taxonomizr usage

Scott Sherrill-Mix

Introduction

taxonomizr provides some simple functions to parse NCBI taxonomy files and accession dumps and efficiently use them to assign taxonomy to accession numbers or taxonomic IDs. This is useful for example to assign taxonomy to BLAST results. This is all done locally after downloading the appropriate files from NCBI using included functions (see below).

The major functions are: * prepareDatabase: download data from NCBI and prepare SQLite database * accessionToTaxa: convert accession numbers to taxonomic IDs * getTaxonomy: convert taxonomic IDs to taxonomy

More specialized functions are: * getId: convert a biological name to taxonomic ID * getRawTaxonomy: find all taxonomic ranks for a taxonomic ID * normalizeTaxa: combine raw taxonomies with different taxonomic ranks * condenseTaxa: condense a set of taxa to their most specific common branch * makeNewick: generate a Newick formatted tree from taxonomic output * getAccessions: find accessions for a given taxonomic ID

And a simple use case might look like (see below for more details):

library(taxonomizr)
#note this will require a lot of hard drive space, bandwidth and time to process all the data from NCBI
prepareDatabase('accessionTaxa.sql')
blastAccessions<-c("Z17430.1","Z17429.1","X62402.1") 
ids<-accessionToTaxa(blastAccessions,'accessionTaxa.sql')
getTaxonomy(ids,'accessionTaxa.sql')

Requirements

This package downloads a few databases from NCBI and stores them in an easily accessible form on the hard drive. This ends up taking a decent amount of space so you’ll probably want around 75 Gb of free hard drive space.

Installation

The package is on CRAN, so it should install with a simple:

install.packages("taxonomizr")

If you want the development version directly from github, use the devtools library and run:

devtools::install_github("sherrillmix/taxonomizr")

To use the library, load it in R:

library(taxonomizr)

Preparation

Since version 0.5.0, there is a simple function to run all preparations. Note that you’ll need a bit of time, download bandwidth and hard drive space before running this command (we’re downloading taxonomic assignments for every record in NCBI). To create a SQLite database called accessionTaxa.sql in the current working directory (you may want to store this somewhere more centrally located so it does not need to be duplicated with every project), we can run:

prepareDatabase('accessionTaxa.sql')
## Downloading names and nodes with getNamesAndNodes()
## Downloading accession2taxid with getAccession2taxid()
## This can be a big (several gigabytes) download. Please be patient and use a fast connection.
## Preprocessing names with read.names.sql()
## Preprocessing nodes with read.nodes.sql()
## Preprocessing accession2taxid with read.accession2taxid()
## Reading ./nucl_gb.accession2taxid.gz.
## Reading ./nucl_wgs.accession2taxid.gz.
## Reading in values. This may take a while.
## Adding index. This may also take a while.
## [1] "accessionTaxa.sql"

If everything works then that should have prepared a SQLite database ready for use. You can skip the “Manual preparation” steps below.

All files are cached locally and so the preparation is only required once (delete/rename the SQLite database and recall the function to regenerate the database). It is not necessary to manually check for the presence of the database since the function checks to see if SQLite database is present and if so skips downloading/processing. For example, running the command again produces:

prepareDatabase('accessionTaxa.sql')
## SQLite database accessionTaxa.sql already exists. Delete to regenerate
## [1] "accessionTaxa.sql"

Note that if you only want the taxonomic data and do not want to assign taxonomy to accession ID then you can just get the much smaller names and nodes data sets and exclude the large download and time consuming databasing of accession IDs by setting getAccessions=FALSE e.g.:

prepareDatabase(getAccessions=FALSE)
## Downloading names and nodes with getNamesAndNodes()
##  [100%] Downloaded 57373562 bytes...
##  [100%] Downloaded 49 bytes...
## Preprocessing names with read.names.sql()
## Preprocessing nodes with read.nodes.sql()
## [1] "nameNode.sqlite"

Assigning taxonomy

Producing accession numbers

NCBI accession numbers are often obtained when doing a BLAST search (usually the second column of output from blastn, blastx, blastp, …). For example the output might look like:

read1   gi|326539903|gb|CP002582.1|     69.68   1745    448     69      3       1702    3517898 3519606 3e-169  608
read2   gi|160426828|gb|CP000885.1|     68.46   1763    452     82      3       1711    1790367 1788655 4e-140  511
...

