Creating, curating and evaluating a mitogenomic reference database to improve regional species identification using environmental DNA

• Published in: Molecular ecology resources Vol. 23; no. 8; pp. 1880 - 1904
• Main Authors: Dziedzic, Emily, Sidlauskas, Brian, Cronn, Richard, Anthony, James, Cornwell, Trevan, Friesen, Thomas A., Konstantinidis, Peter, Penaluna, Brooke E., Stein, Staci, Levi, Taal
• Format: Journal Article
• Language: English
• Published: Oxford Wiley Subscription Services, Inc 01.11.2023
• Subjects: Bats; Biodiversity; Comparative analysis; Environmental DNA; Freshwater fish; Genera; Genomics; Taxa; Oregon; United States > US
• ISSN: 1755-098X; 1755-0998
• DOI: 10.1111/1755-0998.13855

Abstract Species detection using eDNA is revolutionizing global capacity to monitor biodiversity. However, the lack of regional, vouchered, genomic sequence information—especially sequence information that includes intraspecific variation—creates a bottleneck for management agencies wanting to harness the complete power of eDNA to monitor taxa and implement eDNA analyses. eDNA studies depend upon regional databases of mitogenomic sequence information to evaluate the effectiveness of such data to detect and identify taxa. We created the Oregon Biodiversity Genome Project to create a database of complete, nearly error‐free mitogenomic sequences for all of Oregon's fishes. We have successfully assembled the complete mitogenomes of 313 specimens of freshwater, anadromous and estuarine fishes representing 24 families, 55 genera and 129 species and lineages. Comparative analyses of these sequences illustrate that many regions of the mitogenome are taxonomically informative, that the short (~150 bp) mitochondrial ‘barcode’ regions typically used for eDNA assays do not consistently diagnose for species and that complete single or multiple genes of the mitogenome are preferable for identifying Oregon's fishes. This project provides a blueprint for other researchers to follow as they build regional databases, illustrates the taxonomic value and limits of complete mitogenomic sequences and offers clues as to how current eDNA assays and environmental genomics methods of the future can best leverage this information.