New DNA Technology Identifies Multiple Fish Species Populating Local Areas
Credit: Kobe University
A Japanese research group has used a new technology that identifies multiple fish species populating local areas by analysing DNA samples from seawater, and proved that this method is accurate and more effective than visual observation. This research was carried out as part of the Japan Science and Technology Strategic Basic Research Programmes.
Until recently, marine surveys of fish species relied on diving or capturing methods that classified fish based on appearance. In addition to requiring a lot of manpower, these methods also depend upon specialist knowledge for fish classification. A new solution to the survey issue has recently drawn attention: environmental DNA metabarcoding, a method which can simultaneously detect multiple species.
This method identifies the fish species through collection and analysis of DNA released by fish in seawater (environmental DNA, or eDNA). Until now, researchers could only gain limited confirmation of the effectiveness of this method because it had only been proven in areas with limited numbers of fish species. In places such as the Japan coast, home to many different fish species, data collected using traditional methods is limited. As the results could not be compared with previous data, the effectiveness of eDNA metabarcoding remained unconfirmed.
This research group used eDNA metabarcoding in Maizuru bay, Kyoto prefecture. After just one day of field surveys applying this method, they were able to detect 128 species of fish from the seawater samples. Over 60% of the species observed during 140 visual surveys spanning 14 years were included in these 128 varieties. Excluding fish varieties who only migrated to Maizuru bay in certain years, this rose to nearly an 80% match. They also detected fish species that could not be confirmed by visual observation. Researchers believe that this method is the first time they have been able to detect certain varieties of fish larvae that are hard to identify through visual observation.
These findings show that even in areas with many different fish species, eDNA metabarcoding enables researchers to survey fish in multiple areas during a short time period. This method has potential applications for monitoring the invasion of foreign species across large areas, surveys of expanding fish distribution, and use in hard to access areas such as the deep sea, subterranean lakes, dangerous polluted waters, and protected areas where collecting specimens is prohibited. The findings were published on January 12 in Scientific Reports.
Yamamoto, S., Masuda, R., Sato, Y., Sado, T., Araki, H., Kondoh, M., Miya, M. (2017). Environmental DNA metabarcoding reveals local fish communities in a species-rich coastal sea. Scientific Reports, 7, 40368. doi:10.1038/srep40368
This article has been republished from materials provided byKobe University. Note: material may have been edited for length and content. For further information, please contact the cited source.
Salmonella Cases No Longer Declining in the EUNews
The declining trend of salmonellosis cases in the EU has levelled off according to the annual report on zoonotic diseases. Cases of Salmonella Enteritidis acquired in the EU have increased in humans by 3% since 2014 and in laying hens, the prevalence increased from 0.7% to 1.21% over the same period.
MRSA Beach RiskNews
Beach-goers know there is always some risk of disease, but a recent study shows they may not be aware of all the dangers the beach poses. A higher-than-expected prevalence of Staphylococcus aureus and methicillin-resistant Staphylococcus aureus (MRSA) were detected at beaches around Lake Erie.READ MORE
New Rapid Test for Valley Fever Should Help Reduce Diagnosis DelaysNews
November saw a spike if cases of Valley fever. Fortunately, the recent—and timely—approval of a new rapid assay test for Valley fever should reduce delays in diagnosing the respiratory fungal infections—a frequent problem in treating the disease, which is caused by spores endemic to soils in the U.S. Southwest.READ MORE