So to identify a taxon for a given sequence you would blast it against e.g. the NCBI nt database and load the results into R. For NCBI databases, the accession number is often the 4th item in the | (pipe) separated reference field (often the second column in a tab separated result). For example, the CP002582.1 in the gi|326539903|gb|CP002582.1| above.

So just as an example, reading in blast results might look something like:

Finding taxonomy for NCBI accession numbers

Now we are ready to convert NCBI accession numbers to taxonomic IDs. For example, to find the taxonomic IDs associated with NCBI accession numbers “LN847353.1” and “AL079352.3”:

## [1] 1313 9606

And to get the taxonomy for those IDs:

##      superkingdom phylum       class      order            
## 1313 "Bacteria"   "Firmicutes" "Bacilli"  "Lactobacillales"
## 9606 "Eukaryota"  "Chordata"   "Mammalia" "Primates"       
##      family             genus           species                   
## 1313 "Streptococcaceae" "Streptococcus" "Streptococcus pneumoniae"
## 9606 "Hominidae"        "Homo"          "Homo sapiens"

You can also get taxonomy for NCBI accession numbers without versions (the .X following the main number e.g. the “.1” in LN847353.1) using the version='base' argument of accessionToTaxa:

## [1] NA NA
## [1] 1313 9606

Finding taxonomy for taxonomic names

If you’d like to find IDs for taxonomic names then you can do something like:

## [1] "9606" "9913" "9605" "9852"

And again to get the taxonomy for those IDs use getTaxonomy:


##      superkingdom phylum     class      order      family      genus  
## 9606 "Eukaryota"  "Chordata" "Mammalia" "Primates" "Hominidae" "Homo" 
## 9913 "Eukaryota"  "Chordata" "Mammalia" NA         "Bovidae"   "Bos"  
## 9605 "Eukaryota"  "Chordata" "Mammalia" "Primates" "Hominidae" "Homo" 
## 9852 "Eukaryota"  "Chordata" "Mammalia" NA         "Cervidae"  "Alces"
##      species       
## 9606 "Homo sapiens"
## 9913 "Bos taurus"  
## 9605 NA            
## 9852 "Alces alces"

Condensing taxonomy

You can use the condenseTaxa function to find the agreements among taxonomic hits. For example to condense the taxonomy from the previous section to the lowest taxonomic rank shared by all three taxa:

##   superkingdom phylum     class      order family genus species
## 1 "Eukaryota"  "Chordata" "Mammalia" NA    NA     NA    NA

This function can also be fed a large number of grouped hits, e.g. BLAST hits for high throughput sequencing reads after filtering for the best hits for each read, and output a condensed taxonomy for each grouping:

##       superkingdom phylum     class      order      family      genus 
## read1 "Eukaryota"  "Chordata" "Mammalia" "Primates" "Hominidae" "Homo"
## read2 "Eukaryota"  "Chordata" "Mammalia" NA         NA          NA    
##       species
## read1 NA     
## read2 NA

Find all taxonomic assignments for a given taxa

To get all taxonomic assignments for a given taxa regardless of their particular rank, you can use the getRawTaxonomy function. Note that there are often many intermediate ranks outside the more common taxonomic ranks. The function returns a list since different IDs can have differing numbers of ranks. It is used similarly to getTaxonomy:

