Skip to main content

Representative taxon sampling from phylogenetic trees

Project description

PARNAS

PARNAS identifies taxa that best represent diversity on a phylogenetic tree and solves urgent needs in virology, such as

  • Objectively finding representative strains for detailed analysis (phenotypic characterization, Bayesian inference, etc.)
  • Vaccine strain selection

PARNAS can take into account previous selections and user's constraints. Additionally, PARNAS is flexible in allowing arbitrary weighing of taxa, e.g., based on predicted fitness/antigenic drift. More broadly PARNAS can be used to

  • Downsample a large phylogeny while optimally preserving the underlying diversity
  • Reduce redundancy among genetic/genomic sequences
  • Identify key diversity groups on a phylogeny

PARNAS is faster and more flexible than ADCL by Matsen et al. (Systematic Biology 2013), which provides a subset PARNAS-enabled functionality.

Installation

To install PARNAS, clone or download this project and run python setup.py install. Note that PARNAS requires Python 3.7 or higher.

PARNAS depends on dendropy and Biopython for phylogenetic and MSA manipulations, numpy and numba for just-in-time compilation of the critical algorithms into machine code, and (optionally) phylo-treetime to infer ancestral substitutions along tree edges. These dependencies will be installed automatically.

Tutorial

We use a human H1N1 (pdm09) dataset with HA sequences collected in 2020, downloaded from IRD, for this tutorial. The alignment and an inferred rooted tree can be found in the tutorial folder.

The basic usage of PARNAS is to find a fixed number of representative taxa, as follows:
parnas -t H1N1_human_2020_IRD.rooted.tre -n 3 --color "H1N1_parnas_n3.tre"
PARNAS will identify 3 best representative strains and save a colored tree to H1N1_parnas_n3.tre. Opening this tree in FigTree, will show the representatives and their respective clusters of strains with different colors. Below is the H1N1_parnas_n3.tre output tree, when opened in FigTree. Each color corresponds to one PARNAS-selected representative and the area of the tree it represents.

Additionally, in the output PARNAS specifies the amount of overall diversity covered by the chosen representatives, which is 43% for our dataset.

Determining the right number of representatives

The "diversity covered" metric calculated by PARNAS is a useful tool to determine how many representatives is sufficient. To find the amount of diversity covered by different numbers of representatives, you can choose a large enough n, e.g., n=20, and run
parnas -t H1N1_human_2020_IRD.rooted.tre -n 20 --diversity "diversity_scores.csv"
This command will save a CSV file with optimal diversity scores for n between 2 and 20. For our dataset, it shows that only 6 representative strains are needed to cover over 60% of the overall diversity. Opening the CSV file in Excel/Numbers, one can then construct the following graph to better visualize the data.

Using prior representatives

It often may be useful to find new representatives, while specifying the previous taxa/strains that were treated as representatives. In our H1N1 dataset, we included two latest H1N1 vaccine strains, A/Wisconsin/588/2019 and A/Hawaii/70/2019. Using PARNAS we can fix these two strains as 'prior' representatives and find new representatives, so that old and new representatives work optimally together. We use --prior option to notify PARNAS of the two vaccine strains by specifying a regular expression matching their names in our dataset (which start with "Vaccine|"):
parnas -t H1N1_human_2020_IRD.rooted.tre -n 3 --prior "Vaccine.*" --color "H1N1_parnas_n3_vaccines.tre"
The result is shown in a tree below. PARNAS colors the prior representatives and the respective parts of the tree in red.

Specifying a coverage radius

You can notify PARNAS that a single taxon 'covers' other taxa within a fixed radius (using --radius option). PARNAS will then find representatives, which together cover as much diversity as possible. Alternatively, PARNAS can find the minimum number of representatives that jointly cover all diversity on the tree (--cover option). This feature can be used to optimally reduce the redundancy in your dataset. Moreover, this feature was motivated by applications in virology, where evolutionary distance often correlates with antigenic drift. For example, in swine influenza A virus research, 5% (amino acid) divergence between HA sequences is considered a correlate of loss in cross-reactivity between strains. Therefore, specifying a radius on a tree corresponding to ~4% sequence divergence, can help identify good vaccine candidates.

To further facilitate this process, PARNAS can take amino acid sequence alignment and pass it to TreeTime to find ancestral AA substitutions along the tree edges. It will then re-scale the tree, so that edge lengths will reflect the number of substitutions along that edge, which will help specify a 4% divergence radius in terms of the # of amino acid substitutions.

parnas -t H1N1_human_2020_IRD.rooted.tre --cover --threshold 96 --aa H1N1_human_2020_IRD.ha1.aln --color "parnas_96coverage.tre"

In the above command we pass the AA alignment of HA1 sequences from our dataset with the --aa option, and specify the 96% threshold (i.e., 4% sequence divergence). Note that --threshold works as a substitute for --radius, when you would like PARNAS to use the alignment information and re-scale the tree. Running this command will show that a single strain (A/Wisconsin/32/2020) is sufficient to cover all diversity on our tree.

