@article {Decelle2019, title = {Algal remodeling in a ubiquitous planktonic photosymbiosis}, journal = {Current Biology}, volume = {29}, number = {6}, year = {2019}, note = {Publisher: Cell Press tex.mendeley-tags: RCC1719}, month = {mar}, pages = {968{\textendash}978.e4}, abstract = {Photosymbiosis between single-celled hosts and microalgae is common in oceanic plankton, especially in oligotrophic surface waters. However, the functioning of this ecologically important cell-cell interaction and the subcellular mechanisms allowing the host to accommodate and benefit from its microalgae remain enigmatic. Here, using a combination of quantitative single-cell structural and chemical imaging techniques (FIB-SEM, nanoSIMS, Synchrotron X-ray fluorescence), we show that the structural organization, physiology, and trophic status of the algal symbionts (the haptophyte Phaeocystis) significantly change within their acantharian hosts compared to their free-living phase in culture. In symbiosis, algal cell division is blocked, photosynthesis is enhanced, and cell volume is increased by up to 10-fold with a higher number of plastids (from 2 to up to 30) and thylakoid membranes. The multiplication of plastids can lead to a 38-fold increase of the total plastid volume in a cell. Subcellular mapping of nutrients (nitrogen and phosphorous) and their stoichiometric ratios shows that symbiotic algae are impoverished in phosphorous and suggests a higher investment in energy-acquisition machinery rather than in growth. Nanoscale imaging also showed that the host supplies a substantial amount of trace metals (e.g., iron and cobalt), which are stored in algal vacuoles at high concentrations (up to 660 ppm). Sulfur mapping reveals a high concentration in algal vacuoles that may be a source of antioxidant molecules. Overall, this study unveils an unprecedented morphological and metabolic transformation of microalgae following their integration into a host, and it suggests that this widespread symbiosis is a farming strategy wherein the host engulfs and exploits microalgae.}, keywords = {RCC1719}, issn = {0960-9822}, doi = {10.1016/J.CUB.2019.01.073}, url = {https://www.sciencedirect.com/science/article/abs/pii/S0960982219301320$\#$undfig1}, author = {Decelle, Johan and Stryhanyuk, Hryhoriy and Gallet, Benoit and Veronesi, Giulia and Schmidt, Matthias and Balzano, Sergio and Marro, Sophie and Uwizeye, Clarisse and Jouneau, Pierre-Henri and Lupette, Josselin and Jouhet, Juliette and Mar{\'e}chal, {\'E}ric and Schwab, Yannick and Schieber, Nicole L. and Tucoulou, R{\'e}mi and Richnow, Hans and Finazzi, Giovanni and Musat, Niculina} }