Connecting data to Open Tree trees

Combining data from OToL and other sources.

One of the major goals of rotl is to help users combine data from other sources with the phylogenetic trees in the Open Tree database. This examples document describes some of the ways in which a user might connect data to trees from Open Tree.

Get Open Tree IDs to match your data.

Let’s say you have a dataset where each row represents a measurement taken from one species, and your goal is to put these measurements in some phylogenetic context. Here’s a small example: the best estimate of the mutation rate for a set of unicellular Eukaryotes along with some other property of those species which might explain the mutation rate:

csv_path <- system.file("extdata", "protist_mutation_rates.csv", package = "rotl")
mu
##                     species       mu pop.size genome.size
## 1   Tetrahymena thermophila 7.61e-12 1.12e+08    1.04e+08
## 2    Paramecium tetraurelia 1.94e-11 1.24e+08    7.20e+07
## 3 Chlamydomonas reinhardtii 2.08e-10 1.00e+08    1.12e+08
## 4  Dictyostelium discoideum 2.90e-11 7.40e+06    3.40e+07
## 5  Saccharomyces cerevisiae 3.30e-10 1.00e+08    1.25e+08
## 6       Saccharomyces pombe 2.00e-10 1.00e+07    1.25e+08

If we want to get a tree for these species we need to start by finding the unique ID for each of these species in the Open Tree database. We can use the Taxonomic Name Resolution Service (tnrs) functions to do this. Before we do that we should see if any of the taxonomic contexts, which can be used to narrow a search and avoid conflicts between different codes, apply to our group of species:

library(rotl)
tnrs_contexts()
## Possible contexts:
##    Animals
##       Birds, Tetrapods, Mammals, Amphibians, Vertebrates
##       Arthropods, Molluscs, Nematodes, Platyhelminthes, Annelids
##       Cnidarians, Arachnids, Insects
##    Bacteria
##       SAR group, Archaea, Excavata, Amoebozoa, Centrohelida
##       Haptophyta, Apusozoa, Diatoms, Ciliates, Forams
##    Fungi
##       Basidiomycetes, Ascomycetes
##    Land plants
##       Hornworts, Mosses, Liverworts, Vascular plants, Club mosses
##       Ferns, Seed plants, Flowering plants, Monocots, Eudicots
##       Rosids, Asterids, Asterales, Asteraceae, Aster
##       Symphyotrichum, Campanulaceae, Lobelia
##    All life

Hmm, none of those groups contain all of our species. In this case we can search using the All life context and the function tnrs_match_names:

taxon_search <- tnrs_match_names(names=mu$species, context_name="All life") knitr::kable(taxon_search) search_string unique_name approximate_match ott_id is_synonym flags number_matches tetrahymena thermophila Tetrahymena thermophila FALSE 180195 FALSE SIBLING_HIGHER 1 paramecium tetraurelia Paramecium tetraurelia FALSE 568130 FALSE 1 chlamydomonas reinhardtii Chlamydomonas reinhardtii FALSE 33153 FALSE 1 dictyostelium discoideum Dictyostelium discoideum FALSE 160850 FALSE 1 saccharomyces cerevisiae Saccharomyces cerevisiae FALSE 356221 FALSE 1 saccharomyces pombe Schizosaccharomyces pombe FALSE 990004 TRUE 1 Good, all of our species are known to Open Tree. Note, though, that one of the names is a synonym. Saccharomyces pombe is older name for what is now called Schizosaccharomyces pombe. As the name suggests, the Taxonomic Name Resolution Service is designed to deal with these problems (and similar ones like misspellings), but it is always a good idea to check the results of tnrs_match_names closely to ensure the results are what you expect. In this case we have a good ID for each of our species so we can move on. Before we do that, let’s ensure we can match up our original data to the Open Tree names and IDs by adding them to our data.frame: mu$ott_name <- unique_name(taxon_search)
mu$ott_id <- taxon_search$ott_id

Find a tree with your taxa

Now let’s find a tree. There are two possible options here: we can search for published studies that include our taxa or we can use the ‘synthetic tree’ from Open Tree. We can try both approaches.

