Photosynthesis on the Edge: Photoinhibition, Desiccation and Freezing Tolerance of Antarctic Bryophytes

Overview

Journal Photosynth Res

Publisher Springer

Date 2020 Oct 9

PMID 33033976

Citations 8

Authors

Alicia Victoria Perera-Castro

Jaume Flexas

Agueda Maria Gonzalez-Rodriguez

Beatriz Fernandez-Marin

Affiliations

Soon will be listed here.

Abstract

In Antarctica, multiple stresses (low temperatures, drought and excessive irradiance) hamper photosynthesis even in summer. We hypothesize that controlled inactivation of PSII reaction centres, a mechanism widely studied by pioneer work of Fred Chow and co-workers, may effectively guarantee functional photosynthesis under these conditions. Thus, we analysed the energy partitioning through photosystems in response to temperature in 15 bryophyte species presenting different worldwide distributions but all growing in Livingston Island, under controlled and field conditions. We additionally tested their tolerance to desiccation and freezing and compared those with their capability for sexual reproduction in Antarctica (as a proxy to overall fitness). Under field conditions, when irradiance rules air temperature by the warming of shoots (up to 20 °C under sunny days), a predominance of sustained photoinhibition beyond dynamic heat dissipation was observed at low temperatures. Antarctic endemic and polar species showed the largest increases of photoinhibition at low temperatures. On the contrary, the variation of thermal dissipation with temperature was not linked to species distribution. Instead, maximum non-photochemical quenching at 20 °C was related (strongly and positively) with desiccation tolerance, which also correlated with fertility in Antarctica, but not with freezing tolerance. Although all the analysed species tolerated - 20 °C when dry, the tolerance to freezing in hydrated state ranged from the exceptional ability of Schistidium rivulare (that survived for 14 months at - 80 °C) to the susceptibility of Bryum pseudotriquetrum (that died after 1 day at - 20 °C unless being desiccated before freezing).

Citing Articles

Basking in the sun: how mosses photosynthesise and survive in Antarctica.

Yin H, Perera-Castro A, Randall K, Turnbull J, Waterman M, Dunn J Photosynth Res. 2023; 158(2):151-169.

PMID: 37515652 PMC: 10684656. DOI: 10.1007/s11120-023-01040-y.

Uphill energy transfer mechanism for photosynthesis in an Antarctic alga.

Kosugi M, Kawasaki M, Shibata Y, Hara K, Takaichi S, Moriya T Nat Commun. 2023; 14(1):730.

PMID: 36792917 PMC: 9931709. DOI: 10.1038/s41467-023-36245-1.

High Resilience and Fast Acclimation Processes Allow the Antarctic Moss to Increase Its Carbon Gain in Warmer Growing Conditions.

Gemal E, Green T, Cary S, Colesie C Biology (Basel). 2022; 11(12).

PMID: 36552282 PMC: 9775354. DOI: 10.3390/biology11121773.

Metabolic profiling and gene expression analyses provide insights into cold adaptation of an Antarctic moss .

Liu S, Li T, Fang S, Zhang P, Yi D, Cong B Front Plant Sci. 2022; 13:1006991.

PMID: 36176693 PMC: 9514047. DOI: 10.3389/fpls.2022.1006991.

Integrated transcriptome and metabolome analyses reveal the adaptation of Antarctic moss to drought stress.

Fang S, Li T, Zhang P, Liu C, Cong B, Liu S Front Plant Sci. 2022; 13:924162.

PMID: 36035699 PMC: 9403716. DOI: 10.3389/fpls.2022.924162.

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