Courtesy Jayne Rattray
July 26, 2019
Scientists shed light on microbial life in Earth鈥檚 deep, dark places
We know more about the surface of the moon than we do about the microbial ecology of Earth鈥檚 deep subsurface, some scientists say. Now, a team of international scientists led by 六九色堂 microbiologists has shed more light on our planet鈥檚 deep, dark places.
In a study supported by collaboration between two research groups in the聽鈥檚听, the team has furthered understanding of how microbes live in deep-sea sediments by 鈥榚ating鈥 hydrocarbons naturally seeping from petroleum reservoirs beneath the seabed.
- Photo above: The study has real-world implications for the oil and gas industry, which analyzes petroleum seeps in exploring for deep-sea oil reservoirs. Also, these kinds of microbes could help naturally biodegrade a spill from a deep-water offshore oil well blowout.聽Photo courtesy Jayne Rattray
Their study combined cutting-edge biological tools 鈥 metagenomics and metabolomics 鈥 to characterize the poorly understood deep-sea bacteria and archaea (structurally similar to bacteria, but with a distinct evolutionary history) that biologists aren鈥檛 yet able to grow and study in the laboratory.
鈥淲e combined these tools in a very challenging environment,鈥 says Dr. Casey Hubert, PhD, associate professor in biological sciences, and Campus Alberta Innovates Program (CAIP) chair, who leads the聽Geomicrobiology Research Group. 鈥淚t enables us to better understand, in a comprehensive way, deep-sea petroleum systems and petroleum-associated micro-organisms that are difficult to get to and hard to sample.鈥
The study has real-world implications for the oil and gas industry, which analyzes petroleum seeps in exploring for deep-sea oil reservoirs. Also, these kinds of microbes could help naturally biodegrade a spill from a deep-water offshore oil well blowout.
The team鈥檚 multidisciplinary聽, 鈥淢etabolic Potential of Uncultured Bacteria and Archaea Associated with Petroleum Seepage in Deep-Sea Sediments,鈥 was recently published in the journal Nature Communications.
Collaboration key to getting a better picture
Using a larger tool box was made possible through a collaboration between the Geomicrobiology Group and the research group led by Dr. Ian Lewis, PhD, assistant professor in biological sciences and Alberta Innovates Translational Health chair.
The work was led by Dr. Xiyang Dong, PhD, a postdoctoral researcher working with Hubert, and Dr. Jayne Rattray, PhD, a research associate in the group, who collaborates with Lewis鈥檚 group on different geomicrobiology projects.聽
鈥淭hey looked for ways to make the research stronger, to produce a more comprehensive picture of microbes metabolizing deep-sea hydrocarbons,鈥 Hubert says.
The research team analyzed microbes in sediment cores obtained from the seabed three kilometres deep at three sites in the Gulf of Mexico. The cores were donated by study collaborator TDI Brooks, a Texas-based company that performs sediment hydrocarbon analysis for the petroleum industry. Other academic collaborators are based in Australia, Japan and the U.K.
The team used metagenomics techniques to extract and sequence the DNA in samples from the microbial communities. By sequencing a massive 55.5 billion bases of community DNA at the聽聽in the聽, the researchers recovered 82 draft genomes (genetic blueprints) affiliated with 21 different groups of bacteria and archaea. Dr. Marc Strous, PhD, a global pioneer in metagenomics聽research, professor in the聽, and CAIP chair and leader of the Energy Bioengineering Group, provided advice on this part of the study.
The team then used the Lewis lab鈥檚 metabolomics techniques to look for the literal tracks of each microbe鈥檚 metabolism to highlight the genes involved. These tracks are called 鈥渕etabolites,鈥 chemical byproducts of the microbes consuming hydrocarbons as their source of carbon and energy.
鈥淲hile genomic information can provide us the blueprint for microbial functional potentials, they cannot tell us what they are really doing in deep-sea sediments. Thanks to the Lewis lab, we could address this question at least partially using metabolomics as a perfect tool for in-situ evidence,鈥 says study lead author Xiyang, now an associate professor at the School of Marine Sciences at Sun Yat-Sen University in Guangzhou, China.
鈥淢etabolomics is a powerful tool for unravelling the complex interactions and understanding the role each organism plays in its environment,鈥 Lewis says.
Valuable resource聽for future research
聽Along with the biological tools, the researchers also employed sediment geochemistry and thermodynamic modelling to predict metabolic capabilities and microbial interactions in deep-sea sediments with petroleum seeps. 鈥淲e鈥檝e characterized this environment to a much greater degree than had been done in the past using single-gene studies,鈥 Hubert says.
鈥淭his piece of work is going to be a valuable resource for other experimentalists studying microbial metabolic processes in deep-water sediments,鈥 noted an expert peer reviewer of the team鈥檚 study for Nature Communications, which makes peer reviews public.
There are thousands of deep-water natural petroleum seeps in the Gulf of Mexico alone, and many more around the world. Hubert鈥檚 research group also studies hydrocarbon seeps in Canadian waters, mainly off Nova Scotia.
Working together, hydrocarbons-degrading bacteria and archaea in the deep seabed act as natural biofilter preventing hydrocarbons from migrating higher up, into the water column, Hubert says.
鈥淥ur findings on these 鈥榖ugs鈥 may be useful to understand their roles in global environmental issues such as climate change and oil pollution,鈥 Xiyang notes.
Funding for the study was provided by Genome Canada and the Canada Foundation for Innovation. The research chairs held by Hubert and Lewis are funded by the Government of Alberta.