Cell wall and organelle modifications during nitrogen starvation in Nannochloropsis oceanica F&M-M24
Autor: | Bianca Roncaglia, Liliana Rodolfi, Alessio Papini, Graziella Chini Zittelli, Mario R. Tredici |
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Rok vydání: | 2021 |
Předmět: |
0106 biological sciences
0303 health sciences Nitrogen starvation Chemistry Plant physiology Lipid accumulation Plant Science Aquatic Science Photosynthesis 01 natural sciences Chloroplast Cell wall 03 medical and health sciences Ultrastructure Thylakoid Lipid droplet Organelle Electron microscopy Biophysics Nannochloropsis oceanica 030304 developmental biology 010606 plant biology & botany |
Zdroj: | Journal of applied phycology 33 (2021): 2069–2080. doi:10.1007/s10811-021-02416-0 info:cnr-pdr/source/autori:Roncaglia B., Papini A., Chini Zittelli G., Rodolfi L., Tredici M. R./titolo:Cell wall and organelle modifications during nitrogen starvation in Nannochloropsis oceanica F&M-M24/doi:10.1007%2Fs10811-021-02416-0/rivista:Journal of applied phycology/anno:2021/pagina_da:2069/pagina_a:2080/intervallo_pagine:2069–2080/volume:33 |
ISSN: | 1573-5176 0921-8971 |
Popis: | Nannochloropsis oceanica F&M-M24 is able to increase its lipid content during nitrogen starvation to more than 50% of the total biomass. We investigated the ultrastructural changes and the variation in the content of main cell biomolecules that accompany the final phase of lipid accumulation. Nitrogen starvation induced a first phase of thylakoid disruption followed by chloroplast macroautophagy and formation of lipid droplets. During this phase, the total amount of proteins decreased by one-third, while carbohydrates decreased by 12–13%, suggesting that lipid droplets were formed by remodelling of chloroplast membranes and synthesis of fatty acids from carbohydrates and amino acids. The change in mitochondrial ultrastructure suggests also that these organelles were involved in the process. The cell wall increased its thickness and changed its structure during starvation, indicating that a disruption process could be partially affected by the increase in wall thickness for biomolecules recovery from starved cells. The wall thickness in strain F&M-M24 was much lower than that observed in other strains of N. oceanica, showing a possible advantage of this strain for the purpose of biomolecules extraction. The modifications following starvation were interpreted as a response to reduction of availability of a key nutrient (nitrogen). The result is a prolonged survival in quiescence until an improvement of the environmental conditions (nutrient availability) allows the rebuilding of the photosynthetic apparatus and the full recovery of cell functions. |
Databáze: | OpenAIRE |
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