Ultrastructural and biochemical analyses reveal cell wall remodelling in lichen-forming microalgae submitted to cyclic desiccation–rehydration

One of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic dehydration-rehydration (D/R) conditions; however, their mechanisms of D/R tolerance are scarcely understood. We tested the hypothesis that D/R-to...

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Published in	Annals of botany Vol. 125; no. 3; pp. 459 - 469
Main Authors	González-Hourcade, María, Braga, Marcia R, del Campo, Eva M, Ascaso, Carmen, Patiño, Cristina, Casano, Leonardo M
Format	Journal Article
Language	English
Published	England Oxford University Press 09.03.2020
Subjects	Cell Wall Desiccation Fluid Therapy Lichens Microalgae Original desiccation Trebouxia microalgae lichen Coccomyxa cell wall folding desiccation tolerance Cell wall cell wall remodelling
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Abstract	One of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic dehydration-rehydration (D/R) conditions; however, their mechanisms of D/R tolerance are scarcely understood. We tested the hypothesis that D/R-tolerant microalgae would have flexible CWs due to species-specific CW ultrastructure and biochemical composition, which could be remodelled by exposure to cyclic D/R. Two lichen microalgae, Trebouxia sp. TR9 (TR9, adapted to rapid D/R cycles) and Coccomyxa simplex (Csol, adapted to seasonal dry periods) were exposed to no or four cycles of desiccation [25-30 % RH (TR9) or 55-60 % RH (Csol)] and 16 h of rehydration (100 % RH). Low-temperature SEM, environmental SEM and freeze-substitution TEM were employed to visualize structural alterations induced by D/R. In addition, CWs were extracted and sequentially fractionated with hot water and KOH, and the gel permeation profile of polysaccharides was analysed in each fraction. The glycosyl composition and linkage of the main polysaccharides of each CW fraction were analysed by GC-MS. All ultrastructural analyses consistently showed that desiccation caused progressive cell shrinkage and deformation in both microalgae, which could be rapidly reversed when water availability increased. Notably, the plasma membrane of TR9 and Csol remained in close contact with the deformed CW. Exposure to D/R strongly altered the size distribution of TR9 hot-water-soluble polysaccharides, composed mainly of a β-3-linked rhamnogalactofuranan and Csol KOH-soluble β-glucans. Cyclic D/R induces biochemical remodelling of the CW that could increase CW flexibility, allowing regulated shrinkage and expansion of D/R-tolerant microalgae.
AbstractList	One of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic dehydration-rehydration (D/R) conditions; however, their mechanisms of D/R tolerance are scarcely understood. We tested the hypothesis that D/R-tolerant microalgae would have flexible CWs due to species-specific CW ultrastructure and biochemical composition, which could be remodelled by exposure to cyclic D/R. Two lichen microalgae, Trebouxia sp. TR9 (TR9, adapted to rapid D/R cycles) and Coccomyxa simplex (Csol, adapted to seasonal dry periods) were exposed to no or four cycles of desiccation [25-30 % RH (TR9) or 55-60 % RH (Csol)] and 16 h of rehydration (100 % RH). Low-temperature SEM, environmental SEM and freeze-substitution TEM were employed to visualize structural alterations induced by D/R. In addition, CWs were extracted and sequentially fractionated with hot water and KOH, and the gel permeation profile of polysaccharides was analysed in each fraction. The glycosyl composition and linkage of the main polysaccharides of each CW fraction were analysed by GC-MS. All ultrastructural analyses consistently showed that desiccation caused progressive cell shrinkage and deformation in both microalgae, which could be rapidly reversed when water availability increased. Notably, the plasma membrane of TR9 and Csol remained in close contact with the deformed CW. Exposure to D/R strongly altered the size distribution of TR9 hot-water-soluble polysaccharides, composed mainly of a β-3-linked rhamnogalactofuranan and Csol KOH-soluble β-glucans. Cyclic D/R induces biochemical remodelling of the CW that could increase CW flexibility, allowing regulated shrinkage and expansion of D/R-tolerant microalgae. One of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic dehydration-rehydration (D/R) conditions; however, their mechanisms of D/R tolerance are scarcely understood. We tested the hypothesis that D/R-tolerant microalgae would have flexible CWs due to species-specific CW ultrastructure and biochemical composition, which could be remodelled by exposure to cyclic D/R.BACKGROUND AND AIMSOne of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic dehydration-rehydration (D/R) conditions; however, their mechanisms of D/R tolerance are scarcely understood. We tested the hypothesis that D/R-tolerant microalgae would have flexible CWs due to species-specific CW ultrastructure and biochemical composition, which could be remodelled by exposure to cyclic D/R.Two lichen microalgae, Trebouxia sp. TR9 (TR9, adapted to rapid D/R cycles) and Coccomyxa simplex (Csol, adapted to seasonal dry periods) were exposed to no or four cycles of desiccation [25-30 % RH (TR9) or 55-60 % RH (Csol)] and 16 h of rehydration (100 % RH). Low-temperature SEM, environmental SEM and freeze-substitution TEM were employed to visualize structural alterations induced by D/R. In addition, CWs were extracted and sequentially fractionated with hot water and KOH, and the gel permeation profile of polysaccharides was analysed in each fraction. The glycosyl composition and linkage of the main polysaccharides of each CW fraction were analysed by GC-MS.METHODSTwo lichen microalgae, Trebouxia sp. TR9 (TR9, adapted to rapid D/R cycles) and Coccomyxa simplex (Csol, adapted to seasonal dry periods) were exposed to no or four cycles of desiccation [25-30 % RH (TR9) or 55-60 % RH (Csol)] and 16 h of rehydration (100 % RH). Low-temperature SEM, environmental SEM and freeze-substitution TEM were employed to visualize structural alterations induced by D/R. In addition, CWs were extracted and sequentially fractionated with hot water and KOH, and the gel permeation profile of polysaccharides was analysed in each fraction. The glycosyl composition and linkage of the main polysaccharides of each CW fraction were analysed by GC-MS.All ultrastructural analyses consistently showed that desiccation caused progressive cell shrinkage and deformation in both microalgae, which could be rapidly reversed when water availability increased. Notably, the plasma membrane of TR9 and Csol remained in close contact with the deformed CW. Exposure to D/R strongly altered the size distribution of TR9 hot-water-soluble polysaccharides, composed mainly of a β-3-linked rhamnogalactofuranan and Csol KOH-soluble β-glucans.KEY RESULTSAll ultrastructural analyses consistently showed that desiccation caused progressive cell shrinkage and deformation in both microalgae, which could be rapidly reversed when water availability increased. Notably, the plasma membrane of TR9 and Csol remained in close contact with the deformed CW. Exposure to D/R strongly altered the size distribution of TR9 hot-water-soluble polysaccharides, composed mainly of a β-3-linked rhamnogalactofuranan and Csol KOH-soluble β-glucans.Cyclic D/R induces biochemical remodelling of the CW that could increase CW flexibility, allowing regulated shrinkage and expansion of D/R-tolerant microalgae.CONCLUSIONSCyclic D/R induces biochemical remodelling of the CW that could increase CW flexibility, allowing regulated shrinkage and expansion of D/R-tolerant microalgae.
Author	Braga, Marcia R Casano, Leonardo M del Campo, Eva M Patiño, Cristina Ascaso, Carmen González-Hourcade, María
AuthorAffiliation	1 University of Alcalá, Department of Life Sciences, Alcalá de Henares , Madrid, Spain 3 Museo Nacional de Ciencias Naturales, CSIC, Department of Biogeochemistry and Microbial Ecology , Madrid, Spain 2 Institute of Botany, Department of Plant Physiology and Biochemistry , São Paulo, SP, Brazil 4 Centro Nacional de Biotecnología, CSIC , Madrid, Spain
AuthorAffiliation_xml	– name: 2 Institute of Botany, Department of Plant Physiology and Biochemistry , São Paulo, SP, Brazil – name: 4 Centro Nacional de Biotecnología, CSIC , Madrid, Spain – name: 1 University of Alcalá, Department of Life Sciences, Alcalá de Henares , Madrid, Spain – name: 3 Museo Nacional de Ciencias Naturales, CSIC, Department of Biogeochemistry and Microbial Ecology , Madrid, Spain
Author_xml	– sequence: 1 givenname: María surname: González-Hourcade fullname: González-Hourcade, María organization: University of Alcalá, Department of Life Sciences, Alcalá de Henares, Madrid, Spain – sequence: 2 givenname: Marcia R surname: Braga fullname: Braga, Marcia R organization: Institute of Botany, Department of Plant Physiology and Biochemistry, São Paulo, SP, Brazil – sequence: 3 givenname: Eva M surname: del Campo fullname: del Campo, Eva M organization: University of Alcalá, Department of Life Sciences, Alcalá de Henares, Madrid, Spain – sequence: 4 givenname: Carmen surname: Ascaso fullname: Ascaso, Carmen organization: Museo Nacional de Ciencias Naturales, CSIC, Department of Biogeochemistry and Microbial Ecology, Madrid, Spain – sequence: 5 givenname: Cristina surname: Patiño fullname: Patiño, Cristina organization: Centro Nacional de Biotecnología, CSIC, Madrid, Spain – sequence: 6 givenname: Leonardo M orcidid: 0000-0002-2304-7317 surname: Casano fullname: Casano, Leonardo M organization: University of Alcalá, Department of Life Sciences, Alcalá de Henares, Madrid, Spain
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Keywords	desiccation Trebouxia microalgae lichen Coccomyxa cell wall folding desiccation tolerance Cell wall cell wall remodelling
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Snippet	One of the most distinctive features of desiccation-tolerant plants is their high cell wall (CW) flexibility. Most lichen microalgae can tolerate drastic...
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SubjectTerms	Cell Wall Desiccation Fluid Therapy Lichens Microalgae Original
Title	Ultrastructural and biochemical analyses reveal cell wall remodelling in lichen-forming microalgae submitted to cyclic desiccation–rehydration
URI	https://www.ncbi.nlm.nih.gov/pubmed/31679006 https://www.proquest.com/docview/2311920813 https://pubmed.ncbi.nlm.nih.gov/PMC7061176
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