Tag Archives: Deepsea

Videos: Deepsea Research Technology

LBL Beacon Recovery Release

Middle School Student Anja Diercks learns about acoustic release operation to recover a Long Base Line (LBL) acoustic beacon after a successful AUV dive. These LBL beacons are necessary in aiding the Inertial Navigation System of the AUV while on survey on the ocean floor, sometimes at depths of 1600 m or more.

LBL Beacon Recovery

Middle School Student Anja Diercks helps recover the acoustic LBL (Long Base Line) beacon she had released from the ocean floor using an acoustic telemetry system minutes before. The Gulf of Mexico had a surprise for her too.

Fiberoptic Multicorer

Watch this successful collection of deep sea sediment cores during 7+ foot waves on a recent research cruise in the Gulf of Mexico. The Science team from National Institute for Undersea Science and Technology and Mississippi Mineral Resources Institute deployed a deep sea multicoring device in 1200 meters of water depth, attached to a fiberoptic winch cable. On the coring rig, they mounted several cameras and light sources. This spectacular mission was accomplished aboard the RV Pelican, during a recent research conducted for ECOGIG.

Credits: Diercks, A.; National Institute for Undersea Science and Technology (NIUST), Mississippi Mineral Resources Institute (MMRI) Ecosystem Impacts of Oil & Gas Inputs to the Gulf (ECOGIG) and Gulf of Mexico Research Institute (GOMRI).

Fact Sheets: Deep-C Science and Outreach Fact Sheets

The Deep Sea to Coast Connectivity in the Eastern Gulf of Mexico (Deep-C) Consortium released a series of publicly available and easy-to-read fact sheets detailing their scientific research and outreach initiatives:

Science: Deepwater Corals

What are corals? Where and how do they live? What are the threats to Gulf corals? Click here to download.

Science: The SailBuoy Project

Experimenting with a new marine device used for scientific observations in the Gulf of Mexico. Click here to download.

Science: Deepwater Sharks

Information about the bluntnose sixgill shark, one of the most common species in the Gulf. Click here to download.

Science: Tiny Drifters – Plankton

What are plankton? Why are plankton important? How did the oil spill affect Gulf plankton? Click here to download.

Science: Oil-Eating Plankton

Naturally occurring microbes in the ocean feed on the hydrocarbons in oil. Click here to download.

Science: Oil Fingerprinting & Degradation

What is oil? How does oil “weathering” occur? And what can oil samples tell us? Click here to download.

Outreach: Gulf Oil Observers

Deep-C’s citizen scientist initiative connecting high school students to ongoing oil spill research. Click here to download.

Outreach: Scientists in the Schools

Interactive visits to middle school classrooms by Deep-C scientists and educators. Click here to download.

Outreach: 2015 Annual ROV Training & Competition

Students from middle and high schools vying for ROV (Remotely Operated Vehicle) domination. Click here to download.

Videos: Gary Finch Highlights ECOGIG Research

Gary Finch Outdoors produced a series of videos highlighting various aspects of the Ecosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG) program, its science, and the important partnerships necessary to make ECOGIG successful. Many of these videos were used by local PBS affiliates in Gulf coast states and were available through the ECOGIG website and YouTube. All videos listed below were developed and produced by Finch Productions, LLC.

What Does ECOGIG Do? (PBS Part 1) (2:20)

Scientists aboard the research vessels R/V Endeavor and E/V Nautilus briefly describe the nature of ECOGIG research.

Collaboration Between Nautilus and Endeavor Tour (PBS Part 2) (2:06)

ECOGIG scientists discuss the research they are conducting on a recent cruise aboard the R/V Nautilus and E/V Endeavor.

ECOGIG R/V Atlantis/ALVIN Cruise: March 30-April 23, 2014 (2:00)

Researchers describe the crucial importance of ALVIN dives in assessing the ecosystem impacts of the Deepwater Horizon explosion.

Deep Sea Life: Corals, Fish, and Invertebrates (4:30)

Dr. Chuck Fisher describes his research examining the fascinating and long-lived deep sea corals impacted by effects of the Deepwater Horizon explosion.

The Eagle Ray Autonomous Underwater Vehicle (AUV) News Piece (5:12)

ECOGIG scientists use the Eagle Ray AUV (autonomous underwater vehicle) to map the seafloor and get visuals so they can better target their sample collecting for study. The National Institute for Undersea Science and Technology (NIUST) provides the submersible.

(Full Length)

(Shortened News Piece)

Food Webs in the Gulf of Mexico (4:30)

ECOGIG scientists Jeff Chanton and Ian MacDonald, both of Florida State University, explain their complementary work exploring the possibility that hydrocarbons from oil have moved into the Gulf food web. Chanton, a chemical oceanographer, tells of a small but statistically significant rise in fossil carbon, a petrochemical byproduct of oil, showing up in marine organisms sampled from Louisiana to Florida. In addition to the hypothesis that Deepwater Horizon oil might be the culprit, biological oceanographer MacDonald discusses other factors that could also be at play, including coastal marsh erosion, natural oil seeps, and chronic oil industry pollution. This is a Finch Productions, LLC video. For more information, visit ECOGIG.ORG. https://ecogig.org/

Landers Technology Development (4:30)

Most of the area around the Deepwater Horizon spill ranges from 900 – 2000 meters below the surface of the Gulf of Mexico. ECOGIG scientists Dr. Chris Martens and Dr. Geoff Wheat talk about Landers, a new technology developed at the University of Mississippi that allows scientists to study the ocean floor at great depths. Landers are platforms custom-equipped with research instruments that can be dropped to the exact site scientists want to study and left for weeks, months, or even years to collect ongoing data.

Marine Snow (4:30)

Dr. Uta Passow describes research she and her colleagues Dr. Arne Dierks and Dr. Vernon Asper conduct on Marine Snow in the Gulf of Mexico. Oil released in 2010 from the Deepwater Horizon explosion floated upwards. Some of this oil then sank towards the seafloor as part of marine snow. When marine snow sinks, it transports microscopic algae and other particles from the sunlit surface ocean to the dark deep ocean, where animals rely on marine snow for food.

Natural Seeps – Geology of the Gulf (4:30)

ECOGIG Scientists Dr. Joe Montoya, Dr. Andreas Teske, Dr. Samantha Joye, and Dr. Ian McDonald describe their collaborative research approach while preparing for the Spring 2014 cruise aboard the R/V Atlantis with research sub ALVIN. Long-term sampling and monitoring of natural oil seeps in the Gulf of Mexico, a global hot spot for these seeps, is crucial for understanding the impacts of oil and gas from explosions like Deepwater Horizon.

Remote Sensing & Modeling (4:30)

ECOGIG scientists Dr. Ian MacDonald and Dr. Ajit Subramaniam describe their work monitoring the health of the Gulf of Mexico via remote sensing. Using images from satellites and small aircraft flown by volunteers, MacDonald looks for signs of surface oil, which could be the result of a natural seep, anthropogenic seeps (chronic oil leaks from ongoing drilling operations), or a larger spill like Deepwater Horizon. Subramaniam uses the changes in light in these images to help him understand what is happening below the sea surface, with particular focus on the health of phytoplankton populations that make up the base of the marine food web. This is a Finch Productions, LLC video with additional footage provided by Wings of Care, a nonprofit that assists with volunteer filming operations.

ROVs in STEM Education News Piece (4:30)

ECOGIG’s Dr. Chuck Fisher describes the use of ROVs in researching deep -sea corals in the Gulf of Mexico, and Ocean Exploration Trust’s Dr. Bob Ballard explains the powerful impacts of ROVs in STEM education, as shown during a recent visit onboard the EV Nautilus by members of the Girls and Boys Club of the Gulf region.

(Full Length)

(Shortened News Piece)

Lesson Plan (Grades 6-8): Deep-Sea Science Middle School Teaching Modules

The Ecosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG) consortium worked with the Georgia Institute of Technology Center for Education Integrating Science, Mathematics, and Computing (CEISMC) to develop and test three middle school teaching modules.

The modules developed are:
– (7th Grade) Life Science – Data Visualization: “Under the Sea” Deep Sea Ecosystems Challenge
– (7th Grade) Life Science – Experimental Design: “Oil Spill Drill” Oil Spill Challenge
– (8th Grade) Physical Science – Experimental Design: “Ocean Blizzard” Marine Snow Challenge

The modules are available upon request from the CEISMC website: https://ampitup.gatech.edu/curricula/ms/science.

Lesson Plan (6-12): The BP Oil Spill and Its Aftermath – Exploring Through Art

“The BP Oil Spill and Its Aftermath – Exploring Through Art” is a middle and high school level lesson plan that utilizes art to explore oil spill science. During the lesson, students will engage in discussions about the Deepwater Horizon oil spill, reflect on and create art related to the spill, and explore ongoing research into the spill’s effect.

The lesson plan was developed by Florida science teacher Alisha Stahl based on her experiences with the DEEPEND Teacher-At-Sea program. The program invites teachers who have completed the consortium’s Gulf of Mexico Exploration Teacher Workshop to join scientists aboard a several-day research cruise. Teachers recorded their at-sea experiences on the DEEPEND Blog and created curricula based on the onboard activities to share with the DEEPEND Education community.

A free downloadable version of the “BP Oil Spill and Its Aftermath – Exploring Through Art” lesson plan can be found HERE. The PowerPoint mentioned in Part 2 of the lesson can be found HERE.

Classroom Activity: Deep-Sea Creatures Coloring Sheets

Six coloring sheets depict some of the diverse sea creatures that researchers encountered during research cruises.

These coloring sheets were developed in partnership with Whale Times, Inc. for a series of summer camps based on Deep-Pelagic Nekton Dynamics (DEEPEND) consortium research called Creep into the DEEPEND.

See below for free, printable PDFs!

Anglerfish Coloring Sheet

Benthic Octopus Coloring Sheet

Deep Red Medusa Coloring Sheet

Deep-Sea Squid Coloring Sheet

Glass Squid Coloring Sheet

Siphonophore Coloring Sheet

Videos: Squirt the Squid Teaches Kids about Deep-Sea Creatures

There are hundreds of deep-pelagic fish species in the Gulf of Mexico, and we are continuously learning about their diversity and behaviors. These short videos, hosted by kid’s science mascot Squirt the Squid, feature research into the diverse and fascinating deep-sea creatures inhabiting the Gulf of Mexico.

Video 1: Cephalopods

Join Squirt as he discusses different cephalopod species in the Gulf of Mexico.

Video 2: Counter-Illumination

Squirt teaches kids about counter-illumination, a natural camouflage strategy in which marine animals produce light that matches the brightness and wavelength of their surroundings, helping them to avoid predators.

Video 3: Dragonfish

Squirt teaches kids about dragonfish, a type of small bioluminescent deep-sea predator that lives in the Gulf of Mexico.

ECOGIG Research Informs Development of Ocean-Based Video Game: Beyond Blue

6743 — A screenshot of a scene in the Beyond Blue video game. Provided by E-Line Media

There is now a novel way to reach audiences and help spark their interest in ocean science that involves the very popular world of video gaming. Launched by E-Line Media in conjunction with the BBC and researchers involved with their Blue Planet II series, the single-player narrative adventure Beyond Blue takes players deep into our ocean’s mysterious and fascinating world.

Beyond Blue video game players join a research team that uses groundbreaking technologies to see, hear, and interact with the ocean through the eyes of Mirai, a deep-sea explorer and scientist who dives deep to learn more about the vibrant and otherworldly underwater environments. Samantha Joye, Regents Professor at the University of Georgia and Director of the ECOGIG consortium, served as a consultant during the development of this new gaming experience that explores the deep ocean.

“Beyond Blue is more than a video game,” explained Joye, “It’s an immersive tour through a fascinating and magical world that will leave you wanting to know more — and to do more. The game will motivate all players to learn more about the ocean and for some, playing will inspire engagement in ocean advocacy. Surely some players will be motivated to pursue a career in ocean science.”

How popular are video games? More than 75% of Americans have a gamer in their household and 70% of American families have a child who plays video games, according to a 2019 report released by the Entertainment Software Association.

E-Line Media, who also published the game Never Alone (Kisima Ingitchuna) that introduces players to little-known tales of native Alaskan culture, wants people to start thinking about the world beyond what they see. The company partnered with BBC Studios (developers of the acclaimed Blue Planet II), OceanX Media (world-class game makers), and some of science’s leading ocean experts to craft an experience through Beyond Blue that reflects the wonder and mystery of the deep ocean.

Beyond Blue features

Exploration and adventure within an untouched world;
A captivating and entertaining soundtrack featuring an original score and music from Miles Davis, The Flaming Lips, The Edisons, and more; and
Sixteen unique mini-documentaries called Ocean Insights that feature original footage and interviews with science’s leading ocean experts.

“Working with the E-Line team to ideate gaming scenarios and imagine futuristic ocean science technologies was an incredible and rewarding experience,” Joye said. “And this is only the beginning – Mirai and her team have a lot more exploring to do!”

View this trailer of the Beyond Blue video game:

Listen as scientists Samantha Joye, David Gruber, and Sylvia Earle talk about their participation as consultants during the Beyond Blue development and their fascination with the ocean at https://www.youtube.com/watch?v=GupPSblAxzo&feature=youtu.be

Get to know Mirai and the woman behind her character at https://www.youtube.com/watch?v=LV_0to-ww6g&feature=youtu.be

The Beyond Blue video game uses several platforms (PC, Xbox One, PS4, and Apple Arcade) and is available for purchase ($19.99 USD) at https://beyondbluegame.com/.

The ECOGIG team has also helped produced a 4-part animated series on ocean science The Adventures of Zack and Molly.

By Nilde Maggie Dannreuther. Contact maggied@ngi.msstate.edu with questions or comments.

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This research was made possible in part by a grant from the Gulf of Mexico Research Initiative (GoMRI) to the Ecosystem Impacts of Oil and Gas Inputs to the Gulf-2 (ECOGIG-2).

The Gulf of Mexico Research Initiative (GoMRI) is a 10-year independent research program established to study the effect, and the potential associated impact, of hydrocarbon releases on the environment and public health, as well as to develop improved spill mitigation, oil detection, characterization and remediation technologies. An independent and academic 20-member Research Board makes the funding and research direction decisions to ensure the intellectual quality, effectiveness and academic independence of the GoMRI research. All research data, findings and publications will be made publicly available. The program was established through a $500 million financial commitment from BP. For more information, visit http://gulfresearchinitiative.org/.

© Copyright 2010-2020 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Videos: E/V Nautilus Clips

These videos were developed to demonstrate research aboard the E/V Nautilus.

ECOGIG in 60 Seconds

Dr. Katy Croff Bell, Chief Scientist of the EV Nautilus crew, explains the mission of ECOGIG.

Imaging Deep-Water Corals (Nautilus Live)

As part of the ECOGIG project, the E/V Nautilus made its way to the site of the 2010 BP Deepwater Horizon oil spill to image affected corals. Using the ROV Hercules’ BEAST CAM, the scientists are able to capture extremely high resolution pictures. These pictures will be used to show change over time and growth rate.

ECOGIG and EV Nautilus Inspire Kids with ROVs

“It was really cool, because I want to be marine biologist when I grow older. So being able to see this and experience the boat and the submarines and how to work them and stuff like that, it was eye awakening. I really want to do this now.” As the Nautilus prepared to launch for a corals research cruise, led by Dr. Chuck Fisher, nearly 200-members of the Boys and Girls Clubs walked on deck to see how the remotely operated vehicles are used for deep sea research. They also built and tested their own miniature ROVs.

Grad Student Schwaab Investigates How Tuna and Billfish Respond to Oil

6710a — Madison Schwaab, a University of South Florida master’s student, stands in front of the gas chromatography-tandem mass spectrometer holding an almaco jack liver extract. (Provided by Madison Schwaab)

Marine ecosystems provide many valuable resources for humans, including seafood and petroleum. Conservation policies that protect marine ecosystems, especially pollution and petroleum-related policies, depend on accurate scientific data about the ways different marine species experience pollution. Madison Schwaab quantifies levels of toxic oil compounds in the bile and tissues (liver, muscle, and gonad) of fifteen pelagic Gulf of Mexico fish species to better understand how oil affects them compared to other species.

Madison is a master’s student with the University of South Florida’s College of Marine Science and a GoMRI Scholar with the Center for the Integrated Modeling and Analysis of Gulf Ecosystems III (C-IMAGE III).

Her Path

Madison spent her childhood catching fish and blue crabs with her father on Chesapeake Bay, where she witnessed firsthand how human activities can negatively affect rivers, bays, and oceans. These experiences piqued her curiosity about quantifying those impacts. As a Temple University undergraduate student, she worked in Dr. Erik Cordes’ deep-sea ecology lab investigating how ocean acidification impacts cold-water coral physiology. She also worked at the Smithsonian Environmental Research Center studying the behavioral avoidance of inland silversides in hypoxic and acidified environments. These research experiences showed her how changing conditions can negatively affect marine and estuarine animals.

6710b — University of South Florida master’s student Madison Schwaab holds a yellowfin tuna caught for subsampling and subsequent contaminant analysis. (Provided by Madison Schwaab)

Madison wanted to conduct anthropogenic-related research and started researching graduate programs in Texas and Florida, where she knew there was ongoing oil spill research. The oil spill research conducted in Dr. Steve Murawski’s Population and Marine Ecosystem Dynamics Lab at the University of South Florida intrigued her, and she reached out to him before applying for a graduate research position there. He invited her to visit during a recruitment weekend, and she immediately clicked with the lab and the university. She joined the group as a master’s student conducting GoMRI-funded research quantifying petrogenic and pyrogenic contaminant concentrations in pelagic fish.