Next, we use a more restrictive threshold of 97% and also add the vaccine strains as the prior representatives. This way PARNAS can indicate the areas of the tree, which are not covered by the vaccine strains and suggest new representatives to complement the vaccine strains.

parnas -t H1N1_human_2020_IRD.rooted.tre --cover --threshold 97 --aa H1N1_human_2020_IRD.ha1.aln --color "parnas_97coverage_vaccines.tre" --prior "Vaccine.*"

Opening parnas_97coverage_vaccines.tre in FigTree will show us that there are two clades in the tree, which are not covered by vaccine strains (the green and blue clades). Note that the tree was re-scaled by PARNAS.

Other functionality

  • Specify weights for taxa, so that taxa/strains with larger weights are better represented.
  • Flexibly exclude taxa to either fully ignore them or to not consider them as potential representatives.

PARNAS usage

parnas -t TREE [-n SAMPLES] [other options]

The input tree should be in nexus or newick format.

For a detailed reference on PARNAS options run parnas -h or see below.

General options

Option Description
--radius Specify a radius (distance on a tree) so that every representative covers all diversity within that radius. PARNAS will then choose representatives that optimally cover as much diversity as possible
--prior Specify prior representatives with a regex. PARNAS will then identify representatives of 'new' diversity
--weights Add a CSV file specifying weights for some or all taxa/strains
--cover Instead of specifying the number of representatives, specify the radius and PARNAS will find representative that cover all diversity on the tree

Output options (combining output options is allowed)

Option Description
--color Specify an output path, where a colored tree will be saved. PARNAS will highlight the chosen representatives and color-partition the tree respective to the representatives. If prior representatives are specified, they (and the subtrees they represent) will be colored red.
--diversity Specify an output path, where a CSV will be saved with diversity scores for all k (number of representatives) from 2 to n. Can be used to choose the right number of representatives for a dataset
--subtree Specify a path, where a subtree with the sampled representatives will be saved (in NEXUS format)

Options to exclude/constrain taxa

Option Description
--exclude REGEX. Matching taxa will not be chosen as representatives, but they will contribute to the objective function
--exclude-fully REGEX. Matching taxa will be completely ignored by PARNAS
--constrain REGEX. Opposite to '--exclude-fully', i.e., only the matching taxa will be considered by PARNAS

Options to control sequence divergence

Option Description
--threshold Number between 0 and 100. The sequence similarity threshold that works as --radius. For example, "95" will imply that each representative covers all leaves within 5% divergence on the tree. To account for sequence divergence, PARNAS will run TreeTime to infer ancestral substitutions along the tree edges and re-weigh the edges based on the number of substitutions on them. A sequence alignment (--nt or --aa) must be specified with this option
--nt Path to nucleotide sequence alignment associated with the tree tips
--aa Path to amino acid sequence alignment associated with the tree tips

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distribution

parnas-0.1.0.tar.gz (31.4 kB view details)

Uploaded Source

Built Distribution

parnas-0.1.0-py3.8.egg (67.8 kB view details)

Uploaded Source

File details

Details for the file parnas-0.1.0.tar.gz.

File metadata

  • Download URL: parnas-0.1.0.tar.gz
  • Upload date:
  • Size: 31.4 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.1 CPython/3.8.5

File hashes

Hashes for parnas-0.1.0.tar.gz
Algorithm Hash digest
SHA256 e112dd83d523ce275144433704459b89e5c11b56addada8d2729fff92b4a0da8
MD5 6558d24d0ef1656b494055cc6cfd2523
BLAKE2b-256 3097218710086718817374ea5174afad27ba0fb752e18131260d11f4a8cc8682

See more details on using hashes here.

File details

Details for the file parnas-0.1.0-py3.8.egg.

File metadata

  • Download URL: parnas-0.1.0-py3.8.egg
  • Upload date:
  • Size: 67.8 kB
  • Tags: Source
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.1 CPython/3.8.5

File hashes

Hashes for parnas-0.1.0-py3.8.egg
Algorithm Hash digest
SHA256 d1b651f1d597da45968fcf1f51ed37084ccae1b46221354683e1290a9d355b93
MD5 916d0e8a4733384290af32276528215b
BLAKE2b-256 5a365d81800884ecb224be7f7f01f258c6436a52e97285135d4baefbeba734f1

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page