DISCOVRE: Diversity, Systematics and Connectivity of Vulnerable Reef Ecosystems Active
June is Oceans Month!
USGS is paving the way for exploration and scientific discovery in the largest ecosystem on our planet: the deep sea.
DEEP SEARCH: The Final Leg
USGS scientists mapped and collected data from deep-sea environments off the U.S. Southeastern coast
Deep-Sea EXPRESS
USGS scientists join multi-agency expedition to study deep-sea reefs and associated habitats off the U.S. West Coast
Deep Sea Discovery
USGS joins partners in discovery of 85-mile-long coral reef off the coast of South Carolina
DISCOVRE (DIversity, Systematics and COnnectivity of Vulnerable Reef Ecosystems) is an integrated, multidisciplinary, international effort investigating the unique and fragile deep-sea coral environments from the microscopic level to the ecosystem level.
Deep-Sea Coral Resources
Check out the links below for more information on deep-sea corals.
The Deep Sea
The deep sea refers to anything below 200 m depth in the ocean; beyond this depth, little to no sunlight reaches, temperatures drop, and pressure increases. Yet, life persists. Diverse environments, such as trenches, canyons, volcanoes, and seamounts, scattered over the seafloor are home to a diversity of fishes, crustaceans, anemones, sea stars, and corals.
Deep-sea corals are as colorful and diverse as their shallow-water counterparts, however, because of the lack of sunlight, deepwater corals obtain energy by using their tentacles to capture prey rather than through photosynthesis. Deep-sea coral reefs provide food and shelter for marine life, including commercially and recreationally important species, and play a critical role in the aquatic food web.
To better understand these little explored yet vital deep-sea coral reef ecosystems, USGS scientists from around the Nation contribute their expertise to the DISCOVRE effort. The multi-disciplinary approach examines components of microbiology, population genetics, paleoecology, food webs, taxonomy, community ecology, physical oceanography, seafloor characteristics, and submarine hazards. DISCOVRE relies on a network of partners from around the country and world, including the Bureau of Ocean Energy Management, National Oceanic and Atmospheric Administration (NOAA), and academic institutions. Using innovative tools and technologies, USGS scientists implement a multi-faceted research program that weaves together expertise in a variety of disciplines to investigate deepwater reefs.
Benthic Ecology
Benthic ecology is the term scientists use to describe the study of the animals living in or on the bottom of a water body. As part of the DISCOVRE project, the Benthic Ecology Group conducts research to understand community structure, biodiversity, trophic structure, and habitat connectivity of marine benthic ecosystems. The work involves examining the animals living in and on the seafloor in a variety of natural and artificial marine habitats:
- deep-sea and shallow-water corals,
- chemosynthetic seeps,
- shipwrecks,
- marine canyons, and
- wetland communities.
Marine Geology and Geophysics
Geology and geophysics refer to the study of physical structure and associated processes occurring on the planet. The USGS marine geology and geophysics team maps seafloor morphology and images the shallow sub-seafloor structure of the canyons, plateaus, and other components of the deep-sea landscape to better understand the processes that form and shape these features. Sampling sediment and rocks allows scientists to ground truth geophysical and visual observations, while providing valuable information about the composition and age of these underwater geologic environments.
Microbial Ecology
Microbial ecology is the study of microbes (bacteria, archaea, fungi, viruses), how they interact with each other, their host (if they are living on/in a plant or animal), and their environment.
Microbes are responsible for important ecosystem services, including biogeochemical cycling, nutrient availability, and structuring ecosystems by providing settlement cues to some invertebrates. Microbial associates have been shown to be key players in coral biology, serving functions such as fixing nitrogen, chelating iron, cycling waste products, and producing antibiotics to keep unwanted microbes from infecting the coral.
USGS identifies, characterizes, and enumerates environmental microbial communities, which are critical components of healthy marine ecosystems such as coral reefs, chemosynthetic seeps, and submarine canyons, with focus on coral microbiomes (both shallow and deep-sea), ecosystem metagenomics, and biodiversity.