Published trees

Before we can search for published studies or trees, we should check out the list of properties we can use to perform such searches:

studies_properties()
## $tree_properties ## [1] "ot:treebaseOTUId" "ot:nodeLabelMode" ## [3] "ot:originalLabel" "oti_tree_id" ## [5] "ot:ottTaxonName" "ot:inferenceMethod" ## [7] "ot:tag" "ot:comment" ## [9] "ot:treebaseTreeId" "ot:branchLengthDescription" ## [11] "ot:treeModified" "ot:studyId" ## [13] "ot:branchLengthTimeUnits" "ot:ottId" ## [15] "is_deprecated" "ot:branchLengthMode" ## [17] "ot:treeLastEdited" "ot:nodeLabelDescription" ## ##$study_properties
##  [5] "ot:studyPublication"          "ot:studyLastEditor"
##  [9] "ot:studyLabel"                "ot:comment"
## [11] "ot:authorContributed"         "ot:studyPublicationReference"
## [13] "ot:curatorName"               "ot:studyId"
## [19] "ot:candidateTreeForSynthesis"

We have ottIds for our taxa, so let’s use those IDs to search for trees that contain them. Starting with our first species Tetrahymena thermophila we can use studies_find_trees to do this search.

studies_find_trees(property="ot:ottId", value=as.character(ott_id(taxon_search)[1]))
## [1] study_ids       dat             n_matched_trees
## <0 rows> (or 0-length row.names)

Well… that’s not very promising. We can repeat that process for all of the IDs to see if the other species are better represented.

hits <- lapply(mu$ott_id, studies_find_trees, property="ot:ottId", detailed = FALSE) sapply(hits, function(x) sum(x[["n_matched_trees"]])) ## [1] 0 0 2 0 1 3 OK, most of our species are not in any of the published trees available. You can help fix this sort of problem by making sure you submit your published trees to Open Tree. A part of the synthesis tree Thankfully, we can still use the complete Tree of Life made from the combined results of all of the published trees and taxonomies that go into Open Tree. The function tol_induced_subtree will fetch a tree relating a set of IDs. Using the default arguments you can get a tree object into your R session: ott_in_tree <- ott_id(taxon_search)[is_in_tree(ott_id(taxon_search))] tr <- tol_induced_subtree(ott_ids = ott_in_tree) ## Warning in collapse_singles(tr, show_progress): Dropping singleton ## nodes with labels: mrcaott2ott276, mrcaott2ott142555, mrcaott2ott3043, ## mrcaott2ott7623, Chloroplastida ott361838, Chlorophyta ott979501, ## mrcaott185ott23323, mrcaott185ott599, mrcaott1427ott25671, ## mrcaott1427ott1544, mrcaott1544ott15345, mrcaott1544ott1795, ## mrcaott9389ott365252, mrcaott9389ott23557, mrcaott23557ott527099, ## mrcaott149ott902, SAR ott5246039, Alveolata ott266751, Ciliophora (phylum ## in subkingdom SAR) ott302424, Intramacronucleata ott340382, Conthreep ## ott5248773, Peniculia ott5257364, Paramecium (genus in subkingdom SAR) ## ott568126, Hymenostomatia ott5257367, Tetrahymena ott47284, Amoebozoa ## ott1064655, mrcaott3973ott5765, mrcaott3973ott26103, mrcaott26103ott273110, ## mrcaott26103ott229626, Dictyostelia ott835575, Dictyostelium ott999665, ## Opisthokonta ott332573, Nucletmycea ott5246132, Fungi ott352914, ## mrcaott48ott3465, mrcaott48ott67172, mrcaott48ott1423, mrcaott48ott4814, ## h2007-2 ott5576447, h2007-1 ott5584405, Dikarya ott656316, ## mrcaott48ott1053, Saccharomycetales ott5976840, Saccharomycetaceae ## ott989994, Saccharomyces ott908546, Taphrinomycotina ott656312, ## Schizosaccharomycetes ott921286, Schizosaccharomycetidae ott5670481, ## Schizosaccharomycetales ott508517, Schizosaccharomycetaceae ott990009, ## Schizosaccharomyces ott990008 plot(tr) Connect your data to the tips of your tree Now we have a tree for of our species, how can we use the tree and the data together? The package phylobase provide an object class called phylo4d, which is designed to represent a phylogeny and data associated with its tips. In oder to get our tree and data into one of these objects we have to make sure the labels in the tree and in our data match exactly. That’s not quite the case at the moment (tree labels have underscores and IDs appended): mu$ott_name[1]
## $Tetrahymena thermophila ## [1] "Tetrahymena thermophila" tr$tip.label[4]
## [1] "Dictyostelium_discoideum_ott160850"

