RCC references

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A
Bestion E, Barton S, García FC, Warfield R, Yvon-Durocher G.  2020.  Abrupt declines in marine phytoplankton production driven by warming and biodiversity loss in a microcosm experiment. Ecology Letters. 23:457–466.PDF icon Bestion et al_2020_Abrupt declines in marine phytoplankton production driven by warming and.pdf (1.26 MB)
Mahmoud RM, Sanfilippo JE, Nguyen AA, Strnat JA, Partensky F, Garczarek L, Kassem NAbo El, Kehoe DM, Schluchter WM.  2017.  Adaptation to blue light in marine synechococcus requires MpeU, an enzyme with similarity to phycoerythrobilin lyase isomerases. Frontiers in Microbiology. 8:243.PDF icon Mahmoud et al_2017_Adaptation to blue light in marine synechococcus requires MpeU, an enzyme with.pdf (1.96 MB)
Gu H, Li X, Chomérat N, Luo Z, Sarno D, Gourvil P, Balzano S, Siano R.  2017.  Adenoides sinensis , a new sand-dwelling dinoflagellate species from China and reexamination of A. eludens from an Atlantic strain. Phycologia. 57:1–13.PDF icon Gu et al_2017_Adenoides sinensis , a new sand-dwelling dinoflagellate species from China and.pdf (1.97 MB)
Gu H, Li X, Chomérat N, Luo Z, Sarno D, Gourvil P, Balzano S, Siano R.  2017.  Adenoides sinensis , a new sand-dwelling dinoflagellate species from China and reexamination of A. eludens from an Atlantic strain. Phycologia. 57:1–13.PDF icon Gu et al_2017_Adenoides sinensis , a new sand-dwelling dinoflagellate species from China and.pdf (1.97 MB)
Decelle J, Stryhanyuk H, Gallet B, Veronesi G, Schmidt M, Balzano S, Marro S, Uwizeye C, Jouneau P-H, Lupette J et al..  2019.  Algal remodeling in a ubiquitous planktonic photosymbiosis. Current Biology. 29:968–978.e4.PDF icon Decelle et al_2019_Algal remodeling in a ubiquitous planktonic photosymbiosis.pdf (5.3 MB)
Stewart A, Rioux D, Boyer F, Gielly L, Pompanon F, Saillard A, Thuiller W, Valay J-G, Maréchal É, Coissac E.  2021.  Altitudinal Zonation of Green Algae Biodiversity in the French Alps. Frontiers in Plant Science. 12:1066.PDF icon Stewart et al. - 2021 - Altitudinal Zonation of Green Algae Biodiversity i.pdf (5.59 MB)
Meng A, Corre E, Probert I, Gutierrez-Rodriguez A, Siano R, Annamale A, Alberti A, Da Silva C, Wincker P, Le Crom S et al..  2018.  Analysis of the genomic basis of functional diversity in dinoflagellates using a transcriptome-based sequence similarity network. Molecular Ecology. :0–2.PDF icon Meng et al_2018_Analysis of the genomic basis of functional diversity in dinoflagellates using.pdf (1.42 MB)
Das S, Lizon F, Gevaert F, Bialais C, Duong G, Ouddane B, Souissi S.  2023.  Assessing indicators of arsenic toxicity using variable fluorescence in a commercially valuable microalgae: physiological and toxicological aspects. Journal of Hazardous Materials. :131215.PDF icon Das et al_2023_Assessing indicators of arsenic toxicity using variable fluorescence in a.pdf (2.11 MB)
C
Gnouma A, Sadovskaya I, Souissi A, Sebai K, Medhioub A, Grard T, Souissi S.  2017.  Changes in fatty acids profile, monosaccharide profile and protein content during batch growth of Isochrysis galbana (T.iso). Aquaculture Research. 48:4982–4990.
Gnouma A, Sadovskaya I, Souissi A, Sebai K, Medhioub A, Grard T, Souissi S.  2017.  Changes in fatty acids profile, monosaccharide profile and protein content during batch growth of Isochrysis galbana (T.iso). Aquaculture Research. 48:4982–4990.
