RCC references

Export 547 results:
Author Title [ Year(Asc)]
2022
Jang SHyeon.  2022.  Assessment of biodiversity, global distribution, and putative ecological niches of suessiacean dinoflagellates by DNA metabarcoding. Frontiers in Ecology and Evolution. 10PDF icon Jang_2022_Assessment of biodiversity, global distribution, and putative ecological niches.pdf (3.56 MB)
Suchéras-Marx B, Viseur S, Walker CE, Beaufort L, Probert I, Bolton C.  2022.  Coccolith size rules – What controls the size of coccoliths during coccolithogenesis? Marine Micropaleontology. 170:102080.
Ferrieux M, Dufour L, Doré H, Ratin M, Guéneuguès A, Chasselin L, Marie D, Rigaut-jalabert F, Le Gall F, Sciandra T et al..  2022.  Comparative Thermophysiology of Marine Synechococcus CRD1 Strains Isolated From Different Thermal Niches in Iron-Depleted Areas. Frontiers in Microbiology. 13PDF icon Ferrieux et al_2022_Comparative Thermophysiology of Marine Synechococcus CRD1 Strains Isolated From.pdf (2.17 MB)
Yung CCM, Redondo ERey, Sanchez F, Yau S, Piganeau G.  2022.  Diversity and Evolution of Mamiellophyceae: Early-Diverging Phytoplanktonic Green Algae Containing Many Cosmopolitan Species. Journal of Marine Science and Engineering. 10:240.PDF icon Yung et al. - 2022 - Diversity and Evolution of Mamiellophyceae Early-.pdf (6.06 MB)
Grébert T, Garczarek L, Daubin V, Humily F, Marie D, Ratin M, Devailly A, Farrant GK, Mary I, Mella-Flores D et al..  2022.  Diversity and evolution of pigment types in marine \textit{Synechococcus cyanobacteria. Genome Biology and Evolution. :evac035.PDF icon Grebert et al_2022_Diversity and evolution of pigment types in marine iSynechococcus-i.pdf (3.21 MB)
Sorokina M, Barth E, Zulfiqar M, Kwantes M, Pohnert G, Steinbeck C.  2022.  Draft genome assembly and sequencing dataset of the marine diatom Skeletonema costatum RCC75. Data in Brief. :107931.PDF icon Sorokina et al. - 2022 - Draft genome assembly and sequencing dataset of th.pdf (521.08 KB)
Fernandes T, Cordeiro N.  2022.  Effects of phosphorus-induced changes on the growth, nitrogen uptake, and biochemical composition of Pavlova pinguis and Hemiselmis cf. andersenii. Journal of Applied Phycology. PDF icon Fernandes_Cordeiro_2022_Effects of phosphorus-induced changes on the growth, nitrogen uptake, and.pdf (1.79 MB)
Ebenezer V, Hu Y, Carnicer O, Irwin AJ, Follows MJ, Finkel ZV.  2022.  Elemental and macromolecular composition of the marine Chloropicophyceae, a major group of oceanic photosynthetic picoeukaryotes. Limnology and Oceanography. n/aPDF icon Ebenezer et al_Elemental and macromolecular composition of the marine Chloropicophyceae, a.pdf (1.61 MB)
Leblond JD, Elkins LC, Graeff JE, Sabir K.  2022.  Galactolipids of the genus Amphidinium (Dinophyceae): an hypothesis that they are basal to those of other peridinin-containing dinoflagellates. European Journal of Phycology. :1–10.PDF icon Leblond et al_2022_Galactolipids of the genus Amphidinium (Dinophyceae).pdf (2.64 MB)
Guérin N, Ciccarella M, Flamant E, Frémont P, Mangenot S, Istace B, Noel B, Belser C, Bertrand L, Labadie K et al..  2022.  Genomic adaptation of the picoeukaryote Pelagomonas calceolata to iron-poor oceans revealed by a chromosome-scale genome sequence. Communications Biology. 5:1–14.PDF icon Guerin et al_2022_Genomic adaptation of the picoeukaryote Pelagomonas calceolata to iron-poor.pdf (4.25 MB)
Penot M, Dacks JB, Read B, Dorrell RG.  2022.  Genomic and meta-genomic insights into the functions, diversity and global distribution of haptophyte algae. Applied Phycology. :1–20.PDF icon Penot et al_2022_Genomic and meta-genomic insights into the functions, diversity and global.pdf (8.69 MB)