Her Work

Madison sampled fifteen pelagic tuna and billfish species collected as by-catch during benthic research cruises (2011 – 2017) and main catch during a pelagic cruise (2018). Because the collection includes different time points and regions, she compared differences in polycyclic aromatic hydrocarbon (PAH) concentrations between these pelagic species and across different regional, spatial, and temporal scenarios. She also used data compiled by her fellow C-IMAGE researchers to compare PAH concentrations in the pelagic species with species living in other ocean habitats.

6710c — (L-R) C-IMAGE Assistant Director Sherryl Gilbert, master’s student Brigid Carr, Ph.D. student Susan Snyder, Principal Investigator Dr. Steve Murawski, researcher Dr. Erin Pulster, and master’s student Madison Schwaab attend the opening of the University of South Florida’s Marine Environmental Chemistry Laboratory in November 2018. (Photo credit: Sean Beckwith)

Madison analyzed fish bile using high-performance liquid chromatography (HPLC) to semi-quantitatively measure PAH equivalent concentrations (parent compounds plus metabolites) of naphthalene, phenanthrene, and benzo[a]pyrene, which indicates short-term (hours to days) PAH exposure. She also prepared liver, muscle, and gonad tissue samples using the Quick, Easy, Cheap, Effective, Rugged, and Safe (QuEChERS) extraction process and applies gas chromatography-tandem mass spectrometry (GC-MS-MS) to assess concentrations of nineteen PAHs (including 16 considered priority pollutants by the EPA) and their alkylated homologues in fish tissue, which indicates long-term (months) PAH exposure.

Only eight of the fifteen pelagic fish examined yielded enough usable data to draw conclusions. Although Madison is still interpreting her data, her early results suggest that there are higher PAH equivalent concentrations in yellowfin tuna bile than the other seven fish species. These levels were similar to concentrations observed in the benthic golden tilefish, which are considered the highest known PAH equivalent concentrations in the Gulf of Mexico. These preliminary findings represent one of the first indications that pelagic fish species can be significantly affected by PAHs deposited into the Gulf of Mexico.

“Finding similar PAH equivalent concentrations in yellowfin tuna and the golden tilefish was unexpected, because the golden tilefish is a burrowing fish and is strongly linked to sediments, where about 21% of Deepwater Horizon hydrocarbons likely settled,” she explained. “Finding significant short-term PAH concentrations in yellowfin tuna several years later suggests that they are possibly being impacted by contamination sources other than Deepwater Horizon, such as the Mississippi River and the on-going natural oil seeps or small oil spills that frequently occur in the Gulf.”

Her Learning

Madison’s GoMRI work was her first experience conducting toxicology research. Her lab mates, especially Dr. Erin Pulster, taught her a great deal about common toxicological methods and operation of analytical instruments. While her lab work focused on the finer details, she experienced the larger implications of her research through field work. “Catching target pelagic species for our oil spill research just meters away from oil rigs highlighted the connection between my research and the bigger picture,” she said. Attending the annual Gulf of Mexico Oil Spill and Ecosystem Science conference helped her learn from oil spill researchers in other fields and further connect her own findings to the entire ecosystem. “Being part of GoMRI allowed me to gain a holistic perspective on Deepwater Horizon’s short- and long-term impacts on Gulf ecosystems and surrounding communities.”

Madison has an increased appreciation for transferable scientific skills, such as statistics and programming, and for opportunities that improve scientific writing and communication. She hopes to find a career where she can use her background and experiences to synthesize scientific findings and inform practices and policies that protect vulnerable ecosystems from pollution and oil contamination.

Praise for Madison

Dr. Murawski explained that Madison’s Deepwater Horizon research has equipped her with broadened skills sets for investigating key contemporary threats to marine ecosystems, especially related to chemical pollution resulting from acute oil spills. “Her work on pollution levels in large pelagic fishes of the Gulf has opened up new venues of research and provided important new insights into how the Gulf of Mexico functions,” he said. “She has a bright future in marine science and policy, wherever her career takes her.”

The GoMRI community embraces bright and dedicated students like Madison Schwaab and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the C-IMAGE website to learn more about their work.

By Stephanie Ellis and Nilde Maggie Dannreuther. Contact sellis@ngi.msstate.edu for questions or comments.

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Grad Student Bickham Helps Capture A Clearer Picture of How Corals Respond to Oil

6696a — Nova Southeastern University master’s student Dawn Bickham assists with the shipment of coral colonies to the Florida Coral Disease Rescue Project. (Provided by Abigail Renegar)

Coral reefs provide food, shelter, and habitat to thousands of organisms living in the Gulf of Mexico. However, their vulnerability to physical and toxicological damage increases corals’ risk during environmental disturbances, particularly in shallow water where dangers from coastline proximity include wastewater pollution, moving sediment, salinity and nutrient changes, scavengers, and boating and fishing activities.

Much research after Deepwater Horizon focused primarily on community-level impacts to corals in areas affected by the oil spill. A Florida-based science team is looking at individual effects at the coral tissue level and is seeking to improve assessments with more-consistent laboratory exposure methods, oil compounds used, and coral species examined.

Dawn Bickham is a master’s student with Nova Southeastern University’s Department of Marine and Environmental Sciences, and she helps assess the health and recovery of shallow-water corals exposed to oil- and oil plus dispersant mixtures. Her findings will help fill knowledge gaps regarding sublethal oil spill effects on coral systems and help responders determine which aspects of the Gulf are most at-risk when an oil spill occurs.

Dawn is a GoMRI Scholar with the project Coral-Tox: A Species-Sensitivity Assessment of Petroleum Hydrocarbon Toxicity to Scleractinian Corals.

Her Path

Dawn’s journey to biological research took a long and unexpected road. After high school, she entered the United States Air Force as an Operations Resource Manager and later completed an Information Technology undergraduate degree at American InterContinental University’s Florida campus. Shortly after, she began training equestrian riders in Plantation, Florida, and shadowed equestrian industry leaders to acquire nutrition and sports medicine skills to help her clients. She also started diving and snorkeling and joked that if she wasn’t on a horse, she was in the water.

6696b — (L-R) Nova Southeastern University Ph.D. student Nicholas Turner, project principal investigator Dr. Abigail Renegar, and Nova Southeastern University master’s student Dawn Bickham prepare the experimental setup for a hydrocarbon exposure trial. (Provided by Abigail Renegar)

Snorkeling sparked Dawn’s curiosity about coral biology, so she searched for local coral research opportunities and volunteered in Dr. Abigail Renegar’s scleractinian coral biology lab at Nova Southeastern University. She spent more than a decade volunteering in the lab and occasionally attended scientific conferences with Dr. Renegar, which further fueled her captivation with coral research. When a lab position became available, Dawn applied to the university’s biological sciences master’s program and joined Dr. Renegar’s GoMRI-funded coral research team. “My interactions with the oil spill community sparked my interest in oil- and dispersant-related research and cultivated a drive to educate the community about spilled oil’s impacts on our marine resources,” said Dawn. “When the opportunity to work with corals in the scope of oil spill response arose, I was excited to pursue it.”

Her Work

Dawn’s current research began with a previous collaboration between the Renegar lab and government and response community research partners to develop a standardized toxicity testing protocol for adult scleractinian corals (hard corals) that considers how different coral species respond to individual oil compounds. During that effort, the team successfully developed and applied the protocol to one species of shallow-water coral and demonstrated the lethal and sublethal impacts of a single hydrocarbon. The Renegar team is building upon that work by including more coral species and predicting the toxicity of other individual hydrocarbons using the critical body burdens (CBB) – the exposure levels that corals can experience before toxicity occurs, which can cause long-term negative health effects. Their results will help determine thresholds of acceptable/unacceptable impact on corals, help predict impact severity, and inform oil spill responders about the potential impacts of oil and various response methods on corals.

Dawn and her colleagues exposed five ecologically relevant coral species (Acropora cervicornis, Solenastrea bournoni, Stephanocoenia intersepta, Siderastrea siderea, and Porites astreoides) to different hydrocarbon concentrations commonly found in Gulf of Mexico crude oil (toluene, 1-methylnaphthalene, and phenanthrene) for 48 hours using a passive dosing method. They collected growth rate and Pulse-Amplitude-Modulation (PAM) data, which measures the corals’ photosynthetic health (how well it absorbs or reflects light), conducted transcriptomic analyses on the coral’s RNA, and determined CBB using visual assessments of coral condition. These metrics will help determine the concentrations at which each hydrocarbon begins negatively affecting the coral. The team also conducted exposures using increasing concentrations of crude oil to validate findings from the single-hydrocarbon experiment and conducted oil plus dispersant exposures to learn more about effects from dispersant use near coral reefs.

After each exposure treatment, Dawn wounded the corals with a dremel to simulate damage that might occur during response operations (from booms or other mitigation equipment) and took photos at different time points (at time of wound, 1 week after, 1 month after, and 3 months after). She is analyzing approximately 800 photos to determine if there is a correlation between oil concentration and the corals’ ability to repair wounds. Dawn’s team plans to generate a detailed understanding of oil toxicity for each coral species by combining the wound repair data, the PAM data, results from the coral’s RNA transcriptomic analysis, and CBB data from visual coral condition assessments. “All of our metrics are put together to address the big picture of coral health, and the outcome we’re starting to see is that corals may be much more resilient than we expected,” said Dawn.

The team will integrate their results into existing and emerging oil toxicity and 3D oil plume models that will visualize and predict how oil affects corals and inform decisions related to the impact severity of response treatments. “As long as we are using and processing oil, it’s not if we have another oil spill disaster, it’s when,” she said. “When we do our experiments, we want to give responders and industry the best information possible before a spill happens.”

Dawn expressed an interest in exploring the coral’s genetic data to observe if exposure triggered the upregulation or downregulation of any genes that might affect the coral’s ability to recover. She speculates that if the exposure triggered an upregulation of genes that help protect the coral, such as mucus production, there may not be enough energy left for the coral to repair itself when wounded. She hopes that future experiments explore this possibility.

Her Learning

The project’s ambitious experiment schedule required much planning and teamwork, which helped Dawn learn how to function as part of a larger research group. She learned skills in experimental design, workload sharing, and laboratory organization and was able to apply her computer science background to manage the project’s large quantities of data. She found that a big challenge of laboratory research is repeating certain tasks over and over, but she emphasized that it is important to conduct detailed analyses that validate one’s findings. “Completing specific tasks multiple times can cause some people to become complacent in those details,” she said. “We ensured that we maintained the same quality of work through the entire process.”

Dawn is thankful that the GoMRI program helped her expand her horizons and learn new skills. She learned the importance of having an advisor who is understanding, eager to teach, and encourages the use of existing knowledge to gain new knowledge. “I’m coming into this project as a second career and, since I don’t come from a biology background, I’m doing a lot of catch up,” she said. “Working with team members and collaborating with industry people and researchers from other projects has been amazing. I’ve found it a very reassuring place to be.”

Dawn hopes to find a position in industry where she can continue working in toxicology and investigate the sublethal effects of environmental disturbances on marine organisms.

Praise for Dawn

Dr. Renegar reflected on Dawn’s unique background as an Air Force veteran and computer scientist. She explained that Dawn’s experiences have granted her a level of maturity that allows her to mentor her fellow graduate students. Since joining the lab, Dawn has become an integral part of the lab culture and Dr. Renegar praised her eagerness to learn new skills and apply her previous knowledge to coral biology research. “Dawn has learned a great deal since joining the lab,” she said. “I have been very pleased with her progress as a scientist!”

The GoMRI community embraces bright and dedicated students like Dawn Bickham and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals.

By Stephanie Ellis and Nilde Maggie Dannreuther. Contact sellis@ngi.msstate.edu for questions or comments.

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Grad Student Slayden Knows Age Is More Than a Number for Oil-Exposed Deep-Sea Fishes

6671a — Nova Southeastern University master’s student Natalie Slayden holds a common fangtooth (Anoplogaster cornuta) that was collected during the DEEPEND consortium DP06 research cruise in the Gulf of Mexico. (Photo by Nina Pruzinsky)

The ocean’s deep-pelagic ecosystem is the largest and least understood habitat on Earth. In the Gulf of Mexico, it was the largest ecosystem affected by the Deepwater Horizon incident. Because there was very limited pre-spill data about deep-pelagic organisms’ biodiversity, abundance, and distribution, it is difficult to determine how oiling may have affected different deep-sea species.

Information about the longevity and age at reproduction of key Gulf of Mexico deep-sea fauna, such as lanternfish or fangtooths, is crucial to determine their vulnerability and resilience to disturbances such as oil spills. However, the depths at which these organisms live and the challenges involved with raising them in captivity or tagging them in the wild make collecting this data difficult.

Natalie Slayden uses ear stones, called otoliths, collected from fish living in Deepwater Horizon-affected waters to study the age and growth of nine Gulf of Mexico deep-sea fish species. Her research can be used to estimate the lifespan and age at which these deep-sea fishes reproduce to determine how quickly a potentially compromised assemblage might be replaced following an environmental disturbance.

Natalie is a master’s student with Nova Southeastern University’s Department of Marine and Environmental Sciences and a GoMRI Scholar with the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) Consortium.

Her Path

6671b — Nova Southeastern University master’s student Natalie Slayden uses a mechanical pencil tip to illustrate the small size of an otolith collected from a lanternfish (Nannobrachium lineatum). (Photo by Natalie Slayden)

Natalie developed an appreciation for marine environments at an early age. Growing up near the Appomattox River in Virginia, she spent her childhood swimming and using kite string and doughballs to fish for catfish on her grandparents’ houseboat. Her family often traveled to North Carolina’s Outer Banks, where they spent their days searching for fish, blue crabs, and hermit crabs in tide pools formed during high tides. These formative experiences inspired Natalie to pursue a biology undergraduate degree with a marine biology concentration at Old Dominion University. During that time, she participated in several research projects, including a Belize study abroad program researching coral reef ecology, a Cayman Islands internship researching lionfish diets, and a project with Dr. Mark Butler’s marine ecology lab investigating how climate change could affect the transmission of the Caribbean spiny lobster disease, PaV1 (Panulirus argus Virus 1).

When Natalie began her marine biology master’s studies at Nova Southeastern University, she volunteered in various labs searching for projects that included meaningful research. One of her volunteer experiences was with Dr. Tracey Sutton’s Oceanic Ecology Lab, and the numerous deep-sea questions and research focuses intrigued her. She joined his lab as a graduate student working on his GoMRI project investigating deep-sea fish’s resiliency to disturbances such as oil spills. “Deep-sea research appealed to me because of how rewarding it can be,” said Natalie. “While I’m currently studying the age and growth of Gulf of Mexico deep-sea fishes, there will always be an avenue for research [related to the deep sea].”

Her Work

6671c — Nova Southeastern University master’s student Natalie Slayden counts otolith rings using a microscope-mounted camera. (Photo by Nina Pruzinsky)

Otoliths, located in the fish’s cranium, assist with hearing and balance and provide a natural, chemical tracer representing an organism’s lifetime record of environmental exposures. Because the otoliths Natalie works with are as small as a grain of sand, she removes them using fine tools and photographs and measures them using a microscope-mounted camera. She then grinds and polishes the otoliths to reveal rings that can help her determine the fish’s age, similar to tree rings. She estimates each specimen’s age as a range based on the unit (days, years, etc.) that the rings likely represent for each species. “The otolith rings can mean different things for each fish and could be counted as days, years, or even represent feeding events or different life stages,” explained Natalie. “So far, it seems that the rings in most of the species I am studying may represent different life events and feeding.”

When interpreting a fish’s age using life events, Natalie measures the fish’s length and compares it to the length at which larval fish swim to depth. Then, she looks for evidence that indicates this event in the otoliths (typically seen as a change in the rings’ darkness or width). She also looks for evidence of life events such as undergoing a transformation or, if a fish is a hermaphrodite, a change in sex. When interpreting the otoliths for feeding events, dark rings can represent starvation while lighter rings indicate a food event or digestion. However, interpreting a fish’s age based on feeding varies between species. For example, lanternfish migrate to the surface each night to feed and acquire daily rings that represent both one day and a meal. Fishes that feed less frequently are more complicated to age, and Natalie depends on existing data about their feeding habits to estimate age.

6671d — Using a microscope, researchers can analyze rings in fish otoliths (pictured) to get historical information related to an organism’s age, life events, and environmental disturbances, similar to interpreting a tree’s history using tree rings. (Photo by Natalie Slayden)

The data that Natalie has collected on fish age can help estimate the average lifespans of different deep-sea species, which helps her interpret their resilience to disturbances. Species who more quickly repopulate due to their short life spans may also more quickly rebound from environmental disturbances like oil exposure. The data on fish age and lifespan from Natalie’s research will become input parameters for models that estimate how long their recovery from disturbances may take. “In an environment disturbed by an oil spill, fish populations with individuals that have a shorter lifespan would likely recover the fastest,” said Natalie. “If we know how old these oil-exposed fish are using the data recorded in their otoliths, it can help us understand how long the oil may have effects on populations.”

Her Learning

Natalie named DEEPEND’s DP06 research cruise in 2018 as her most rewarding experience participating in GoMRI research and recalled her excitement at seeing deep-sea organisms first-hand as they came out of trawling nets. She felt fortunate to work alongside scientists from diverse fields and learn new skills from other researchers, especially a team that often discovers new organisms. “The researchers were nice, welcoming, and fun to be around, and the crew was just as excited about our research as we were,” she said. “The cruise taught me the importance of comradery and simply being good to one another.”

