Using eDNA to biomonitor the fish community in a tropical oligotrophic lake.

Martha Valdez-Moreno,Stephanie L Pedersen,Kyrylo Bessonov,Manuel Elías-Gutiérrez,Paul D N Hebert,Natalia V Ivanova,Hideyuki Doi

doi:10.1371/journal.pone.0215505

Martha Valdez-Moreno, Stephanie L Pedersen + Show 5 more

Open Access

https://doi.org/10.1371/journal.pone.0215505

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Journal: PloS one	Publication Date: Apr 22, 2019
Citations: 41	License type: CC BY 4.0

Affiliation: University of Guelph, El Colegio de la Frontera Sur

Abstract

Environmental DNA (eDNA) is an effective approach for detecting vertebrates and plants, especially in aquatic ecosystems, but prior studies have largely examined eDNA in cool temperate settings. By contrast, this study employs eDNA to survey the fish fauna in tropical Lake Bacalar (Mexico) with the additional goal of assessing the possible presence of invasive fishes, such as Amazon sailfin catfish and tilapia. Sediment and water samples were collected from eight stations in Lake Bacalar on three occasions over a 4-month interval. Each sample was stored in the presence or absence of lysis buffer to compare eDNA recovery. Short fragments (184–187 bp) of the cytochrome c oxidase I (COI) gene were amplified using fusion primers and then sequenced on Ion Torrent PGM or S5 before their source species were determined using a custom reference sequence database constructed on BOLD. In total, eDNA sequences were recovered from 75 species of vertebrates including 47 fishes, 15 birds, 7 mammals, 5 reptiles, and 1 amphibian. Although all species are known from this region, six fish species represent new records for the study area, while two require verification. Sequences for five species (2 birds, 2 mammals, 1 reptile) were only detected from sediments, while sequences from 52 species were only recovered from water. Because DNA from the Amazon sailfin catfish was not detected, we used a mock eDNA experiment to confirm our methods would enable its detection. In summary, we developed protocols that recovered eDNA from tropical oligotrophic aquatic ecosystems and confirmed their effectiveness in detecting fishes and diverse species of vertebrates.

Highlights

Environmental DNA has gained popularity for biomonitoring, especially for the detection of invasive species and for baseline surveys of animal and plant communties [1,2]
We developed field sampling protocols and a HTS pipeline which enabled the efficient recovery of Environmental DNA (eDNA) from several tropical aquatic ecosystems
Water samples consistently revealed more vertebrate species than sediment samples about 10% of the species were only recovered from sediments

Summary

Introduction

Environmental DNA (eDNA) has gained popularity for biomonitoring, especially for the detection of invasive species and for baseline surveys of animal and plant communties [1,2]. This eDNA derives from cells shed into the environment as mucus, urine, feces, or gametes [2,3,4,5,6,7]. More than 120 articles have considered eDNA, including a special issue on the topic [8]. Using eDNA to biomonitor fish in a tropical lake and MEG thank CONACYT for support through the Sabbatical Stays Program (Grants 261790 and 262267). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript

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