## $`9606`
##                species                  genus              subfamily 
##         "Homo sapiens"                 "Homo"            "Homininae" 
##                 family            superfamily              parvorder 
##            "Hominidae"           "Hominoidea"           "Catarrhini" 
##             infraorder               suborder                  order 
##          "Simiiformes"          "Haplorrhini"             "Primates" 
##             superorder                  clade                clade.1 
##     "Euarchontoglires"        "Boreoeutheria"             "Eutheria" 
##                clade.2                  class                clade.3 
##               "Theria"             "Mammalia"              "Amniota" 
##                clade.4                class.1             superclass 
##            "Tetrapoda" "Dipnotetrapodomorpha"        "Sarcopterygii" 
##                clade.5                clade.6                clade.7 
##         "Euteleostomi"           "Teleostomi"        "Gnathostomata" 
##                clade.8              subphylum                 phylum 
##           "Vertebrata"             "Craniata"             "Chordata" 
##                clade.9               clade.10               clade.11 
##        "Deuterostomia"            "Bilateria"            "Eumetazoa" 
##                kingdom               clade.12           superkingdom 
##              "Metazoa"         "Opisthokonta"            "Eukaryota" 
##                no rank 
##   "cellular organisms" 
## 
## $`9913`
##                species                  genus              subfamily 
##           "Bos taurus"                  "Bos"              "Bovinae" 
##                 family             infraorder               suborder 
##              "Bovidae"               "Pecora"           "Ruminantia" 
##                  order             superorder                  clade 
##         "Artiodactyla"       "Laurasiatheria"        "Boreoeutheria" 
##                clade.1                clade.2                  class 
##             "Eutheria"               "Theria"             "Mammalia" 
##                clade.3                clade.4                class.1 
##              "Amniota"            "Tetrapoda" "Dipnotetrapodomorpha" 
##             superclass                clade.5                clade.6 
##        "Sarcopterygii"         "Euteleostomi"           "Teleostomi" 
##                clade.7                clade.8              subphylum 
##        "Gnathostomata"           "Vertebrata"             "Craniata" 
##                 phylum                clade.9               clade.10 
##             "Chordata"        "Deuterostomia"            "Bilateria" 
##               clade.11                kingdom               clade.12 
##            "Eumetazoa"              "Metazoa"         "Opisthokonta" 
##           superkingdom                no rank 
##            "Eukaryota"   "cellular organisms"

These raw taxonomy with varying numbers of levels can be normalized so that all taxa share the same number of levels (aligning by taxonomic levels that are not the unspecific “clade”) using the normalizeTaxa function:

##      no rank              superkingdom superkingdom.1 kingdom   kingdom.1  
## 9606 "cellular organisms" "Eukaryota"  "Opisthokonta" "Metazoa" "Eumetazoa"
## 9913 "cellular organisms" "Eukaryota"  "Opisthokonta" "Metazoa" "Eumetazoa"
##      kingdom.2   kingdom.3       phylum     subphylum  subphylum.1 
## 9606 "Bilateria" "Deuterostomia" "Chordata" "Craniata" "Vertebrata"
## 9913 "Bilateria" "Deuterostomia" "Chordata" "Craniata" "Vertebrata"
##      subphylum.2     subphylum.3  subphylum.4    superclass     
## 9606 "Gnathostomata" "Teleostomi" "Euteleostomi" "Sarcopterygii"
## 9913 "Gnathostomata" "Teleostomi" "Euteleostomi" "Sarcopterygii"
##      superclass.1           superclass.2 superclass.3 class      class.1 
## 9606 "Dipnotetrapodomorpha" "Tetrapoda"  "Amniota"    "Mammalia" "Theria"
## 9913 "Dipnotetrapodomorpha" "Tetrapoda"  "Amniota"    "Mammalia" "Theria"
##      class.2    class.3         superorder         order          suborder     
## 9606 "Eutheria" "Boreoeutheria" "Euarchontoglires" "Primates"     "Haplorrhini"
## 9913 "Eutheria" "Boreoeutheria" "Laurasiatheria"   "Artiodactyla" "Ruminantia" 
##      infraorder    parvorder    superfamily  family      subfamily   genus 
## 9606 "Simiiformes" "Catarrhini" "Hominoidea" "Hominidae" "Homininae" "Homo"
## 9913 "Pecora"      NA           NA           "Bovidae"   "Bovinae"   "Bos" 
##      species       
## 9606 "Homo sapiens"
## 9913 "Bos taurus"

