RCC references

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Gadler P, Reiter TC, Hoelsch K, Weuster-Botz D, Fabe K.  2009.  Enantiocomplementary inverting sec-alkylsulfatase activity in cyano- and thio-bacteria Synechococcus and Paracoccus spp.: selectivity enhancement by medium engineering. Tetrahedron: Asymmetry. 20:115–118.
Koslová A, Hackl T, Bade F, Kasikovic ASanchez, Barenhoff K, Schimm F, Mersdorf U, Fischer MG.  2024.  Endogenous virophages are active and mitigate giant virus infection in the marine protist Cafeteria burkhardae. Proceedings of the National Academy of Sciences. 121:e2314606121.PDF icon Koslova et al_2024_Endogenous virophages are active and mitigate giant virus infection in the.pdf (2.07 MB)
Lobanov AV, Fomenko DE, Zhang Y, Sengupta A, Hatfield DL, Gladyshev VN.  2007.  Evolutionary dynamics of eukaryotic selenoproteomes: large selenoproteomes may associate with aquatic life and small with terrestrial life. Genome Biology. 8:R198.
Doré H, Farrant GK, Guyet U, Haguait J, Humily F, Ratin M, Pitt FD, Ostrowski M, Six C, Brillet-Guéguen L et al..  2020.  Evolutionary mechanisms of long-term genome diversification associated with niche partitioning in marine picocyanobacteria. Frontiers in Microbiology. 11:1–23.PDF icon Dore et al_2020_Evolutionary mechanisms of long-term genome diversification associated with.pdf (13.44 MB)
Liu H, Probert I, Uitz J, Claustre H, Aris-Brossou S, Frada M, Not F, de Vargas C.  2009.  Extreme diversity in noncalcifying haptophytes explains a major pigment paradox in open oceans. Proceedings of the National Academy of Sciences of the United States of America. 106:12803–12808.PDF icon Liu et al_2009_Extreme diversity in noncalcifying haptophytes explains a major pigment paradox.pdf (1.68 MB)
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Hackl T, Martin R, Barenhoff K, Duponchel S, Heider D, Fischer MG.  2020.  Four high-quality draft genome assemblies of the marine heterotrophic nanoflagellate Cafeteria roenbergensis. Scientific Data. 7:29.PDF icon Hackl et al_2020_Four high-quality draft genome assemblies of the marine heterotrophic.pdf (555.19 KB)
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Monier A, Sudek S, Fast NM, Worden AZ.  2013.  Gene invasion in distant eukaryotic lineages: discovery of mutually exclusive genetic elements reveals marine biodiversity. The ISME journal. 7:1764–1774.PDF icon Monier et al. - Gene invasion in distant eukaryotic lineages discovery of mutually exclusive genetic elements reveals marine biodiversit.pdf (2.08 MB)
Humily F, Partensky F, Six C, Farrant GK, Ratin M, Marie D, Garczarek L.  2013.  A gene island with two possible configurations is involved in chromatic acclimation in marine synechococcus. PLoS ONE. 8:e84459.PDF icon Humily et al_2013_A gene island with two possible configurations is involved in chromatic.pdf (1.54 MB)
Misumi O, Yoshida Y, Nishida K, Fujiwara T, Sakajiri T, Hirooka S, Nishimura Y, Kuroiwa T.  2008.  Genome analysis and its significance in four unicellular algae, Cyanidioshyzon merolae, Ostreococcus tauri, Chlamydomonas reinhardtii, and Thalassiosira pseudonana. Journal of Plant Research. 121:3–17.
