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  • [♪ INTRO]

  • Imagine that you're a scientist trying to track a species that's notoriously hard to find.

  • Maybe you'll look for footprints, or droppings.

  • Perhaps you'll put out camera traps hoping to spot them as they move about.

  • Or you could just scoop up a bottle of stream water or a cup of dirt

  • and look for DNA fragments instead!

  • That's the amazing potential of environmental DNA, or eDNA

  • and scientists are already using it to study animals in all sorts of ways.

  • eDNA is DNA that can be extracted from an environmental substrate, like soil or water.

  • You see, all living things leave their DNA behind like a trail of breadcrumbs

  • thanks to biological castoffs like saliva, feces, urine, or skin cells.

  • And scientists can use this eDNA to essentially press rewind

  • and see what's passed through an area recently.

  • That's because species have unique genetic codes.

  • Even regions of DNA that look broadly similar between species

  • have unique differences that can be used to separate one from another.

  • So a researcher can collect a cup of soil or water and

  • sequence the DNA in it to see what species are around.

  • Often, this is done by looking for fragments of mitochondrial DNA.

  • And, as the name implies, that's the DNA found inside of mitochondria, the cell's energy factories.

  • Each cell can have dozens or even thousands of these mitochondria,

  • so there are generally more copies of mitochondrial DNA

  • than nuclear DNA per celland that makes these sequences easier

  • to find in environmental samples, especially ones where the DNA

  • may be degraded or dilute.

  • The tricky part is translating a presence/absence signal into a

  • reliable estimate of how many individuals of a species there are.

  • And scientists are still trying to figure that all out, as there are a lot of factors

  • that affect how much DNA is shed from an animal

  • and how long a given bit of DNA sticks around.

  • For example, DNA may decay faster in a hot environment than in a cold one,

  • or dilute and disperse more in streams and oceans than in soil.

  • But even with these challenges, eDNA is already helping scientists manage

  • and conserve species, because it can be used to monitor animals that are rare,

  • like to hide, or are otherwise hard to see.

  • Take the bluegill sunfish, for example.

  • Native to North America, this freshwater fish was introduced to Japan

  • in the 1960s and has now become one of their most notorious invasive species.

  • It eats basically anything it can, and has the potential to push species

  • towards extinction, so some areas are trying to get rid of them to help

  • conserve native freshwater ecosystems.

  • But in order to do that, scientists have to know where the bluegills are.

  • And if you've ever tried to spot a fish from shore before,

  • you know this can be difficult: what you see can be influenced by

  • the fish's size, behavior, and habitat.

  • So, in a 2013 study, a group of researchers tried using eDNA to find

  • bluegills in 70 ponds in Japan.

  • They collected water samples from each pond,

  • but also walked along the shore to see if they could spot the fish themselves.

  • They saw bluegills in 8 of the 70 ponds, and were able to successfully find

  • bluegill DNA in the matching water samples.

  • But they also found bluegill DNA in 11 additional ponds!

  • So eDNA gave them a more complete picture of the fish's distribution.

  • And sometimes, eDNA reveals animals that scientists aren't expecting to find.

  • For example, scientists in the Baltic Sea were testing an eDNA protocol

  • for detecting harbor porpoises in sea water when they found something surprising.

  • Their results showed DNA from a long-finned pilot whale.

  • These whales are rarely seen in the area, with only two unconfirmed sightings.

  • eDNA analysis in the ocean is a bit harder than in freshwater:

  • the larger body of water creates more opportunity for dilution and dispersal of DNA.

  • That means the authors couldn't rule out the possibility that the DNA

  • had drifted over a long distance or originated from a dead animal.

  • But, the results still suggest that eDNA can be used to detect

  • hard to observe animals in areas they rarely frequent.

  • And eDNA can also help spot animals in their native habitats

  • when they're just really hard to find.

  • In Virginia, wood turtles are declining in number because people are

  • destroying their habitat and poaching them to keep as pets.

  • They're considered both an endangered species and a management priority,

  • so scientists really want to know exactly where these turtles are.

  • Butthey're turtles.

  • Not only do they spend a lot of time underwater in muddy streams,

  • they also tend to look like rocks.

  • It can take years and lots of money to train people to spot them reliably.

  • So, a team of scientists decided to try eDNA as a potentially easier and cheaper solution.

  • They looked for turtles at 37 locations across Virginia by wading through streams

  • with nets and aquatic view scopescontraptions that look a bit like

  • an overturned bucket with a lens at the end which allowed them

  • to peek below the water's surface.

  • And at each site, they also carefully filtered water samples to collect eDNA.

  • They saw turtles at 17 of the sites, and found positive eDNA hits at 13 of those.

  • Those false negative resultswhere the eDNA did not correspond to visual sightings

  • revealed factors that impact successful eDNA monitoring,

  • like turtle density, days since last rainfall, and water temperature.

  • By understanding these, the team was able to optimize their protocol

  • to improve detection and sensitivity in future studies.

  • But despite these limitations, the group found eDNA at 3 sites

  • where turtles were not seen by the surveyors.

  • The researchers think those sites were likely places where they had

  • missed the turtles visually because there were so few of them around.

  • eDNA surveying also wound up being more cost efficient

  • than human surveys, so the team recommended it for monitoring

  • these threatened turtles in Virginia and beyond.

  • And these are just a few of the many ways eDNA is already

  • helping scientists track and find species.

  • It's also tracking invasive golden mussels, dangerous mosquito larvae,

  • and vulnerable manatee populations, for example.

  • A 2019 study even suggested eDNA could tell us how much coral there is on a reef.

  • And it isn't just for aquatic animals.

  • eDNA has also been used to look at things like earthworm communities

  • and adorable lemurs called aye-ayes.

  • And at least one project is trying to ID birds by sequencing eDNA pulled from the air.

  • There are some kinks to be worked out, but ultimately,

  • eDNA could completely change how we find and monitor all sorts of living things.

  • And with thousands of species on the brink of extinction,

  • the unique insights we're getting from eDNA may be more important than ever.

  • Thanks for watching this episode of SciShow, which is produced by Complexly.

  • If you liked learning about this neat way scientists study living things,

  • you might like another one of our channels: Nature League.

  • In every episode, host Brit Garner explores the diversity of life on Earth

  • and questions what we think we know about the natural world.

  • [♪ OUTRO]

[♪ INTRO]

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eDNA:科學家如何看到隱藏的動物 (eDNA: How Scientists See Hidden Animals)

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    林宜悉 發佈於 2021 年 01 月 14 日
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