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baltic - adaptable lightweight tree import code for molecular phylogeny manipulation, analysis and visualisation. This fork will no longer receive updates, so any further development to baltic is going to happen at https://github.com/evogytis/baltic.

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baltic: the Backronymed Adaptable Lightweight Tree Import Code

baltic was initially developed to extract various statistics from molecular phylogenies derived from BEAST in a customised way. My influenza B virus reassortment paper used early versions of baltic’s code to look at how the human influenza B virus segment diversity is structured according to genomic background. I’ve since split up the various bits of code into three parts:


baltic

baltic.py is the tree parser itself. It uses three main classes - node, leaf and tree to import, manipulate and plot BEAST trees with their rich variety of comments. Node and leaf classes have references to the usual set of parameters you would find in a phylogeny - index of character in string designating the branch (a unique identifier within the tree), length, height, position in time (absoluteTime), X and Y coordinates, a dictionary encoding BEAST branch comments (traits) and a reference to their parent (None for root) and a string designating their type (branchType). The node class additionally have a children attribute, which is a list of the node’s children, another list called leaves that contains tip names that descend from that node, a numChildren attribute, which is the length of the leaves list and a childHeight attribute which tracks when the last tip descending from the node existed. The leaf class has two extra attributes called name and numName. Trees drawn from the posterior distribution will usually encode tips as numbers to save space and require a translation map to convert back into actual interpretable tip names. In baltic numName will be the exact name for the tip that was used in the tree string, with functions to allow the translation of numName into name.

baltic.py evolved from a short linked list script on StackOverflow and underwent a major overhaul in order to correct an article that was wrong. The code should be fairly legible (and commented) and highly adaptable to suit anyone’s needs.


Usage basics

By convention baltic is imported as bt:

import baltic as bt

When called with a tree string the make_tree() function return a baltic tree object:

treeString='((A:1.0,B:2.0):1.0,C:3.0);'

myTree = bt.make_tree(treeString)

Note that if you're not using newick, nexus or nextstrain JSON trees (loadNewick, loadNexus, and loadJSON functions respectively) you'll have to write some code to parse out the tree string. baltic will warn the user if it can't parse something. If this happens you should check if your tip names or annotations contain characters that should never be found outside of functional tree string bits, such as commas, parentheses or semicolons. Alternatively, it may be that the regexes that are used to parse out tip names or annotations don't cover some special character you use to define your taxa and will require some editing of baltic.py to alleviate the problem. Feel free to raise an issue if this happens.

make_tree() is a function that parses the tree string and builds the data structure that is the phylogenetic tree. It works exactly like all other tree parsers:

  • Every time an opening parenthesis (() is encountered in the tree string a new instance of node class is created. The new class' .index attribute is set to the index along the tree string where it was encountered, giving that particular class a unique identifier within the tree string. The .parent attribute is set to whatever the previous object encountered was, similarly, since the last encountered object could only be another node, the current node is added to its parents list of children. Finally we set our new node as the 'current' node of the tree and append the node to the list of objects (.Objects, which are branches) contained in the tree.

  • Every time a string is encountered which may or may not be surrounded by quotation marks (' or ") or have the beginning of an annotation block ([) we create a new leaf class. It also receives an .index identifier, like the node class. Unlike the node class, however, the .numName attribute is also set as the string that defined the tip. In BEAST trees it will be the number that identifies the tip, but it could also be a regular string.

  • Next baltic looks for annotations, which are the blocks in the format [&parameter1=1.0,parameter2=0.0]. These are transformed into the .traits dictionary for the branch. In this example the branch being parsed would receive a dictionary with two keys: cur_branch.traits = {'parameter1' : 1.0, 'parameter2' : 0.0}.

  • Annotations should be followed by branch lengths preceded by a colon (:). The branch length is assigned to the current branch's .length attribute.

  • Forks in the tree string are defined as commas (,) and ends of clades are defined by closing parentheses ()) and both mean that whatever comes next is in relation to the parent branch of whatever branch we were dealing with earlier.

  • Finally tree strings are finished with a semi colon (;).

