphmap2  
make modules  
make  

After this, run GraphMap2 using:

bin/graphmap2 align -x rnaseq -r ref.fa -d reads.fastq -o out.sam  

Previous Version: 0.5.2
Release date: 26 May 2017

Bugfix version, addressing several segfault and other important issues:

  • Fixed mapping outside of reference bounds.
  • Merged a pull request with some useful insanity tests (thanks @robegan21).
  • Changed the unmapped / Inf E-value (the ZE:f: tag) to be a valid float value (std::numeric_limits<float>::max() instead of Inf).
  • Added several missing #includes.

Previous Version: 0.5.1
Release date: 04 March 2017

Patch version resolving huge memory consumption when building the index.
Index construction now consumes similar amount of memory as the final constructed index.
Index files (stored to disk) constructed using v0.5.0 are fully compatible with v0.5.1 and can be used directly.

*new* - Minimizer index
The hash index has now been completely reimplemented.
Index construction is now much faster than before.

There are several new important features to mention:

  • The index supports minimizers - the minimizer window size can be specified via command line and by default is equal to 5. To switch off minimizers, use --minimizer-window 1.
  • The number of hits for each seed lookup is now thresholded by a percentile value, e.g. --freq-percentile 0.99 means that 1% of the most repetitive seeds will be skipped. To turn off this feature, specify --freq-percentile 1.0. This feature slightly reduces sensitivity, but plays a huge role when mapping to large references.
  • --fly-index enables building the index on the fly, instead of storing it to disk.
  • To switch off minimizers and percentile filtering, there is a composite option -x sensitive. This will produce results similar to previous versions.
  • In case the version of an index file is not compatible with GraphMap, previous versions would automatically overwrite the index file. This is now prevented by default, and GraphMap now simply halts with a command line message. To force automatic rebuild if necessary (but not rebuild if a valid index file exists), use: --auto-rebuild-index. To rebuild the index in any case, specify: --rebuild-index.
  • Renamed the --sensitive mode to --double-index

Owler overlapping mode was also enhanced with the new index, and now works much faster on larger datasets. Also, Owler allows for spaced seeds, and a custom shape can be specified via commandline (--shape parameter, default is a full 15bp seed).

Many bug fixes were also made, including the ones related to mapping to circular references, various segfaults, and extra new lines when outputting secondary alignments. Some of the segfaults were caused by the index, which is now addressed with the new version.

Also, this release fixes an issue with transcriptome mapping, where recall would drop (however, not precision).

Important - GraphMap's index is actually a hash table of seed positions, and is therefore larger than the index for mappers which use the BWT. An estimate of the size of the index is about ~14 x reference_size for the final index. This means that for a human genome, constructing the index would peak at about ~42 GB. Smaller indexes can be achieved by using a larger minimizer window (--minimizer-window), but this will probably cause a drop in sensitivity.

Mapping to transcriptomes
GraphMap can now accept a GTF file to internally construct a transcriptome sequence from a given reference genome, and map RNA-seq data to it. The final alignments are converted back to genome space by placing N operations in the CIGAR strings.

To use the new transcriptome mapping option simply specify a GTF file using the --gtf option:
graphmap2 align -r reference.fa --gtf reference.gtf -d reads.fastq -o out.sam

For a detailed change log from the previous release, take a look at doc/changelog.md.

For more information on overlapping, take a look at overlap.md.
For detailed installation instructions, take a look at INSTALL.md file.
Description of custom parameters in GraphMap's SAM output can be found at doc/sam_output.md.

Features

  • Mapping position agnostic to alignment parameters.
  • Consistently very high sensitivity and precision across different error profiles, rates and sequencing technologies even with default parameters.
  • Circular genome handling to resolve coverage drops near ends of the genome.
  • E-value.
  • Meaningful mapping quality.
  • Various alignment strategies (semiglobal bit-vector and Gotoh, anchored).
  • Overlapping of reads for de novo assembly.
  • Transcriptome mapping through internal construction of a transcriptome from a given genomic reference and a GTF file.
  • ...and much more.

GraphMap is also used as an overlapper in a new de novo genome assembly project called Ra (https://github.com/mariokostelac/ra-integrate).
Ra attempts to create de novo assemblies from raw nanopore and PacBio reads without requiring error correction, for which a highly sensitive overlapper is required.

Currently, development of a new spliced-alignment mode for mapping RNA-seq reads is under way.
Description of the current effort as well as how to reach the experimental implementation can be found here: doc/rnaseq.md.

Quick start on Linux x64

git clone https://github.com/lbcb-sci/graphmap2.git  
cd graphmap2
make modules  
make  

# To align:  
./bin/Linux-x64/graphmap2 align -r reference.fa -d reads.fasta -o output.sam  

# To overlap:  
./bin/Linux-x64/graphmap2 owler -r reads.fasta -d reads.fasta -o output.mhap  

Description

GraphMap is a novel mapper targeted at aligning long, error-prone third-generation sequencing data.
It is designed to handle Oxford Nanopore MinION 1d and 2d reads with very high sensitivity and accuracy, and also presents a significant improvement over the state-of-the-art for PacBio read mappers.

