Detecting fossorial salamanders using eDNA: Development and validation of quantitative and end-point PCR assays for the detection of five species of Ambystoma

Detecting fossorial salamanders using eDNA: Development and validation of quantitative and end-point PCR assays for the detection of five species of Ambystoma

In the past decade, quantification of environmental DNA (eDNA) has become firmly established as an effective method for detecting the presence of organisms of research and conservation interest. Salamanders of the family Ambystomatidae are large, fossorial species; adults are rarely encountered abov...

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Veröffentlicht in:Conservation genetics resources 2023-12, Vol.15 (4), p.187-198
Hauptverfasser: Brammell, Ben F., Strasko, Elizabeth K., Brewer, Sara A., Piche, Rebecca R., Sams, Cierla M., Mott, Cy L., Stull, Malinda A.
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Ambystoma
Animal Genetics and Genomics
Biodiversity
Biomedical and Life Sciences
Breeding sites
Conservation Biology/Ecology
Design
Ecology
Environmental DNA
Evolutionary Biology
Genetics
Habitats
Larvae
Life Sciences
Methods and Resources
Plant Genetics and Genomics
Polymerase chain reaction
Reptiles & amphibians
Spawning
Species
Surveys
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container_end_page 198
container_issue 4
container_start_page 187
container_title Conservation genetics resources
container_volume 15
creator Brammell, Ben F.
Strasko, Elizabeth K.
Brewer, Sara A.
Piche, Rebecca R.
Sams, Cierla M.
Mott, Cy L.
Stull, Malinda A.
description In the past decade, quantification of environmental DNA (eDNA) has become firmly established as an effective method for detecting the presence of organisms of research and conservation interest. Salamanders of the family Ambystomatidae are large, fossorial species; adults are rarely encountered above ground outside of their brief reproductive season. Larvae develop rapidly, in ephemeral pools or streams, often with multiple species coexisting in a single habitat. We developed species-specific PCR assays for Ambystoma barbouri , Ambystoma jeffersonianum , Ambystoma opacum , Ambystoma maculatum , and Ambystoma tigrinum based on locally sequenced specimens and tested each in silico and in vitro as well as conducted field surveys, using both end-point and quantitative PCR to test all in situ except A. tigrinum . In silico and in vitro tests confirm specificity of each primer. In situ larvae surveys were conducted and water samples collected from known Ambystoma breeding sites in central and eastern Kentucky, USA. Larvae of one or more species were observed at 12/13 sites. A total of 14 separate species sightings were observed, and in each case, eDNA from the observed species was detected via qPCR. Additionally, nine qPCR detections were observed at sites where species were not field observed. End-point PCR results were less effective in detecting field observed species, and primers appeared to bind to DNA from non-salamander targets. These primers, when used with a probe in a qPCR assay, provide an effective means of determining species presence rapidly and definitively and therefore offer to increase the ease of range delineation and spawning habitat studies.
doi_str_mv 10.1007/s12686-023-01322-6
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subjects Ambystoma
Animal Genetics and Genomics
Biodiversity
Biomedical and Life Sciences
Breeding sites
Conservation Biology/Ecology
Design
Ecology
Environmental DNA
Evolutionary Biology
Genetics
Habitats
Larvae
Life Sciences
Methods and Resources
Plant Genetics and Genomics
Polymerase chain reaction
Reptiles & amphibians
Spawning
Species
Surveys
title Detecting fossorial salamanders using eDNA: Development and validation of quantitative and end-point PCR assays for the detection of five species of Ambystoma
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