Palacio AS, Cabello AMaría, García FC, Labban A, Morán XAnxelu G, Garczarek L, Alonso-Sáez L, López-Urrutia Á.  2020.  Changes in population age-structure obscure the temperature-size rule in marine cyanobacteria. Frontiers in Microbiology. 11:2059.PDF icon Palacio et al_2020_Changes in population age-structure obscure the temperature-size rule in marine.pdf (1.72 MB)
Palacio AS, Cabello AMaría, García FC, Labban A, Morán XAnxelu G, Garczarek L, Alonso-Sáez L, López-Urrutia Á.  2020.  Changes in population age-structure obscure the temperature-size rule in marine cyanobacteria. Frontiers in Microbiology. 11:2059.PDF icon Palacio et al_2020_Changes in population age-structure obscure the temperature-size rule in marine.pdf (1.72 MB)
Mucko M, Padisák J, Udovič MGligora, Pálmai T, Novak T, Medić N, Gašparović B, Štefanić PPeharec, Orlić S, Ljubešić Z.  2020.  Characterization of a lipid-producing thermotolerant marine photosynthetic pico-alga in the genus Picochlorum (Trebouxiophyceae). European Journal of Phycology. 00:1–16.PDF icon Mucko et al_2020_Characterization of a lipid-producing thermotolerant marine photosynthetic.pdf (3.24 MB)
Guillou L.  2011.  Characterization of the Parmales: much more than the resolution of a taxonomic enigma. Journal of Phycology. 47:2–4.PDF icon Guillou_2011_Characterization of the Parmales.pdf (245.73 KB)
Dorrell RG, Gile G, McCallum G, Méheust R, Bapteste EP, Klinger CM, Brillet-Guéguen L, Freeman KD, Richter DJ, Bowler C.  2017.  Chimeric origins of ochrophytes and haptophytes revealed through an ancient plastid proteome. eLife. 6:1–45.
Santos ALopes dos, Pollina T, Gourvil P, Corre E, Marie D, Garrido JLuis, Rodríguez F, Noël M-H, Vaulot D, Eikrem W.  2017.  Chloropicophyceae, a new class of picophytoplanktonic prasinophytes. Scientific Reports. 7:14019.PDF icon Lopes dos Santos et al_2017_Chloropicophyceae, a new class of picophytoplanktonic prasinophytes.pdf (4.58 MB)
Santos ALopes dos, Pollina T, Gourvil P, Corre E, Marie D, Garrido JLuis, Rodríguez F, Noël M-H, Vaulot D, Eikrem W.  2017.  Chloropicophyceae, a new class of picophytoplanktonic prasinophytes. Scientific Reports. 7:14019.PDF icon Lopes dos Santos et al_2017_Chloropicophyceae, a new class of picophytoplanktonic prasinophytes.pdf (4.58 MB)
Jancek S, Gourbiere S, Moreau H, Piganeau G.  2008.  Clues about the genetic basis of adaptation emerge from comparing the proteomes of two Ostreococcus ecotypes (Chlorophyta, Prasinophyceae). Molecular Biology and Evolution. 25:2293–2300.PDF icon Jancek et al_2008_Clues about the genetic basis of adaptation emerge from comparing the proteomes.pdf (263.79 KB)
Thomy J, Sanchez F, Gut M, Cruz F, Alioto T, Piganeau G, Grimsley N, Yau S.  2021.  Combining Nanopore and Illumina Sequencing Permits Detailed Analysis of Insertion Mutations and Structural Variations Produced by PEG-Mediated Transformation in Ostreococcus tauri. PDF icon Thomy et al. - 2021 - Combining Nanopore and Illumina Sequencing Permits.pdf (1.99 MB)
Thomy J, Sanchez F, Gut M, Cruz F, Alioto T, Piganeau G, Grimsley N, Yau S.  2021.  Combining Nanopore and Illumina Sequencing Permits Detailed Analysis of Insertion Mutations and Structural Variations Produced by PEG-Mediated Transformation in Ostreococcus tauri. PDF icon Thomy et al. - 2021 - Combining Nanopore and Illumina Sequencing Permits.pdf (1.99 MB)
Thomy J, Sanchez F, Gut M, Cruz F, Alioto T, Piganeau G, Grimsley N, Yau S.  2021.  Combining Nanopore and Illumina Sequencing Permits Detailed Analysis of Insertion Mutations and Structural Variations Produced by PEG-Mediated Transformation in Ostreococcus tauri. Cells. 10:664.PDF icon Thomy et al. - 2021 - Combining Nanopore and Illumina Sequencing Permits.pdf (1.99 MB)

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