6671e — Nova Southeastern University master’s students Nina Pruzinsky (left) and Natalie Slayden (right) process samples collected from a deep-sea trawl during the DEEPEND Consortium DP06 research cruise. (Provided by DEEPEND)

Natalie presented her research at the 2019 Gulf of Mexico Oil Spill and Ecosystem Science conference and plans to present an updated talk at this year’s event. “I am incredibly thankful to be a member of the GoMRI science community,” she said. “It is an honor to be able to work alongside and learn from scientists who are at the top of their fields.”

Natalie is confident that the skills she learned working in Dr. Sutton’s lab will help her transition to the workforce. She also believes that gaining diverse skills and having a multidisciplinary background will expand her future options and plans to take additional course work in cyber security and computer programming after graduating. “It’s ok to be unsure of what exactly you want to do and to change the subject matter of your work,” she said. “I went from studying Caribbean Spiny lobsters to studying deep-sea fishes living a mile below the surface. There is no limit!”

Praise for Natalie

Dr. Sutton explained that Natalie represents everything that his lab and the GoMRI program promotes, especially scholarship, leadership, and character. He described her as being scientifically fearless, attacking the research with gusto. “She learned the intricacies of ageing fishes, then applied them to a group of fishes who are not only quite technically difficult (having small, aberrant otoliths) but also quite difficult to interpret, as they live below the daily signals of sunlight,” he said.

Dr. Sutton also praised Natalie’s leadership skills when she leads the lab’s daily operations and, by extension, the efforts of numerous DEEPEND research projects. He explained that she handles all things with grace and generosity and takes requests with a smile. “The word with Natalie is trust – when she handles a task, you know it will be done well and on time,” said Dr. Sutton. “She speaks softly and slowly but thinks quickly, creating a joyful, positive vibe in the lab for which I am extremely grateful.”

The GoMRI community embraces bright and dedicated students like Natalie Slayden and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the DEEPEND website to learn more about their work.

By Stephanie Ellis and Nilde Maggie Dannreuther. Contact sellis@ngi.msstate.edu for questions or comments.

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Classroom Activity (K-12): “Build-A-?” Teaching Activities and Guides – Deepsea Coral and Tubeworms

These learning activities introduce students to different deep-sea organisms living in the Gulf of Mexico.

The Build a Deep-Sea Coral activity utilizes an easy craft project to get students thinking about the architecture of deep-sea corals (which is different from shallow-water corals) and the animals that live on or near the coral. Students can also discuss how corals that live without sunlight obtain their nutrition.

The Build a Deep Sea Tube Worm activity uses a simple craft to teach students about tube worm anatomy and its unique way that tube worms obtain energy from the deep sea.

Grad Student Pruzinsky Uses Morphological Patterns to ID Young Tuna for Population Assessments

6570a — Nina Pruzinsky holds a juvenile little tunny (Euthynnus alletteratus) that she identified on the DEEPEND DP06 cruise. (Photo by Natalie Slayden)

The Deepwater Horizon oil spill overlapped with the spawning activities of many ecologically and economically important tuna species. However, the significant knowledge gap regarding early life stage tuna taxonomy and distribution makes it difficult to understand how the spill may have affected them.

As a graduate student, Nina Pruzinsky examined the abundance, distribution, and morphological characteristics of larval and juvenile tunas (Scombridae) and identified primary drivers of their distribution to help fill this gap and inform future management and conservation efforts.

Nina, who recently completed her graduate studies, was a master’s student in Nova Southeastern University’s Department of Marine and Environmental Sciences and a GoMRI Scholar with the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) Consortium.

Her Path

6570b — (L-R) Dr. Isabel Romero, Nina Pruzinsky, and Natalie Slayden sort samples from a DEEPEND DP06 cruise aboard the R/V Point Sur. (Photo by Heather Judkins)

Nina discovered her interest in environmental research during high school class trips to Virginia and Jamaica. She and her classmates surveyed diverse environments, such marshes and coral reefs, and learned about the marine and terrestrial organisms living in them. These hands-on experiences along with a freshman ocean science class at the University of Delaware prompted her to pursue an environmental science degree. As an undergraduate student, she studied in the Cayman Islands, obtained an AAUS Scientific Diver certification, and interned in Dr. Mark Warner’s Algal Physiology Research Laboratory, where she studied coral symbiotic dinoflagellates. However, Nina realized that she was most interested in researching poorly studied fish taxa.

After reading several of Dr. Tracey Sutton’s deep-sea research articles, Nina applied for an open graduate research position at his Nova Southeastern University Oceanic Ecology Lab. When she began working with Sutton, he was leading the DEEPEND Consortium, which had just begun their work assessing how the Deepwater Horizon oil spill may have damaged the Gulf of Mexico’s little-explored deep-sea ecosystems. “My personal goal is to provide information that can help maintain and assess populations and ecosystems,” said Nina. “Seeing how DEEPEND was designed for new discoveries and assessing the oil-damaged water column drove my decision to work with Dr. Sutton.”

Her Work

6570c — Nina Pruzinsky prepares elongated bristlemouth (Sigmops elongatus) specimens for tissue sampling at sea. (Photo by Natalie Slayden)

Juvenile tunas are particularly difficult to identify to the species level (there are 15 tuna species worldwide). Although larval tunas are well-described, juveniles grow out of many diagnostic larval characteristics but have not yet developed the adult features needed for identification. Nina examined the morphological characteristics of over 900 larval and juvenile tuna (Scombridae) specimens collected during seven northern Gulf of Mexico research cruises in 2010 – 2011 and 2015 – 2017. She identified each larval and juvenile tuna specimen to the lowest taxonomic level possible and confirmed her identifications using genetic barcoding. Then, she identified physical characteristics unique to each undescribed juvenile tuna species, finding that body ratios and spine/fin ray counts were key morphological characteristics for identification.

Nina calculated species-specific body ratios using measurements of the head, upper jaw, snout, eyes, and fins. She then observed if and how these ratios changed as early-life-stage tuna matured. Combining reported ratios and her new ratios, she determined the definitive physical characteristics that can be used to identify different juvenile tuna species. “Species-specific body ratios can either be used in conjunction with morphological characteristics or on their own,” said Nina. “For example, a known diagnostic feature of larval and (now) juvenile Acanthocybium solandri (wahoo) is that their snout is twice the size of their eye diameter. However, A. solandri can also be identified using fin ray counts. Both approaches are useful, depending on the condition of the specimen.”

6570d — Jason Mostowy and Nina Pruzinsky rinse the catch from the bongo nets into the codend on a DEEPEND ichthyoplankton cruise aboard the R/V Pelican. (Photo provided by Nina Pruzinsky)

Nina determined the faunal composition and standardized abundance for tuna samples collected during the seven research cruises. She observed that Euthynnus alletteratus (little tunny), Thunnus atlanticus (blackfin tuna), Auxis thazard (frigate mackerel), and Katsuwonus pelamis (skipjack tuna) were the most-abundant species in the analyzed samples. Using sampling location, Nina modeled the distribution of these species and statistically compared their abundance patterns to variables that may drive early life stage assemblage structure and distribution, including location and depth, time of day and year, and oceanographic features such as salinity and temperature. Although each tuna species exhibited a different vertical, seasonal, and horizontal distribution pattern, Nina observed that seasonality and species-specific environmental preferences (such as salinity level) were the main drivers of spatial distribution across the Gulf of Mexico.

“More oil rigs are being added throughout the Gulf, especially in waters that overlap with tuna spawning sites, increasing the chance of another spill. As larvae are planktonic [only float, not swim], they will not be able to avoid an oil spill,” said Nina. “Understanding the distribution, drivers of assemblage structure, and faunal composition of Gulf of Mexico tunas will assist management and conservation efforts, help assess how an oil spill impacts vulnerable early life stages, and potentially predict future year class strength.”

Her Learning

6570e — Nina Pruzinsky identifies a larval tuna on a DEEPEND ichthyoplankton cruise on the R/V Blazing Seven. (Photo by Jessica Lee)

Nina participated in two deep-sea research cruises and two DEEPEND ichthyoplankton research cruises while working in Dr. Sutton’s lab. During these expeditions, she led the data management and cruise planning efforts, interacted with colleagues from other institutions, and gained hands-on experience with the sample collection process. “Working with DEEPEND, there is always a chance to see something new, whether that is new to science, new to the Gulf, or new to my own personal experiences,” she said. “The excitement and comradery among the science crew was contagious, and I was constantly learning through either my own experiences or from hearing my colleagues’ stories. I would not trade that experience for the world!”

Nina said that being a part of the GoMRI community was extremely rewarding, especially learning from and sharing her research with scientists from other fields and projects. She said, “So far, I have presented at several conferences and was an invited speaker at the 2019 Gulf of Mexico Oil Spill and Ecosystem Science Conference in New Orleans, LA. It is an incredible experience learning about the research going on within the Gulf of Mexico and telling my own story.”

Her Future

6570f — Nina Pruzinsky holds a dragonfish (Echiostoma barbatum) specimen in the ship’s laboratory. (Photo by Natalie Slayden)

Nina completed her master’s degree in 2018 and is continuing her DEEPEND research as a Research Associate and lab manager in Dr. Sutton’s Oceanic Ecology Lab. When she isn’t on a research cruise, she manages multiple large databases, oversees sample collection and processing, writes cruise reports, participates in education and outreach efforts, and trains graduate research assistants, students, and volunteers. She hopes to continue working with people within and outside of academia and apply her growing research and managerial skills to her future career.

Nina suggested that students pursuing an environmental science or marine biology career should volunteer or intern in different laboratories to gain experience in various scientific fields. She reflected that her own career began working with dinoflagellates but eventually led her to deep-sea and tuna research. “Get involved!” she said. “You never know where your interests will take you.”

Praise for Nina

6570g — DEEPEND team on the DP06 cruise, July 2018. (Photo credit: Dr. Danté Fenolio)

Dr. Sutton said that Nina impressed him from her first interview with her academic record, writing skills, talent, drive, and joyful personality. “After I advertised the first two research assistant positions for DEEPEND, I sorted the applications into two folders: Nina Pruzinsky and everyone else,” he joked. It was no surprise to him when Nina became a pillar in his lab while also tackling challenging morphological analyses and conducting advanced biophysical modeling.

“Simply put, if I had a nickel for every time a troubled student or even a DEEPEND co-PI uttered the phrase ‘I’ll ask Nina,’ I could probably fund another student,” said Sutton. “I was dreading the thought of lab operations without her after she defended her thesis and was so overjoyed when she chose to stay with us as a Research Associate. I feel comfortable speaking for both myself and every co-PI when I say that she has been one of DEEPEND’s brightest stars.”

The GoMRI community embraces bright and dedicated students like Nina Pruzinsky and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the DEEPEND website to learn more about their work.

By Stephanie Ellis and Nilde Maggie Dannreuther. Contact sellis@ngi.msstate.edu for questions or comments.

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© Copyright 2010-2019 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Podcast: The Loop Podcast [English + Español]

The Loop podcast takes a deep dive into the Gulf of Mexico with the researchers studying the processes, mechanisms, and impacts of oil spills.

Researchers from the Center for Integrated Modeling and Analysis of Gulf Ecosystems (C-IMAGE) discuss their studies with David Levin of Mind Open Media. C-IMAGE is an international research group studying mud, microbes and mammals after two mega spills, Deepwater Horizon and Ixtoc I. The goal of C-IMAGE is to advance understanding of the fundamental processes and mechanisms of marine blowouts and their consequences, ensuring that society is better-prepared to mitigate future events.

Episode 1: Overview of C-IMAGE
C-IMAGE PI Dr. Steven Murawski talks to David Levin about C-IMAGE’s research goals and the importance of integration when tackling large scale impacts. This episode is available in English and Spanish. (Transcript: English, Español)

Español:

Episode 2: The Mud and the Blood
C-IMAGE PIs Steven Murawski and David Hollander talk to David Levin aboard the R/V Weatherbird II in August 2012 about looking for Deepwater Horizon‘s impacts on Gulf of Mexico mud and fish. This episode is available in English and Spanish. (Transcript: English, Español)

Español:

Episode 3: The “Not-So-Visible” Impacts of the Deepwater Horizon Oil Spill on the Gulf of Mexico
Three years after the BP oil well disaster, scientists are struggling to understand the effects on the Gulf ecosystem. David Levin reports on the oil’s impact on the tiny creatures that form the base of the food chain. (Transcript: English)

Episode 4: Fitting the Gulf of Mexico Inside a Computer: How to Build an Ecosystem Model
David Levin talks with C-IMAGE members Cameron Ainsworth, Jason Lenes, Michelle Masi, and Brian Smith about building an ecosystem model of the Gulf of Mexico to describe how oil spills impact marine life. (Transcript: English, Español)

Episode 5: The Pressure is On!
David Levin talks with C-IMAGE PI Steven Murawski and scientists from the Technical University of Hamburg at Harburg Michael Schluter and Karen Malone about their ongoing experiments examining oil and gas droplets under high pressure to learn more about the Deepwater Horizon oil spill. (Transcript: English, Español)

Episode 6: Oil – It’s What’s for Dinner…
C-IMAGE scientists want to know more about how oil-eating microorganisms behave in the cold deep ocean to learn more about what happened to the oil from the Deepwater Horizon blowout. High-pressure experiments underway at our high pressure facility at the Hamburg University of Technology focus on how these microbes use oil and what happens to them in the process. Results from these studies may lead to a new way to clean up spills by eliminating its most poisonous ingredients. (Transcript: English, Español)

Episode 7: The Ixtoc Spill – Reflections
The Deepwater Horizon oil spill happened just a few years ago, but it might be possible to predict its impact on the Gulf by studying another major spill, one that happened in 1979. “These are two of the largest spills in the world’s history as far as blowouts go, and they were both in the Gulf of Mexico.” Wes Tunnell is a marine biologist who is looking at the aftermath of both spills. It’s almost like he’s looking at the same crime scene, separated by more than three decades. How? Give a listen. Mind Open Media producer David Levin talks to Wes Tunnell and John Farrington about their experiences during the 1979 Ixtoc spill and the applications to new blowouts thirty years late. This episode is available in English and Spanish. (Transcript: English, Español)

Español:

Episode 8: In the Mud in Mexico
“We were of the mind that with studying the Deepwater Horizon in the northern Gulf we weren’t getting a full Gulf of Mexico perspective.” Geochemist David Hollander is traveling with an international team of scientists aboard a Mexican research vessel. Over the last few years, his team has studied the effects of the 2010 Deepwater Horizon spill. But today, they’re looking back at a spill that happened 35 years ago and what they learn on this trip might help them understand the future of the Gulf. Mind Open Media producer David Levin talks to David Hollander, Joel Ortega Ortiz, Isabel Romero, Adriana Gaytán-Caballero, and Travis Washburn about their experiences on the RV Justo Sierra in the southern Gulf of Mexico during the research on the Ixtoc spill. (Transcript: English, Español)

Episode 9: Forensic Oceanography
Listen to learn how scientists reanalyzed remotely sensed data taken in the late 1970s to study the Ixtoc 1 oil spill. Dr. Chuanmin Hu and his graduate student Shaojie Sun use the Landsat and Coastal Zone Color Scanner (CZCS) data to develop “treasure maps” of oil from the IXTOC-1 spill to steer field studies. Listen in to find out how they did it. This episode is available in English and Spanish. (Transcript: English, Español)

Español:

Episode 10: The Risks for Fish
What happened to the fish in the days and weeks after the Deepwater Horizon oil spill? With a suite of exposure studies, C-IMAGE researchers are monitoring fish health after oil exposure in order to find out. Dr. Dana Wetzel and Kevan Main of Mote Marine Laboratory give fish a small does of oil through either their food, water, or the sea floor sediments, then analyze how their bodies recover. (Transcript: English, Español)

Episode 11: The Cuban Connection: Spills, Science Diplomacy
C-IMAGE collaborated with researchers from the University of Havana for the first join U.S.-Cuban expedition in over 50 years. (Transcript: English)

Episode 12: MTS TechSurge
When research and industry can communicate effectively when responding to an oil spill, both the environment and oil industry benefit from shared knowledge and new technologies. (Transcript: English)

Episode 13: For a Few Dollars More – Costs and Ecosystem Services after Spills
When oil spills are assessed through an economic viewpoint, both environmental and human impacts must be considered to provide a full picture. (Transcript: English)

Episode 14: Modeling Arctic Oil Spills
Understanding the long-term effects of arctic spills like this one could be even more urgent now than ever, as oil exploration makes its way to the North Slope of Alaska (including inside the Arctic National Wildlife Refuge). C-IMAGE has developed a computer model of the entire Gulf ecosystem, so they could test how future spills would affect the region. And now, they’re applying those tools farther north. (Transcript: English)

Episode 15: Asphalt Ecosystems
At the bottom of the Gulf of Mexico, some truly bizarre ecosystems are hiding in the darkness among the asphalt volcanoes and supporting huge colonies of unique life. C-IMAGE has been analyzing these ecosystems and reveals that if chemosynthetic communities are harmed, it could affect other environments as well. The microbes that power those communities don’t just eat chemicals in oil or asphalt—they also eat up a lot of free-floating carbon that would otherwise escape to the rest of the ocean… and eventually, get into the atmosphere, adding to global climate change. (Transcript: English)

Episode 16: Panel Discussion
For the past several years, The Loop covered the work of scientists studying the aftermath of the 2010 Deepwater Horizon oil spill. The research is winding down and this is The Loop‘s last podcast with C-IMAGE! (Transcript: English)

Video + Lesson Plan: The Adventures of Zack and Molly [English + Español]

The Adventures of Zack and Molly is a four-part animated short video series that tells the story of a young man, Zack, who is more interested in the small world of his smartphone than the larger world around him. Zack’s online request for a roommate is answered by Molly, a tech-savvy Dumbo Octopus on a mission to tell the world about the importance of the deep ocean. Molly wants to use Zack’s apartment for her global communications headquarters, but Zack is skeptical. To win Zack over, Molly takes him to her deep ocean home in the Gulf of Mexico to see its unique features and diverse marine life and help him understand how human activities threaten its health. In episode 4 (added in March 2020), the duo takes a field trip to the deep sea ecosystems in the Gulf of California to see some amazing underwater features and meet an underappreciated superhero.

