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Mixotrophy by Phytoflagellates in the Northern Gulf of Alaska: Impacts of Physico-Chemical Characteristics and Prey Concentration on Feeding by Photosynthetic Nano- and Dinoflagellates.. 2021.
Diel variations in the photosynthetic parameters of Prochlorococcus strain PCC 9511: combined effects of light and cell cycle. Limnology and Oceanography. 50:850–863.. 2005.
Unveiling membrane thermoregulation strategies in marine picocyanobacteria. New Phytologist. :nph.16239.. 2019.
Trait-dependent variability of the response of marine phytoplankton to oil and dispersant exposure. Marine Pollution Bulletin. 153:110906.. 2020.
Phaeobacter inhibens induces apoptosis-like programmed cell death in calcifying Emiliania huxleyi. Scientific Reports. 9:1–12.. 2019.
The Phaeodactylum genome reveals the evolutionary history of diatom genomes. Nature. 456:239–244.. 2008.
Comparative genomics reveals surprising divergence of two closely related strains of uncultivated UCYN-A cyanobacteria. The ISME Journal. 8:2530–2542.. 2014.
Decrease in coccolithophore calcification and CO2 since the middle Miocene. Nature Communications. 7:10284.. 2016.
Experimental identification and in silico prediction of bacterivory in green algae. The ISME Journal. :1–14.. 2021.
Light history influences the response of the marine cyanobacterium Synechococcus sp. WH7803 to oxidative stress. Plant Physiology. 156:1934–1954.. 2011.
Phenotypic variability in the coccolithophore emiliania huxleyi.. PloS one. 11:e0157697.. 2016.
Influence of temperature and CO 2 on Plasma-membrane permeability to CO 2 and HCO 3 - in the marine haptophytes emiliania huxleyi and calcidiscus leptoporus (prymnesiophyceae). Journal of Phycology. :jpy.13017.. 2020.
Population genomics of picophytoplankton unveils novel chromosome hypervariability. Science Advances. 3:e1700239.. 2017.
Organellar inheritance in the green lineage: Insights from ostreococcus tauri. Genome Biology and Evolution. 5:1503–1511.. 2013.
Genomes of diverse isolates of the marine cyanobacterium Prochlorococcus. Scientific Data. 1:1–11.. 2014.
Quantitative assessment of picoeucaryotes in the natural environment using taxon specific oligonucleotide probes in association with TSA-FISH (Tyramide Signal Amplification - Fluorescent In Situ Hybridization) and flow cytometry. Applied and Environmental Microbiology. 69:5519–5529.. 2003.
X-ray nanotomography of coccolithophores reveals that coccolith mass and segment number correlate with grid size. Nature Communications. 10:751.. 2019.
Abrupt declines in marine phytoplankton production driven by warming and biodiversity loss in a microcosm experiment. Ecology Letters. 23:457–466.. 2020.
Capacity of the common Arctic picoeukaryote Micromonas to adapt to a warming ocean. Limnology and Oceanography Letters. 5:221–227.. 2020.
Morphological and phylogenetic characterization of new gephyrocapsa isolates suggests introgressive hybridization in the Emiliania/Gephyrocapsa complex (haptophyta). Protist. 166:323–336.. 2015.
Integrative taxonomy of the pavlovophyceae (haptophyta) : a reassessment. Protist. 162:738–761.. 2011.
On the description of Tisochrysis lutea gen . nov . sp . nov . and Isochrysis nuda sp. nov. in the Isochrysidales, and the transfer of Dicrateria to the Prymnesiales (Haptophyta). Journal of Applied Phycology. 25:1763–1776.. 2013.
Genetic delineation between and within the widespread coccolithophore morpho-species Emiliania huxleyi and Gephyrocapsa oceanica (Haptophyta). Journal of Phycology. 50:140–148.. 2014.
Recent reticulate evolution in the ecologically dominant lineage of coccolithophores. Frontiers in Microbiology. 7. 2016.