Doré H, Leconte J, Guyet U, Breton S, Farrant GK, Demory D, Ratin M, Hoebeke M, Corre E, Pitt FD et al..  2022.  Global Phylogeography of Marine Synechococcus in Coastal Areas Reveals Strong Community Shifts. mSystems. :e00656–22.PDF icon Dore et al_2022_Global Phylogeography of Marine Synechococcus in Coastal Areas Reveals Strong.pdf (1.87 MB)
Liao S, Huang Y.  2022.  Group 2i Isochrysidales flourishes at exceedingly low growth temperatures (0 to 6 °C). Organic Geochemistry. :104512.PDF icon Liao et Huang - 2022 - Group 2i Isochrysidales flourishes at exceedingly .pdf (862.05 KB)
Vázquez V, León P, Gordillo FJL, Jiménez C, Concepción I, Mackenzie K, Bresnan E, Segovia M.  2022.  High-CO2 Levels Rather than Acidification Restrict Emiliania huxleyi Growth and Performance. Microbial Ecology. PDF icon Vazquez et al_2022_High-CO2 Levels Rather than Acidification Restrict Emiliania huxleyi Growth and.pdf (1.81 MB)
Fernandes T, Cordeiro N.  2022.  High-value lipids accumulation by Pavlova pinguis as a response to nitrogen-induced changes. Biomass and Bioenergy. 158:106341.PDF icon Fernandes et Cordeiro - 2022 - High-value lipids accumulation by Pavlova pinguis .pdf (3.94 MB)
Parsy A, Guyoneaud R, Lot M-C, Baldoni-Andrey P, Périé F, Sambusiti C.  2022.  Impact of salinities, metals and organic compounds found in saline oil & gas produced water on microalgae and cyanobacteria. Ecotoxicology and Environmental Safety. 234:113351.PDF icon Parsy et al. - 2022 - Impact of salinities, metals and organic compounds.pdf (1.49 MB)
Zhang Q-C, Liu C, Wang J-X, Kong F-Z, Niu Z, Xiang L, Yu R-C.  2022.  Intense blooms of Phaeocystis globosa in the South China Sea are caused by a unique “giant-colony” ecotype. Harmful Algae. 114:102227.PDF icon Zhang et al. - 2022 - Intense blooms of Phaeocystis globosa in the South.pdf (7.05 MB)
Biller S, Marin MMuñoz, Lima S, Matinha-Cardoso J, Tamagnini P, Oliveira P.  2022.  Isolation and Characterization of Cyanobacterial Extracellular Vesicles. Journal of Visualized Experiments. PDF icon Biller et al_2022_Isolation and Characterization of Cyanobacterial Extracellular Vesicles.pdf (557.9 KB)
Falciatore A, Bailleul B, Boulouis A, Bouly J-P, Bujaldon S, Cheminant-Navarro S, Choquet Y, de Vitry C, Eberhard S, Jaubert M et al..  2022.  Light-driven processes: key players of the functional biodiversity in microalgae. Comptes Rendus. Biologies. 345:1–24.PDF icon Falciatore et al_2022_Light-driven processes.pdf (2.62 MB)
Castejón D, Nogueira N, Andrade CAP.  2022.  Limpet larvae (Patella aspera Röding, 1798), obtained by gonad dissection and fecundation in vitro, settled and metamorphosed on crustose coralline algae. Journal of the Marine Biological Association of the United Kingdom. :1–12.PDF icon Castejon et al_2022_Limpet larvae (Patella aspera Roding, 1798), obtained by gonad dissection and.pdf (901.99 KB)
Domínguez-Martín MAgustina, López-Lozano A, Melero-Rubio Y, Gómez-Baena G, Jiménez-Estrada JAndrés, Kukil K, Díez J, García-Fernández JManuel.  2022.  Marine \textit{Synechococcus sp. Strain WH7803 Shows Specific Adaptative Responses to Assimilate Nanomolar Concentrations of Nitrate. Microbiology Spectrum. 10:e00187–22.PDF icon Domínguez-Martín et al. - 2022 - Marine Synechococcus sp. Strain WH7803 Show.pdf (2.07 MB)
Nikitashina V, Stettin D, Pohnert G.  2022.  Metabolic adaptation of diatoms to hypersalinity. Phytochemistry. :113267.PDF icon Nikitashina et al. - 2022 - Metabolic adaptation of diatoms to hypersalinity.pdf (1.63 MB)

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