Environmental DNA for conservation

Biodiversity must be documented before it can be conserved. However, it may be difficult to document species with few individuals (Thompson, 2013; Goldberg et al., 2016), thus it requires a multitude of tools to detect species that occur in low numbers or are elusive (see the various chapters in thi...

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Bibliographic Details
Main Author: Piaggio, Antoinette J.
Format: Text
Language:unknown
Published: DigitalCommons@University of Nebraska - Lincoln 2021
Subjects:
Animal Sciences
Environmental Sciences
Life Sciences
Natural Resources and Conservation
Natural Resources Management and Policy
Other Environmental Sciences
Other Veterinary Medicine
Population Biology
Terrestrial and Aquatic Ecology
Veterinary Infectious Diseases
Veterinary Medicine
Veterinary Microbiology and Immunobiology
Veterinary Preventive Medicine
Epidemiology
and Public Health
Zoology
Arctic
Online Access:https://digitalcommons.unl.edu/icwdm_usdanwrc/2551
https://digitalcommons.unl.edu/context/icwdm_usdanwrc/article/3543/viewcontent/Piaggio_CT_2021_Environmental_DNA.pdf
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Summary:Biodiversity must be documented before it can be conserved. However, it may be difficult to document species with few individuals (Thompson, 2013; Goldberg et al., 2016), thus it requires a multitude of tools to detect species that occur in low numbers or are elusive (see the various chapters in this volume). One tool that has become useful for conservation efforts utilizes environmental DNA, which is DNA shed into the environment by organisms (eDNA; Taberlet et al., 2018). Typically this involves taking environmental samples such as soil, water, air, or using biological surrogates for sampling biodiversity (e.g. leeches, sponges, carrion flies, etc.; Schnell et al., 2012; Calvignac-Spencer et al., 2013; Lynggaard et al., 2019; Mariani et al., 2019) and using laboratory approaches to concentrate, isolate, and test for target DNA through polymerase chain reaction (PCR) amplification (Taberlet et al., 2018). The utilization of eDNA for species detection is part of a larger field of non-invasive DNA sampling, which more broadly includes collecting DNA passively from wildlife, through collection of faeces, saliva, feathers, hair, or other methods of sampling shed DNA. Environmental DNA has been used to document presence/absence of a target species (Ficetola et al., 2008a, 2008b; Himter et al., 2017) or to quantify relative abundance for biodiversity from varied environments such as the arctic (e.g. Leduc et al., 2019; Von Duyke et al., 2019), marine (e.g. Port et al., 2016; Jo et al, 2017; Stoeckle et al., 2018), freshwater (e.g. Lacoursi^re-Roussel et al., 2016; Doi et al., 2017), and tropical (e.g. Schnell et al., 2012; Gogarten et al, 2020) ecosystems. The application of this technology includes the detection of invasive species, pathogens (including DNA and RNA), species of conservation concern, and biodiversity (Acevedo-Whitehouse et al., 2010; Rees et al., 2014; Sakai et al, 2019). In this world -of 'fast-paced technological advances, not all new methods prove useful in an applied context. Although eDNA has ...

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