GraphMap was also designed for ease-of-use: the default parameters can handle a wide range of read lengths and error profiles, including: Illumina, PacBio and Oxford Nanopore.
This is an especially important feature for technologies where the error rates and error profiles can vary widely across, or even within, sequencing runs.

The GraphMap algorithm is structured to achieve high-sensitivity and speed using a five-stage read-funneling approach. In stage I, GraphMap uses a novel adaptation of gapped spaced seeds to efficiently reduce the search space and get seed hits as a form of coarse alignment. These are then refined in stage II using graph-based vertex-centric processing of seeds to efficiently construct alignment anchors. GraphMap then chains anchors using a kmer version of longest common subsequence (LCSk) construction (stage III), refines alignments by chaining anchors in the anchored mode or with a form of L1 linear regression in the semiglobal alignment mode (stage IV) and finally evaluates the remaining candidates to select the best location to reconstruct a final alignment (stage V). GraphMap computes a BLAST-like E-value as well as a mapping quality for its alignments.

Evaluation on MinION sequencing datasets against short and long-read mappers indicates that GraphMap increases mapping sensitivity by at least 15-80%. GraphMap alignments are the first to demonstrate consensus calling with <1 error in 100,000 bases, variant calling on the human genome with 76% improvement in sensitivity over the next best mapper (BWA-MEM), precise detection of structural variants from 100bp to 4kbp in length and species and strain-specific identification of pathogens using MinION reads.

Further details about the algorithm, comparison with other mappers and usage applications can be found in the preprint of our paper:
Fast and sensitive mapping of error-prone nanopore sequencing reads with GraphMap

Nanopore sequencing data of E. Coli UTI89 generated in-house and used in the paper now available on ENA:
PRJEB9557

Installation

To build GraphMap from source type:

make modules	# This pulls the latest version of all required submodules
make

You will need a recent GCC/G++ version (>=4.7).

Run sudo make install to install the graphmap binary to /usr/bin.

More installation instructions can be found in the INSTALL.md file.

Usage examples

# **Align** all reads from a given FASTA/FASTQ file using anchored alignment approach:  
./graphmap2 align -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# **Overlap** all reads from a given FASTA/FASTQ file and report overlaps in MHAP format (fast):  
./graphmap2 owler -r reads.fa -d reads.fa -o overlaps.mhap  

# **Align** all reads to a transcriptome sequence:  
./graphmap2 align -r scerevisiae.fa --gtf scerevisiae.gtf -d reads.fastq -o alignments.sam  


# Align all reads and report alignments using the extended CIGAR format.  
./graphmap2 align -r escherichia_coli.fa -d reads.fastq -o alignments.sam --extcigar  

# Align all reads from a given FASTA/FASTQ file with default number of threads using semiglobal bit-vector alignment:  
./graphmap2 align -a sg -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Overlap all reads from a given FASTA/FASTQ in a full GraphMap mode with generating alignments (slow):  
./graphmap2 align -x overlap -r reads.fa -d reads.fa -o overlaps.sam  

# Align reads using the Gotoh for semiglobal alignment:  
./graphmap2 align -a sggotoh -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Align reads using Gotoh alignment with anchored approach:  
./graphmap2 align -a anchorgotoh -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Process reads from a circular genome:  
./graphmap2 align -C -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Threshold the E-value of alignments to 1e-100. Alignments with E-value > 1e-100 will be called unmapped:  
./graphmap2 align --evalue 1e-100 -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Output all secondary alignments instead of only one best:  
./graphmap2 align --secondary -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Control the similarity for secondary alignments. All alignments to within F*num_covered_bases from the best will be output.  
./graphmap2 align --secondary -F 0.05 -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Limit the number of threads to 8, and load reads in batches of 50MB:  
./graphmap2 align -t 8 -B 50 -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Align reads using more sensitive parameters for Illumina data:  
./graphmap2 align -x illumina -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Load all reads in one batch and align only the first 1000 reads:  
./graphmap2 align -B 0 -n 1000 -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Rebuild the index if it already exists:  
./graphmap2 align --rebuild-index -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

# Generate only the index.  
./graphmap2 align -I -r escherichia_coli.fa  

# Run a debug version of GraphMap (build with "make debug") and verbose the SAM output to see various info about alignment:  
./graphmap-debug align -b 3 -r escherichia_coli.fa -d reads.fastq -o alignments.sam  

Contact information

For additional information, help and bug reports please send an email to one of the following:
ivan.sovic@irb.hr, mile.sikic@fer.hr, nagarajann@gis.a-star.edu.sg

Acknowledgement

This work was supported by the IMaGIN platform (project No. 102 101 0025), through a grant from the Science and Engineering Research Council, funding to the Genome Institute of Singapore from the Agency for Science, Technology and Research (A*STAR), Singapore, and funding from the Croatian Science Foundation (Project no. UIP-11-2013-7353 - Algorithms for Genome Sequence Analysis).

We would like to acknowledge the contribution of Ivan Krpelnik for his help and involvement in development of the transcriptome mapping option.

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