The red alga Tsunamia transpacifica (Stylonematophyceae) from plastic drift shows adaptation to its uncommon habitat in ultrastructure and soluble low molecular weight carbohydrate composition

The recently described red alga Tsunamia transpacifica (Stylonematophyceae) was previously isolated from plastic drift found at the pacific coast, but the natural habitat remains unknown. Here, we investigate ultrastructural details and the low molecular weight soluble carbohydrate composition to ge...

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Bibliographic Details
Published in:Protoplasma 2021-11, Vol.258 (6), p.1307-1321
Main Authors: Holzinger, Andreas, Obwegeser, Sabrina, Andosch, Ancuela, Karsten, Ulf, Oppermann, Christina, Ruth, Wolfgang, van de Meene, Allison, Goodman, Christopher D., Lütz-Meindl, Ursula, West, John A.
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Biosorption
Carbohydrate composition
Cell Biology
Cell walls
Chloroplasts
Cobalt
Cytoplasm
Degradation products
Drift
Ecosystem
Extracellular polymers
Habitats
Life Sciences
Light microscopy
Liquid chromatography
Mass spectroscopy
Molecular Weight
Original
Original Article
Phosphorus
Plant Sciences
Plastics
Rhodophyta
Solutes
Sorbitol
Stylonematophyceae
Tsunamia transpacifica
Ultrastructure
Zoology
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Summary:The recently described red alga Tsunamia transpacifica (Stylonematophyceae) was previously isolated from plastic drift found at the pacific coast, but the natural habitat remains unknown. Here, we investigate ultrastructural details and the low molecular weight soluble carbohydrate composition to get further insight into the adaptation to this uncommon habitat. By means of high pressure freeze fixation, followed by freeze substitution, we could detect an up to 2-µm-thick cell wall surrounded by a distinct layer of extracellular polymeric substances (EPS), likely responsible for the adhering capacities of Tsunamia . The central position of the nucleus and multilobed parietal chloroplast, already observed by light microscopy, could be confirmed. The ultrastructure revealed large electron-dense bodies (EB) in the central cytoplasm, likely resembling degradation products of the chloroplast. Interestingly, these structures contained phosphorous and cobalt, and iron was found in smaller rounded electron-dense bodies by electron energy loss spectroscopy (EELS). Accumulation of these elements suggests a high biosorption activity of Tsunamia . Liquid chromatography-mass spectrometry (LC–MS) data showed the presence of two heterosides (floridoside and digeneaside) together with the polyol sorbitol, which are known as organic osmolytes and compatible solutes. Taken together, these are the first observations on ultrastructural details, element storage and accumulation of protective compounds are contributing to our understanding of the ultrastructural and osmotic solute basis for the ability of Tsunamia to thrive on plastic surfaces.
ISSN:0033-183X
1615-6102
DOI:10.1007/s00709-021-01674-6