Home

Awesome

CC BY-NC-SA 4.0

Strainy

Version 1.2

Strainy is a tool for phasing and assembly of bacterial strains from long-read sequencing data (either Oxford Nanopore or PacBio). Given a reference (or collapsed de novo assembly) and set of aligned reads as input, Strainy produces multi-allelic phasing, individual strain haplotypes and strain-specific variant calls.

Compared to the current metagenomic strain profiling approaches, Strainy offers multiple unique features. First, it provides direct phasing of strains-specific variants, enabling evolutionary analysis of haplotypes rather than individual mutations. Second, Strainy provides a method to quantity strains and distinguish the most abundant and/or most divergent strains. Third, Strainy enables assembly-based analysis, which is useful in the absence of a high quality reference genome, especially in cross-samples comparison.

Contents

Installation

The recommended way of installing is through conda or mamba . Strainy is distributed via bioconda channel and can be installed using one of the following:

conda install bioconda::strainy

or

mamba install strainy

The other way is to install from the repository:

git clone https://github.com/katerinakazantseva/strainy
cd strainy
git submodule update --init
make -C submodules/Flye
conda env create -f environment.yml -n strainy

Once installed, you will need to activate the conda environment prior to running:

conda activate strainy
./strainy.py -h

Note that if you use an M1 conda installation, you should run conda config --add subdirs osx-64 before installation. Find details here

Quick usage

After repository cloning/installation, you should be able to run:

conda activate strainy
./strainy.py --gfa_ref test_set/toy.gfa --fastq test_set/toy.fastq.gz --output out_strainy --mode hifi --threads 8

The --gfa specifices input strain-collapsed graph (e.g. from de novo metagenomic assembly). --fastq specifies the matching long-read data. --output is the output directory, --mode speficies read type (either hifi or nano), --threads specifices the number of threads o use.

The output directory out_strainy will contain strain-level assmebly strain_contigs.gfa along with phased alignment alignment_phased.bam, strain variants calls strain_variants.vcf and other info. See below for the details on how to interpret strainy output.

Also see a more detailed tutorial for the example of how to use Strainy.

Docker container

Alternatively, you can use a Docker container (using the example provided in test_set Strainy directory):

ST_DIR=`pwd`
docker run -v $ST_DIR:$ST_DIR -u `id -u`:`id -g` mkolmogo/strainy:1.0 strainy --gfa $ST_DIR/test_set/toy.gfa --fastq $ST_DIR/test_set/toy.fastq.gz -o $ST_DIR/out_strainy --threads 8 --mode hifi

Strainy input

Strainy supports PacBio HiFi, Nanopore R9 (Guppy5+) and R10 sequencing.

The two main inputs to Strainy are:

Preparing de novo metagenomic assemblies

We have developed Strainy using metaFlye metagenomic assembly graphs as input. The recommended set of parameters is --meta --keep-haplotypes --no-alt-contigs -i 0.

Note that -i 0 disables metaFlye's polishing procedure, which we found to improve read assignment to bubble branches during minimap2 realignment. --keep-haplotypes retains structural variations between strains on the assembly graph. --no-alt-contigs disables the output of "alternative" contigs, which can later confuse the read aligner.

Parameters description

Required

ArgumentDescription
-o, --outputOutput directory
-g, --gfa_refInput assembly graph (.gfa) (may be produced with metaFlye or minigraph)
-f, --fasta_refInput reference fasta (for linear genome)
-q, --fastqFASTQ file containing reads ( PacBio HiFi or Nanopore sequencing)
-m, --modeType of the reads {hifi,nano}

Optional

ArgumentDescription
--snp.vcf file, with variants of the desired allele frequency. If not provided, Strainy will use the built-in pileup-based caller
-b, --bam.bam file generated by aligning the input reads to the input graph, minimap2 will be used to generate a .bam file if not provided
-a, --allele-frequencyAllele frequency threshold for built-in pileup-based caller. Will only work if --snp is not used (default: None)
-d, --cluster-divergenceThe maximum number of total mismatches allowed in the cluster per 1 kbp. Should be selected depending on SNP rates and their accuracy. Higher values can reduce high fragmentation at the cost of clustering accuracy (default: None)
--unitig-split-lengthThe length (in kb) which the unitigs that are longer will be split, set 0 to disable (default: 50 kb)
--min-unitig-coverageThe minimum coverage threshold for phasing unitigs, unitigs with lower coverage will not be phased (default: 20)
--max-unitig-coverageThe maximum coverage threshold for phasing unitigs, unitigs with higher coverage will not be phased (default: 500)
-t, --threadsNumber of threads to use (default: 4)
--debugEnables debug mode for extra logs and output
-s, --stageStage to run: phase, transform or e2e (phase + transform) (default: e2e)

Output files

Strainy tutorial

Here we illustrate Strainy usage scenario using the simulated metagenomic dataset of five E. coli strains. Download the input data:

wget https://zenodo.org/records/11187925/files/strainy_ecoli_example.tar.gz
tar -xvf strainy_ecoli_example.tar.gz

It contains simulated reads and metaFlye assembly graph. Optionally, if you want to reproduce the metaFlye assembly, you can run:

flye --nano-hq strainy_ecoli_example/ecoli_5strain_sim_badread.fastq.gz -o metaflye -t 30 --meta --no-alt-contigs --keep-haplotypes -i 0

