Genomic evidence for global ocean plankton biogeography shaped by large-scale current systems

Richter, Daniel J.; Watteaux, Romain; Vannier, Thomas; Leconte, Jade; Frémont, Paul; Reygondeau, Gabriel; Maillet, Nicolas; Henry, Nicolas; Benoit, Gaëtan; Silva, Ophélie Da; Delmont, Tom O.; Fernàndez-Guerra, Antonio; Suweis, Samir; Narci, Romain; Berney, Cédric; Eveillard, Damien; Gavory, Frédérick; Guidi, Lionel; Labadie, Karine; Mahieu, Eric; Poulain, Julie; Romac, Sarah; Roux, Simon; Dimier, Céline; Kandels, Stefanie; Picheral, Marc; Searson, Sarah; Pesant, Stéphane; Aury, Jean‐Marc; Brum, Jennifer R.; Lemaitre, Claire; Pelletier, Éric; Bork, Peer; Sunagawa, Shinichi; Lombard, Fabien; Karp‐Boss, Lee; Bowler, Chris; Sullivan, Matthew B.; Karsenti, Eric; Mariadassou, Mahendra; Probert, Ian; Peterlongo, Pierre; Wincker, Patrick; Vargas, Colomban de; d’Alcalà, Maurizio Ribera; Iudicone, Daniele; Jaillon, Olivier

doi:10.7554/elife.78129

Cited by 42 publications

(42 citation statements)

References 65 publications

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“…While the sampling route did not sample both basins the same year, there is a continuum in the seasons sampled. Both basins have a relatively high seasonality, yet recent studies ( 4, 8, 9 ) suggest that relatively stable plankton biogeographies exist at the global scale, which is confirmed here (see below). In terms of connectivity, values of minimum transport time by currents (Tmin) computed from previous studies ( 8, 9 ) between each proximal station (defined by this minimum transport time) confirm that the flow of currents is directed from the Atlantic into the Arctic (Figure 1).…”

Section: Resultssupporting

confidence: 83%

“…They are key players in many biogeochemical processes such as primary production via photosynthesis ( 1 ), carbon export to the deep ocean ( 2–4 ) and essentially sustain the entire oceanic trophic system ( 5 ). Many studies based either on satellite ( 6, 7 ) or genomic data ( 4, 8, 9 ) revealed a mainly latitudinal and temperature driven biogeographical partitioning of the oceans. While some species have strictly defined environmental niches ( 4, 10 ), some display cosmopolitan biogeographies, such as Bathycoccus prasinos which is present in both polar and temperate oceans ( 11 ) or Pelagomonas calceolata that is cosmopolitan in all except polar oceans ( 12 ).…”

Section: Introductionmentioning

confidence: 99%

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Changes in functional composition and gene expression in eukaryotic plankton at the Atlantic-Arctic Polar front

Frémont

Silva

Campese

et al. 2022

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Planktonic communities are shaped by ocean currents and participate in multiple global biogeochemical cycles. Unraveling how the functions of communities respond to strong environmental gradients will improve our understanding of the interactions between climate change and marine ecosystems. Here, we investigate changes in functions and gene expression of eukaryotic plankton transiting between the North Atlantic Ocean (NAO) in winter and the Arctic Ocean (AO) in spring/summer using metatranscriptomes and metagenomes from Tara Oceans. In Arctic communities, functions involved in maintaining the protein pool and translation machinery appear to be more active. Four major phylogenetically distant algal groups are abundant in both basins and show similar strategies at transcriptional level, including increased expression of some functions related to cold acclimation. These results shade lights on gene expression strategies shared by cosmopolitan phototrophs of widely separated lineages.

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Section: Resultssupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Changes in functional composition and gene expression in eukaryotic plankton at the Atlantic-Arctic Polar front

Frémont

Silva

Campese

et al. 2022

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“…Oceans cover 70% of the surface of our planet and are home to myriad bacterial species that are responsible for many of Earth’s crucial biogeochemical functions ( 1, 2 ), including fixing carbon and nitrogen, recycling nutrients and dissolved organic matter, and degrading biomass. Surveys of the ocean microbiome over broad spatial and temporal scales have revealed repeatable patterns across seasons ( 3–6 ), latitude ( 7 ), and depth ( 8 ), which have been linked to a variety of environmental factors, including temperature ( 3, 4, 8, 9 ), water mixing ( 10, 11 ), nutrient availability ( 12 ), light ( 13 ), and the occurrence of phytoplankton blooms ( 6 ). Nevertheless, general principles underlying the compositional turnover of vital marine bacterial communities are lacking, impairing our ability to predict the response of ocean systems to future environmental changes.…”