normalizeTaxa does its best to figure out the order of taxonomic levels automatically but can sometimes be left with ambiguous cases. This will result in an error like:

Error in topoSort(c(nonClade, list(lineageOrder)), errorIfAmbiguous = TRUE) : 
  Ambiguous ordering found in topoSort (suborder vs infraorder)

That’s saying that the algorithm is unclear from the data whether suborder or infraorder is the more specific taxonomic level. To clarify, give the lineageOrder parameter a vector going from most to least specific like:

normalizeTaxa(raw,lineageOrder=c('infraorder','suborder'))

For especially troublesome sets, you may have to repeat this step several times getting a new error each time to find all the ambiguities. This would result in building up a vector specifying the ordering of several ambiguous levels like:

normalizeTaxa(raw,lineageOrder=c('infraorder','suborder','superorder','infraclass','subclass','class'))

Finding accessions for a given taxonomic ID

To find all the accessions for a given taxonomic ID, you can use the getAccessions function. This is a bit of an unusual use case so to preserve space, an index is not created by default in read.accession2taxid. If you are going to use this function, you will want to rebuild the SQLite database with the indexTaxa argument set to true with something like:

## Reading nucl_gb.accession2taxid.gz.
## Reading nucl_wgs.accession2taxid.gz.
## Reading in values. This may take a while.
## Adding index. This may also take a while.

Then you can get the accessions for taxa 3702 with a command like (note that the limit argument is used here in order to preserve space):

##    taxa accession
## 1  3702  X58148.1
## 2  3702  X66414.1
## 3  3702  X60045.1
## 4  3702  X07376.1
## 5  3702  X54927.1
## 6  3702  X54926.1
## 7  3702  X54928.1
## 8  3702  X54930.1
## 9  3702  X54929.1
## 10 3702  X52320.1

Convert taxonomy to Newick tree

This is probably only useful in a few specific cases but a convenience function makeNewick to convert taxonomy into a Newick tree is included. The function takes a matrix with columns corresponding to taxonomic categories and rows corresponding to taxonomic assignments, e.g. the output from condenseTaxa or getTaxonomy or normalizeTaxa and reduces it to a Newick formatted tree. For example:

##      [,1]        [,2]       [,3]       [,4]       [,5]        [,6]   
## [1,] "Eukaryota" "Chordata" "Mammalia" "Primates" "Hominidae" "Homo" 
## [2,] "Eukaryota" "Chordata" "Mammalia" "Primates" "Hominidae" "Pan"  
## [3,] "Eukaryota" "Chordata" "Mammalia" NA         "Cervidae"  "Alces"
## [1] "((((((Homo,Pan)Hominidae)Primates,((Alces)Cervidae)_)Mammalia)Chordata)Eukaryota);"

If quotes are needed, then specify the quote argument:

## [1] "(((((('Homo','Pan')'Hominidae')'Primates',(('Alces')'Cervidae')_)'Mammalia')'Chordata')'Eukaryota');"

By default, makeNewick includes trailing nodes that are all NA in the tree e.g.:

##      [,1]        [,2]       [,3]       [,4]       [,5]        [,6]  
## [1,] "Eukaryota" "Chordata" "Mammalia" "Primates" "Hominidae" "Homo"
## [2,] "Eukaryota" "Chordata" "Mammalia" "Primates" "Hominidae" "Pan" 
## [3,] "Eukaryota" "Chordata" NA         NA         NA          NA
## [1] "((((((Homo,Pan)Hominidae)Primates)Mammalia,(((_)_)_)_)Chordata)Eukaryota);"

If these nodes are not desired then set excludeTerminalNAs to FALSE:

## [1] "((((((Homo,Pan)Hominidae)Primates)Mammalia)Chordata)Eukaryota);"

Note that taxa may be the most specific taxon for a given taxa in the taxonomy matrix but will not be a leaf in the resulting tree if it appears in other taxonomy e.g. Chordata in this example.

