DNA breakthrough detects genetic diversity of invasive fish: Research
New York, US: Ecologists have proven that the genetic material that species shed into their environments can reveal not only the presence of the species but also a wide range of information about the genetics of whole populations — information that may assist scientists to trace the source of a new invasive population and prevent further invasion.
The advancement in environmental DNA (eDNA) also opens new possibilities for protecting endangered and vulnerable species.
“For the benefit of biodiversity conservation, we’re getting closer and closer to what forensic scientists do every day at crime scenes,” said study co-author David Lodge, director of the Cornell Atkinson Center for Sustainability.
In the new study, published in the Proceedings of the National Academy of Sciences, the researchers demonstrated that their methodology was successful in field sampling of invasive round goby fish throughout the Great Lakes and the New York Finger Lakes.
In their Great Lakes study, which involved collecting water and tissue samples from round goby fish in 13 locations from Lake Michigan to Oneida Lake, the researchers found that their eDNA sampling methodology can be used to detect nuclear genetic variations, making it possible to analyze genetic diversity and variation within species.
This information is useful for natural resource managers because it can help them trace the source of a new invasive population as well as prevent further invasion or minimize harm by determining how invasive species are moving and how to stop them.
The breakthrough can also help scientists understand the demographics of imperilled species without requiring the physical capture of animals that are already rare and vulnerable. Species experiencing population declines can suffer from a loss of genetic diversity, and eDNA may allow researchers to detect those declines earlier, according to the first author of the study, Kara Andres.
Andres is a former graduate student in Lodge’s lab and now a postdoctoral fellow at Washington University in St Louis. She wrote the paper with co-authors Lodge and Jose Andrés, a Cornell Atkinson faculty fellow and a senior research associate who co-directs the Cornell Environmental DNA and Genomics Core Facility.
“It is a major step in unlocking the full potential of genomics techniques when applied to aquatic eDNA samples,” Jose Andrés said. “In the near future, I anticipate that this technique will allow us to study the status and health of elusive species. I believe this holds profound implications, particularly in marine environments.”