These educational videos are intended for adults and children ages 10-18 and are accompanied by a Learning Guide providing discussion points, connections to Next Generation Science Standards, hands-on activities, and further resources.

Free Learning Guide PDF:
Learning Guide – English!
Guía de Aprendizaje – Español!

The Adventures of Zack and Molly Three-Part Compilation:

Las Aventuras de Zack y Molly – Subtitulos en Español:

Episode 4 – The Amazing Beggiatoa:

Las Aventuras de Zack y Molly #4 – la Increible Beggiatoa [Subtitulos en Español]:

Sea Grant Releases One Pager on Where Deepwater Horizon Oil Went

The Sea Grant Oil Spill Outreach Team released a Fact Sheet that uses easy-to-understand graphics and descriptions about how some oil accumulated at shorelines, on the ocean’s surface, in an underwater plume, and on the seafloor.

Where did the oil go? A Deepwater Horizon fact sheet provides a public-friendly resource for all who are interested in a healthy marine environment. The publication highlights the important points made in the more detailed eight-page bulletin Deepwater Horizon: Where did the oil go?

Oil also provided a food source for certain microbes who increased their numbers where oil was present to ingest it. Learn more about the role that microbes play in oil fate: Microbes and oil: What’s the connection?

The Sea Grant Oil Spill Outreach Team synthesizes peer-reviewed science for a broad range of general audiences, particularly those who live and work across the Gulf Coast. Sea Grant offers oil-spill related public seminars across the United States.

Information about upcoming Sea Grant science seminars and recently-held events is available here. To receive email updates about seminars, publications, and the outreach team, click here.

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GoMRI and the Sea Grant programs of the Gulf of Mexico (Florida, Mississippi-Alabama, Louisiana, and Texas) have partnered to create an oil spill science outreach program.

The Gulf of Mexico Research Initiative (GoMRI) is a 10-year independent research program established to study the effect, and the potential associated impact, of hydrocarbon releases on the environment and public health, as well as to develop improved spill mitigation, oil detection, characterization and remediation technologies. An independent and academic 20-member Research Board makes the funding and research direction decisions to ensure the intellectual quality, effectiveness and academic independence of the GoMRI research. All research data, findings and publications will be made publicly available. The program was established through a $500 million financial commitment from BP. For more information, visit https://gulfresearchinitiative.org/.

© Copyright 2010- 2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Grad Student Richards Uses Fish Muscle Tissue to Explore Deep-Sea Food Web Structure

6385a — Travis sorts through Neuston net samples looking for the Sargassum frogfish (Histrio histrio) aboard the R/V Point Sur. (Provided by DEEPEND)

The deep-pelagic habitat (200 m depth to just above the seabed) is the largest habitat in the Gulf of Mexico, yet we know very little about it compared to coastal and shallow-water habitats. Our limited understanding of this major marine habitat makes it extremely difficult to assess the effects of disturbances such as the Deepwater Horizon oil spill. Travis Richards seeks to better understand the structure of deep-pelagic food webs by tracing the energy flow from the food web base through higher trophic levels. His research will help expand our understanding of the deep-pelagic habitat and serve as a reference point for future studies and response efforts.

Travis is a Ph.D. student at Texas A&M University at Galveston’s Marine Biology Department and a GoMRI Scholar with the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) consortium.

His Path

6385b — Travis holds a large mahi caught during a fishing break between sampling efforts. (Provided by DEEPEND)

Travis discovered his interest in biology through the many scientists and science educators in his family who exposed him to diverse habitats and species through frequent camping, fishing, and hiking trips. His family’s travels took him to sites across the United States, including several trips to the Gulf of Mexico coastline. During his undergraduate and graduate career, he explored a variety of marine ecology opportunities and developed a specialization in marine food webs. He had just completed an ecology and evolutionary biology master’s degree at Florida State University when Dr. David Wells at Texas A&M University at Galveston contacted him about a Ph.D. student position researching deep-sea food webs. He eagerly accepted and joined Wells’ lab team working on the DEEPEND project.

Travis explained that the immersive outdoor experiences of his childhood have become a large part of his identity and are a driving force behind his research interests. “Those transformative experiences give conducting research on marine Gulf of Mexico organisms a personal significance,” he said. “I now have a career pursuing a field that interested me since childhood and contributing to our understanding of an ecosystem that played a significant role in my life.”

His Work

6385c — Travis catalogues tissue samples in the R/V Point Sur lab for a large barcoding project. (Provided by DEEPEND)

Travis helps collect deep-pelagic organisms using a Multiple Opening and Closing Net with Environmental Sensing System (MOCNESS) that is towed from surface waters to 1500 m depth. He analyzes natural chemical tracers called stable isotopes (variants of chemical elements that have a distinct signature as they transfer from prey to predator) in different organisms’ muscle tissues to identify their position within the food web. He can then piece together the food web’s structure to trace the initial food source and document the natural flow of energy through the food web.

Travis will use the data to describe variation in food web structure, identify the number of deep-pelagic trophic groups with different functions, and determine how much deep-pelagic organisms contribute to the diets of demersal (near the seabed) and epipelagic (surface to 200 m depth) predators. So far, Travis has observed that deep-pelagic food webs are more complex and nuanced than researchers have previously thought. His preliminary results indicate that the food web’s structure varies both seasonally and across horizontal and vertical spatial scales. Researchers can use this information to make better predictions about the ways that removal of targeted species by fisheries or disturbances such as oil spills will affect the food web and the greater pelagic ecosystem.

His Learning

6385d — Researchers aboard the R/V Point Sur pose in front of a large waterspout during a summer 2015 research cruise. (Provided by DEEPEND)

Travis has learned that productivity matters to success in academia. One must always make progress on some aspect of their research, and there is always a paper that needs work or an experiment that can be set up. He said that seeing the contributions of one’s research is a motivating reward for the hard work. “I’m continually impressed with the research being conducted within the different GoMRI funded projects. When you attend a GoMRI meeting, you get a real sense for how much we’re learning about the Gulf of Mexico. It’s exciting to know that our work is contributing to a new and more complete understanding of the Gulf.”

One of Travis’s most memorable experiences working with the DEEPEND consortium is conducting field work – a rare opportunity due to the challenging logistics and expensive nature of deep-sea sampling. “You never know what you’ll bring up in the nets,” he said. “With each research cruise, I’ve been able to see incredibly unique organisms, such as anglerfishes, lanternfishes, and cephalopods, that I never imagined I’d get to see in person.”

His Future

Travis hopes to conduct research as a post-doc and eventually take a position at a liberal arts college teaching and leading a small research program. He advises that students considering a scientific career take advantage of every research opportunity available to them, even those not focused on their exact interests. “Do the best possible work you can at each position you take,” he said. “Once you demonstrate your ability to perform well at a variety of positions, more opportunities will start to open up for you.”

Praise for Travis

Dr. Wells commended Travis’ commitment to leading the deep-sea trophic ecology component of the project’s research, noting that he often puts in extra time to make his research responsibilities his primary task. “He is always willing to participate on cruises and be involved in meetings and present his results,” said Wells. “He recently published his first dissertation chapter in ICES Journal of Marine Science (Trophic Ecology of Meso- and Bathypelagic Predators in the Gulf of Mexico) and is clearly on track to do great things with his project.”

The GoMRI community embraces bright and dedicated students like Travis Richards and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the DEEPEND website to learn more about their work.

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© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Student Researcher Blogs Highlight Exciting Deep-Ocean Discoveries

6371a — Corinne Meinert holds a deep-sea fish collected during a research cruise. Corinne studies the biodiversity of fish eggs and larval fish that drift in ocean currents. (Provided by DEEPEND)

The Gulf of Mexico is one of four “super-diverse” ecoregions in the world; yet, we don’t know much about how its deep environment changed after Deepwater Horizon because very little was known about it before the spill. Since the spill, the data about deep-ocean life are growing as scientists with the DEEPEND research consortium study the deep Gulf’s organisms and processes. Their findings will help develop a baseline to monitor future changes.

Master’s-level graduate students working alongside DEEPEND scientists are writing a weekly blog series about their research contributions. “When these disasters occur, the deep sea is not often thought of – it is kind of an out of sight, out of mind situation,” said student Devan Nichols. “The deep sea is a mysterious place, and scientists still have a lot to learn about its complexity and the organisms found there.”

Here are some deep-ocean research areas that these students have written about, which can help inform management decisions to predict, protect, and increase recruitment for future populations.

Gulf Shrimp

6371b — Sergestes corniculum, one of the species Richard Hartland studies. The sergestids are important members of the oceanic community, both as consumers of zooplankton and as prey for higher trophic levels. (Provided by DEEPEND)

Devan Nichols, Richard Hartland, Ronald Sieber, and Nathan LaSpina at Nova Southeastern University are studying potential impacts to Gulf shrimp (family Oplophoridae, family Sergestidae, family Euphausiidae and family Benthesicymidae). They are examining data collected in 2011, comparing them to data collected in 2015, 2016, and 2017, and identifying changes in abundance, biomass (weight), and vertical migrations.

The data are beginning to show a sharp decrease in abundance between 2011 and 2015 – 2017 and that the warm water input from the Loop Current may affect abundance. Further analyses are required to verify if the Current affects migration habits.

Young Fish

6371c — Corinne Meinert displays a snake mackerel (Gempylus serpens) on her fingertip to demonstrate ichthyoplankton’s tiny sizes. She and her research group have collected and identified over 18,000 individual larval fish across 99 different families. (Provided by DEEPEND)

Corinne Meinert (Texas A&M University at Galveston), Sebastian Velez (Florida Atlantic University), and Nina Pruzinsky (Nova Southeastern University) are researching the biodiversity, dispersal processes, and spatial distribution of early life stage fishes.

Meinert uses genetic methods to analyze oceanic ichthyoplankton – fish eggs and larval fishes that drift in ocean currents – and learn about their biodiversity and population dynamics. This information gives insight into the status of the oceanic environment, since higher fish diversity typically indicates a healthier ecosystem.

Velez focuses on larvae from nearshore species (snappers and groupers) that utilize offshore habitats (up to 1,500 m depth). He observed strong biodiversity in these expatriates and found that some species, such as the Wenchman snapper, have the ability to stall their settlement, likely in search of a suitable habitat. “When you walk into a restaurant and order sushi or a fish dinner […] the odds against a particular animal making it to a harvestable size are astounding,” said Velez. “These fishes [often] represent multi-million dollar industries in the form of commercial and recreational fisheries. Understanding the biology and life history of [these] species is imperative in informing future management decisions.”

Pruzinsky studies the spatiotemporal distributions of early life stage tuna to learn about their habitat preferences and help compile key identification features for juvenile tuna species. These features include pigmentation patterns, body shape, ratios of different body parts, and fin ray counts. She developed high-resolution models of larval and juvenile tuna distributions as a function of habitat. These models represent some of the first for juvenile tunas (as opposed to the better-known larvae and adults).

Adult Fishes

6371d — One of the largest (>15cm) ever recorded specimens of the Bullis’s Barracudina (Stemonsudis bullisi). This endemic species had previously only been known from two juvenile specimens around 6 cm long. (Provided by DEEPEND)

Characterizing the behaviors and distribution of deep-sea fishes is a major focus of DEEPEND. Rich Jones at Florida Atlantic University is researching the important but poorly known fish family Paralepididae (barracudina), whose unique bioluminescence is derived from liver tissues. Using data from large pelagic trawls (NRDA ONSAP sampling), he observed that barracudina actively avoid smaller, research-sized nets, suggesting that we have probably underestimated their abundances and importance historically. He also noted distinct differences in diet and water column distribution between barracudina species.

Nova Southeastern University student Kristian Ramkissoon researches the composition, abundance, and vertical distribution of the bristlemouth fish genus Cyclothone, the most abundant vertebrate on the planet. He has observed that these fishes do not vertically migrate, but instead occupy relatively predictable and distinct depth ranges. He is attempting to assess the impact of hydrographic features such as the Loop Current and its eddies on Cyclothone distribution.

Fellow Nova student Natalie Slayden studies otoliths – ear stones whose rings represent a fish’s age. She plans to describe and correlate otolith ring patterns with the fish’s life history and estimate the ages of various mesopelagic and bathypelagic fishes, most for the first time.

Max Weber at Texas A&M University at Galveston uses genetic methods to investigate if population size fluctuations in deep-sea fishes mirror those of coastal species. Stable populations reflect a stable environment, yet Max’s preliminary analyses reveal population declines and expansions that indicate the environment is more volatile than previously assumed.

Eating Habits

6371e — Examples of microplastics ingested by deep-pelagic fishes and crustaceans in the Gulf of Mexico: (A) microbeads, (B-E) microfragments, and (F) microfibers. (Provided by Ryan Bos)

Three Nova Southeastern University students analyze fish gut contents as part of their focus on food webs. Mike Novotny is researching bathypelagic fishes called “Tubeshoulders” (family Platytroctidae) to explore their feeding behaviors and prey preferences – the first known study into the diet of this important family. He observed that these creatures are zooplanktivores that feed on gelatinous animals (e.g., jellyfishes and relatives), something not previously known.

Ryan Bos focuses on fish and shrimp ingestion of microplastics (ranging 1 μm – <5 mm), which can cause false feelings of fullness, obstruct feeding appendages, decrease reproductive fitness, and premature death. He identified microplastics (which burn, melt, curl up, or repel when touched with a hot needle) and observed that nearly one-third of the fishes and crustaceans tested ingested at least one piece of plastic. These findings highlight the ubiquitous influence of anthropogenic pollutants in the deep ocean.

Matt Woodstock is studying mesopelagic fishes to better understand the ecology of endoparasites, which live within another organism (a host) and travel through the food web to complete their life cycles. The presence of many different parasites suggests that the fish’s diet may have shifted over time or may come from many different prey. These results will help researchers make conclusions about the connectivity and stability of different ecosystems.

Rare Finds

6371f — Imaging demonstrating the cranial pigmentation that Kristian Ramkissoon uses to differentiate between Cyclothone species. (Provided by Kristian Ramkissoon)

Many of the students’ research projects focus on little-studied Gulf of Mexico organisms and processes and are the first studies of their kind. For example, three of the nineteen barracudina species captured for Jones’s research represent the first records of those species, and Woodstock is the first person to record parasites within the species he studies.

“Some of the fishes we have identified have only been seen by a handful of people before in oceanographic history,” said Rich Jones. “The opportunity to study the habits of these rare animals with a comprehensive suite of data, let alone hold them in your hand, is a unique pleasure of working with DEEPEND.”

Learn more about DEEPEND research:

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This research was made possible in part by a grant from the Gulf of Mexico Research Initiative (GoMRI) to the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) consortium.

© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Documentary + Short Clips: “Jewels of the Gulf” – Oil Impacts on Deep-Sea Corals

5189 Jewels of the Gulf is a 16-minute documentary highlighting research into Deepwater Horizon’s continued impacts on deep-sea corals.

Background: On April 20th 2010, approximately 50 miles from the Louisiana coastline, the Deepwater Horizon oil rig experienced a catastrophic failure that resulted in the largest marine oil spill in history. Over the course of 87 days, an estimated 210 million gallons of oil surged into the Gulf of Mexico from a wellhead nearly one mile beneath the surface. Images in the media portrayed the dire consequences to human lives and livelihoods, animals, and shorelines. But there are impacts that the media didn’t cover — the impacts of the spill on the deepwater ecosystems of the Gulf. Ecosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG) consortium scientists are documenting the continued impacts of the accident on the unique and beautiful deep sea corals that form the basis of diverse biological communities deep beneath the Gulf’s surface.

The Research: The Jewels of the Gulf research cruise was a 12-day expedition assessing the effects of oil, methane, and chemical dispersants on deep-sea corals. Remotely operated vehicles at over 1000 meters depth captured hundreds of high-resolution still images of corals that the researchers have been monitoring since 2010. The researchers analyzed the images and compared them to those from previous expeditions to document the spill’s impacts and assess the coral’s post-spill recovery and survival. The team, led by Dr. Iliana Baums from Pennsylvania State University, collected both high-resolution images of the corals to document changes over time and live coral samples to study back in the lab. During the expedition, a live ROV camera feed was broadcast so the public could view what the scientists were seeing in real time. To learn more about the Jewels of the Gulf expedition, meet the scientists, and more, visit ECOGIG’s Cruise Blogs here.

Prior to the release of the full-length documentary, ECOGIG released three short videos using footage from the expedition that focused on different aspects of coral research.

Part 1: What is a Deep-Sea Coral?

Thousands of meters beneath the surface of the Gulf of Mexico, ECOGIG scientists study the ecology of deep sea corals living on the seafloor. What is a deep sea coral? How do they nourish themselves in the darkness? What makes them unique?

Part 2: How Do Scientists Study Deep-Sea Corals?

ECOGIG scientists use remotely operated vehicles and high-resolution camera equipment to study deep sea ecosystems in the Gulf of Mexico.

Part 3: Why Study Deep-Sea Corals?

A better understanding of deep sea corals in the Gulf of Mexico will advance our knowledge of deep sea ecosystems as well as guide management decisions in response to future disturbances.