Changelog

v0.9.3

v0.9.2

v0.8.4

v0.8.3

v0.8.2

v0.8.1

v0.8.0

v0.7.1

v0.7.0

v0.6.0

v0.5.3

v0.5.0

Manual preparation of database (usually not necessary)

Note: Since version 0.5.0, it is usually not necessary to run the following manually, the function prepareDatabase() should do most of this automatically for you (see above).

In order to avoid constant internet access and slow APIs, the first step in using the package is to downloads all necessary files from NCBI. This uses a bit of disk space but makes future access reliable and fast.

Note: It is not necessary to manually check for the presence of these files since the functions automatically check to see if their output is present and if so skip downloading/processing. Delete the local files if you would like to redownload or reprocess them.

Download names and nodes

First, download the necessary names and nodes files from NCBI:

## [1] "./names.dmp" "./nodes.dmp"

Download accession to taxa files

Then download accession to taxa id conversion files from NCBI. Note: this is a pretty big download (several gigabytes):

## This can be a big (several gigabytes) download. Please be patient and use a fast connection.
## [1] "./nucl_gb.accession2taxid.gz"  "./nucl_wgs.accession2taxid.gz"

If you would also like to identify protein accession numbers, also download the prot file from NCBI (again this is a big download):

## This can be a big (several gigabytes) download. Please be patient and use a fast connection.
## [1] "./prot.accession2taxid.gz"

Convert names, nodes and accessions to database

Then process the downloaded names and nodes files into a more easily accessed form:

Next process the downloaded accession files into the same database (this one could take a while):

## Reading nucl_gb.accession2taxid.gz.
## Reading nucl_wgs.accession2taxid.gz.
## Reading prot.accession2taxid.gz.
## Reading in values. This may take a while.
## Adding index. This may also take a while.

Now everything should be ready for processing. All files are cached locally and so the preparation is only required once (or whenever you would like to update the data). It is not necessary to manually check for the presence of these files since the functions automatically check to see if their output is present and if so skip downloading/processing. Delete the local files if you would like to redownload or reprocess them.

Switch from data.table to SQLite

Version 0.5.0 marked a change for name and node lookups from using data.table to using SQLite. This was necessary to increase performance (10-100x speedup for getTaxonomy) and create a simpler interface (a single SQLite database contains all necessary data). Unfortunately, this switch requires a couple breaking changes: * getTaxonomy changes from getTaxonomy(ids,namesDT,nodesDT) to getTaxonomy(ids,sqlFile) * getId changes from getId(taxa,namesDT) to getId(taxa,sqlFile) * read.names is deprecated, instead use read.names.sql. For example, instead of calling names<-read.names('names.dmp') in every session, simply call read.names.sql('names.dmp','accessionTaxa.sql') once (or use the convenient prepareDatabase as above)). * read.nodes is deprecated, instead use read.names.sql. For example. instead of calling nodes<-read.names('nodes.dmp') in every session, simply call read.nodes.sql('nodes.dmp','accessionTaxa.sql') once (or use the convenient prepareDatabase as above).

I’ve tried to ease any problems with this by overloading getTaxonomy and getId to still function (with a warning) if passed a data.table names and nodes argument and providing a simpler prepareDatabase function for completing all setup steps (hopefully avoiding direct calls to read.names and read.nodes for most users).

I plan to eventually remove data.table functionality to avoid a split codebase so please switch to the new SQLite format in all new code.