Before you can run any analysis you will usually have to traverse the tree such that branch lengths which are available in the tree string are transformed into branch heights:

myTree.traverse_tree()

This takes the .length attributes of each branch and sums or subtracts them, as appropriate during a tree traversal and the .height attribute of each branch (node or leaf object) is set, where the root of the tree has .height = 0.0 and the most recent tip is the highest object in the tree. The tree traversal will also set the tree's .treeHeight attribute.

If your tree happens to have branch lengths in units of time you can use the .height attribute to modify the .absoluteTime attribute of each branch, such that the entire tree is calibrated and position correctly in time. This involves finding the most recent tip in the tree (in absolute time), subtracting the .treeHeight and adding the .height of the each branch.

Most analytic operations will involve looking at each branch individually without referring back to the tree structure much, beyond immediate children or parents of a particular branch. This is done by iterating over the tree's .Objects list, which contains all the branches in the tree. If you want to print out the height of each internal branch whose parent had a different trait value you would do it as:

for k in myTree.Objects:
   if isinstance(k,bt.node) ## (or, alternatively if k.branchType=='node')
       if k.traits[myTrait] != k.parent.traits[myTrait]:
           print k.height

samogitia

samogitia.py is the heavy-lifting, tree file-wrangling script in the collection. It’s main role is to parse BEAST tree files, use baltic to create tree data structures, which samogitia then manipulates to create BEAST-like log files that can usually be imported into Tracer or used in another program.


austechia

austechia.ipynb is the fancy Jupyter notebook that takes tree files, usually MCC trees from BEAST, and plots them. It is meant to be part teaching tool to get people to think about how trees are plotted, to allow for highly customisable representations of trees (e.g. Fig 6 in my MERS-CoV paper) and to improve the aesthetics situation in phylogenetics.


galindia

galindia.ipynb is a notebook that uses baltic to plot JSONs from nextstrain.org in order to allow customisable, static, publication-ready figures for phylogenies coming from nextstrain's augur pipeline.


curonia

curonia.ipynb generalises the notebook used to animate the spread of Ebola virus in West Africa. This notebook should require minimal manual editing to produce similarly styled animation of other study systems.


baltic was used in the following publications:

