Mesozooplankton is a very diverse group of small animals ranging in size from 0.2 to 20 mm not able to swim against ocean currents. It is a key component of pelagic ecosystems through its roles in the trophic networks and the biological carbon pump. Traditionally studied through microscopes, recent methods have been however developed to rapidly acquire large amounts of data (morphological, molecular) at the individual scale, making it possible to study mesozooplankton using a trait-based approach. Here, combining quantitative imaging with metabarcoding time-series data obtained in the Sargasso Sea at the Bermuda Atlantic Time-series Study (BATS) site, we showed that organisms’ transparency might be an important trait to also consider regarding mesozooplankton impact on carbon export, contrary to the common assumption that just size is the master trait directing most mesozooplankton-linked processes. Three distinct communities were defined based on taxonomic composition, and succeeded one another throughout the study period, with changing levels of transparency among the community. A co-occurrences’ network was built from metabarcoding data revealing six groups of taxa. These were related to changes in the functioning of the ecosystem and/or in the community’s morphology. The importance of Diel Vertical Migration at BATS was confirmed by the existence of a group made of taxa known to be strong migrators. Finally, we assessed if metabarcoding can provide a quantitative approach to biomass and/or abundance of certain taxa. Knowing more about mesozooplankton diversity and its impact on ecosystem functioning would allow to better represent them in biogeochemical models.

Zooplankton undergo a vertical migration which exposes them to gradients of light, temperature, oxygen and food availability on a predictable daily schedule. Anticipating and responding to these environmental conditions, which independently are known to influence metabolic rates, likely has an appreciable effect on the delivery of waste products to the distinctly different daytime (deep) and nighttime (surface) habitats. Disentangling the co-varying and potentially synergistic interactions on metabolic rates has proven difficult, despite the importance of this migration to oceanic biogeochemical cycling. This study examines the transcriptomic and proteomic profile of the circumglobal migratory copepod, Pleuromamma xiphias, over the diel cycle. The transcriptome showed a large number of up-regulated genes during the middle of the day – the period often considered to be of lowest metabolic activity. There were proteomic and transcriptomic peaks in oxidative stress response and muscle proteins after the periods of migration, suggestive of a physiological consequence of migration. There were changes in metabolic pathways over time, with increased ammonium production signals during the evening and chitin synthesis and degradation pathways during the day. Comparisons of patterns across the paired datasets suggest that 1) estimates of physiological rates made in the laboratory in steady state conditions that don’t account for time of day may not be adequate to predict in situ phenotypes 2) use of ‘omics datasets to predict organismal phenotypes must be done cautiously as highly dynamic patterns in the transcriptome and proteome are often dampened and sometimes asynchronous at the enzyme or organismal level.

Protists represent the majority of the eukaryotic diversity in the oceans. They have different functions in the marine food web, playing essential roles in the biogeochemical cycles. Meanwhile the available data is rich in horizontal and temporal coverage, little is known on their vertical structuring, particularly below the photic zone. The present study applies DNA metabarcoding to samples collected over three years in conjunction with the BATS time-series to assess marine protist communities in the epipelagic and mesopelagic zones. The protist community showed a dynamic seasonality in the epipelagic, responding to hydrographic yearly cycles. Mixotrophic lineages dominated throughout the year; however, autotrophs bloomed during the rapid transition between the winter mixing and the stratified summer, and heterotrophs had their peak at the end of summer, when the base of the thermocline reaches its deepest depth. Below the photic zone, the community, dominated by Rhizaria, is depth-stratified and relatively constant throughout the year, mirroring local hydrographic and biological features such as the oxygen minimum zone. The results suggest a dynamic partitioning of the water column, where the niche vertical position for each community changes throughout the year, likely depending on nutrient availability, the mixed layer depth, and other hydrographic features. Finally, the protist community closely followed mesoscale events (eddies), where the communities mirrored the hydrographic uplift, raising the deeper communities for hundreds of meters, and compressing the communities above.