The utility of environmental DNA from sediment and water samples for recovery of observed plant and animal species from four Mojave Desert springs

Maura Palacios Mejia; Emily Curd; Kiumars Edalati; Mark A. Renshaw; Roy Dunn; Daniel Potter; Naomi Fraga; Jenna Moore; Justin Saiz; Robert Wayne; Sophie S. Parker

doi:10.1002/edn3.161

Environmental DNA (Jan 2021)

The utility of environmental DNA from sediment and water samples for recovery of observed plant and animal species from four Mojave Desert springs

Maura Palacios Mejia,
Emily Curd,
Kiumars Edalati,
Mark A. Renshaw,
Roy Dunn,
Daniel Potter,
Naomi Fraga,
Jenna Moore,
Justin Saiz,
Robert Wayne,
Sophie S. Parker

Affiliations

Maura Palacios Mejia: Ecology & Evolutionary Biology University of California, Los Angeles Los Angeles CA USA
Emily Curd: Ecology & Evolutionary Biology University of California, Los Angeles Los Angeles CA USA
Kiumars Edalati: Ecology & Evolutionary Biology University of California, Los Angeles Los Angeles CA USA
Mark A. Renshaw: U.S. Geological Survey ‐ Wetland and Aquatic Research Center Gainesville FL USA
Roy Dunn: Transition Habitat Conservancy Pinon Hills CA USA
Daniel Potter: Transition Habitat Conservancy Pinon Hills CA USA
Naomi Fraga: California Botanic Garden Claremont CA USA
Jenna Moore: Bureau of Land Management ‐ California Desert District ‐ Needles Field Office Needles CA USA
Justin Saiz: Bureau of Land Management ‐ California Desert District ‐ Needles Field Office Needles CA USA
Robert Wayne: Ecology & Evolutionary Biology University of California, Los Angeles Los Angeles CA USA
Sophie S. Parker: The Nature Conservancy Los Angeles CA USA

DOI: https://doi.org/10.1002/edn3.161
Journal volume & issue: Vol. 3, no. 1
pp. 214 – 230

Abstract

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Abstract Mojave Desert springs are fragile ecosystems, hosting endemic plants and animals, which are threatened by the increasing human demand for water and climate change. To develop management practices that will protect the groundwater‐dependent ecosystems at Mojave Desert springs, real‐time, low‐cost biodiversity monitoring, and assessments are required. Environmental DNA (eDNA) metabarcoding uses DNA shed from organisms (e.g., skin cells, feces, and pollen) that are present in water, air, soil, or sediment samples to assess community composition. This approach can increase the detection sensitivity for rare and elusive species, compared with expensive and time‐consuming conventional methods, which also require taxonomic expertise. This study tests the effectiveness of eDNA techniques in capturing the observed Mojave Desert spring biodiversity in the winter and spring of 2019 at four distinct, naturally occurring springs. We also test the utility of sample types (water vs. sediment) for capturing biodiversity. We found that each of the four Mojave Desert springs supports a unique biological community. Sediment samples contained the greatest biodiversity, but all sample types captured species observed in the field by humans or camera traps. We also found no statistical difference in species richness captured in winter and spring except for the Cytochrome Oxidase I marker, for which winter had greater biodiversity. This study supports the use of eDNA metabarcoding as an effective tool to mirror observation by human observers of ecological communities in desert springs. The study demonstrates the importance of appropriately timing eDNA field sampling, primer selection, and using field‐based surveys of wildlife and plants in addition to eDNA detection. This study also identified gaps in reference sequence databases for Mojave biodiversity and encourages collaboration of eDNA researchers with managers for effective conservation management plans.

Published in Environmental DNA

ISSN: 2637-4943 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Geography. Anthropology. Recreation: Environmental sciences; Science: Microbiology: Microbial ecology
Website: https://onlinelibrary.wiley.com/journal/26374943

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