Characterizing the microbial communities associated with deep-sea corals in these environments will increase the knowledge of the biodiversity in these ecosystems and provide insight into the variability or uniqueness of the corals between deep-sea environments.
Paleoclimatology
Paleoclimatology is the study of past climates using evidence found in a variety of the Earth's surfaces. USGS scientists are using long-lived black corals as archives to determine the climate and ocean chemistry over hundreds to thousands of years. Deep-sea corals are extremely useful in determining past climates, and recent developments in coral sampling techniques, as well as the ability to study corals in a wide variety of geographic areas, has increased the value of using deep-sea corals for climate change studies. Coral skeletons have rings, similar to trees, that help scientists determine environmental cycles and ocean variability.
Population Genetics
Population genetics is the study of genetic variation within and between populations. Understanding how the biodiversity of corals and other invertebrates is distributed throughout the deep-sea environment can help guide management of sensitive species, especially in areas of interest to oil and gas exploration. USGS uses genetic tools to characterize biodiversity and local and regional patterns of genetic connectivity among deep-sea coral habitats.
For more information:
CSA Ocean Sciences Inc. Ross S, Brooke S, Baird E, Coykendall E, Davies A, Demopoulos A, France S, Kellogg C, Mather R, Mienis F, Morrison C, Prouty N, Roark B, Robertson C. 2017. Exploration and Research of Mid-Atlantic Deepwater Hard Bottom Habitats and Shipwrecks with Emphasis on Canyons and Coral Communities: Atlantic Deepwater Canyons Study. Draft Report. Sterling (VA): U.S. Dept. of the Interior, Bureau of Ocean Energy Management, Atlantic OCS Region. OCS Study BOEM 2017-060. 1,000 p. + apps.
Below are science projects associated with DISCOVRE.
Below are publications associated with this project.
Focused fluid flow and methane venting along the Queen Charlotte fault, offshore Alaska (USA) and British Columbia (Canada)
Paleoclimate ocean conditions shaped the evolution of corals and their skeletal composition through deep time
Distribution of deep-water scleractinian and stylasterid corals across abiotic environmental gradients on three seamounts in the Anegada Passage
Cascadia Margin cold seeps: Subduction zone fluids, gas hydrates, and chemosynthetic habitats
Mapping, exploration, and characterization of the California continental margin and associated features from the California-Oregon border to Ensenada, Mexico
Molecular indicators of methane metabolisms at cold seeps along the United States Atlantic margin
Submarine canyons influence macrofaunal diversity and density patterns in the deep-sea benthos
Benthic infaunal communities of Baltimore and Norfolk Canyons
Quantifying changes to infaunal communities associated with several deep-sea coral habitats in the Gulf of Mexico and their potential recovery from the DWH oil spill
Microbiomes of stony and soft deep-sea corals share rare core bacteria
Examination of Bathymodiolus childressi nutritional sources, isotopic niches, and food-web linkages at two seeps in the US Atlantic margin using stable isotope analysis and mixing models
Windows to the deep 2018: Exploration of the southeast US Continental margin
Below are news stories associated with this project.
Below are partners associated with this project.
- Overview
DISCOVRE (DIversity, Systematics and COnnectivity of Vulnerable Reef Ecosystems) is an integrated, multidisciplinary, international effort investigating the unique and fragile deep-sea coral environments from the microscopic level to the ecosystem level.
Deep-Sea Coral ResourcesCheck out the links below for more information on deep-sea corals.
The Deep Sea
The deep sea refers to anything below 200 m depth in the ocean; beyond this depth, little to no sunlight reaches, temperatures drop, and pressure increases. Yet, life persists. Diverse environments, such as trenches, canyons, volcanoes, and seamounts, scattered over the seafloor are home to a diversity of fishes, crustaceans, anemones, sea stars, and corals.
