Virus-host coexistence in phytoplankton through the genomic lens

Yau, Sheree; Krasovec, Marc; Benites, L. Felipe; Rombauts, Stéphane; Groussin, Mathieu; Vancaester, Emmelien; Aury, Jean‐Marc; Derelle, Évelyne; Desdevises, Yves; Escande, Marie‐Line; Grimsley, Nigel; Guy, Julie; Moreau, Hervé; Sanchez-Brosseau, Sophie; Peer, Yves Van de; Vandepoele, Klaas; Gourbière, Sébastien; Piganeau, Gwenaël

doi:10.1126/sciadv.aay2587

Cited by 40 publications

(43 citation statements)

References 48 publications

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“…The vast majority (95%) of non-VIPs may not have a significant impact on CEE, because they do not strongly impact the host population, for instance, by stably coexisting with their hosts. It is worth noting that experimental studies have reported cultures of algae with viruses that reach a stable co-existence state after a few generations ( Yau et al., 2020 ).…”

Section: Resultsmentioning

confidence: 99%

Eukaryotic virus composition can predict the efficiency of carbon export in the global ocean

et al. 2021

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Section: Resultsmentioning

confidence: 99%

Eukaryotic virus composition can predict the efficiency of carbon export in the global ocean

et al. 2021

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“…Here, we explored the potential of an untargeted metabolomic approach including pigments, lipids, and other uncharacterized metabolites to investigate chemotaxonomic markers in 12 marine microalgal strains from 11 species, including 9 microalgae from the green lineage; the Mamiellales Ostreococcus tauri [20], O. mediterraneus [21], Bathycoccus prasinos [22], Micromonas commoda [23], and Mantoniella sp., the Chlorellales Picochlorum costavermella [24], and strains from basal groups Nephroselmis sp. and Pyramimonas sp.…”

Section: Introductionmentioning

confidence: 99%

Metabolomic Insights into Marine Phytoplankton Diversity

2020

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The democratization of sequencing technologies fostered a leap in our knowledge of the diversity of marine phytoplanktonic microalgae, revealing many previously unknown species and lineages. The evolutionary history of the diversification of microalgae can be inferred from the analysis of their genome sequences. However, the link between the DNA sequence and the associated phenotype is notoriously difficult to assess, all the more so for marine phytoplanktonic microalgae for which the lab culture and, thus, biological experimentation is very tedious. Here, we explore the potential of a high-throughput untargeted metabolomic approach to explore the phenotypic–genotypic gap in 12 marine microalgae encompassing 1.2 billion years of evolution. We identified species- and lineage-specific metabolites. We also provide evidence of a very good correlation between the molecular divergence, inferred from the DNA sequences, and the metabolomic divergence, inferred from the complete metabolomic profiles. These results provide novel insights into the potential of chemotaxonomy in marine phytoplankton and support the hypothesis of a metabolomic clock, suggesting that DNA and metabolomic profiles co-evolve.

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“…They can be easily cultured in the laboratory, witnessed by more than 300 strains maintained in the Roscoff Culture Collection (RCC) in France [1], and they diverged at the base of the green lineage that includes land plants, thus providing a starting point for phylogenetic analyses [2]. Several of their streamlined haploid genomes have been completely sequenced and analysed [3,4,5,6,7,8], and they harbour a minimal number of genes for cellular processes, as reflected in the size of their nuclear genomes. Species in the genus Ostreococcus, for example, which so far includes four phylogenetically divergent [9] species with fully sequenced genomes (see [3,4,8] and ), have only 12–14 Mb of nuclear DNA, comparable to that of yeast (12.1 Mb) [10].…”

Section: Introductionmentioning

confidence: 99%

“…Several of their streamlined haploid genomes have been completely sequenced and analysed [3,4,5,6,7,8], and they harbour a minimal number of genes for cellular processes, as reflected in the size of their nuclear genomes. Species in the genus Ostreococcus, for example, which so far includes four phylogenetically divergent [9] species with fully sequenced genomes (see [3,4,8] and ), have only 12–14 Mb of nuclear DNA, comparable to that of yeast (12.1 Mb) [10]. This is much smaller than those of other model species in the green lineage such as mosses ( Physcomitrella patens , 476 Mb, [11]) Arabidopsis thaliana (135 Mb [12]) or maize (2.4 Gb [13]).…”

Section: Introductionmentioning

confidence: 99%

Simplified Transformation of Ostreococcus tauri Using Polyethylene Glycol

Sanchez

Geffroy

Norest

et al. 2019

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Ostreococcus tauri is an easily cultured representative of unicellular algae (class Mamiellophyceae) that abound in oceans worldwide. Eight complete 13–22 Mb genomes of phylogenetically divergent species within this class are available, and their DNA sequences are nearly always present in metagenomic data produced from marine samples. Here we describe a simplified and robust transformation protocol for the smallest of these algae (O. tauri). Polyethylene glycol (PEG) treatment was much more efficient than the previously described electroporation protocol. Short (2 min or less) incubation times in PEG gave >104 transformants per microgram DNA. The time of cell recovery after transformation could be reduced to a few hours, permitting the experiment to be done in a day rather than overnight as used in previous protocols. DNA was randomly inserted in the O. tauri genome. In our hands PEG was 20–40-fold more efficient than electroporation for the transformation of O. tauri, and this improvement will facilitate mutagenesis of all of the dispensable genes present in the tiny O. tauri genome.

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Virus-host coexistence in phytoplankton through the genomic lens

Cited by 40 publications

References 48 publications

Eukaryotic virus composition can predict the efficiency of carbon export in the global ocean

Eukaryotic virus composition can predict the efficiency of carbon export in the global ocean

Metabolomic Insights into Marine Phytoplankton Diversity

Simplified Transformation of Ostreococcus tauri Using Polyethylene Glycol

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