rotl provides a convienence function strip_ott_ids to deal with these.

tr$tip.label <- strip_ott_ids(tr$tip.label, remove_underscores=TRUE)
tr$tip.label %in% mu$ott_name
## [1] TRUE TRUE TRUE TRUE TRUE TRUE

Ok, now the tips are together we can make a new dataset. The phylo4d() functions matches tip labels to the row names of a data.frame, so let’s make a new dataset that contains just the relevant data and has row names to match the tree

library(phylobase)
mu_numeric <- mu[, c("mu", "pop.size", "genome.size")]
rownames(mu_numeric) <- mu$ott_name tree_data <- phylo4d(tr, mu_numeric) And now we can plot the data and the tree together plot(tree_data) Find external data associated with studies, trees and taxa from Open Tree In the above example we looked for a tree that related species in another dataset. Now we will go the other way, and try to find data associated with Open Tree records in other databases. Get external data from a study Let’s imagine you were interested in extending or reproducing the results of a published study. If that study is included in Open Tree you can find it via studies_find_studies or studies_find_trees and retrieve the published trees with get_study. rotl will also help you find external. The function study_external_IDs retrieves the DOI for a given study, and uses that to gather some more data: extra_data <- try(study_external_IDs("pg_1980"), silent=TRUE) if (!inherits(extra_data, "try-error")) extra_data ## External data identifiers for study ##$doi:  10.1016/j.ympev.2006.04.016
##  $pubmed_id: 16762568 ##$nucleotide_ids: vector of 58 IDs
##  $external_data_url http://purl.org/phylo/treebase/phylows/study/TB2:S1575 Here the returned object contains an external_data_url (in this case a link to the study in Treebase), a pubmed ID for the paper and a vector IDs for the NCBI’s nuleotide database. The packages treebase and rentrez provide functions to make use of these IDs within R. As an example, let’s use rentrez to download the first two DNA seqences and print them. library(rentrez) seqs <- try(entrez_fetch(db="nucleotide", id=extra_data$nucleotide_ids[1:2], rettype="fasta"), silent = TRUE)