Deep-sea corals are as colorful and diverse as their shallow-water counterparts, however, because of the lack of sunlight, deepwater corals obtain energy by using their tentacles to capture prey rather than through photosynthesis. Deep-sea coral reefs provide food and shelter for marine life, including commercially and recreationally important species, and play a critical role in the aquatic food web.
To better understand these little explored yet vital deep-sea coral reef ecosystems, USGS scientists from around the Nation contribute their expertise to the DISCOVRE effort. The multi-disciplinary approach examines components of microbiology, population genetics, paleoecology, food webs, taxonomy, community ecology, physical oceanography, seafloor characteristics, and submarine hazards. DISCOVRE relies on a network of partners from around the country and world, including the Bureau of Ocean Energy Management, National Oceanic and Atmospheric Administration (NOAA), and academic institutions. Using innovative tools and technologies, USGS scientists implement a multi-faceted research program that weaves together expertise in a variety of disciplines to investigate deepwater reefs.
Benthic Ecology
Benthic ecology is the term scientists use to describe the study of the animals living in or on the bottom of a water body. As part of the DISCOVRE project, the Benthic Ecology Group conducts research to understand community structure, biodiversity, trophic structure, and habitat connectivity of marine benthic ecosystems. The work involves examining the animals living in and on the seafloor in a variety of natural and artificial marine habitats:
- deep-sea and shallow-water corals,
- chemosynthetic seeps,
- shipwrecks,
- marine canyons, and
- wetland communities.
Marine Geology and Geophysics
Geology and geophysics refer to the study of physical structure and associated processes occurring on the planet. The USGS marine geology and geophysics team maps seafloor morphology and images the shallow sub-seafloor structure of the canyons, plateaus, and other components of the deep-sea landscape to better understand the processes that form and shape these features. Sampling sediment and rocks allows scientists to ground truth geophysical and visual observations, while providing valuable information about the composition and age of these underwater geologic environments.
Microbial Ecology
Microbial ecology is the study of microbes (bacteria, archaea, fungi, viruses), how they interact with each other, their host (if they are living on/in a plant or animal), and their environment.
Microbes are responsible for important ecosystem services, including biogeochemical cycling, nutrient availability, and structuring ecosystems by providing settlement cues to some invertebrates. Microbial associates have been shown to be key players in coral biology, serving functions such as fixing nitrogen, chelating iron, cycling waste products, and producing antibiotics to keep unwanted microbes from infecting the coral.
USGS identifies, characterizes, and enumerates environmental microbial communities, which are critical components of healthy marine ecosystems such as coral reefs, chemosynthetic seeps, and submarine canyons, with focus on coral microbiomes (both shallow and deep-sea), ecosystem metagenomics, and biodiversity.
Characterizing the microbial communities associated with deep-sea corals in these environments will increase the knowledge of the biodiversity in these ecosystems and provide insight into the variability or uniqueness of the corals between deep-sea environments.
Paleoclimatology
Paleoclimatology is the study of past climates using evidence found in a variety of the Earth's surfaces. USGS scientists are using long-lived black corals as archives to determine the climate and ocean chemistry over hundreds to thousands of years. Deep-sea corals are extremely useful in determining past climates, and recent developments in coral sampling techniques, as well as the ability to study corals in a wide variety of geographic areas, has increased the value of using deep-sea corals for climate change studies. Coral skeletons have rings, similar to trees, that help scientists determine environmental cycles and ocean variability.
Population Genetics
Population genetics is the study of genetic variation within and between populations. Understanding how the biodiversity of corals and other invertebrates is distributed throughout the deep-sea environment can help guide management of sensitive species, especially in areas of interest to oil and gas exploration. USGS uses genetic tools to characterize biodiversity and local and regional patterns of genetic connectivity among deep-sea coral habitats.
For more information:
CSA Ocean Sciences Inc. Ross S, Brooke S, Baird E, Coykendall E, Davies A, Demopoulos A, France S, Kellogg C, Mather R, Mienis F, Morrison C, Prouty N, Roark B, Robertson C. 2017. Exploration and Research of Mid-Atlantic Deepwater Hard Bottom Habitats and Shipwrecks with Emphasis on Canyons and Coral Communities: Atlantic Deepwater Canyons Study. Draft Report. Sterling (VA): U.S. Dept. of the Interior, Bureau of Ocean Energy Management, Atlantic OCS Region. OCS Study BOEM 2017-060. 1,000 p. + apps.
