Litcius/Paper detail

How dry is dry? Molecular mobility in relation to thallus water content in a lichen

Fabio Candotto Carniel, Beatriz Fernández‐Marín, Erwann Arc, Teresa Craighero, José Manuel Laza, Guido Incerti, Mauro Tretiach, Ilse Kranner

2020Journal of Experimental Botany35 citationsDOI

Abstract

Lichens can withstand extreme desiccation to water contents of ≤ 0.1 g H2O g-1 DW, and in the desiccated state are among the most extremotolerant organisms known. Desiccation-tolerant life-forms such as seeds, mosses and lichens survive 'vitrification', that is the transition of their cytoplasm to a 'glassy' state, which causes metabolism to cease. However, our understanding of the mechanisms of desiccation tolerance is hindered by poor knowledge of what reactions occur in the desiccated state. Using Flavoparmelia caperata as a model lichen, we determined at what water contents vitrification occurred upon desiccation. Molecular mobility was assessed by dynamic mechanical thermal analysis, and the de- and re-epoxidation of the xanthophyll cycle pigments (measured by HPLC) was used as a proxy to assess enzyme activity. At 20 °C vitrification occurred between 0.12-0.08 g H2O g-1 DW and enzymes were active in a 'rubbery' state (0.17 g H2O g-1 DW) but not in a glassy state (0.03 g H2O g-1 DW). Therefore, desiccated tissues may appear to be 'dry' in the conventional sense, but subtle differences in water content will have substantial consequences on the types of (bio)chemical reactions that can occur, with downstream effects on longevity in the desiccated state.

Topics & Concepts

DesiccationThallusDesiccation toleranceVitrificationLichenBotanyDry weightBiologyChemistryAndrologyMedicineLichen and fungal ecologyBiocrusts and Microbial EcologyBryophyte Studies and Records