Grad Student DeLeo Used Genetics to Explore Oil, Dispersant Effects on Deep-Sea Corals

6332a — Danielle retrieves live coral samples from an ROV quiver aboard the 2012 R/V Falkor expedition. (Provided by ECOGIG)

Responders to the Deepwater Horizon incident applied unprecedented amounts of chemical dispersant on the surface oil slick and into the deep underwater plume forming from the riser pipe. Shortly thereafter, researchers observed that a brown flocculant material containing oil and dispersant components covered some deep-sea corals near the incident site. Danielle DeLeo, during her graduate research, investigated oil and dispersant’s overall toxicity on deep-sea corals and assessed genetic changes that might help explain the resulting impacts.

Danielle completed her Ph.D. biology program at Temple University during which she was recognized as a GoMRI Scholar with the Ecosystem Impacts of Oil and Gas Inputs to the Gulf-2 (ECOGIG-2).

Her Path

6332b — Danielle assesses coral fragment health during a timed series of experimental oil and dispersant exposures aboard the 2012 R/V Falkor expedition. (Provided by ECOGIG)

Danielle fell in love with the ocean at a young age despite road blocks she faced in her local school system. Growing up, she attended schools with weak STEM programs and faced resistance from educators when she expressed interest in the sciences. “As a female, my advisors never encouraged me to pursue a major in STEM fields and, in some cases, made me think I couldn’t hack it,” she explained. “Even so, I found a way to turn my interests into a career that I love and became a first-generation college graduate.”

She discovered her interest in deep-sea ecosystems as an undergraduate student at Penn State University. While working in Dr. Charles Fisher’s lab, Danielle assisted graduate students and researchers with preparations for a rapid response cruise that surveyed the Deepwater Horizon incident’s initial effects on Gulf of Mexico coral communities. “Learning about deep-sea habitats and the various ways in which scientists explore and sample these environments was an eye-opening experience for me,” she said. “I became passionate about studying the oil spill’s anthropogenic impacts on deep-water coral communities.” Danielle completed her Ph.D. research with Dr. Erik Cordes at Temple University, where she worked as a member of the ECOGIG consortium that investigates impacts from oil spills and other stressors on deep-sea corals.

Her Work

6332c — Danielle (front) and former Penn State University graduate student Dannise Ruiz work on coral exposure experiments aboard the 2013 R/V Nautilus cruise. (Provided by ECOGIG)

Danielle conducted exposure experiments with coral fragments for 96 hours using treatments of oil, dispersant, and an oil-dispersant mixture. “We have no idea what actual oil and dispersant concentrations the corals were exposed to in situ or for what duration,” she explained. “Instead, we know what the resulting damage or impacts looked like. Therefore, we tested a variety of concentrations and oil-water-dispersant mixtures to see what the overall toxicity of each was and what chemicals and/or combinations would cause the lethality and damage we observed in situ. We chose a range of exposure concentrations for our experiments based preliminary testing to examine mortality rates.”

She conducted two exposure series. One series used whole chemical mixtures of dissolved and undissolved portions of oil and dispersant (high concentration 25 ppm, medium 7.9 ppm, low 0.8 ppm). The other series used only dissolved water-accommodated fractions (based on the highest oil concentrations detected during the spill ~300 μM to find lethal doses, as none of the bulk-oil concentrations proved to be lethal). Initial total hydrocarbon concentrations were high 250 μM, medium 150 μM, and low 50 μM; and initial total dispersant concentrations were high 176.7 mg/L, medium 106.0 mg/L, and low 35.3 mg/L.

6332d — Danielle monitors ROV sampling efforts in the control room aboard the 2013 R/V Nautilus cruise. (Provided by ECOGIG)

Danielle examined changes in the coral’s gene expression after exposure using high-throughput RNA sequencing and transcriptomics. She focused her analyses on exploring genome-wide effects underlying the stress responses observed in floc-exposed corals, such as polyp coiling or death, excess mucous production, damaged tissue, and exoskeletons.

Danielle observed that, at similar concentrations to the oil, dispersant-only treatments appeared most toxic to deep-sea corals followed by oil-dispersant mixtures and then oil alone. Dispersants caused an overall decline in coral health and exacerbated the lethality of oil exposure. Oil and dispersant exposures also activated the corals’ immune responses and wound-repair mechanisms, suggesting that the corals may have been able to partially survive short-term exposures if the technology and methodology to limit initial exposure periods at depth existed. Her findings support a growing body of research that suggests deep-sea dispersant applications may have had some unintended consequences as it relates to soft coral communities. This reinforces the need for exploring new response efforts and technology in the event of future deep-water oil spills.

6332e — Danielle in the deep submersible vehicle Alvin at ~1100 meters depth in the Gulf of Mexico, 2014. (Provided by ECOGIG)

“These consequences are extremely important to consider for future oil spill clean-up efforts in deep waters,” she said. “The gene expression studies for in situ impacted corals reveal some of the molecular-level impacts that manifested into the physical damage observed at oil-impacted deep-water coral sites, while also elucidating their recovery potential.”

Her Learning

Working with Dr. Cordes, Danielle conducted research aboard different vessels, handled and cared for deep-sea specimens, and assisted with collections using remotely operated vehicles and the deep submergence vehicle Alvin. Her work provided many life-changing experiences that reinforced her passion for deep-sea research. She said, “I was extremely lucky to have the opportunity to dive in Alvin twice at deep Gulf of Mexico sites to collect samples for my dissertation research. It was an experience that I will always cherish.”

Her Future

6332f — Danielle boards the deep submersible Alvin for her first dive, 2014. (Provided by ECOGIG)

Danielle began a post-doctoral position in 2016 with Dr. Heather Bracken-Grissom at Florida International University exploring the evolution of bioluminescence in deep-sea crustaceans. Now she applies the skills and methods she learned to answer new questions about deep-sea invertebrates.

She advises science-interested students to explore their interests, take risks, and seek out classes or workshops to help narrow their interests. “As a city kid, I never imagined I would end up becoming a marine biologist studying the deep sea,” she said. “Seek out mentors who encourage and inspire you as well as opportunities working or volunteering in labs or in the field. It could change your life’s path – it did for me!”

Praise for Danielle

6332g — Danielle and Dr. Bracken-Grissom collect samples during a Florida Straits field course in 2017. (Photo Credit: Danielle DeLeo)

Dr. Cordes said that Danielle continuously impressed him during her time at Temple University. “She took on many challenges and, through her development of bioinformatics tools, took our research in directions that wouldn’t have been possible before. I look forward to seeing where her career will take her and furthering our collaboration in the future.”

The GoMRI community embraces bright and dedicated students like Danielle DeLeo and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the ECOGIG website to learn more about their work.

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6332h — Danielle and Dr. Bracken-Grissom deploy a mid-water trawl net aboard the R/V Bellows. (Credit: DeLeo)

© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

BBC’s Planet Earth: Blue Planet II Features Deep Ocean Research and Scientists

6316 — Dr. Mandy Joye (L) inside a deep-ocean submersible. Photo courtesy of Buck Tayleor, Alucia Productions.

“Magical discovery moments” is how Dr. Samantha “Mandy” Joye describes scenes at the bottom of the ocean. Now, thanks to the BBC-produced documentary series Blue Planet II, we can get a glimpse of these discovery moments and join discussions about the ocean’s importance.

The series, narrated by David Attenborough, includes seven episodes about exploring the world’s ocean. Included in these episodes are footage featuring research by GoMRI-funded consortia Deep Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) and Ecosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG).

Watch this video clip Brine Pool: Exploring an Alien World for Blue Planet II featuring oceanographers Drs. Sylvia Earl and Mandy Joye as they dive in a submersible and explore the bottom of the ocean.

Brine Pools: Exploring an Alien World for Blue Planet II from Alucia Productions on Vimeo.
This video is a part of Our Blue Planet, a joint venture between Alucia Productions and BBC Earth to get people talking about the ocean.

Resources:

Video clip Brine Pool of Death is from the Blue Planet II Series The Deep, which features DEEPEND and ECOGIG research footage
Video clips featuring Dr. Mandy Joye (ECOGIG director): The Future of the Oceans and Searching for Cures in the Deep Sea
Websites for the BBC’s Blue Planet II and Alucia Productions
Websites for DEEPEND and ECOGIG

Here are a few stories about GoMRI-funded research in response to the Deepwater Horizon oil spill, which includes DEEPEND and ECOGIG research:

Two documentaries produced by Screenscope Dispatches from the Gulf are part of the PBS series Journey to Planet Earth.
Science at Sea: Deep-Sea Research Informs Taxonomic Assessment of Gulf Fauna
Smithsonian Features Research about Brittle Stars Helping Coral Recover from Oil Spill
Discovering Vibrant, Dynamic Life in the Deep Gulf of Mexico
Scientists on Alvin have Eyes on the Bottom of Deepwater Horizon Site

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© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Science at Sea: Deep-Sea Research Informs Taxonomic Assessment of Gulf Fauna

6292a — Researchers sort the catch into fishes, crustaceans, squids, and jellyfishes. (Provided by DEEPEND)

The deep-pelagic ecosystem was the largest habitat affected by the Deepwater Horizon incident, yet our limited knowledge about its fauna makes it difficult to compare their conditions before and after the spill. Researchers with the DEEPEND consortium are developing a quantitative, taxonomically comprehensive assessment of these deep-sea creatures to estimate their vulnerability and ability to recover from disturbances. The scientists led two research expeditions in 2017 and collected acoustic and physical oceanography data, 113 water samples, and over 10,000 specimens from net sampling.

Casting a Wide Net

6292b — The researchers used Neuston nets to conduct near-surface sampling. (Provided by DEEPEND)

DEEPEND Principle Investigator Dr. Tracey Sutton led the spring-time cruise, which began in Gulfport, Mississippi, and visited stations throughout the northern Gulf, including the Desoto Canyon. His team completed 17 deep-pelagic (surface to 1500 m depth) trawl deployments using the Multiple Opening/Closing Net and Environmental Sensing System (MOCNESS) plus CTD (conductivity, temperature, depth) and multibeam acoustical profiling. Researchers fitted the MOCNESS with an autonomous sonar (WideBand Autonomous Transceiver, WBAT), a new sensor capable of tracking the vertical migrations of individual organisms. Ship sonars can identify where organisms are by measuring sound that they reflect, but do not provide enough information to examine the individuals in each layer of the water column. Using the WBAT technology, the team gathered more detailed information about organisms near the net, which they compared to the information gathered by the ship’s sonar.

6292c — Tracey Sutton and April Cook filter a water sample for large organisms. (Provided by DEEPEND)

The researchers sorted each catch into major taxon (fishes, crustaceans, squids, and jellyfishes) and identified, measured, weighed, and collected tissue samples from target organisms. Specimens were then stored in ethanol, formalin, or frozen for use in future analyses. The team filtered water samples for microorganisms using sterile 0.45 micron filters and froze the samples for DNA extraction and sequencing at the Nova Southeastern University Oceanographic Center. Using the CTD collections, the team could determine where water masses were located, where maximum photosynthesis occurred, and where distinct microbial communities were located.

6292d — The team caught this Red Velvet Whalefish (Barbourisia rufa) between 600 – 1000 m and sampled it for stable isotope and genetic sequencing. (Provided by DEEPEND)

Consortium researcher Dr. Michelle Zapp Sluis led the summer ichthyoplankton cruise, which began at the Louisiana Universities Marine Consortium in Chauvin, Louisiana, and visited 47 stations throughout the Mississippi Canyon region. The researchers deployed bongo nets from the back of the boat to collect mesopelagic fish specimens (at ~100 meters depth, at night) and deployed Neuston nets from the side of the boat to collect fish larvae near the sea surface. Collections from nighttime deployments will help the team identify larvae and fishes that vertically migrate on a diel basis. Other collections included zooplankton and associated invertebrate taxa harvested from net contents and Sargassum seaweed for stable isotope analyses. The team will conduct genetic analyses on selected taxa of fishes (e.g., tunas) to confirm their identities.

Building on the Past to Inform the Future

6292e — Researchers caught this deep-sea bioluminescent jellyfish, a Three Helmet Jellyfish (Periphylla periphylla), in an oblique tow at 0 – 1500 m depth. (Provided by DEEPEND)

The expeditions are part of the consortium’s three-year sampling and analysis program. The program builds on the field and data management protocols of the NOAA-supported Offshore Nekton Sampling and Analysis Program (ONSAP) and the Deepwater Acoustics Program (DAP), which Sutton and consortium researcher Dr. Kevin Boswell designed and executed in 2010-2011 as part of NOAA’s Natural Resource Damage Assessment (NRDA).

According to Sutton, some of DEEPEND’s most important findings to date include: 1) a dramatic and persistent decline in the numbers of deep-pelagic fishes, shrimps, and squids since 2011; 2) the detection of continued hydrocarbon signatures in the ovaries of female fishes and shrimps, which might indicate a connection between the declines and the oil spill; and 3) the continued discovery of new species and new species’ occurrences in the deep Gulf, furthering the notion that the Gulf is among the world’s most diverse deep-water ecosystems. “One thing that astounds me on every cruise is how diverse the deep Gulf is,” said Sutton. “Despite this being our fifth deep-trawling cruise in addition to the 2011 work we did, we are still finding new things.”

Painting the Bigger Picture

6292f — The team rinses the bongo nets and record the flowmeter data. (Provided by DEEPEND)

The consortium plans to use samples and data from the two cruises for (1) community analysis and recruitment studies (what and how much lives where, how populations are replacing themselves); (2) genetic studies (did the oil spill change the genetic makeup of Gulf populations); (3) contaminant studies (are there still traces of Deepwater Horizon hydrocarbons in deep-sea animals); (4) physics studies (does the flow of water in the Gulf structure pelagic assemblages); and (5) a host of ecological studies (the food web structure of the deep Gulf and effects on reproduction).

The cruises also contribute to the education and outreach aspects of scientific research through DEEPEND’s Teacher-at-Sea program, daily blogs from scientists, and the growing collection of high-quality and often rare deep-sea photography by Dr. Danté Fenolio (available here on the DEEPEND website).

6292g — Researchers examine a bongo net catch. (Provided by DEEPEND)

Learn more about DEEPEND research:

Read: Discovering Vibrant, Dynamic Life in the Deep Gulf of Mexico
Visit the DEEPEND website and Facebook page

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This research was made possible in part by a grant from the Gulf of Mexico Research Initiative (GoMRI) to the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) consortium.

© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Lesson Plan (Grades 9-12): Deep-Sea Bioluminescence, Hydrothermal Vents, and Food Webs

Click to visit DEEPEND…

Free, downloadable classroom materials covering topics ranging from bioluminescence, marine environments, hydrothermal vents, food webs and Light in the deep sea – including curricula and experiment instructions.

Grades 9th – 12th
Bioluminescence
Candy Chemosynthesis
Hydrothermal Vent Food Web
Oceanographic Terms and Equipment
ROV in a Bag
Water-down Topographic Map
Marine Environments Teaching Module
Light in the Deep Sea
The BP Oil Spill and its aftermath, explored through art – presentation
The BP Oil Spill and its aftermath, explored through art – lesson plan
Adaptations Teaching Module

Visit DEEPEND’s Education/Outreach Program

Kids Blog Adult Blog

Visit our social media pages…

Lesson Plan (Grades 6-8): BP Oil Spill and Aftermath in Marine Environments

DEEPEND

Free, downloadable classroom materials covering topics ranging from the BP Oil Spill and its aftermath explored through art, marine environments, hydrothermal vents, food webs and light in the deep sea – including curricula and experiment instructions!

Grades 6th – 8th
Hydrothermal Vent Food Web
Light at the Bottom of the Deep, Dark Ocean?
Marine Environments Teaching Module
Light in the Deep Sea
The BP Oil Spill and its aftermath, explored through art – presentation
The BP Oil Spill and its aftermath, explored through art – lesson plan
Adaptations Teaching Module

Visit DEEPEND’s Education/Outreach Program

Kids Blog Adult Blog

Visit our social media pages…

Lesson Plan (K-5): “Taking Science Deeper” Deep-Sea Curricula, Activities, and Coloring Pages

Free, downloadable classroom materials covering topics ranging from bioluminescence to hydrothermal vent food webs and include curricula, experiment instructions, and coloring sheets!

Taking Science Deeper Activities
Grades K – 5

Coloring Sheet – Deep Red Medusa
Coloring Sheet – Deep Sea Squid
Coloring Sheet – Glass Squid
Coloring Sheet – Anglerfish
Coloring Sheet – Benthic Octopus
Coloring Sheet – Siphonophore

Visit DEEPEND’s Education/Outreach Program

Kids Blog Adult Blog

Visit our social media pages…

Smithsonian Features Research about the Gulf of Mexico’s Highly Diverse Deep-Sea Habitat

6280 — Astronesthes macropogon have a bioluminescent whisker-like sensory organ that attracts small prey into striking distance. (Photo by Dante´ Fenolio)

The Smithsonian’s Ocean Portal published an article about the diverse deep sea species found in the Gulf of Mexico following the Deepwater Horizon incident. The DEEPEND research consortium identified nearly 800 different species in Gulf waters, including 180 species not previously observed in the Gulf of Mexico region.

Read the article The Gulf of Mexico: A Deep-Sea Treasure Trove of Fishes to learn more about deep Gulf biodiversity and what factors researchers theorize may be the cause.

Learn why and how scientists study deep-sea organisms: Discovering Vibrant, Dynamic Life in the Deep Gulf of Mexico
Learn how researchers map and classify deep-sea organisms: Study Develops Biogeographic Classification of the World’s Deep Oceans

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GoMRI and the Smithsonian have a partnership to enhance oil spill science content on the Ocean Portal website.

