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WOODS HOLE, Mass. — Some of the ocean’s tiniest organisms get swept into underwater currents that act as a conduit, shuttling them from the sunny surface to darker depths, where they play an important role in carbon cycling and other ecosystem dynamics, according to new research.

Published this week in Proceedings of the National Academy of Sciences and based on fieldwork during three research cruises spanning 2017 to 2019, focuses on subtropical regions in the Mediterranean Sea. It uncovered how some microscopic single-celled organisms that are too light to sink beyond 100 meters or so — like phytoplankton and bacteria — end up going deeper into the ocean, where there's not enough sunlight for these photosynthetic organisms to live.

"It's often a one-way trip for these organisms, but by taking this trip, they play a critical role in connecting different parts of the ocean,” said first author Mara Freilich, who is now an assistant professor in Brown University’s Division of Applied Mathematics and Department of Earth, Environmental and Planetary Sciences.

Freilich conducted the research during her Ph.D. in the joint MIT-Woods Hole Oceanographic Institution (WHOI) doctoral program with Amala Mahadevan, senior scientist at WHOI, in a close collaboration with Alexandra Z. Worden, senior scientist at С����Ƶ, and her team.

The currents the team found are called intrusions. By sweeping up tiny organisms, they help change the types of food available in the deeper layers of the ocean while also transporting a significant amount of carbon from the water surface. This helps feed other organisms in the ocean’s food chain and increases the complexity of the ecosystem at deeper depths, influencing how life and chemistry work underwater.

“With the strong data from the Mediterranean establishing a process of three-dimensional conduits as a mechanism for bringing surface microbes to the dark ocean in warm waters, we have been able to see traces of similar export in open ocean regions, especially in the North Atlantic at the Bermuda Atlantic Time-series Study (BATS) site,” said Worden.

Altogether, the study challenges conventional understanding of how carbon, which is turned into organic matter by photosynthesis in the sunlit layer of the ocean, gets transported to depth.

“The majority of photosynthesis — by which light is converted into organic carbon, a food source for living organisms — happens in the upper 50 meters of the ocean,” Freilich said. “So the question has always been: How does the carbon that gets fixed through photosynthesis get into the deep ocean? The sinking of carbon-rich particles has always been thought to be the only answer to this question. But what we found is that tiny, single-celled organisms get caught in the oceanic flow to form intrusions... This mechanism has been unaccounted in previous estimates of carbon transport.”

The researchers found the intrusions occur year-round and originate in areas rich with biomass, including where the plant-like organisms (algae) are at their highest concentrations. Previously, ocean currents were only thought to carry carbon to depth seasonally. The researchers suggest these intrusions are widespread in the world’s subtropical oceans. They provide conduits for the continual transport of carbon and oxygen from the sunlit ocean to depth.

“We observed microbial communities that looked just like surface microbial communities down to 200 meters,” Freilich said. “In other regions, we think this could be a lot deeper. To our surprise, we found that the majority of microbes in the intrusions were bacteria that feed on carbon fixed by the photosynthesizing cells. This showed that the bulk of the biomass transported from the sunlit layers comprised of non-photosynthetic microbes.”

As a collaboration between the U.S., Spain and Italy, the scientists went on three expeditions during which they used special tools to measure properties like water temperature, salinity and fluorescence properties at different depths. Genetic diversity analyses alongside advanced methods for enumerating and distinguishing microbial populations were then performed and revealed differences between intrusion samples and background waters. Seeing that the microbial communities in the deeper intrusion samples resembled surface microbial communities showed that they were being transported to depth, and transported fast enough that these surface communities were still largely intact, not degraded. The researchers also used computer models to simulate ocean currents to reveal how the communities of tiny algae and bacteria were moved in the water.

Along with underscoring the ecological importance of intrusions in shaping oceanic biodiversity, the study also touches on how intrusions could be affected by climate change. It is thought that as the Earth's oceans get warmer, the proportion of carbon in tiny cells would increase and the transport in intrusions may not be as affected as other mechanisms that carry carbon to depth. Intrusions change our understanding of how carbon moves around in the ocean and could help regulate carbon storage and microbial dynamics in the deep ocean.

“There's so much more to explore now that we've found this,” Freilich said. “What's next is taking what we've learned here and determining if we can use this to predict how changes in the microbial community composition would affect the transport of carbon and the global carbon cycle in a changing climate.”