Key questions for research and conservation of mesophotic coral ecosystems and temperate mesophotic ecosystems.

Mesophotic coral ecosystems (MCEs) and temperate mesophotic ecosystems (TMEs) have received increasing research attention during the last decade as many new and improved methods and technologies have become more accessible to explore deeper parts of the ocean. However, large voids in knowledge remain in our scientific understanding, limiting our ability to make scientifically based decisions for conservation and management of these ecosystems. Here, we present a list of key research and conservation questions to enhance progress in the field. Questions were generated following an initial open call to MCE and TME experts, representing a range of career levels, interests, organizations (including academia, governmental, and nongovernmental), and geographic locations. Questions were refined and grouped into eight broad themes: (1) Distribution, (2) Environmental and Physical Processes, (3) Biodiversity and Community Structure, (4) Ecological Processes, (5) Connectivity, (6) Physiology, (7) Threats, and (8) Management and Policy. Questions were ranked within themes, and a workshop was used to discuss, refine, and finalize a list of 25 key questions. The 25 questions are presented as a guide for MCE and TME researchers, managers, and funders for future work and collaborations

Key Questions for Research and Conservation of Mesophotic Coral Ecosystems and Temperate Mesophotic Ecosystems

Mesophotic coral ecosystems (MCEs) and temperate mesophotic ecosystems (TMEs) have received increasing research attention during the last decade as many new and improved methods and technologies have become more accessible to explore deeper parts of the ocean. However, large voids in knowledge remain in our scientific understanding, limiting our ability to make scientifically based decisions for conservation and management of these ecosystems. Here, we present a list of key research and conservation questions to enhance progress in the field. Questions were generated following an initial open call to MCE and TME experts, representing a range of career levels, interests, organizations (including academia, governmental, and nongovernmental), and geographic locations. Questions were refined and grouped into eight broad themes: (1) Distribution, (2) Environmental and Physical Processes, (3) Biodiversity and Community Structure, (4) Ecological Processes, (5) Connectivity, (6) Physiology, (7) Threats, and (8) Management and Policy. Questions were ranked within themes, and a workshop was used to discuss, refine, and finalize a list of 25 key questions. The 25 questions are presented as a guide for MCE and TME researchers, managers, and funders for future work and collaborations

Biodiversity of Reef-Building, Scleractinian Corals

Zooxanthellate scleractinian corals are moderately well-known for shallow reef habitats, but not for mesophotic depths (>30 m) that are relatively difficult to access. Mesophotic habitats are light-limited, with different hydrodynamics and sedimentation processes, which result in growth forms that are often difficult to classify using traditional schemes based largely on shallow reef specimens. We analyzed published data and museum records, using specimen-based records to minimize classification issues, finding 53 mesophotic species in the western Atlantic Ocean (85% of total species) and 338 in the Indo-Pacific (45%). Only four species were recorded exclusively below 30 m depth, while the great majority were common shallow reef taxa. Over 96% of western Atlantic and 82% of Indo-Pacific genera and most coral lineages were represented below 30 m depth. In the Indo-Pacific, species and genus richness varied widely between regions and were significantly correlated with shallow reef species richness. Overall, species richness decreased steadily with increasing depth, with little evidence for distinct faunal boundaries: 157 species occurred >= 60 m and 31 deeper than 100 m, with species occurrence only moderately related to phylogeny. Our knowledge of mesophotic biodiversity is rapidly changing as more regions are documented and new molecular techniques suggest taxonomic revisions and resolve deepwater cryptic species. We conclude that mesophotic scleractinian fauna are largely a subset of shallow scleractinian fauna, comprising a significant proportion of coral species and most genera, with the potential to play a significant role in lineage preservation and the future of coral reefs