- Science
Below are science projects associated with DISCOVRE.
- Publications
Below are publications associated with this project.
Filter Total Items: 103Focused fluid flow and methane venting along the Queen Charlotte fault, offshore Alaska (USA) and British Columbia (Canada)
Fluid seepage along obliquely deforming plate boundaries can be an important indicator of crustal permeability and influence on fault-zone mechanics and hydrocarbon migration. The ~850-km-long Queen Charlotte fault (QCF) is the dominant structure along the right-lateral transform boundary that separates the Pacific and North American tectonic plates offshore southeastern Alaska (USA) and western BAuthorsNancy G. Prouty, Daniel S. Brothers, Jared W. Kluesner, J. Vaughn Barrie, Brian D. Andrews, Rachel Lauer, Gary Greene, James E. Conrad, Thomas Lorenson, Michael D. Law, Diana Sahy, Kim Conway, Mary McGann, Peter DartnellPaleoclimate ocean conditions shaped the evolution of corals and their skeletal composition through deep time
Identifying how past environmental conditions shaped the evolution of corals and their skeletal traits provides a framework for predicting their persistence and that of their non-calcifying relatives under impending global warming and ocean acidification. Here we show that ocean geochemistry, particularly aragonite–calcite seas, drives patterns of morphological evolution in anthozoans (corals, seaAuthorsAndrea M. Quattrini, Eliana Rodriguez-Burgueno, B. C. Faircloth, P. Cowman, M. R. Brugler, G. Farfan, M. E. Hellberg, M. V. Kitahara, Cheryl Morrison, D. A. Paz-Garcia, J. D. Reimer, C. S. McFaddenDistribution of deep-water scleractinian and stylasterid corals across abiotic environmental gradients on three seamounts in the Anegada Passage
In the Caribbean Basin the distribution and diversity patterns of deep-sea scleractinian corals and stylasterid hydrocorals are poorly known compared to their shallow-water relatives. In this study, we examined species distribution and community assembly patterns of scleractinian and stylasterid corals on three high-profile seamounts within the Anegada Passage, a deep-water throughway linking theAuthorsSteven R. Auscavitch, Jay J. Lunden, Alexandria Barkman, Andrea Quattrini, Amanda Demopoulos, Erik E. CordesCascadia Margin cold seeps: Subduction zone fluids, gas hydrates, and chemosynthetic habitats
Priority Geographic Area: The outer continental shelf and upper continental slope from Canada/U.S. border offshore Washington State to the Mendocino Fracture Zone (Northern California), entirely within the U.S. Exclusive Economic Zone (EEZ), from the outermost shelf to at least 2000 m water depth (Figure 1). Description of Priority Area: Since 2015, over a thousand water column gas plumes originatAuthorsAmanda Demopoulos, Carolyn D. Ruppel, Nancy G. Prouty, Janet Watt, Tamara Baumberger, David A ButterfieldMapping, exploration, and characterization of the California continental margin and associated features from the California-Oregon border to Ensenada, Mexico
Priority Geographic Area: Both within and outside US Exclusive Economic Zone (EEZ). California continental margin. This area includes and continues south of the geographic area captured in the Watt et al. white paper. Description of Priority Area: The California continental margin, from the narrow shelf to abyssal depths, contains diverse seafloor features that influence benthic community types, bAuthorsAmanda Demopoulos, Nancy G. Prouty, Daniel S. Brothers, Janet Watt, James E. Conrad, Jason Chaytor, Chris CaldowMolecular indicators of methane metabolisms at cold seeps along the United States Atlantic margin
