A world in a bottle of water

Modern gene-sequencing technologies have advanced so much that the analysis of such environmental DNA, or eDNA, from small samples of water or soil could revolutionize the way scientists understand ecology and conservation in ecosystems all over the world. “It’s really remarkable that in the twenty-first century we’re still not able to say exactly what lives in the ocean,” says Barbara Block, a marine scientist at Stanford who has been monitoring fish in the Pacific and Atlantic for decades. But today, just a liter of ocean water, housing millions of genetic sequences, can tell many tales about the ecological history of a place.

As ocean acidification and climate change become the new reality, scientists wonder what will happen to the distribution and well-being of plants and animals. “Monitoring communities and ecosystems is going to be much easier done by DNA methods,” says Elizabeth Andruszkiewicz Allan, an environmental engineer at Woods Hole Oceanographic Institution in Massachusetts who analyzed Stark’s samples while at Stanford. “You take one water sample and look for everything from microbes to whales.”

Just as we constantly shed DNA-containing dead cells, creatures in the oceans — from bacteria up to hulking blue whales — leave invisible environmental signs of their presence. Today’s sequencing tools are so powerful that researchers can now detect these minute traces of DNA spread out in the environment and, with refined computational methods, figure out what creatures they came from.

Finding the obvious and the elusive

To use eDNA to track species, scientists first multiply, then read, the segments found in a sample. Then they match them to known DNA sequences from species of interest.

In a study in 2012, for example, Philip Francis Thomsen, then at the Natural History Museum of Denmark and now at the University of Aarhus, and his colleagues collected seawater from sites around the Baltic Sea. They detected eDNA from harbor porpoises and long-finned pilot whales, the latter a species rarely seen in the Baltic — showing that the technology had the potential to “find” elusive species. 

And last year, researchers in Alaska tracked the abundance of spawning salmon in a small stream by analyzing salmon DNA in the water, finding that it’s possible to use eDNA to estimate the abundance of a single species at a specific place even in flowing waters.

Sometimes, scientists use a version of the technique known as metabarcoding to assess DNA from whole groups of organisms, providing a broader snapshot of the biodiversity in a spot in the ocean. This has three key advantages compared to traditional ways of surveying biodiversity: It’s highly sensitive, it’s cheaper, and it’s noninvasive.

“So often, you have to kill whatever you’re interested in to collect it,” says Starks, who uses eDNA sequencing at her job at the consulting company Cramer Fish Sciences. “It’s nice to be able to not have to do that.”

Diving in

Use of eDNA analysis in the ocean got its start in the late 1980s, when scientists began looking at DNA in microbial blooms. Now scientists all over the world are studying all kinds of creatures and ecosystems to learn about the complexities of marine communities.Thomsen, for instance, has used eDNA to study whale sharks in the Arabian Gulf and fish ecology deep off the coast of Greenland. Scientists in Southern California have detected white sharks with eDNA. Researchers in Alaska have studied the harbor porpoise, elusive in those waters. Australian scientists recently were able to detect signals from all of life’s major groups in that nation’s Coral Bay using eDNA methodology.

“I think it will have a big impact on our understanding of not only the dynamics of communities, but also the presence and absence of species,” says Melania Cristescu, an ecological genomicist at McGill University in Canada, whose work focuses on eDNA in freshwater environments. “That is what excites me.”

Thanks to the advance of genetic sequencing technologies, environmental DNA research, particularly in the ocean, has boomed in the last decades. Shown are scientific publications studying or referencing environmental DNA, per a major publisher’s database. 

 Researchers in Monterey Bay started studying the eDNA of the animals that live in the area six years back, when Ryan Kelly, then a researcher at Stanford’s Center for Ocean Solutions, set out to compare eDNA sampling to traditional biodiversity surveys. Kelly wondered whether analyzing eDNA would be an accurate as well as a faster and easier method than having divers physically count animals underwater.He knew that DNA degrades fast in the ocean, so he first wanted to test just how reliable and sensitive eDNA technology could be. To that end, he started his work in a controlled setting at the Monterey Bay Aquarium, where the 4.5-million-liter Open Sea Tank hosts 12 species of animals, including Pacific sardines, mackerel and sea turtles.“Here we have a known community — we can see the fish in the tank,” Kelly remembers thinking. “If we take a liter of water out of this, can we see the genetics of the DNA of the fish that are in there?”His team collected water samples from the tank and tested the eDNA. Not only did the team detect the eDNA of most of the bony fish groups resident in the tank, but the method also pinpointed the DNA from the food species fed to those animals.

Beyond what divers can see

Kelly next wanted to look at eDNA in the ocean. He worried that eDNA in seawater could be carried long distances by currents and that samples might therefore not represent the actual biodiversity of a site. So in 2013, he and his team put this concern to the test in the well-studied waters off Pacific Grove, a city northwest of Monterey. Alongside the eDNA work, divers also recorded the vertebrate species they saw at the sample sites, including rockfish, wrasses, surfperch and seals.The divers spotted 12 types of fishes and marine mammals; the eDNA technique detected 11 of these. But the genetic analysis also revealed 18 additional fishes, mammals and birds that the visual surveys missed even though the animals are known to live there. Kelly’s team also found that eDNA analysis could distinguish between habitats as close as 60 meters apart. Following this work, marine biologist Collin Closek, also at the Center for Ocean Solutions, similarly found that eDNA from untested Monterey Bay water samples matched visual observations of anchovies and humpback whales recorded at the same time. 

A harbor porpoise (Phocoena phocoena) photographed in the Bay of Fundy, Canada, in September 2012. Harbor porpoises can be hard to track, so researchers use eDNA to study their population and genetics.