insect is an R package for taxonomic identification of
amplicon sequence variants generated by DNA meta-barcoding analysis. The
learning and classification algorithms implemented in the package are
based on full probabilistic models (profile hidden Markov models) and
offer highly accurate taxon IDs, albeit at a relatively high
computational cost.
The package also contains functions for searching and downloading reference sequences and taxonomic information from NCBI, a “virtual PCR” tool for sequence trimming, a function for purging erroneously labeled reference sequences, and several other tools.
insect is designed to be used in conjunction with the dada2 pipeline or
other de-noising tools that produce a list of amplicon sequence variants
(ASVs). While unfiltered sequences can also be processed with high
accuracy, the insect classification algorithm is
relatively slow, since it uses a computationally intensive dynamic
programming algorithm to find the likelihood values of each sequence
given the models at each node of the classification tree. Hence filtered
input datasets are generally be much faster to process.
To download insect from CRAN and load the package, run
install.packages("insect")
library(insect)To download the latest development version from GitHub, run:
devtools::install_github("shaunpwilkinson/insect", build_vignettes = TRUE)
library(insect)Classifiers for some of the more commonly used metabarcoding primer sets are available here:
| Marker | Target | Primers | Source | Version | Date | Download |
|---|---|---|---|---|---|---|
| 12S | Fish | MiFishUF/MiFishUR (Miya et al 2015) | GenBank | 1 | 20181111 | RDS (9MB) |
| 16S | Marine crustaceans | Crust16S_F/Crust16S_R (Berry et al 2017) | GenBank | 4 | 20180626 | RDS (7.1 MB) |
| 16S | Marine fish | Fish16sF/16s2R (Berry et al 2017; Deagle et al 2007) | GenBank | 4 | 20180627 | RDS (6.8MB) |
| 18S | Marine eukaryotes | 18S_1F/18S_400R (Pochon et al 2017) | SILVA_132_LSUParc, GenBank | 5 | 20180709 | RDS (11.8 MB) |
| 18S | Marine eukaryotes | 18S_V4F/18S_V4R (Stat et al 2017) | GenBank | 4 | 20180525 | RDS (11.5 MB) |
| 23S | Algae | p23SrV_f1/p23SrV_r1 (Sherwood & Presting 2007) | SILVA_132_LSUParc | 1 | 20180715 | RDS (26.9MB) |
| COI | Metazoans | mlCOIintF/jgHCO2198 (Leray et al 2013) | Midori, GenBank | 5 | 20181124 | RDS (140 MB) |
| ITS2 | Cnidarians and sponges | scl58SF/scl28SR (Wilkinson et al in prep) | GenBank | 5 | 20180920 | RDS (6.6 MB) |
To classify a sequence or set of sequences, first read them into R as a “DNAbin” list object. FASTA files can be parsed as follows:
x <- readFASTA("<path-to-file>.fasta")Alternatively users may wish to assign taxon IDs to the output from the DADA2 pipeline, in which case the column names of the ouput table can be parsed as in the following example:
data("samoa")
x <- char2dna(colnames(samoa))
## name the sequences sequentially
names(x) <- paste0("ASV", seq_along(x))The next step is to download and read in the classifier. It is important to ensure that the classifier was trained using the same primer set as that used to generate the query data. In this example the data were generated from autonomous reef monitoring structures in American Samoa (ARMS) using the COI metabarcoding primers mlCOIintF and jgHCO2198 (Leray et al 2013), and de-noised, filtered and merged following the DADA2 tutorial.
The COI classifier was created using the MIDORI UNIQUE 20180221 trainingset, supplemented with around 14,000 non-metazoan COI sequences downloaded from GenBank.
The 140 MB classifier can be downloaded to the current working directory and read into R as follows:
download.file("https://www.dropbox.com/s/dvnrhnfmo727774/classifier.rds?dl=1",
destfile = "classifier.rds", mode = "wb")
classifier <- readRDS("classifier.rds")There is an option to perform a nearest-neighbor search prior to the
computationally-expensive recursive model test procedure, which can save
time and improve resolution (‘recall’) at lower taxonomic ranks. Note
that this can be a double-edged sword; if multiple species share an
identical or near-identical sequence, and the true taxon of the query
sequence is missing from the trainingset, the algorithm may
over-classify the sequence and return a congeneric taxon. To perform a
nearest-neighbor search with a similarity threshold of 0.99 (meaning any
sequence in the trainingset with a similarity greater than or equal to
99% is considered a match), set ping = 0.99. To stay on the
safe side, we will set ping = 1 (i.e. only sequences with
100% identity are considered matches).
out <- classify(x, classifier, threshold = 0.8)| representative | taxID | taxon | rank | score | kingdom | phylum | class | order | family | genus | species |
|---|---|---|---|---|---|---|---|---|---|---|---|
| ASV1 | 2806 | Florideophyceae | class | 0.9981 | Florideophyceae | ||||||
| ASV2 | 6379 | Chaetopterus | genus | 1.0000 | Metazoa | Annelida | Polychaeta | Spionida | Chaetopteridae | Chaetopterus | |
| ASV3 | 2806 | Florideophyceae | class | 0.9989 | Florideophyceae | ||||||
| ASV4 | 2172821 | Multicrustacea | superclass | 1.0000 | Metazoa | Arthropoda | |||||
| ASV5 | 131567 | cellular organisms | no rank | 0.9952 | |||||||
| ASV6 | 2806 | Florideophyceae | class | 0.9981 | Florideophyceae | ||||||
| ASV7 | 39820 | Nereididae | family | 1.0000 | Metazoa | Annelida | Polychaeta | Phyllodocida | Nereididae | ||
| ASV8 | 116571 | Podoplea | superorder | 0.9995 | Metazoa | Arthropoda | Hexanauplia | ||||
| ASV9 | 2806 | Florideophyceae | class | 0.9482 | Florideophyceae | ||||||
| ASV10 | 1 | root | no rank | NA | |||||||
| ASV11 | 115834 | Hesionidae | family | 1.0000 | Metazoa | Annelida | Polychaeta | Phyllodocida | Hesionidae | ||
| ASV12 | 1443949 | Corallinophycidae | subclass | 0.9910 | Florideophyceae | ||||||
| ASV13 | 33213 | Bilateria | no rank | 1.0000 | Metazoa | ||||||
| ASV14 | 131567 | cellular organisms | no rank | 0.9952 | |||||||
| ASV15 | 2806 | Florideophyceae | class | 0.9993 | Florideophyceae | ||||||
| ASV16 | 39820 | Nereididae | family | 1.0000 | Metazoa | Annelida | Polychaeta | Phyllodocida | Nereididae |
A more detailed overview of the package and its functions can be found here or by running
vignette("insect-vignette")If you experience a problem using this software please feel free to raise it as an issue on GitHub.
This software was developed at Victoria University of Wellington with funding from a Rutherford Foundation Postdoctoral Research Fellowship award from the Royal Society of New Zealand. Unpublished COI data care of Molly Timmers (NOAA).