This research was made possible in part by a grant from BP/The Gulf of Mexico Research Initiative (GoMRI) to the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) consortium.

The GoMRI is a 10-year independent research program established to study the effect, and the potential associated impact, of hydrocarbon releases on the environment and public health, as well as to develop improved spill mitigation, oil detection, characterization and remediation technologies. An independent and academic 20-member Research Board makes the funding and research direction decisions to ensure the intellectual quality, effectiveness and academic independence of the GoMRI research. All research data, findings and publications will be made publicly available. The program was established through a $500 million financial commitment from BP. For more information, visit https://gulfresearchinitiative.org/.

© Copyright 2010-2018 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Graphics: DEEPEND Photographic Timeline Highlights Deepsea Biodiversity

4892/5066 Researchers performed 99 trawl deployments (over 500 samples) during five Gulf of Mexico research cruises. The photographic timeline progresses through catches from different cruise trawls to highlight deepsea biodiversity, including some extremely rare deepsea species.

Explore the timeline here!

RFP-V Knap: Deep-sea Risk Assessment & Species Sensitivity

Researcher Anthony Hayden Knap

The Deep-sea Risk Assessment and species sensitivity to WAF, CEWAF and Dispersant project is lead by P.I. Anthony Hayden Knap, Texas A&M University.

Subsea injection of dispersants offers some significant benefits compared to the application of dispersants on the sea surface, for example access to the freshest and non-emulsified oil in the high turbulence environment, ability to reduce the volume of required dispersant by injecting it directly into the oil stream without the loss of the product, ability to operate day and night under a wider range of weather conditions, and availability of a large water mass to rapidly decrease the concentration of a dispersed oil intrusion. Although dispersant application at the sea surface has been extensively studied, more data are needed on the efficiency and environmental impacts of dispersed oil in the subsea to evaluate and document acceptability of this response technique.

We will test a series of deep sea organisms to the effect of specific individual hydrocarbons, as well as WAF, CEWAF and Dispersant. If successful, we are hoping to develop a new method for the effects of contaminants on marine organisms.

Click for access to GoMRI’s YouTube videos of RFP-V Projects…

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This project was funded by the Gulf of Mexico Research Initiative (GoMRI) in the RFP-V funding program.

DEEPEND Logs DP05 Cruise Through Kids Blog

4452 Following a short weather delay, the consortium kicked off its fifth research cruise, a two-week survey of Gulf of Mexico. The DEEPEND team has been posting updates on their progress to the project’s Kids Blog almost daily.

Visit the blog to catch up on the latest news.

DEEPEND Kids Blog

DEEPEND Outreach

Oceanography Highlights Findings from Deepwater Horizon Research

Cover of the September 2016 Oceanography Magazine, Volume 29, Number 3

7^th year of the largest coordinated research endeavor around an ocean event.

The 2010 Deepwater Horizon oil spill and subsequent response efforts raised concerns about impacts on the Gulf of Mexico’s ocean and coastal environments. The Gulf of Mexico Research Initiative (GoMRI), in response to the spill, initiated an unprecedented 10-year scientific research program funded by BP. Seven years into the program, we know more than ever before about the Gulf’s complex environment, dynamic processes, and response to stressors.

Oceanography magazine dedicated a special issue to this research, GoMRI: Deepwater Horizon Oil Spill and Ecosystem Science, and below are highlights from 13 papers it featured.*

WHERE OIL WENT

Surface oil covered a cumulative area of 149,000 km² in the northeastern Gulf. Wind and currents transported surface slicks towards land, affecting approximately 1,800-2,100 km of shoreline, a third of which were moderately to heavily oiled including 1,075 km in Louisiana. Macondo oil was visually evident at the edge of Louisiana marshes and up to 10 m inland.

Subsea oil and gas rose through the water column and formed an underwater oil plume that covered an area of approximately 930 km² and made direct contact with continental slope sediments. A significant proportion of surface oil returned to the deep seafloor primarily through an extensive marine oil snow sedimentation event known as a “dirty blizzard,” forming a 0.5-1.2 cm thick floc layer.

Cleanup efforts removed oil from 73% of beaches affected by the spill, but residual oil remained as surface residue balls (SRBs), submerged oil mats, and in marsh plants and sediment, and is subject to continued weathering, biodegradation, and possible resuspension.

HOW OIL CHANGED

Crude oils contain thousands of compounds that, upon entering a marine environment, undergo significant compositional changes from weathering processes such as evaporation, dissolution, emulsification, dispersion, sedimentation/flocculation, microbial degradation, and photooxidation.

Most crude oil compounds are readily biodegradable and generally follow a clear degradation pattern: n-alkanes first followed by branched alkanes, lower molecular weight aromatics, higher molecular weight aromatics, and cyclic alkanes. Anaerobic biodegradation is a slower process than aerobic degradation, and crude oil compounds can remain relatively unaltered in reduced sediments and environments for long time periods and may appear as relatively fresh oil compared to surface oil exposed to aerobic conditions.

MICROBIAL RESPONSE AFFECTING OIL FATE

Macondo oil had a relatively low content of persistent resins and asphaltenes, and warm temperatures supported geochemical and biological degradation. The prevalence of oil-degrading bacteria generated a prompt response from the microbial community and subsequent biodegradation. Microbial communities in the plume were different from those in non-plume waters and exhibited a significant enrichment of hydrocarbon-degrading metabolic genes. Aerobic oxidation of short chain alkanes, propane, and butane caused up to 70% of oxygen depletion observed in the oil plume.

Residual oil trapped in Pensacola Beach sands showed a progression of microbial populations linked to hydrocarbon degradation. Early-responder microbes were followed by populations capable of aromatic hydrocarbon decomposition. Microbial abundance in oiled sands was 10-10,000 times that in clean sands in the first four months after oil came ashore. A typical beach-environment microbial community returned after one year but differed significantly from pre-spill communities.

DEEP OCEAN IMPACTS

Carbon from the spill was likely incorporated into the mesopelagic (200-1,000 m depth) food web through consumption of prey rich in depleted carbon. The nature of microbial communities in the deep sea likely changed. An 80-93% decline in benthic foraminifera was related to reducing conditions and increased polycyclic aromatic hydrocarbons (PAH) concentrations.

Deepsea megafauna had lower diversity and abundance near the spill site relative to regions farther away, though blue marlin, Atlantic sailfish, blackfin tuna, and dolphinfish showed no significant reduction in larval abundance. Bottom-dwelling golden tilefish had the highest concentrations of naphthalene metabolite levels in bile measured in fishes globally. Tunas and jacks collected near the spill site exhibited developmental crude oil cardiotoxicity, suggesting a possible loss of early predator recruits that spawn in open waters. Sperm whale acoustic activity decreased near the spill site by a factor of two and increased farther away, suggesting they relocated.

Hard-bottom communities, including natural and artificial reefs, suffered injuries that were severe and long-lasting. Macrofauna and meiofauna diversity had not recovered after four years, and community structure differences still persist. Deep-sea colonial corals, in particular octocorals near the spill site, showed visible evidence of impact, and flocculent material covering the coral contained chemical fingerprints associated with Macondo oil and DOSS (dioctyl sodium sulfosuccinate). Researchers returned to these coral eight times and observed continued impacts such as tissue death with some coral skeletons secondarily colonized by hydrozoans.

Field measurements showed that planktonic community abundance and species composition returned to pre-spill conditions within a year. Laboratory experiments indicated that zooplankton exposed to sublethal crude oil levels bioaccumulated five PAHs, which could increase their susceptibility to predation and enhance trophic transfer of toxic PAHs.

MARSH IMPACTS

There were immediate negative impacts in moderately to heavily oiled marshes in southeastern Louisiana. The average concentration of total alkanes and PAHs in June 2013 was 20 and 374 times pre-oiled conditions, respectively. Total alkane concentrations were on a trajectory to be near baseline levels by 2015, but this did not occur likely a result of multiple resuspension events from storms.

Some damaged marsh shorelines showed precipitous shoreline erosion at least 2.5 years after oiling due to damaged root systems. Marshes lost due to oiling and shoreline erosion will not return without human intervention. Forty-two months after the spill, heavily oiled marshes showed near-complete plant mortality, and live aboveground biomass was 50% of reference marshes. Decreased living marsh vegetation and population levels of some fauna were obvious for 2-5 years. Meiofauna density was lower along with S. alterniflora grasses in heavily oiled areas.

Fiddler crab average size declined and there were proportion shifts in two species composition. Periwinkle snails density declined, and a slow recovery in abundance and size distribution was related to habitat recovery. Worms, seed shrimp, and mud dragons had not recovered to background levels 48 months post-spill. Killifish showed little evidence of spill impacts. Horse fly abundance declined sharply. Arthropods were suppressed by 50% in 2010 but had largely recovered in 2011. Seaside Sparrow nests on unoiled sites were more likely to fledge than those on oiled sites. Loons varied in frequency with PAHs by year and exhibited reduced body mass as PAH concentrations increased.

These effects are expected to continue – possibly for decades – to some degree, or the marsh ecosystem will reach a new baseline condition in heavily damaged areas.

FISH & SEAFOOD IMPACTS

Commercial, recreational, and subsistence fisheries were closed in fall 2010 in areas where oil was observed and predicted to travel and reopened by April 2011. Impacts on fisheries productivity were relatively short-lived, with landings and their values returning to pre-spill levels or greater for most fishery species. However, long-term effects are yet to be determined. Laboratory studies indicate that early life stages of fish are generally more sensitive to oil and dispersant’s sublethal effects (with some resulting in reduced swimming performance and cardiac function) than adults.

Public health risks from exposure to crude oil residue through seafood or coastal beaches returned to pre-spill levels after the spill dissipated. Seafood from reopened areas was found to be safe for consumption, with PAH levels comparable to those found in common local processed foods. PAH concentrations detected in many seafood samples during and following the spill were at least 2 orders of magnitude below levels of public health concern. DOSS was detected in less than 1% of samples and at levels below public health concern.

Tests on SRBs showed that Vibrio vulnificus were 10 times higher than the surrounding sand and up to 100 times higher than seawater, suggesting that SRBs can act as reservoirs for bacteria including human pathogens. Coquina clams initially showed higher PAH levels relative to the surrounding sand, but levels decreased continuously and were undetectable in sand (one year) and Coquina tissues (two years).

DISPERSANT EFFECTS & FUTURE TECHNOLOGIES

Dispersant increased the oil fraction that spread within the water column and laterally displaced oil that reached the sea surface. Dispersants reduced droplet sizes and rise velocities, resulting in a more than tenfold increase in the downstream length of the surface oil footprint.

Chemical dispersants may be more toxic to some marine organisms than previously thought, and small oil droplets created by dispersant use and directly consumed by marine organisms are often more toxic than crude oil alone. Dispersant effects on microorganisms might be taxa-specific, and some studies suggest that dispersants stimulated biodegradation while others conclude the opposite. Degradation rates of hexadecane and naphthalene were more rapid in the absence of dispersants, as was the overall removal of the water-accommodated oil fraction.

Dispersant applied at the broken riser pipe helped form a deep water oil plume. DOSS was likely transferred to the plume and was later detected in surface sediments, on corals, and within oil-sand patties.

A future option is development of plant-based materials for efficient chemical herding of compact oil slicks into layers that are sufficiently thick to enable oil burning or skimming. Opportunities exist for new dispersants that work in synergy with current dispersants and mitigate some of their disadvantages. Examples include a system containing soybean lecithin and the surfactant Tween 80, substitution of lecithin for DOSS, and using carbon-based particles and silicas to stabilize emulsified droplets. Laboratory research needs to be conducted at concentrations and under conditions relevant to marine environments.

MODELING CAPABILITIES

Model improvements provide a better understanding of droplet formation in the turbulent plume above the wellhead. No model during the spill could predict droplet size distribution, which dictates rise times, dissolution, and biodegradation. Oil spill models now include the ability to simulate the rise of a buoyant oil plume from the seabed to the surface. Consideration of oil’s 3D movement permits the prediction of oil spreading through subsurface plumes. Our understanding of the near-surface oceanic layer and atmospheric boundary layer, including the influences of waves and wind, has also improved.

Oil spill modeling routines will likely be included in Earth system models, linking physical models with marine sediment and biogeochemical components. Advances in coupled nearfield-farfield dynamic modeling together with real-time, seven-day circulation forecasts allow for near-real-time tracking and forecasting of oil dynamics. This is the most promising approach for rapid evaluation of blowout predictions to support first response decisions.

* Overton, E.B., T.L. Wade, J.R. Radović, B.M. Meyer, M.S. Miles, and S.R. Larter. 2016. Chemical composition of Macondo and other crude oils and compositional alterations during oil spills. Oceanography 29(3):50–63

Socolofsky, S.A., E.E. Adams, C.B. Paris, and D. Yang. 2016. How do oil, gas, and water interact near a subsea blowout? Oceanography 29(3):64–75

Passow, U., and R.D. Hetland. 2016. What happened to all of the oil? Oceanography 29(3):88–95

Özgökmen, T.M., E.P. Chassignet, C.N. Dawson, D. Dukhovskoy, G. Jacobs, J. Ledwell, O. Garcia-Pineda, I.R. MacDonald, S.L. Morey, M.J. Olascoaga, A.C. Poje, M. Reed, and J. Skancke. 2016. Over what area did the oil and gas spread during the 2010 Deepwater Horizon oil spill? Oceanography 29(3):96–107

John, V., C. Arnosti, J. Field, E. Kujawinski, and A. McCormick. 2016. The role of dispersants in oil spill remediation: Fundamental concepts, rationale for use, fate, and transport issues. Oceanography 29(3):108–117

Passow, U., and K. Ziervogel. 2016. Marine snow sedimented oil released during the Deepwater Horizon spill. Oceanography 29(3):118–125

Tarr, M.A., P. Zito, E.B. Overton, G.M. Olson, P.L. Adhikari, and C.M. Reddy. 2016. Weathering of oil spilled in the marine environment. Oceanography 29(3):126–135

Joye, S.B., S. Kleindienst, J.A. Gilbert, K.M. Handley, P. Weisenhorn, W.A. Overholt, and J.E. Kostka. 2016. Responses of microbial communities to hydrocarbon exposures. Oceanography 29(3):136–149

Rabalais, N.N., and R.E. Turner. 2016. Effects of the Deepwater Horizon oil spill on coastal marshes and associated organisms. Oceanography 29(3):150–159

Murawski, S.A., J.W. Fleeger, W.F. Patterson III, C. Hu, K. Daly, I. Romero, and G.A. Toro-Farmer. 2016. How did the Deepwater Horizon oil spill affect coastal and continental shelf ecosystems of the Gulf of Mexico? Oceanography 29(3):160–173

Buskey, E.J., H.K. White, and A.J. Esbaugh. 2016. Impact of oil spills on marine life in the Gulf of Mexico: Effects on plankton, nekton, and deep-sea benthos. Oceanography 29(3):174–181

Fisher, C.R., P.A. Montagna, and T.T. Sutton. 2016. How did the Deepwater Horizon oil spill impact deep-sea ecosystems? Oceanography 29(3):182–195

Dickey, R., and M. Huettel. 2016. Seafood and beach safety in the aftermath of the Deepwater Horizon oil spill. Oceanography 29(3):196–203

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© Copyright 2010- 2017 Gulf of Mexico Research Initiative (GoMRI) – All Rights Reserved. Redistribution is encouraged with acknowledgement to the Gulf of Mexico Research Initiative (GoMRI). Please credit images and/or videos as done in each article. Questions? Contact web-content editor Nilde “Maggie” Dannreuther, Northern Gulf Institute, Mississippi State University (maggied@ngi.msstate.edu).

Grad Student Girard Uses High-Definition Imagery to Assess Post-Spill Coral Recovery

Fanny digitizes a high-definition image of an impacted coral colony to quantify impacts, growth, and recovery. (Photo by Cherisse DuPreez)

Deep-sea corals are important organisms that support a healthy and diverse deep-sea ecosystem. However, there is much we do not know about certain coral species, including how they grow, reproduce, or interact with other organisms. Fanny Girard’s research helps bridge that knowledge gap through her work on how disturbances such as oil spills affect deep-sea coral colonies and if those effects have lasting impacts. She hopes that her research will underline the need to protect these important deep-sea ecosystems.

Fanny is a Ph.D. student in Pennsylvania State University’s biology program and a GoMRI Scholar with the Ecosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG) consortium.

Her Path

Fanny takes photos of corals in the ROV control van onboard the E/V Nautilus. (Photo credit: Ocean Exploration Trust)

Fanny grew up on the Mediterranean coast of southern France and developed a special affinity for the ocean. Her desire to work on ocean related issues started when she was eleven years old, scuba diving with her mother. While pursuing a biology bachelor’s degree at Pierre and Marie Curie University, Fanny explored marine mammal ecology during internships studying whale populations in Canada’s Gulf of St. Lawrence. Her graduate marine ecology studies at the University of Western Brittany included a course on the deep sea that inspired her to change direction. “Even though the deep sea is the largest ecosystem on earth, there is still so much to discover. That fact made me want to get involved in deep-sea research,” she said.

Fanny participated in various deep-sea research projects during her master’s work, including projects at the Institut Français de Recherche pour l’Exploitation de la Mer (IFREMER) in France and Dalhousie University in Halifax, Nova Scotia. Her master’s advisor introduced her to Pennsylvania State University’s Dr. Chuck Fisher, who offered her a Ph.D. position researching deep-sea corals for the ECOGIG project. “I had read about some of [Dr. Fisher’s work] in the Gulf of Mexico and was very excited about joining his lab,” said Fanny. “A lot of research still needs to be done to protect corals, and I really wanted to be part of this effort.”

