The deep-sea is a vast and relatively sparsely characterized domain. As little as 0.01% of deep-sea benthic habitats have been characterized in detail. Characterizing the distribution of organisms and environmental components of the deep-sea is pivotal to the creation and implementation of successful resource management. Benthic habitat maps are a good method to inventory and characterize deep-sea habitats. Recent advances in technology, such as multibeam sonar and remotely operated vehicles (ROVs), have allowed for greater understanding of these ecosystems. As it is difficult and expensive to collect data deep-sea benthic community composition, environmental surrogates of biological data would be economically beneficial. Ideally, a surrogate is an easily-measured abiotic indicator that greatly influences benthic community composition. The quality of a surrogate can be extrapolated to represent the quality of benthic habitat. The Miami Terrace is a deep-sea ecosystem that has begun to be explored and characterized. Previous studies noted that community compositions vary with broad-scale geomorphology on the Miami Terrace. This study addresses a swath of data collected from the Miami Terrace to determine if geomorphology in high resolution bathymetry could serve as a viable surrogate to biological data for the initial characterization of benthic habitats on the Miami Terrace. Data from cable impact assessment surveys for the South Florida Ocean Measurement Facility (SFOMF) and the Department of Energy were utilized in this study. Images from these surveys were analyzed to generate and detail twelve transects across a section of the Miami Terrace. This cross section of the terrace had previously been sectioned into distinct geomorphologic zones (Messing et al., 2012). The geomorphologic zones assessed in this study were High Slope Inner Terrace (HSIT), Low Slope Inner Terrace (LSIT), High Slope Outer Terrace Platform (HSOTP), Low Slope Outer Terrace Platform (LSOTP), High Slope Outer Terrace Ridge (HSOTR), and Low Slope Outer Terrace Ridge (LSOTR). Images from these transects were analyzed to generate percent cover and community data. This data includes overall organism density, species richness, and an inventory of all organisms greater than 4 cm identified to the lowest taxonomic level possible. This data was taken in concert with previously collected environmental data (e.g. depth, slope, and geomorphology) and subjected to multivariate statistical analysis. Patterns in organism density across the transects align with the progression of the transects by slope and geomorphologic region. Depth was seen to increase from Inner Terrace to Outer Terrace Platform. The Outer Terrace Ridge exhibited an increase in the percent cover of hardbottom habitat; which is preferential for many organisms. This corresponded to a shift in the organism density of multiple Cnidarians and Poriferans. In particular, the density of stylasterids and several sponges increased towards the Outer Terrace Ridge. One High Slope Inner Terrace…
In 1984, a portion of the deep-water Oculina coral reef ecosystem off eastern Florida was protected as the Oculina Habitat Area of Particular Concern (OHAPC), prohibiting bottom trawls, longlines, dredges, and anchors. Unfortunately, the northern two thirds of the reef system remained open to these gear until 2000 when the OHAPC boundaries were expanded to 1029 km2. In the 1970s, the Oculina reefs were teeming with large spawning aggregations of grouper and snapper. By the early 1990s, commercial and recreational fishing had decimated the fish populations, and the coral had been severely impacted by bottom trawling for rock shrimp. Historical photographic transects, taken in the 1970s with the Johnson-Sea-Link sub-mersibles, provide crucial evidence of the status and health of the reefs prior to heavy fishing and trawling activities. Quantitative analyses of photographic images by point count reveal drastic loss of live coral cover between 1975 and 2001. Six coral reef sites had nearly 100% loss of live coral, whereas only two reefs which were within the boundaries of the original OHAPC since 1984 survived and were not impacted by trawling. Management and conservation plans for deep-sea coral reef ecosystems worldwide must be based on sound scientific understanding as well as adequate surveillance and enforcement; this study will help build a foundation for this understanding.
Molecular systematic studies have indicated that the hexactinellid sponge species Rossella nodastrella Topsent (Lyssacinosida, Rossellidae), previously only known from the NE Atlantic, is only distantly related to its congeners, which are restricted to the Southern Ocean, representing the only case thus far reported of a diphyletic genus in the class Hexactinellida. Here we describe new material of "Rossella" nodastrella from cold-water coral reefs in the NW Atlantic (Florida). Morphological comparison with the holotype from the Azores and specimens recently reported from off Ireland reveal at least two distinct species, which we corroborate with molecular data. Because the diphyletic nature of "Rossella" is further supported with inclusion of the new specimens in the molecular phylogeny, we erect a new genus, Nodastrella gen. nov., for these two species. The Irish specimens are synonymized with our new species Nodastrella asconemaoida sp. nov. Subtle morphological and molecular differences between the E and W Atlantic specimens are for the time being ascribed to intraspecific geographic variation, but indicate that Nodastrella might contain more (sub) species, pending investigation of additional specimens, especially from intermediate locations.
As part of the 2002 NOAA Ocean Exploration Islands in the Stream expedition, our objective was to explore novel sources of marine-derived chemicals that may be applied to the development of Pharmaceuticals. Virtually no drug discovery research has targeted the deep-water coral reef communities in this region, and in particular the microbial associates living in these communities. Some of the sites visited have never been dived on previously. This is the first documentation of these habitats and their biodiversity. During a total of 23 dives in the Johnson-Sea-Link II submersible, more than 200 benthic macrofauna and sediment samples were collected and analyzed. The abundance and diversity of sponges and octocorals were greater than expected from reports in the literature. Several new species or new records of occurrence of sponges and octocorals were discovered. Chemical profiles of extracts made from specimens of sponges and octocorals indicate that novel compounds are present in many of the samples. NOAA's Ocean Explorer website and HBOI's At-Sea website documented near real-time postings of essays, interviews, photographs, and video from mission scientists, crew, and educators, describing daily dive activities and discoveries. A Professional Development Institute was conducted to familizarize Florida educators with the Ocean Exploration program and curriculum.