Section: Main Textmentioning

confidence: 99%

Warmer temperatures favor slower-growing bacteria in natural marine communities

Abreu

Bello

Bunse

et al. 2022

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Earth's life-sustaining oceans harbor diverse bacterial communities that display varying composition across time and space. While particular patterns of variation have been linked to a range of factors, unifying rules are lacking, preventing the prediction of future changes. Here, analyzing the distribution of fast- and slow-growing bacteria in ocean datasets spanning seasons, latitude, and depth, we show that higher seawater temperatures universally favor slower-growing taxa, in agreement with theoretical predictions. Our results explain why slow growers dominate at the ocean surface, during summer, and near the tropics, and provide a framework to understand how bacterial communities will change in a warmer world.

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“…Microbial eukaryotes have been widely explored in marine ecosystems (P. López-García et al 2001;Lovejoy, Massana, and Pedrós-Alió 2006;Worden, Cuvelier, and Bartlett 2006;Countway et al 2007;Massana and Pedrós-Alió 2008;Alexander et al 2009;Stoeck et al 2010;Logares et al 2014;Vargas et al 2015), whereas there are fewer studies available regarding their distribution and diversity in soils (Fell et al 2006;Shen et al 2014;Moon-van der Staay et al 2006;Mahé et al 2017) and in freshwater systems (Šlapeta, Moreira, and López-García 2005;Debroas et al 2017). Freshwater ecosystems are more fragmented and isolated (Dodson 1992;Reche et al 2005) in comparison to the open ocean where microbial communities are transported by currents on a global scale (Villarino et al 2018;Richter et al 2020). This intrinsic lower connectivity of freshwater ecosystems hinders the dispersal of freshwater organisms and increases the genetic diversity (Dias et al 2013).…”

Section: Introductionmentioning

confidence: 99%

Taxonomic composition, community structure and molecular novelty of microeukaryotes in a temperate oligomesotrophic lake as revealed by metabarcoding

Mitsi

Richter

Arroyo

et al. 2022

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Microbial eukaryotes are diverse and ecologically important organisms, yet sampling constraints have hindered the understanding of their distribution and diversity in freshwater ecosystems. Metabarcoding has provided a powerful complement to traditional limnological studies, revealing an unprecedented diversity of protists in freshwater environments. Here, we aim to expand our knowledge of the ecology and diversity of protists in lacustrine ecosystems by targeting the V4 hypervariable region of the 18S rRNA gene in water column, sediment and biofilm samples collected from Sanabria Lake (Spain) and surrounding freshwater ecosystems. Sanabria is a temperate lake, which are relatively understudied by metabarcoding in comparison to alpine and polar lakes. The phylogenetic diversity of microbial eukaryotes detected in Sanabria span all currently recognized eukaryotic supergroups, with Stramenopiles being the most abundant and diverse supergroup in all sampling sites. Parasitic microeukaryotes account for 21% of the total protist ASVs identified in our study and were dominated by Chytridiomycota, both in terms of richness and abundance in all sampling sites. Sediments, biofilms and water column samples harbour distinct microbial communities. Phylogenetic placement of poorly assigned and abundant ASVs indicates molecular novelty inside Rhodophyta, Bigyra, early-branching Nucletmycea and Apusomonadida. In addition, we report the first freshwater incidence of the previously exclusively marine genera Abeoforma and Sphaeroforma. Our results contribute to a deeper understanding of microeukaryotic communities in freshwater ecosystems, and provide the first molecular reference for future biomonitoring surveys in Sanabria Lake.

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Genomic evidence for global ocean plankton biogeography shaped by large-scale current systems

Cited by 42 publications

References 65 publications

Changes in functional composition and gene expression in eukaryotic plankton at the Atlantic-Arctic Polar front

Changes in functional composition and gene expression in eukaryotic plankton at the Atlantic-Arctic Polar front

Warmer temperatures favor slower-growing bacteria in natural marine communities

Taxonomic composition, community structure and molecular novelty of microeukaryotes in a temperate oligomesotrophic lake as revealed by metabarcoding

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