if (inherits(seqs, "try-error")) {
cat("NCBI temporarily down.")
} else cat(seqs)
## >AM181011.1 Plectroninia neocaledoniense partial 28S rRNA gene, specimen voucher G316300 (Queensland Museum)
## GCTAGCAAGCGCGTCGGTGGTTCAGCCGGCTGGTCTCGTCGAGTTGTCGGTGTGCGGATCCGAACGGACC
## GCGGCCGATGGCGTCGGCGGGCAAGCTGTGGTGCACTCTGTCGGCGTGCGCGTCAGCGTCGGTTTCGGCC
## GGACGACGAGGCGCTCGGGGAAGGTAGCTGGACCGGTCTTCGGTGCAGTGTTATAGCCCTGGGCCGCTGG
## GTTCGGCGTTTGGGACCGAGGAGAGAGATGATCGCTGCAGCGCCTGTCTCCCTCTCGAGGGGGGCTAGCC
## AGCCGCTGTTTGGGTGGCGTCACTGGCGGAGGACTGCACGCAGTGCTTCGCCGGTGGTCGTGTCCAGGCG
## GGCGGTGTGGGTATAGAGGCGCTTAGGACGCTGGCGTCCAAATGGCCGTGCGCGACCCGTCTTGAAACAC
## GGACCAAGGAGTCTAGCATGTGCGCGAGTCTTAGGGTGTGGAAGCCCTCGGGCGCAATGAAAGTGAAGGG
## CCGTCGTCTCTCGGGGCTGCGGTGTGAGGTGAGAGCCGTCGCCGTCGGGTGGCGGTGCATCATCGGCCGG
## TCCATCCTGCTCTCAGGAGGATCTGCGCAAGAGCGTGTTTGCTGGGACCCGAAAGATGGTGAACTATGCC
## TGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGGTTCTGACGTGCAAATCGATCGTCA
## AATTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGG
## ATAGCTGGAACTCGTCTTGACACAGTTTTATCAGGTAAAGCGAATGATTAGAGGTCTTGGGGGTGAAACA
## CCCTCAACCTATTCTCAAACTTTAAATAGGTAAGAAGCGCGACTTGCTCAATTGAAGTGGCGCGCAGTGA
## ATGTGAGTTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGCTCGGTTA
## AGGTGCCCAAGTCGACGCTCATCAGACCCCAGAAAAGGTGTTGGTCGATATAGACAGCAGGACGGTGGCC
## ATGGAAGTCGGAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCTGAAAATGGAT
## GGCGCTCAAGCGTCGCACCTATACCGAGCCGTCGTGGTAAATGCCAGGCCACGACGAGTAGGAGGGCGCG
## GTGGTCGTGACGCAGCCCTTGGCGCGAGCCTGGGCGAAACGGCCTCCGGTGCAGATCTTGGTGGTAGTAG
## CAAATATTCAAATGAGAGCTTTGAAGACCGAAGTGGAGAAAGGTTCCATGTGAACAGCAGTTGGACATGG
## GTTAGTCGATCCTAAGAGATAGGGAAGTTCCGTGTGAAAGTGCGCAATGCGCTTCTGTGCTGCGCGCCTC
## CTATCGAAAGGGAATCGGGTTAATATTCCCGAACCGGAAGGCGGATATCTCTGGCTCTCGGGTCAGGAGC
## GGCAACGCAAGCGTACTGCGAGACGTCGGCGGGGGCTCCGGGAAGAGTTGTCTTTTCTTTTTAACGCAGT
## CGCCATCCCTGGAATCGGTTTGCCCGGAGATAGGGTTGGCTGGCTCGGTAAAGCAGCACACTTCATGTGC
## TGTCCGGTGCGCTCTCGACGGCCCTTGAAAATCGCAGGTGTGCATCGATTCTCGCATCCGGTCGTACTCA
## TAACCGCATCAGGTCTCCAAGGT
##
## >AM181010.1 Eilhardia schulzei partial 28S rRNA gene, specimen voucher G316071 (Queensland Museum)
## GCTAGTAATGTACGTTGGTGGTTCAGCCGGCTAGTCTTGTCGAGTCGTCGTGTGGTGGATCCGACTGGAC
## CGTCCGCGGTGGTGTCGGCGGGCGAGCTGTGGTGCACTCTACGGACGTGCGCGTCAGCGTCGGTTCTCGA
## TGGGCGATAAGGTGCGTGGGGGAAGGTGGCTCGGTCCTTGGGAACTGAGTGTTACAGACCCTGGTGCTGG
## GCTCGTCGTGGGACCGAGGAGAGAGAGAGATGATCGCTGCGGCACCTGCCCCGTTGTCATTTTTCGGGGC
## TAGCCAGCCGTTTGTCAGGTGTGCGTCGGACGTTGAGGACTGCACGCAGTGCTGGACGTGGAGGCGTGAT
## CTGATGGCGGTGTGGGCATTAGAGGTGCCTAGGACGCTGGCGTCCAAATGGCCGTGCGCGACCCGTCTTG
## AAACACGGACCAAGGAGTCTAACATGTGCGCGAGTCTTAGGGTGTGCAAGCCCTCGGGCGCAATGAAAGT
