Article Highlight | 6-Dec-2024

Robots give scientists unprecedented access to study coral reef biodiversity

Study confirms accurateness of underwater robot eDNA samplers to track marine life

Okinawa Institute of Science and Technology (OIST) Graduate University

Background

Mesophotic coral ecosystems have some of the highest diversity of stony corals (Scleractinia) in the world, making them particularly important for researchers. These ecosystems are also unique because they host more native species compared to shallow-water coral ecosystems. However, they are difficult to monitor because they are often located at deeper depths of 30 to 150 meters.

To accurately monitor these corals, scientists require both scuba diving and taxonomy skills, which can be challenging. Existing monitoring methods therefore impose limitations on conducting thorough surveys, and new methods are needed.

Scientists have found an innovative solution: environmental DNA (eDNA) analysis using underwater mini remotely operated vehicles or Mini-ROVs. By collecting and analyzing genetic material that corals naturally release into the water – environmental DNA or eDNA – multiple species present in these deeper-water environments can now be identified without direct observations. This makes it easier to study previously hard-to-access biodiversity hotspots.

Researchers at the Marine Genomics Unit at the Okinawa Institue of Science and Technology (OIST) and their collaborators at the University of the Ryukyus and NTT Communications, have established a robust system to monitor mesophotic coral ecosystems using a combination of underwater robots and eDNA barcoding. Their findings have been published in the journal Coral Reefs.

Methodology 

Four monitoring sites in Shigeo Reef near Motobu Peninsula in Okinawa, Japan, were surveyed. Two sites were approximately 35-45 m in depth (SR1 and SR2), and two deeper sites were approximately 54-59 m in depth (SR1 and SR2). A Mini-ROV collected water samples from each site. Seawater samples were collected approximately 0.5-1 m above the reef bottom and carefully preserved to protect any coral eDNA present. 

The scientists analyzed mitochondrial DNA to identify coral species. To improve accuracy, a custom database using complete mitochondrial genomes of corals was created. This database helped identify the eDNA sequences and allowed the researchers to accurately identify and analyze coral genera present in their samples.

Findings 

The eDNA analysis and underwater robot observations revealed different coral communities at each study site. SR1 was rich with several coral types, particularly Acropora, Seriatopora, and Pachyseris, along with some Cycloseris and Galaxea. SR2 was dominated by Seriatopora corals with some Galaxea present. SR4 showed a diverse community led by Alveopora, accompanied by various other coral types. In contrast, SR3 had the sparsest coral coverage, featuring only a few Lobophyllids and Cycloseris, despite being close to the more diverse SR4 site. These varied distributions made these sites ideal for testing the effectiveness of the new DNA sampling method.

Importantly, the results from the eDNA metabarcoding analysis confirmed previous observational data on coral species at all 4 sites. However, the technique is not without its limitations. In some cases, the eDNA analysis could not distinguish between closely related coral species, and the success rate of DNA sampling varied between locations. Despite these challenges, the study represents an important step forward in coral reef research. The ability to detect coral species through water samples and visually confirm their presence provides scientists with a valuable new tool for monitoring coral reef health and biodiversity in hard-to-reach locations.

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