  • van Vuren JP, Ladner JT, Grobbelaar AA, Wiley MR, Lovett S, Allam M, Ismail A, le Roux C, Weyer J, Moolla N, Storm N, Kgaladi J, Sanchez-Lockhart M, Conteh O, Palacios G, Paweska JT, 2019. Phylodynamic Analysis of Ebola Virus Disease Transmission in Sierra Leone. Viruses, 11(1), 71; doi.
  • Bell SM, Katzelnick L, Bedford T, 2018. Dengue antigenic relationships predict evolutionary dynamics, bioRxiv 432054; doi.
  • Lee JM, Huddleston J, Doud MB, Hooper KA, Wu NC, Bedford T, Bloom JD, 2018. Deep mutational scanning of hemagglutinin helps predict evolutionary fates of human H3N2 influenza variants, PNAS 115(35): 8276-8285.
  • Dokubo EK, Wendland A, Mate SE, Ladner JT, ..., Palacios G, Fallah MP, 2018. Persistence of Ebola virus after the end of widespread transmission in Liberia: an outbreak report, Lancet Infect Dis 18: 1015–1024.
  • Venkatesh D, Poen MJ, Bestebroer TM, ..., Brown IH, Fouchier RAM, Lewis NS, 2018. Avian influenza viruses in wild birds: virus evolution in a multi-host ecosystem, J Virol 92:e00433-18.
  • Chu DKW, Hui Kenrie PY, Perera RAPM, Miguel E, Niemeyer D, Zhao J, Channappanavar R, Dudas G, Oladipo JO, Traoré A, Fassi-Fihri O, Ali A, Demissie GF, Muth D, Chan MCW, Nicholls JM, Meyerholz DK, Kuranga SA, Mamo G, Zhou Z, So RTY, Hemida MG, Webby RJ, Roger F, Rambaut A, Poon LLM, Perlman S, Drosten C, Chevalier V, Peiris M, 2018. MERS coronaviruses from camels in Africa exhibit region-dependent genetic diversity. PNAS 115(12): 3144-3149.
  • Whitmer SLM, Ladner JT, Wiley MR, Patel K, Dudas G, Rambaut A, Sahr F, Prieto K, Shepard SS, Carmody E, Knust B, Naidoo D, Deen G, Formenty P, Nichol ST, Palacios G, Ströher U, 2018. Active Ebola Virus Replication and Heterogeneous Evolutionary Rates in EVD Survivors. Cell Reports 22(5): 1159-1168.
  • Dudas G, Carvalho L, Rambaut A, Bedford T. MERS-CoV spillover at the camel-human interface, 2017. eLife 7: e31257.
  • Langat P, Raghwani J, Dudas G, ..., Russell C, Pybus OG, McCauley J, Kellam P, Watson SJ. Genome-wide evolutionary dynamics of influenza B viruses on a global scale, 2017. PLOS Pathogens 13(12): e1006749.
  • Grubaugh ND, Ladner JT, Kraemer MUG, Dudas G, Tan AL, Gangavarapu K, Wiley MR, White S, Thézé J, ..., Bedford T, Pybus OG, Isern S, Palacios G, Andersen KG. Multiple introductions of Zika virus into the United States revealed through genomic epidemiology, 2017. Nature 546: 401–405.
  • Dudas G, Carvalho LM, Bedford T, Tatem AJ, ..., Suchard M, Lemey P, Rambaut A. Virus genomes reveal the factors that spread and sustained the West African Ebola epidemic, 2017. Nature 544(7650): 309-315.
  • Bell SM, Bedford T. Modern-Day SIV viral diversity generated by extensive recombination and cross-species transmission, 2017. PLoS Pathog 13(7): e1006466.
  • Holmes EC, Dudas G, Rambaut A, Andersen KG. The Evolution of Ebola virus: Insights from the 2013-2016 Epidemic, 2016. Nature 538(7624): 193-200.
  • Whitmer SLM, Albariño C, Shepard SS, Dudas G, ..., Nichol ST, Ströher U. Preliminary Evaluation of the Effect of Investigational Ebola Virus Disease Treatments on Viral Genome Sequences, 2016. Journal of Infectious Diseases:jiw177.
  • Rambaut A, Dudas G, Carvalho LM, Park DJ, Yozwiak NL, Holmes EC, Andersen KG. Comment on “Mutation rate and genotype variation of Ebola virus from Mali case sequences”, 2016. Science 353(6300):658-658.
  • Lewis NS, Russell CA, Langat P, ..., Dudas G, ..., Watson SJ, Brown IH, Vincent AL. The global antigenic diversity of swine influenza A viruses, 2016. eLife 5: e12217.
  • Quick J, Loman NJ, Duraffour S, Simpson JT, Severi E, Cowley L ..., Dudas G, ..., Günther S, Carroll MW. Real-time, portable genome sequencing for Ebola surveillance, 2016. Nature 530(7589): 228-232.
  • Dudas G, Rambaut A, MERS-CoV recombination: implications about the reservoir and potential for adaptation, 2016. Virus Evolution 2(1):vev023.
  • Ladner JT, Wiley MR, Mate S, Dudas G, ... Palacios G. Evolution and Spread of Ebola Virus in Liberia, 2014-2015, 2015. Cell Host & Microbe 18(6): 659-669.
  • Park DJ, Dudas G, Wohl S, Goba A, Whitmer SLM, ..., Sabeti PC. Ebola Virus Epidemiology, Transmission, and Evolution during Seven Months in Sierra Leone, 2015. Cell 161(7): 1516-1526.
  • Carroll MW, Matthews DA, Hiscox JA, ... Dudas G, ... Günther S. Temporal and spatial analysis of the 2014-2015 Ebola virus outbreak in West Africa, 2015. Nature 524(7563): 97-101.
  • Dudas G, Bedford T, Lycett S, Rambaut A. Reassortment between Influenza B Lineages and the Emergence of a Coadapted PB1–PB2–HA Gene Complex, 2015. Molecular Biology and Evolution 32(1): 162-172.
  • Gire SK, Goba A, Andersen KG, ... Dudas G, ... Sabeti PC. Genomic surveillance elucidates Ebola virus origin and transmission during the 2014 outbreak, 2014. Science 345(6202): 1369-1372.

Copyright 2016 Gytis Dudas. Licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

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baltic - adaptable lightweight tree import code for molecular phylogeny manipulation, analysis and visualisation. This fork will no longer receive updates, so any further development to baltic is going to happen at https://github.com/evogytis/baltic.

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