Then, you can run Strainy using:

./strainy.py --gfa_ref strainy_ecoli_example/ecoli_5strain_metaflye_hap.gfa --fastq strainy_ecoli_example/ecoli_5strain_sim_badread.fastq.gz --mode nano -t 30 --output strainy_out

This run may take ~2h in 30 threads. If you don't want to wait, you can download results from here:

wget https://zenodo.org/records/11187925/files/strainy_ecoli_out.tar.gz
tar -xvf strainy_ecoli_out.tar.gz

Now, let's take a look at the results! multiplicity_info.txt will contain some assembly stats, and the information about strain multiplicity:

Reference utgs input:	len: 6459094	num: 515	N50:28856
Reference utgs select:	len: 6367432	num: 433	N50:29273
Reference utgs phased:	len: 5439417	num: 319	N50:31133
Strain utgs asmembled:	len: 20620769	num: 1729	N50:16393

Multiplicity
Mul	RefSeqLength
1	   1653400	********************
2	    455200	*****
3	    770300	*********
4	   1634900	*******************
5	   1547500	******************
6	    246800	**
7	     21700	
8	      8300	
10	      1800

The total input size was ~6.4Mb, and Strainy transformed it into 20.6 Mb of strain-specific sequence. ~1.6 of the input reference strain had multiplicity 1 - e.g. not collapsed, but the rest corresponded to 2+ strains. Most collapsed sequence had either 4 or 5. The bottom of the file also contains info about the divergence of the assembled strain (wrt to the collapsed reference):

SNP divergence
Rate	StrainSeq
0.03981	371500	**
0.03162	1099100	*******
0.02512	1563900	**********
0.01995	1495400	*********
0.01585	2964600	*******************
0.01259	2523100	****************
0.01000	3052800	********************
0.00794	1685300	***********
0.00631	1516200	*********
0.00501	861600	*****
0.00398	586200	***
0.00316	374300	**
0.00251	301800	*
0.00200	233500	*

Next, let's use IGV to look in more detail. Open preprocessing_data/gfa_converted.fasta as a reference, and alignment_phased.bam as a track. This shows the phased alignment, and you can enable coloring and grouping by YC tag. In addition, you can add intermediate/strain_utgs.fasta_ref_aln.bam track with the assmebled strain haplotgs. It may look something like this, clearly showing 5 read clusters and assembled haplotypes:

Strainy overview

Each variant position will be described in strain_variants.vcf. For example, the following VCF entry tells that the substitution is supported by 2 strains (enumerated in ALT_HAP), and 3 strains have reference state (enumerated in REF_HAP).

edge_308    3453    Strainy_SNP_17146   G   T   60  PASS    ALT_HAP=edge_308_119,edge_308_1000107;REF_HAP=edge_308_10015,edge_308_10014,edge_308_20016  GT:DV:D      P    0/1:2:5

But often, it may look a bit more complex. On the example eblow you see more strain clusters that sometimes do not span the entire reference unitig. This often happens if there is not enough heterozygosity to separate two or more strains:

Strainy overview

In fact, if you visualize the strain_unitigs.gfa with Bandage, you can see how these strain unitigs are connected together:

Strainy overview

Finally, phased_unitig_info_table.csv contains statistics about individual phased strain unitigs.

Overview of the Strainy algorithm

<p align="center"> <img src="img/overview.png" /> </p>

This is a brief description, and more details are available in our preprint.

The goal of the Strainy is to recover collapsed strain haplotypes from the input graph. First, input reads are mapped against the input assembly graph and the alignment is used to call SNP variants (which could also be provided as input). Then, the phasing module is used to group aligned reads into strain clusters. Afterwards, strain haplotypes are reassembled from clustered reads.

In brief, the phasing module works as follows. First, for each strain-collapsed input contig, Strainy builds a connection graph, which encodes the pairwise distances between reads aligned to this contig. Next, it clusters reads based on the strain of origin using the community detection approach. While initial clustering separates the most divergent strains, closely related strains (with less variants between them) may remain collapsed. To overcome this, Strainy recursively repeats the clustering procedure with the increased sensitivity to strain variants Clustering stringency threshold may be increased to allow collapsing of very similar strains, while separating more divergent strains.

Clustered reads are then reassembled locally using the Flye polisher, forming strain haplotigs. Strainy builds an overlap graph of these haplotigs, where paths on the graph correspond to phased strain sequence, interleaved by unphased sequences. Finally, Strainy applies graph simplification algorithms to improve the assembly contiguity. As output, Strainy provides assembled strain haplotypes, along with phased read alignment, strain variant calls (small and structural) and information about strain multiplicity and divergence.

Acknowledgements

Consensus function of Strainy is Flye

Community detection algorithm is Karate club

Contributers

Strainy was originally developed at at Kolmogorov lab at NCI

Code contributors:

Citation

Ekaterina Kazantseva, Ataberk Donmez, Maria Frolova, Mihai Pop, Mikhail Kolmogorov. "Strainy: phasing and assembly of strain haplotypes from long-read metagenome sequencing" Nature Methods 2024, https://doi.org/10.1038/s41592-024-02424-1

License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

CC BY-NC-SA 4.0