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Agulhas rings provide the principal route for ocean waters to circulate from the Indo-Pacific to the Atlantic basin. Their influence on global ocean circulation is well known, but their role in plankton transport is largely unexplored. We show that, although the coarse taxonomic structure of plankton communities is continuous across the Agulhas choke point, South Atlantic plankton diversity is altered compared with Indian Ocean source populations. Modeling and in situ sampling of a young Agulhas ring indicate that strong vertical mixing drives complex nitrogen cycling, shaping community metabolism and biogeochemical signatures as the ring and associated plankton transit westward. The peculiar local environment inside Agulhas rings may provide a selective mechanism contributing to the limited dispersal of Indian Ocean plankton populations into the Atlantic.

Accompanying material, text, data and figures for the article de Vargas et al., 'Eukaryotic plankton diversity in the sunlit ocean', Science 348, 1261605 (2015), doi: 10.1126/science.1261605

Les dinoflagellés forment un groupe complexe de protistes avec une grande diversité de morphologies, physiologies, et cycles de vies qui leur confèrent une forte capacité d'adaptation à l'ensemble des milieux (marins et dulçaquicoles) et habitats (pélagiques et benthiques) aquatiques rendant difficile l¿étude de leur diversité et de leur écologie. L'objectif de cette thèse a été la recherche de patrons globaux de biodiversité et de structuration des communautés de dinoflagellés pélagiques marins à l'échelle planétaire. Un protocole d'échantillonnage morphogénétique, couvrant la totalité de leur spectre de taille et une partie importante de leurs variabilités spatio-temporelles, a été développé (Tara-Oceans). Divers outils d'acquisition automatique à haut débit des données ont été testés. La diversité, l'abondance relative et la distribution géographique des espèces du genre Neoceratium ont été évaluées en mer Méditerranée par FlowCAM. Une étude de la structuration de la biodiversité a été réalisée par metabarcoding de l¿ADNr 18S (fragment V9). La construction d'une base de séquences ADNr de référence (DinR2) a permis l¿assignation taxonomique des metabarcodes environnementaux. L¿approche par metabarcode révèle une diversité remarquable et insoupçonnée des pico-dinoflagellés (<5µm) et que, indépendamment de l'écosystème étudié et de la période d'échantillonnage, l¿abondance des différents ordres dépend essentiellement de la taille (pico-, nano-, micro-, et meso-plancton). La structuration des communautés de dinoflagellés de différentes fractions de tailles de la zone photique a été confrontée à certains facteurs environnementaux ouvrant des pistes de recherche prometteuses Dinoflagellates form a complex group of protists with a variety of morphologies, physiologies, and life cycles that give them a strong adaptation to all aquatic environments (marine and freshwater) and habitats (pelagic and benthic) making difficult to study their diversity and ecology. The objective of this thesis was the search for global biodiversity patterns and community structure of marine pelagic dinoflagellates across the world?s oceans. A morphogenetic sampling protocol, covering the entire spectrum of their size and an important part of their spatio-temporal variability, was developed (Tara-Oceans). Various tools for an automatic acquisition broadband data were tested. Diversity, relative abundance and geographical distribution of the genus Neoceratium were evaluated by FlowCAM in Mediterranean Sea. A study of the structure of biodiversity was conducted by metabarcoding with 18S rDNA (V9 fragment). Building a base of rDNA reference sequences (DinR2) allowed the taxonomic assignment of environmental metabarcodes. The metabarcode approach reveals a remarkable and unexpected diversity of pico-dinoflagellates (<5?m) and, regardless of the studied ecosystem and the sampling period, that abundance of different levels mainly depends to the size fractions (pico-, nano-, micro- and meso- plankton). Structuring of dinoflagellates communities in different size fractions of the photic zone was facing to some environmental factors and opens promising avenues for research

Cold-water corals form substantial biogenic habitats on continental shelves and in deep-sea areas with topographic highs, such as banks and seamounts. In the Atlantic, many reef and mound complexes are engineered by Lophelia pertusa, the dominant framework-forming coral. In this study, a variety of mapping approaches were used at a range of scales to map the distribution of both cold-water coral habitats and individual coral colonies at the Mingulay Reef Complex (west Scotland). The new ArcGIS-based British Geological Survey (BGS) seabed mapping toolbox semi-automatically delineated over 500 Lophelia reef ‘mini-mounds’ from bathymetry data with 2-m resolution. The morphometric and acoustic characteristics of the mini-mounds were also automatically quantified and captured using this toolbox. Coral presence data were derived from high-definition remotely operated vehicle (ROV) records and high-resolution microbathymetry collected by a ROV-mounted multibeam echosounder. With a resolution of 0.35 × 0.35 m, the microbathymetry covers 0.6 km2 in the centre of the study area and allowed identification of individual live coral colonies in acoustic data for the first time. Maximum water depth, maximum rugosity, mean rugosity, bathymetric positioning index and maximum current speed were identified as the environmental variables that contributed most to the prediction of live coral presence. These variables were used to create a predictive map of the likelihood of presence of live cold-water coral colonies in the area of the Mingulay Reef Complex covered by the 2-m resolution data set. Predictive maps of live corals across the reef will be especially valuable for future long-term monitoring surveys, including those needed to understand the impacts of global climate change. This is the first study using the newly developed BGS seabed mapping toolbox and an ROV-based microbathymetric grid to explore the environmental variables that control coral growth on cold-water coral reefs.