News Release

MBL scientists to explore hidden realm of microbes, viruses beneath the ocean floor

Grant and Award Announcement

Marine Biological Laboratory

Axial Node of OOS

image: These are plans for the National Science Foundation’s cabled seafloor observatory at Axial Seamount (inset), west of the Oregon coast. view more 

Credit: University of Washington

WOODS HOLE, MASS.—The microbes and viruses shrouded in darkness below the ocean floor are bound to become much less mysterious, due to a bold research program led by MBL Bay Paul Center Scientist Julie Huber and her colleagues from several institutions. The program has received a $2.25 million award from the Gordon and Betty Moore Foundation.

"Microbial communities dominate nearly every corner of our oceans, yet they remain vastly under-sampled and our understanding of them is severely limited," Huber says. This is especially true for microbes that live below the earth's crust, in the subseafloor, one of largest marine realms but also the hardest to access and explore.

Over the next three years, Huber and her colleagues will undertake novel and at times risky experiments – some at the bottom of the ocean – to understand the microbes and viruses in the subseafloor rocks of Axial Seamount, a deep-sea volcano in the Pacific Ocean about 300 miles west of Oregon.

The scientists aim to "break open the black box of deep-sea microbiology, and take our understanding of subseafloor microbial processes and the carbon cycle to a new level."

Because Axial is a highly active volcano that spews hot fluid from its depths, millions of microbes that are normally buried are pushed up in the vent fluids, where scientists can capture them for study. In 2007, Huber and other MBL scientists discovered an amazing diversity of microbial life in the Axial vent fluids, which were analyzed at the MBL's Josephine Bay Paul Center.

And yet, they have just scratched the surface of understanding this dynamic ecosystem.

Very little is known about how viruses and microbes interact in the subseafloor, Huber says, which is one focus of their research. "Are the viruses infecting the microbes? Are they killing them? Are they transferring genes? We don't know. The field of environmental viral ecology has come a long way in the past decade, and we have a picture of how viruses work in the surface ocean. But there have been very few studies in the deep sea."

The scientists also seek a more detailed "portrait" of the microbial members of the subseafloor community. They want to know who the "producers" are in this unique food chain—the microbes that, like plants on land, can capture energy, synthesize their own food, and in turn serve as food for other organisms. (On land, the producers capture energy through photosynthesis; in the deep ocean, where there is no light, they rely on chemical energy.)

And finally, a major question is how subseafloor microbes alter the flow of carbon and nutrients in the deep ocean.

"The ocean is a huge sink of carbon, and we know very little about how carbon is moving in the deep ocean," Huber says. "We are interested in knowing how much carbon is being controlled by microbes in the deep sea; how much carbon is being fixed, and how much is coming out of the vent ecosystem." This could have important implications, as some nations are considering injecting carbon dioxide from fossil fuel use into the ocean floor, which at present would have completely unknown consequences.

One of the most exciting prospects is how Huber's team will sample and analyze the vent fluids. Typically, on research expeditions to deep-sea vents, the ship lowers a remotely operated vehicle (ROV) down to the vent, nearly a mile below the ocean surface. There, the ROV's robotic arm captures the hot fluid samples and brings them back to the ship for onshore analysis. For the first few years, Huber's team will follow this traditional method.

However, they also plan to develop novel protocols and instruments so they can drop down to Axial, take fluid samples, and carry out experiments on the seafloor.

"Normally, after we take a vent sample, it has to travel all the way back up through the water column to the ship, so it goes through a lot of pressure and temperature changes and there is a big time lag," Huber says. That leads to questions about how well the lab measurements reflect the "reality" in nature. "Here, the idea is to collect the samples on the sea floor, keep them at in situ pressure and temperature, run an experiment, and then stop the experiment on the seafloor. We can then analyze the results back in the lab." This will allow them to compare seafloor and lab experiments and see if they get the same result.

The project is taking place at an exciting time at Axial Seamount, which is one of the best-studied deep-sea volcanoes in the world. By 2013, Axial will be connected to land by live cable for power and communications, through the National Science Foundation's Ocean Observatories Initiative (OOI). The protocols that Huber and her team are developing for seafloor sampling and analysis could be integrated into the Axial Seamount node of the OOI.

Joining Huber, who is the lead scientist on the project, are principal investigators Joseph Vallino of the MBL's Ecosystems Center, who will develop an integrated ecosystem model of subseafloor viral and microbial communities; David A. Butterfield and Giora Proskurowski of University of Washington; James F. Holden of University of Massachusetts, Amherst; and Lisa Zeigler Allen of J. Craig Venter Institute.

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Background papers

Huber JA, et al. (2007) Microbial Population Structures in the Deep Marine Biosphere. Science 318: 97-100.

Chadwick WW,, Nooner SL, Butterfield DA, and Lilley, MD (2012) Seafloor deformation and forecasts of the April 2011 eruption at Axial Seamount. Nature Geoscience 5, 1-4.


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