Abstract
DNA metabarcoding is a promising approach for rapidly surveying biodiversity and is likely to become an important tool for measuring ecosystem responses to environmental change. Metabarcoding markers need sufficient taxonomic coverage to detect groups of interest, sufficient sequence divergence to resolve species, and will ideally indicate relative abundance of taxa present. We characterized zooplankton assemblages with three different metabarcoding markers (nuclear 18S rDNA, mitochondrial COI, and mitochondrial 16S rDNA) to compare their performance in terms of taxonomic coverage, taxonomic resolution, and correspondence between morphology‐ and DNA‐based identification. COI amplicons sequenced on separate runs showed that operational taxonomic units representing >0.1% of reads per sample were highly reproducible, although slightly more taxa were detected using a lower annealing temperature. Mitochondrial COI and nuclear 18S showed similar taxonomic coverage across zooplankton phyla. However, mitochondrial COI resolved up to threefold more taxa to species compared to 18S. All markers revealed similar patterns of beta‐diversity, although different taxa were identified as the greatest contributors to these patterns for 18S. For calanoid copepod families, all markers displayed a positive relationship between biomass and sequence reads, although the relationship was typically strongest for 18S. The use of COI for metabarcoding has been questioned due to lack of conserved primer‐binding sites. However, our results show the taxonomic coverage and resolution provided by degenerate COI primers, combined with a comparatively well‐developed reference sequence database, make them valuable metabarcoding markers for biodiversity assessment.
Highlights
Recent research has begun to validate metabarcoding as a time and cost-efficient method for biodiversity surveys in terrestrial, freshwater, and marine ecosystems (Hirai, Kuriyama, Ichikawa, Hidaka,& Tsuda, 2015; Ji et al, 2013; Thomsen et al, 2012; Valentini et al, 2016)
Our results suggest the number of 18S ribosomal DNA (rDNA) hroughput sequencing (HTS) reads provides a better proxy for calanoid copepod biomass than mitochondrial markers, but should be confirmed and extended to other zooplankton groups using well-characterized samples such as mock communities
Our study extends previous research demonstrating the value of metabarcoding for rapidly surveying biodiversity, including the potential to identify nonmetazoans and developmental stages such as eggs and larvae, as well as environmental DNA and parasite detections not possible with traditional methods
Summary
Recent research has begun to validate metabarcoding as a time and cost-efficient method for biodiversity surveys in terrestrial, freshwater, and marine ecosystems (Hirai, Kuriyama, Ichikawa, Hidaka,& Tsuda, 2015; Ji et al, 2013; Thomsen et al, 2012; Valentini et al, 2016). Recent research has begun to validate metabarcoding as a time and cost-efficient method for biodiversity surveys in terrestrial, freshwater, and marine ecosystems The results of metabarcoding studies depend on the markers used providing sufficient taxonomic coverage and resolution for the taxa of interest. The coverage of metabarcoding markers is more of an issue for taxonomically diverse samples such as zooplankton surveys. Sites 1–5 January 1 sample/site 2 DNA extracts/sample DNA Template (n = 10) COI (TD) COI (46) COI (46). Site 2 January March April 1 sample 2 samples
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