A lipid biomarker study was undertaken to determine the microbial composition and variability in authigenic carbonates and associated soft bottom habitats from the Norfolk and the Baltimore Canyon seep fields along the US mid-Atlantic margin. Results from this study capture a distinct molecular signal from methane oxidizing archaea, including archaeol (I), sn-2-hydroxyarchaeol, pentamethylicosaneAuthorsNancy G. Prouty, Pamela L. Campbell, Hilary Close, Jennifer F. Biddle, Sabrina BeckmannSubmarine canyons influence macrofaunal diversity and density patterns in the deep-sea benthos
Submarine canyons are often morphologically complex features in the deep sea contributing to habitat heterogeneity. In addition, they act as major conduits of organic matter from the shallow productive shelf to the food deprived deep-sea, promoting gradients in food resources and areas of sediment resuspension and deposition. This study focuses on the Baltimore and Norfolk canyons, in the westernAuthorsCraig M. Robertson, Amanda Demopoulos, Jill Bourque, Furu Mienis, Gerard Duineveld, Mark Lavaleye, R. Koivisto, S. Brooke, S. Ross, M. Rhode, A. DaviesBenthic infaunal communities of Baltimore and Norfolk Canyons
The imperative for finding, cataloging, and understanding continental margin diversity derives from the many key functions, goods and services provided by margin ecosystems and by an increasingly deleterious human footprint on our continental slopes (Levin and Dayton 2009). Progress in seafloor mapping technology and direct observation has revealed unexpected heterogeneity, with a mosaic of habitaAuthorsCraig M. Robertson, Jill Bourque, Amanda DemopoulosQuantifying changes to infaunal communities associated with several deep-sea coral habitats in the Gulf of Mexico and their potential recovery from the DWH oil spill
Extensive information is available about infaunal soft-sediment communities in the Gulf of Mexico (Gulf) (Pequegnat et al. 1990, Rowe and Kennicutt II 2009, Wei et al. 2010), particularly from the large-scale sampling effort of the Deep Gulf of Mexico Benthos (DGOMB) project in the early 2000s (Rowe and Kennicutt II 2009). Infaunal soft-sediment communities in the northern Gulf differ by geographiAuthorsJill R. Bourque, Amanda W.J. DemopoulosMicrobiomes of stony and soft deep-sea corals share rare core bacteria
Background: Numerous studies have shown that bacteria form stable associations with host corals and have focused on identifying conserved “core microbiomes” of bacterial associates inferred to be serving key roles in the coral holobiont. Because studies tend to focus on only stony corals (order Scleractinia) or soft corals (order Alcyonacea), it is currently unknown if there are conserved bacteriaAuthorsChristina A. KelloggExamination of Bathymodiolus childressi nutritional sources, isotopic niches, and food-web linkages at two seeps in the US Atlantic margin using stable isotope analysis and mixing models
Chemosynthetic environments support distinct benthic communities capable of utilizing reduced chemical compounds for nutrition. Hundreds of methane seeps have been documented along the U.S. Atlantic margin (USAM), and detailed investigations at a few seeps have revealed distinct environments containing mussels, microbial mats, authigenic carbonates, and soft sediments. The dominant mussel, BathymoAuthorsAmanda Demopoulos, Jennifer McClain Counts, Jill Bourque, Nancy Prouty, Brian Smith, Sandra Brooke, Steve W. Ross, Carolyn RuppelWindows to the deep 2018: Exploration of the southeast US Continental margin
Windows to the Deep 2018: Exploration of the Southeast US Continental Margin was a 36-day expedition aboard NOAA Ship Okeanos Explorer to acquire data on priority exploration areas identified by the ocean management and scientific communities. This expedition involved high-resolution multibeam sonar mapping and ROV dives, ranging from 340 m to 3,400 m depth, across the southeast US continental marAuthorsLeslie R Sautter, Cheryl L. Morrison, Kasey Cantwell, Derek Sowers, Elizabeth Lobecker - Web Tools
- News
Below are news stories associated with this project.
Filter Total Items: 40 - Partners
Below are partners associated with this project.