## GAAGGCTCGGCGGCGCTAGTCGAGCTGAGGTGAGAGCCGTGGCCGTTGCATGTGGCGGCGGCGGCGCATC
## ATCGGCCGGTCCATCCTGCTCTCAGGGGGATCCGAGCAAGAGCGTATTTGTTGGGACCCGAAAGATGGTG
## AACTATGCCTGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGATTCTGACGTGCAAAT
## CGATCGTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTT
## TCCCTCAGGATAGCTGGAGCTCTTGGACACAGTTTTATCAGGTAAAGCGAATGATCAGAGGTCTTGGGGG
## TGAAACACCCTCAACCTATTCTCAAACTTTAAATCGGTAAGAAGCGCGACTTGCTGAATTGAAGCCGCGC
## GCAAGCAATGTGAGTTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGC
## TGGGTTAAGGTGCCAAAGTCGACGCTCATCAGACCCCAGAAAAGGTGTTGGTTGATATAGACAGCAGGAC
## GATGGCCATGGAAGTCGGAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCTGAA
## AATGGATGGCGCTCAAGCGTCGCACCTATACCGGGCCGTCGTCGCAAATGCCAGGCGACGACGAGTAGGA
## GGGCGCAGTGGTCGTCATGCAGCCCTTGGCGTGAGCCTGGGTCAAACGGCCTCTGGTGCAGATCTTGGTG
## GTAGTAGCAAATATTCAAATGAGAGCTTTGAAGACCGAAGTGGAGAAAGGTTCCATGTGAACAGCAGTTG
## GACATGGGTTAGTCGATCCTAAGTGATAGGGGAGCTCCGTATGAAAGTGCGCAATCGGCCCTGCTTGTGT
## CGCCTTGCGCCACCTATCGAAAGGGAATCGGGTTAATATTCCCGAACCGGAAGGCGGATTTTCTCTGGCT
## CTCGGGTCAGGAGCGGCAACGCTAGCGAACCGCGAGACGTCGGCGGGGGCTCCGGGAAGAGTTGTCTTTT
## CTTTTTAACGCAGTCGCCATCCCTGGAATCGGTTTGCCCGGAGATAGGGTTGGCTGGCTCGGTAAAGCAG
## CACACTTCATGTGCTGTCCGGTGCGCTCTCGACGGCCCTTGAAAATCGCGGCGAGTGTAGTCTGATTTTC
## GCATCCGTTCGTACTCATAACCGCATCAGGTCTCCAAGGT

You could further process these sequences in R with the function read.dna from ape or save them to disk by specifying a file name with cat.

Find a OTT taxon in another taxonomic database

It is also possible map an Open Tree taxon to a record in another taxonomic database. For instance, if we wanted to search for data about one of the tips of the sub-tree we fetched in the example above we could do so using taxon_external_IDs:

Tt_ids <- taxon_external_IDs(mu\$ott_id[2])
Tt_ids
##   source       id
## 1  silva AY102613
## 2   ncbi     5888
## 3   gbif  7415807

A user could then use rgbif to find locality records using the gbif ID or rentrez to get genetic or bibliometric data about from the NCBI’s databases.

What next

The demonstration gets you to the point of visualizing your data in a phylogenetic context. But there’s a lot more you do with this sort of data in R. For instance, you could use packages like ape, caper, phytools and mcmcGLMM to perform phylogenetic comparative analyses of your data. You could gather more data on your species using packages that connect to trait databases like rfishbase, AntWeb or rnpn which provides data from the US National Phenology Network. You could also use rentrez to find genetic data for each of your species, and use that data to generate branch lengths for the phylogeny.