Advances in Environmental DNA Sampling for Observing Ocean Twilight Zone Animal Diversity

The ocean’s vast twilight, or mesopelagic, zone (200–1,000 m depth) harbors immense biomass consisting of myriad poorly known and unique animal species whose quantity and diversity are likely considerably underestimated. As they facilitate the movement of carbon from surface waters to the deep sea t...

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Bibliographic Details
Published inOceanography (Washington, D.C.) Vol. 36; no. 1; pp. 80 - 86
Main Authors Govindarajan, Annette F., Adams, Allan, Allan, Elizabeth, Herrera, Santiago, Lavery, Andone, Llopiz, Joel, McCartin, Luke, Yoerger, Dana R., Zhang, Weifeng
Format Journal Article
LanguageEnglish
Published Rockville Oceanography Society 01.03.2023
Subjects
Acidification
Animal behavior
Animal species
Animals
Anthropogenic factors
Biodiversity
Carbon cycle
Climate change
Deep sea
Deoxyribonucleic acid
DNA
Feeding behavior
Genetic markers
Harbors
Marine pollution
Ocean acidification
Overfishing
Sampling
Species diversity
Surface water
TECHNOLOGY: Environmental DNA
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Summary:The ocean’s vast twilight, or mesopelagic, zone (200–1,000 m depth) harbors immense biomass consisting of myriad poorly known and unique animal species whose quantity and diversity are likely considerably underestimated. As they facilitate the movement of carbon from surface waters to the deep sea through feeding and migratory behaviors, ocean twilight zone (OTZ) animals are vital to regulating Earth’s climate (Ducklow et al., 2001). However, anthropogenic threats, such as climate change, ocean acidification, pollution, and overfishing pose an imminent threat to OTZ animals. Long-term spatially and temporally intensive observations are essential to our understanding of biodiversity in the OTZ, to resolving global carbon cycles, and to monitoring ocean health. Environmental DNA (eDNA) analysis, which involves studying the trace genetic signatures of organisms (Figure 1), is a promising approach to filling this urgent need. eDNA can be sampled and diagnostic genetic markers (“barcodes”) can be sequenced in order to detect the animals inhabiting a given water parcel. Other laboratory protocols (e.g., quantitative PCR, or “qPCR” and “digital droplet PCR”) can be applied to facilitate quantitative assessments of specific target species (Eble et al., 2020). In seagoing oceanographic research, eDNA assessment is transitioning from being considered an experimental approach to becoming an established routine that can be scaled up to match ocean observing needs.
ISSN:1042-8275
2377-617X
DOI:10.5670/oceanog.2023.s1.27