Derelle E, Ferraz C, Rombauts S, Rouze P, Worden AZ, Robbens S, Partensky F, Degroeve S, Echeynie S, Cooke R et al..  2006.  Genome analysis of the smallest free-living eukaryote Ostreococcus tauri unveils many unique features. Proceedings of the National Academy of Sciences of the United States of America. 103:11647–11652.PDF icon Derelle et al_2006_Genome analysis of the smallest free-living eukaryote Ostreococcus tauri.pdf (1.01 MB)
Robbens S, Khadaroo B, Camasses A, Derelle E, Ferraz C, Inze D, Peer Y Van de, Moreau H.  2005.  Genome-wide analysis of core cell cycle genes in the unicellular green alga Ostreococcus tauri. Molecular Biology and Evolution. 22:589–597.PDF icon Robbens et al_2005_Genome-wide analysis of core cell cycle genes in the unicellular green alga.pdf (527.35 KB)
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)
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)
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)
Worden AZ, Lee J.-H, Mock T, Rouzé P, Simmons MP, Aerts AL, Allen AE, Cuvelier ML, Derelle E, Everett MV et al..  2009.  Green evolution and dynamic adaptations revealed by genomes of the marine picoeukaryotes Micromonas. Science. 324:268–272.
López-Pacheco IY, Ayala-Moreno VGuadalupe, Mejia-Melara CArlette, Rodríguez-Rodríguez J, Cuellar-Bermudez SP, González-González RBerenice, Coronado-Apodaca KG, Farfan-Cabrera LI, González-Meza GMaría, Iqbal HMN et al..  2023.  Growth Behavior, Biomass Composition and Fatty Acid Methyl Esters (FAMEs) Production Potential of Chlamydomonas reinhardtii, and Chlorella vulgaris Cultures. Marine Drugs. 21:450.PDF icon López-Pacheco et al. - 2023 - Growth Behavior, Biomass Composition and Fatty Aci.pdf (2.38 MB)
Zhang Y, Li Z, Schulz KG, Hu Y, Irwin AJ, Finkel ZV.  2021.  Growth-dependent changes in elemental stoichiometry and macromolecular allocation in the coccolithophore Emiliania huxleyi under different environmental conditions. Limnology and Oceanography. 66:2999–3009.PDF icon Zhang et al. - 2021 - Growth-dependent changes in elemental stoichiometr.pdf (312.78 KB)
Frada M, Young J, Cachão M, Lino S, Martins A, Narciso Á, Probert I, de Vargas C.  2010.  A guide to extant coccolithophores (Calcihaptophycidae, Haptophyta) using light microscopy.. Journal of Nannoplankton Research. 31:58–112.PDF icon Frada et al_2010_A guide to extant coccolithophores (Calcihaptophycidae, Haptophyta) using light.pdf (2.52 MB)
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Fernandes T, Cordeiro N.  2020.  Hemiselmis andersenii and chlorella stigmatophora as new sources of High-value compounds: A lipidomic approach. Journal of Phycology. :jpy.13042.
Bottini C, Dapiaggi M, Erba E, Faucher G, Rotiroti N.  2020.  High resolution spatial analyses of trace elements in coccoliths reveal new insights into element incorporation in coccolithophore calcite. Scientific Reports. 10:9825.PDF icon Bottini et al. - 2020 - High resolution spatial analyses of trace elements.pdf (9.04 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)
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Fischer R, HA G, Ptacnik R.  2017.  Identity of the limiting nutrient (N vs. P) affects the competitive success of mixotrophs. Marine Ecology Progress Series. 563:51–63.
Faucher G, Hoffmann L, Bach LT, Bottini C, Erba E, Riebesell U.  2017.  Impact of trace metal concentrations on coccolithophore growth and morphology: laboratory simulations of Cretaceous stress. Biogeosciences. 14:3603–3613.PDF icon Faucher et al. - 2017 - Impact of trace metal concentrations on coccolitho.pdf (13.72 MB)
Fischer R, Giebel H-A, Hillebrand H, Ptacnik R.  2017.  Importance of mixotrophic bacterivory can be predicted by light and loss rates. Oikos. 126:713–722.
Frada MJ, Bidle KD, Probert I, de Vargas C.  2012.  In situ survey of life cycle phases of the coccolithophore Emiliania huxleyi (Haptophyta). Environmental Microbiology. 14:1558–1569.PDF icon Frada et al_2012_In situ survey of life cycle phases of the coccolithophore Emiliania huxleyi.pdf (888.67 KB)

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