An impacted coral imaged in 2011 (left) and 2016 (right). Part of this coral has visibly recovered, but most of the colony was still heavily impacted six years post-spill. (Image by Fanny Girard)

Her Work

Natural mortality is a rare event among deep-sea octocorals, also known as sea fans, whichhave the potential to act as sentinels for anthropogenic impacts. Fanny uses high-definition imagery to assess the Deepwater Horizon oil spill’s long-term impacts on octocorals.

Since 2010, her group’s lab has been monitoring hundreds of coral colonies at oil exposed and control sites. The team collects high-definition images of the same corals every year using ROV-mounted camera equipment. Fanny digitizes the images and identifies visible impacts to coral branches, including excess mucus, bare skeletons, and secondary colonization by hydroids. She compares the annual images to assess recovery over time and identifies factors potentially influencing recovery, which helps determine if the spill had delayed or long-term effects on the coral’s health and growth.

Her analyses suggest that while lightly-impacted corals have mostly recovered, many colonies are still unhealthy with little recovery evident. While deep-sea octocorals naturally grow extremely slowly, the growth of the impacted corals was barely detectable after six years, and significantly-impacted corals have lost branches continuously since 2011. Fanny recently authored a peer-reviewed article providing evidence that brittle stars, which live on and have a symbiotic relationship with coral colonies, appeared to protect and facilitate coral recovery.

Fanny stands in front of the ROV Global Explorer after a successful dive. She uses ROVs to image corals and collect different types of samples, including coral, water, and sediment. (Photo by Cherisse DuPreez)

The slow growth rates and abnormal branch loss that their team observed could indicate a lengthy post-oil spill recovery process. Fanny created a mathematical model that uses a matrix population model to project how many branches per coral colony will present as healthy, unhealthy, or colonized by hydroids and estimate recovery time. “The model suggests that it will take decades until all remaining branches appear healthy,” Fanny explained. “It will take another century until the lost branches have regrown.” She said that the long term image-based monitoring technique used in her research is an excellent tool to identify corals that suddenly become damaged or die, indicating an environmental disturbance.

Her Learning

Fanny experienced the most scientific growth while working with her advisors, Drs. Chuck Fisher and Iliana Baums, conducting field work aboard research cruises. Since beginning her Ph.D., she has participated in at least one research cruise each year and acted as chief scientist during a 2016 cruise. She says that the interdisciplinary nature of expeditions gave her a greater appreciation for other fields and introduced her to people who share her passion for the environment. The experiences taught her important skills for conducting research expeditions, such as coordinating between scientists, crew members, and ROV teams. “Making connections is extremely important for graduate students to find employers and identify future collaborations, but it can also be very difficult,” said Fanny. “I think being part of the GoMRI science community really facilitated that process.”

Her Future

Fanny plans to continue studying the deep sea and hopes her research can help protect and restore vulnerable ecosystems. She is considering post-doc opportunities, possibly in Europe, but is willing to travel anywhere for the right project. She advises students considering a scientific career to follow their passion, even if it seems difficult. As an undergraduate student, Fanny often expressed a desire to go on expeditions and study the ocean. However, most people dismissed her goals because of limited job opportunities and advised her to pursue a more mainstream profession. “I didn’t listen, and now I’m doing what I love,” she said. “I think if you are determined and love what you are doing, you will succeed.”

Praise for Fanny

Dr. Fisher said that Fanny has been an important asset to his team’s research since her first day. He explained that she developed the research methods used to demonstrate and quantify the brittle stars’ beneficial effects on oil-impacted coral’s recovery on her own. “Fanny is a pleasure to work with and has taken our research in new and exciting directions,” he said. “Most recently, she developed a mathematical model to predict the eventual fate of long-lived corals impacted by the oil spill.”

The GoMRI community embraces bright and dedicated students like Fanny Girard and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the ECOGIG website to learn more about their work.

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Smithsonian Features Luminous Critters Living in the Deep, Dark Gulf

Scientists are finding fascinating discoveries in the largely unknown deep waters of the Gulf of Mexico.

Some fishes, invertebrates, and bacteria have evolved a special adaptation to living in dark conditions using bioluminescence. What’s new is the discovery of specific bacteria species that live symbiotically on anglerfish and emit light.

The Smithsonian recently published an article about these anglerfish and bacteria based on research funded by the Gulf of Mexico Research Initiative (GoMRI). Scientists with the DEEPEND consortium comb through mountains of marine samples and microbial DNA sequence data to help us better understand risks when events like the Deepwater Horizon strike.

Read the article Meet the Tiny Bacteria That Give Anglerfishes Their Spooky Glow to find out how fish who don’t produce their own light pair up with bacterium that do.

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GoMRI and the Smithsonian have a partnership to enhance oil spill science content on the Ocean Portal website.

This research was made possible in part by a grant from BP/The Gulf of Mexico Research Initiative (GoMRI) to the Deep-Pelagic Nekton Dynamics of the Gulf of Mexico (DEEPEND) consortium. The GoMRI is a 10-year independent research program established to study the effect, and the potential associated impact, of hydrocarbon releases on the environment and public health, as well as to develop improved spill mitigation, oil detection, characterization and remediation technologies. An independent and academic 20-member Research Board makes the funding and research direction decisions to ensure the intellectual quality, effectiveness and academic independence of the GoMRI research. All research data, findings and publications will be made publicly available. The program was established through a $500 million financial commitment from BP. For more information, visit http://gulfresearchinitiative.org/.

Grad Student Max Weber Fishes for Insight into Deep-Pelagic Fish Taxonomy

Max removes tissue from a fish for future genetic analysis aboard the RV Point Sur. (Provided by Max Weber)

There are hundreds of deep-pelagic fish species in the Gulf of Mexico, but we know very little about their taxonomy, diversity, and population sizes. Max Weber plans to catch fifteen individual specimens of each of the 500 known deep-sea Gulf fish species to help us better understand these organisms and how the Deepwater Horizon oil spill may have impacted them and environment.

Max is a marine biology master’s student at Texas A&M University (TAMU) and a GoMRI Scholar with the DEEPEND consortium.

His Journey

Max’s desire to become a scientist started with his childhood obsession with dinosaurs, and he told others that he was going to be a paleontologist. “When I got a little older I realized that, while dinosaurs were still amazing, I preferred animals that were not extinct,” Max laughed. His interest turned to marine life and he became, and continues to be, an avid fisherman, motivated by his desire to catch new fish species.

He pursued his scientific interests as an undergraduate at Tulane University where he earned degrees in ecology and evolutionary biology. Prior to pursuing graduate school, he gained real-world experience and skills working with organizations such as San Diego Zoo’s Desert Tortoise Conservation Center and the Houston Audubon Society. The Society’s conservation director Richard Gibbons introduced him to TAMU’s Ron Eytan after discovering Max’s interest in fishery science. “Dr. Eytan offered me a position to work with DEEPEND,” Max said. “This presented a unique opportunity to work with amazing fish from the deep-sea environment that are rarely seen.”

His Work

Max presents his research on deep-sea fish genetic diversity at the 2016 Gulf of Mexico Oil Spill and Ecosystem Science Conference in Tampa, Florida. (Provided by Max Weber)

The remote and extreme physical conditions of the deep-sea environment have inhibited our understanding of deep-sea organisms’ biology and diversity. Scientists have some information about many deep-sea species from a handful of samples, which is rarely enough to understand their taxonomic relationships. Max explained that he is searching for DNA evidence that will help them learn more. “For example, males, females, and juveniles of the family Cetomimidae, usually called whalefishes, are strikingly different and were traditionally classified as three separate families of fish,” Max explained. “DNA evidence finally revealed the true nature of their relationship to one another.”

He and his colleagues collect fish specimens using a Multiple Opening/Closing Net and Environmental Sensing System (MOCNESS), a towed system of multiple automated nets that sample at specific depths. Max identifies the fishes caught, removes some tissue for gene sequencing, and keeps the rest of the fish as a voucher specimen. Back at the lab, he sequences portions of the mitochondrial genome to provide a standard DNA barcode for each sample.

Max explained that this genetic sequencing provides invaluable information and described the project’s first sequences as “a big milestone” and the foundation of his research. His analysis is revealing that a number of species may in fact be cryptic, meaning that they are actually two or three similar species that have been mistakenly classified as the same. He will use the gene sequencing data to investigate patterns of genetic and species diversity and changes in population size over time. This information will help illuminate long-term trends in the Gulf’s deep-sea environment.

His Learning

Anoplogaster cornuta or common fangtooth (Provided by Max Weber).

When beginning his research, Max found himself unexpectedly moved by the contents of the team’s first trawl. “I had seen some of the fish in photos before the cruise, but that was the first time I had encountered any of those rare fish in person,” he said. “As a group, deep-sea fishes are incredible and so different than what you see in other environments.”

He also emphasized the importance of perseverance in scientific research, explaining that lab procedures that have been perfected on common fishes do not always translate well to deep-sea populations. “One thing I am consistently learning is that science may not always go right the first time you try,” he said. “It is critical to have a good attitude and be persistent when your methods require several rounds of adjustment.”

His Future

Echiostoma barbatum (Provided by Max Weber).

Max is considering the possibility of pursuing a Ph.D. and hopes to ultimately find a job in fisheries. “I could go with industry- or university-based fisheries jobs but am leaning towards something in the sphere of a government agency,” he said. Max will complete his fourth research cruise in August and receive another round of sequence data shortly afterwards. He plans to continue analyzing this new data and complete his thesis by spring 2017.

Praise for Max

Max prepares for a dive. (Provided by Max Weber)

Dr. Ron Eytan, assistant professor of marine biology at TAMU Galveston, said that Max impressed everyone with the way he immersed himself in DEEPEND’s team, “Max walked into this project from day one without any background in genetics and took to it wholeheartedly with enthusiasm and confidence.” Eytan said it became apparent on Max’s first research cruise that he would push himself to his mental and physical limits to do what the project needed. “He walked in there; he didn’t get seasick; and he commenced to be on his feet for hours and hours taking genetic samples from fish having never done it before,” Eytan said. “He worked like a champ, and he’s done that every cruise since.”

Max’s work with deep sea species and genetic diversity expands and supports research that Eytan and other DEEPEND scientists are doing with fish genetics overall. “We know nothing about [the species Max investigates] whatsoever,” Eytan said. “His work will make a major contribution to our understanding about how genetic diversity works in the deep sea.”

The GoMRI community embraces bright and dedicated students like Max Weber and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals. Visit the DEEPEND website to learn more about their work.

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RFP-V Meneveau: Improving How Oil Spill Models Predict Plume Dispersion and Transport

A Large Eddy Simulation of oil droplet (color contours) and gas bubble (white lines) plumes emerging from 1500 m below the surface into a stratified ocean, including 3D Coriolis force and west-to-east current effects. (Simulation performed by Dr. Di Yang, University of Houston)

Deep ocean oil plumes that formed from the Deepwater Horizon spill and their subsequent rise through the water column were greatly influenced by physical mixing mechanisms such as turbulence, Langmuir circulations, and sub-mesoscale eddies.

These mixing processes are crucial variables needed for existing models to accurately predict a plume’s overall size, shape, and transport direction. Improving our understanding about these processes that affect a spill’s development can better inform response efforts.

The Gulf of Mexico Research Initiative recently awarded Dr. Charles Meneveau a grant to develop an enhanced Large Eddy Simulation (LES) framework for predicting multiscale physical dispersion mechanisms and estimating the effectiveness of remediation strategies. The framework will incorporate relevant length and time scales and address specific needs of oil droplet dispersion ocean modeling.

Different-sized oil droplets rise at varying rates and interact through mixing mechanisms in different ways. These physical interactions affect how parts of the plume move to the surface and create slicks of various shapes and sizes. If applied, chemical dispersants can reduce droplet diameters and alter a plume’s composition, biodegradation susceptibility, transport direction, size, and surface signature.

The team will adapt droplet size distribution models in LES that predict plumes with multiple-size oil droplets by including turbulence and dispersant effects on oil transport. A technique known as the Extended Nonperiodic Domain LES for Scalar transport (ENDLESS) will be developed to simulate oil plume transport in the ocean mixed layer at scales that can capture simultaneously small-scale turbulence and regional-scale transport that affect oil transport predictions. The results will improve how regional models trace oil droplet plume dispersion.

The researchers will use their model to also perform LES computations that analyze the efficacy and efficiency of deep-sea and surface dispersant application and impacts on oil plume evolution under varying application scenarios (location, quantity, type of dispersant) and environmental conditions.

Meneveau explained that this research will be used to develop engineering tools for rapid real-time assessment, helping to improve emergency response and spill monitoring, “Applying state-of-the-art enhanced simulation tools to the field of oil spill modeling will help develop fundamental new insights in a research area with direct applications to the challenges confronting the Gulf of Mexico region and the energy industry.”

The project’s researchers are Charles Meneveau of Johns Hopkins University, Marcelo Chamecki of University of California Los Angeles, and Di Yang of the University of Houston. Their project is Transport and Fate of Oil in the Upper Ocean: Studying and Modeling Multi-Scale Physical Dispersion Mechanisms and Remediation Strategies Using Large Eddy Simulation.

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Meet Undergraduate Students Cameron and Oscar!

Oscar and Cameron in front of a cylindrical tank that will be used to house samples. Photo Credit: ADDOMEx

Cameron Jackson, a sophomore, is studying marine biology Texas A&M University at Galveston (TAMUG) and Oscar Agueda is a senior who will be getting his degree in marine science (TAMUG); both students are minoring in chemistry. When asked about career aspirations they stated that they hoped to go on to graduate school. “I want to do deep-sea research; bioluminescence in particular is something that really interests me” says Cameron. Oscar, on the other hand, is more interested in ocean and environmental sciences “So I’m right where I need to be”.

Both students approached Dr. Peter Santschi and Dr. Kathy Schwehr of LOER lab (Laboratory for Oceanographic and Environmental Research) in hopes of gaining valuable research experience. Drs. Santschi and Schwehr are principal investigators for Aggregation and Degradation of Dispersants and Oil by Microbial Exopolymers (ADDOMEx) , one of several consortia that are funded by the Gulf of Mexico Research Initiative to research the impacts of oil spills on the marine environment.

Fitting the rods that will hold the cylindrical
tanks to the table. Photo Credit: ADDOMEx

The students have been working to build a roller table that will be used for a set of experiments conducted by ADDOMEx. Advice and specifications for the roller tables have been provided by Dr. Uta Passow, a fellow researcher from the University of California Santa Barbara.

The roller table will be used keep samples of phytoplankton and microbes in constant motion to study the formation of marine snow with and without the addition of oil and Corexit (a common dispersant used to treat oil spills).

“It’s like a shaker table, but for a cylindrical tank”, says Oscar.

“I think my dad put it best,” Cameron explains which a chuckle, “in that the roller table is essentially a glorified hot dog cooker at a convenience store. And this is really the perfect way to think about it because it continually rolls the tanks in a horizontal manner.”

“The roller tables will be used to mimic the movement of water in the ocean” says Cameron. “Stagnant water really doesn’t exist in the ocean, and using standing water in our experiments would create conditions that don’t accurately reflect what is happening in the ocean.”

“It’s been a challenge to invent ways to overcome little problems like ensuring that the screws, bolts, and mounts were the proper size” he goes on. “For the first three or four days I didn’t have a drill, so I put the frame together using a screwdriver. I actually broke the screwdriver.”

When asked how this project has changed their perspectives on how research is done, Cameron stated that he “always imagined that you just buy any instruments you might need, so being told to actually design and build the roller tables was a bit of a surprise.”

“I expected that we would be in the lab most of the time” said Oscar. “Instead we’ve been outside working on the table almost every day, but it’s been fun. I would definitely recommend working in a lab to other students, it looks great on your resume… just be prepared to get sweaty!”

According to Cameron you should “bring a pair of headphones”.
After finishing the roller tables, the students will be moving on to work that will include measuring the tensile strength and hydrophobicity/hydrophilicity of the exopolymeric substances that are produced by the study species of marine phytoplankton and microbes in upcoming experiments.

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Credit for this story: ADDOMEx

Teacher-At-Sea Chronicles DEEPEND Cruise

Science Selfie at Sea with Dr. Heather Bracken-Grissom onboard the DEEPEND Cruise (Image credit: DEEPEND)

Christia Hewlett was the official Teacher-At-Sea during the consortium’s most recent research cruise. She documented the equipment, experiences, and even the researchers on board for the DEEPEND blog. You can find all of her posts about the cruise here.

“I hope that I will be able to take back what I have learned and share it with generations of students; inspiring them to explore the world around them, ask questions and love science – especially marine science!”

Teacher At Sea,…. Christia Hewlett

Visit DEEPEND’s Education/Outreach Program

Kids Blog Adult Blog

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Discovering Vibrant, Dynamic Life in the Deep Gulf of Mexico

One of many fascinating creatures in the deep Gulf of Mexico is the Melanocetus johnsoni. This anglerfish has a fleshy growth from its head (the esca or illicium) that acts as a lure. (Photo by Dante Fenolio)

The Deep-Pelagic Nekton Dynamics (DEEPEND) consortium expands knowledge as a restoration tool for the Gulf’s largest ecosystem

Much uncertainty remains about impacts on the deep-sea environment from the 2010 oil spill that erupted more than 5,000 feet below the sea surface. However, knowing what was affected or what may change in the future is particularly difficult with little to no pre-existing knowledge about this obscure ecosystem. Environmental impact assessments of an area require some baseline of what lives and happens there.Scientists with the consortium Deep-Pelagic Nekton Dynamics of the Gulf of Mexico, or DEEPEND, are working to improve our understanding of the deep Gulf’s life and processes since the Deepwater Horizon oil spill. DEEPEND recently completed the first year of a multi-year Gulf of Mexico Research Initiative grant. Consortium director Tracey Sutton, Associate Professor and biological oceanographer at Nova Southeastern University, shared some thoughts about their project, goals, and accomplishments so far:

DEEPEND scientists conduct midwater trawling from the R/V Point Sur using an opening-closing MOCNESS trawl with a 10 m² mouth area. (Photo provided by DEEPEND)

The energy industry is working in deep realms that haven’t been censused properly. Our research will help us know more about the deep Gulf than we know about any deep-pelagic ecosystem on Earth. We can’t see it, we don’t fish much of it directly, but it really matters.

Learning About the Deep Gulf

Understanding why the deep Gulf matters is one of the main goals for the DEEPEND research team. Prior to this project, some members of the DEEPEND team were studying the world’s oceans and learned things that changed their understanding of deep-ocean life, as Sutton described:

The scientific community has likely underestimated the amount of deep-pelagic fish biomass in the world’s oceans by an order of magnitude. These deep fish mediate a lot of carbon transfer through their grazing and consumption of plankton. The number of species in the Gulf of Mexico is high, and we are finding new things all the time – it’s one of the most species-rich deep-pelagic ecosystems in the world.

To collect samples at deep depths, researchers use long lengths (2.5 miles!) of conducting cable on the R/V Point Sur. (Photo provided by DEEPEND)

The DEEPEND teams seeks to expand knowledge about the deep Gulf as a restoration tool for this immense and poorly understood system and, thereby, improve our ability to gauge its health. Being able to gauge the health of the Gulf is tied to understanding its deep-water biomass, which Sutton referred to as their “unit of currency” for ecological studies:

To track an ecosystem’s health, you have to track living carbon or biomass, from microscopic plant life and zooplankton to larvae and animals. We need to understand how much biomass is out there, where it is distributed, and how often it replaces itself.
The DEEPEND research project continues the work that NOAA contracted Sutton and colleagues to conduct as part of the 2010 Natural Resource Damage Assessment. Their team led an exploratory survey that included 230 sea days, collecting data from three Gulf domains: the bathypelagic, or “midnight zone” waters (>1000 m depth), the middle “twilight zone” waters (200-1000 m depth), and the epipelagic “surface zone” waters. They realized there was an enormous amount of basic science that had yet to be conducted.

The DEEPEND project expands their past work to determine the deep Gulf’s natural variability on an annual basis, a critical component needed to understand effects of a specific event like an oil spill. Sutton said that building upon that initial ten-month continuous data set from 2010 provides an unprecedented opportunity to understand a deep-ocean system in a larger context.

Deep Sea Explorations

DEEPEND researchers pull in the nets of the MOCNESS to see what they have collected. (Photo provided by DEEPEND)

The DEEPEND team completed four expeditions in 2015 and plan to do the same in 2016 and 2017 to assess the deep-pelagic community through sampling, acoustical sensing, modeling, and laboratory analyses. They sort, count, and weigh the majority of samples collected while onboard, prepping them for more detailed analyses later. So far, they have collected 2,275 fish samples and identified 375 taxonomic groups and 72 species. They expect to discover new species like they did last year with a new anglerfish Lasiognathus dinema and a new dragonfish.

Hydroacoustics transducer (left) and transducer in sensing mode (boom lowered) on R/V Point Sur during DEEPEND cruise. (Photo provided by DEEPEND)

Researchers will use acoustic sensing data to identify layers of fish and their horizontal and vertical distribution at specific depths, which will help them see large scale patterns of biomass. They want to make their data available as soon as possible, especially for their biophysical modelers who will help them identify drivers of variability and investigate possible effects from the spill on ecosystem attributes.

Knowing where to collect samples in the deep ocean is challenging. Sutton described the surface as looking like one big mass of blue water, but underneath there is a lot of physical movement and structure. That is where the DEEPEND partners at the Naval Research Laboratory with their advanced computational models come into play. They tell the researchers what the sea conditions will be so they can collect samples across large physical features such as eddies and Mississippi River flows.

Data to Assess Change

Pachystomias microdon, the smalltooth dragonfish, is one of the few creatures on Earth who can produce red light. (Photo by Dante´ Fenolio)

The team will use data obtained during the 2010-2011 and 2015-2017 periods to establish time-series data for detecting ecosystem shifts or responses. According to Sutton, the DEEPEND project should produce enough data to model variability, which is rare for a deep system:

We hope to establish a kind of bellwether for the Gulf’s overall health and inspire long-term monitoring efforts. These datasets will help us detect change. Our best shot for understanding the impact of an event is to understand what drives natural variability, the backdrop for detecting specific change.

A juvenile blue marlin. Shelf and slope waters in the Deepwater Horizon spill area serve as critical spawning, nursery, and foraging habitat of several important oceanic species (billfishes, tunas, swordfish, dolphinfishes). Ichthyoplankton surveys will help DEEPEND investigate potential ecological effects of the spill on early-life stages of pelagic fishes. (Photo provided by Jay Rooker)

The DEEPEND team is also seeking to understand the connectivity of the Gulf with the Atlantic Ocean basin. Sutton explained how this ties to assessment:

When looking at the impact of a specific event like an oil spill, you need to know if the things that live in the Gulf are residents or if they are part of a larger continuum of life that flux into and out of the Gulf. These are two very different things for assessment. If something is a resident, an event such as an oil spill could denude a whole population, and it would take time for it to replace itself.

Following the Gene Flow

The DEEPEND genetic studies are an important component to understanding life in the deep Gulf. Researchers will assign most samples a genetic barcode or fingerprint and then run a full genome sequence on selected model species. The team will look at the basic connectivity of individuals within a larger population, and genetically match an early life stage of one thing to an older life stage of something that might look quite different. This research will help improve understanding about the genetic diversity in deep sea populations, and Sutton explained how this improves impact assessment:

DEEPEND researchers found a new species of deep-sea anglerfish, Lasiognathus dinema, between 1,000-1,500 meters depth in the northern Gulf of Mexico (Pietsch and Sutton, 2015). Newsweek chose this species as one of the top 20 new species discovered in 2015. (Photo by Theodore Pietsch)

Assessing genetic diversity plays a key role in evaluating the status of populations and in conservation and management efforts. We can determine genetically if a population has undergone a recent drastic reduction of numbers. We will examine if the oil spill impacted population sizes of fishes and invertebrate species enough to cause a reduction in their genetic diversity.

Sharing Science Discoveries

The DEEPEND team will share their research with several audiences: the scientific community, the formal education community, and the broader public through private sector groups such as the San Antonio Zoo and the Oregon Coast Aquarium. The team is creating an image and genetic atlas of Gulf of Mexico fish, larvae, and microbes with over 7,000 samples photographed. Sutton explained why their group is particularly excited about outreach:

Squid Abralia redfieldi. (Photo by Dante´ Fenolio)

Deep-water environments have this “Jacques Cousteau” appeal. Apart from space, it’s one of the few places where we have a real shot at seeing something brand new, something that likely has huge teeth and light organs. We want to share our discoveries so people will know that the ocean is full of an amazing variety of life.

They already have experienced great success at reaching large student groups through the help of their partners at Whale Times, who developed an experiential online classroom event “Creep into the DEEPEND.” Last year 7,000+ students enrolled, and they and their teachers became Virtual Science Team Members. The outreach team plans to build on this success, as Sutton described:

Astronesthes macropogon have a bioluminescent whisker-like sensory organ that attracts small prey into striking distance. (Photo by Dante´ Fenolio)

There’s no better way to get the word out than to show people what’s down there. Creep into the DEEPEND used our activities, photos, videos, Skype interviews, and SeaMail to help students and teachers discover Gulf animals, research, and scientists. This year, we will offer 20+ Creep into the DEEPEND Summer Camp classes to 12 museums/science centers. There is plenty of fascination with science, and I think there is a little scientist in everybody.

Scientist Danté Fenolio, the DEEPEND photographer, has a new book that will be released soon that credits the consortium’s work: Life in the Dark: Illuminating Biodiversity in the Shadowy Haunts of Planet Earth.

Team DEEPEND

Dr. Tracey Sutton, director of the DEEPEND consortium. (Photo provided by DEEPEND)

Sutton considers one of the most valuable aspects of the DEEPEND consortium to be the many scientists who work together on different components towards a common goal. This diverse research group can ask better questions – and find better answers – than if they worked separately.

The DEEPEND project’s member institutions include Nova Southeastern University, Florida International University, the Naval Research Laboratory, Texas A&M University Galveston, the University of South Florida, the University of South Florida St. Petersburg, Florida Atlantic University, NOAA, Stony Brook University, the University of Illinois at Urbana-Champaign, the San Antonio Zoo, Durango Multimedia, Resphera Biosciences, and Whale Times . Click here for a list of individual participants and roles.

For more information about the DEEPEND program, click here or visit the DEEPEND website.

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Grad Student Dannenberg is Unlocking Mysteries of Deepwater Coral Communities

Richard Dannenberg on the R/V Falcor during an ROV dive to study Gulf coral beds. (Image credit: Schmidt Ocean Institute)

Deep below the surface of the Gulf of Mexico live vast canyons of coral. Recent news reports suggest that the Deepwater Horizon oil spill may have impacted the health of these corals.

To find out, Richard Dannenberg is delving into their world, looking at the bacteria that live with the coral for clues about that potential damage. He explains, “If we can get a sense of which bacteria are important and what their roles in the ecosystem are, we can use this to assess some effects of oil spills that might not be apparent from visual inspection of the corals.”

Rich is a GoMRI scholar with ECOGIG, working towards his Ph.D. in biology at Pennsylvania State University (PSU). He talks about the road that led him to the bottom of the Gulf and where he hopes it will lead.

His Path

Rich became interested in the deep sea during an undergraduate bioorganic chemistry course. The combination of a group assignment examining the life forms around hydrothermal vents pouring hot, mineral-rich fluids from beneath the seafloor and an in-class viewing of The Blue Planet—a mini-series detailing our oceans’ natural history—changed his life. “I was instantly hooked,” he recalls. “I knew that I could happily study the deep sea for the rest of my life.”

ROV pilot Toshi Mikagawa (center), and Samantha Berlet (right) wear 3D glasses to view live footage of coral beds deep beneath the Gulf. (Photo provided by Rich Dannenberg)

At first, his desires were no more specific than deep-sea research. But while touring graduate programs, he visited Dr. Chuck Fisher, a biologist at PSU and a co-Principal Investigator studying corals as part of the ECOGIG’s oil spill research project. Rich talked with the Fisher lab team about their work and found himself intrigued by how deep-sea corals managed to get enough energy without the sun-dependent algae that shallow-water corals use. Although he considered other graduate programs, he could not get the possibility of conducting coral research out of his mind.

Rich became involved with ECOGIG in his first year of his doctoral program at PSU, joining an expedition to look at long-term effects of the oil spill. He was the only graduate student chosen to help Fisher collect underwater imagery of deep-water coral beds on that mission. Rich describes this introduction to field research as “a great learning experience and a lot of work, but a lot of fun too.”

His Work

Rich records data about the phenotypes of black corals collected in the Gulf. (Photo provided by Rich Dannenberg)

It’s easy to tell if corals are dead, Rich said, but hard to know when they’re sick or damaged other than finding dead polyps on them. The goal is to better understand the health of the broader environment by examining changes in the surrounding bacterial community. Doing so could uncover valuable ways to assess coral damage in its earliest stages, which could possibly lead to a reversal of the process. But that is no easy task either as Rich explains, “We currently know next-to-nothing about the functions of bacterial communities in deep-sea corals.”

To bridge that knowledge gap, Rich is conducting both field and lab studies on two groups of corals. For one group, the Paramuricea coral, he does not collect samples. Instead he leaves those corals on the seafloor, and each year, Rich and his team return to photograph and monitor their condition, being careful to not touch them. He collected four colonies of the other coral group, Leiopathes, from the Mississippi Canyon and Atwater Valley in the Gulf and brought them back to the lab for live study.

After acclimating the coral to the lab environment, he cut them into smaller fragments and put each fragment in a tube with different concentrations of either oil, dispersant, both, or neither to see how the coral responded to contaminants. Rich then analyzed the bacteria on the coral, detailing each bacterium’s entire genetic information to identify differences at the gene-level. This process shows how the bacterial community reacts to the different treatments, giving insight about impacts to the corals’ health. “If I see a consistent group of bacteria present within all samples from this species,” he explains, “I can start to look at other species and other locations to see how specific the coral-bacterial associations are.”

His Learning

Penn State students Richard Dannenberg and Samantha Berlet work on either side of ROV pilot Jamie Sherwood during an ROV dive aboard the R/V Falcor. (Image credit: Debbie Nail Meyer)

Rich has been most impressed with the ECOGIG scientists’ profound sense of community, especially among the small group of deep-sea researchers. His first expedition was especially eye-opening in that regard. “Collaboration is everywhere, especially on cruises,” he said, “there is absolutely no way any individual researcher would get their work done without at least some help from those around them.” On board, he had the opportunity to assist world famous researchers with their work, but there was the flip side of that as well, “Having a ship full of researchers meant that whenever I needed help with something, I could reliably count on that help magically appearing.”

That spirit of collaboration went beyond field work, as Rich explained, “At virtually every scientific gathering, I’ve been surprised by how many good ideas come from just talking about my work to other scientists. And that sounds pretty obvious, since that’s why these scientific gatherings happen in the first place, but to me the degree to which interacting with others can foster a positive change in my thinking and research was always surprising.”

Rich has also learned the importance of doing work you love, “If you try to force an interest in something you’ll end up losing motivation very quickly, but passion can carry you through almost anything, giving you the willpower to work harder than you ever thought you could.”

His Future

Rich is on the fence about where he will wind up after completing his Ph.D. While he enjoys academia’s balance of research and teaching, he is also interested in a government position or working in industry. Until he decides, his focus remains on data collection and on his upcoming wedding.

Praise for Richard

Rich’s advisors, Chuck Fisher and Iliana Baums of PSU, expressed confidence that his research will play an important role in helping scientists understand how deep-water corals respond to stress. “His project is quite ambitious,” Baums said and noted the large scale of Rich’s study, “starting with a description of the yet uncharacterized microbiome of deep sea corals and then investigating how this population of microbes changes in response to oil and dispersant exposure.” Fisher and Baums explained that while this topic has received little attention in the past, it has become increasingly clear that single-celled organisms living near the coral play an important role in determining the health and resilience of the entire community.

Fisher added that much of the project’s success is due to Rich’s adaptability. “Rich has overcome a number of unexpected and rather major challenges while developing his methods and is now generating very interesting data on this cutting-edge subject.”

The GoMRI community embraces bright and dedicated students like Richard Dannenberg and their important contributions. The GoMRI Scholars Program recognizes graduate students whose work focuses on GoMRI-funded projects and builds community for the next generation of ocean science professionals.

Visit the ECOGIG website to learn more about their work.

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This research was made possible in part by a grant from BP/The Gulf of Mexico Research Initiative (GoMRI) to theEcosystem Impacts of Oil and Gas Inputs to the Gulf (ECOGIG) consortium.

Educators Dive into ROV Training and Emerge with Innovative Teaching Tools

Fairview High School teacher Stephanie Chambers navigates an underwater ROV while out at sea aboard DISL’s R/V Alabama-Discovery. (Photo credit: Tina Miller-Way, DISL)

Ten high school teachers from Alabama and Florida are returning to their 2013-2014 science classes armed with new skills, materials, and inspiration. In July, these educators attended a five-day workshop entitled Technology in Marine Science. They built and operated Remotely Operated Vehicles (ROVs) and, more importantly, learned how to use them as teaching tools in their classrooms. Throughout the coming year, the teachers will help their students design, build, and test their own ROVs and prepare them for spring competition.

The Dauphin Island Sea Lab (DISL) directs and hosts this and other teacher workshops as part of a larger education effort by the Deep Sea to Coast Connectivity in the Eastern Gulf of Mexico (Deep-C) research consortium. Their goal is to incorporate oil-spill related research – a topic of high public interest – into classrooms and assist teachers and students in understanding and using this relevant research and associated scientific and engineering concepts as well as a means to further Science, Technology, Engineering, and Mathematics (STEM) education.

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The Kids and the Cups – Teaching Oceanography Using Styrofoam

Laura Spencer, a graduate student in Dr. Steven DiMarco’s lab at Texas A&M University, took cups from three classrooms with her on the Gulf Integrated Spill Research Tracer cruise (G03) in the Gulf of Mexico. The cups were lowered in the water on one of the CTD casts. When the CDT was raised, the 5 inch cups shrank to half their original size.

Dr. Steve DiMarco and his graduate student, Laura Spencer, visited two of the classes on 30 April 2013. The cups were returned to the students.

“Why do they shrink?” asked one of the students.

DiMarco used the cup demonstration to explain the property of pressure in the ocean to the students. The pressure on Earth’s surface is approximately 14.7 pounds per square inch. When the cup is lowered 3000 feet into the Gulf, pressure increased approximately Certificate100 times that of Earth’s surface, squeezing all the air out of the cup and reducing it to half its original size.

DiMarco presented a slide show to the students discussing the Deepwater Horizon oil spill. Topics included the fate of oil from the spill, effects of the oil spill on the Gulf ecosystem and what the Gulf Integrated Spill Research (GISR) consortium hopes to discover from their current research in the Gulf of Mexico. Spencer, who participated in the two GISR tracer cruises (G02 and G03), described what is was like to spend a month at sea doing research. The students were fascinated to learn about life at sea.

DiMarco and Spencer presented the students with certificates for participating as “student oceanographers” in the GISR G03 cruise.