Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx

The terrestrial flora of Antarctica’s frozen continent is restricted to sparse ice-free areas and dominated by lichens and bryophytes. These plants frequently battle sub-zero temperatures, extreme winds and reduced water availability; all influencing their ability to survive and grow. Antarctic moss...

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Bibliographic Details
Main Authors: Alicia V. Perera-Castro, Melinda J. Waterman, Johanna D. Turnbull, Michael B. Ashcroft, Ella McKinley, Jennifer R. Watling, Jessica Bramley-Alves, Angelica Casanova-Katny, Gustavo Zuniga, Jaume Flexas, Sharon A. Robinson
Format: Dataset
Language:unknown
Published: 2020
Subjects:
Botany
Plant Biology
Plant Systematics and Taxonomy
Plant Cell and Molecular Biology
Plant Developmental and Reproductive Biology
Plant Pathology
Plant Physiology
Plant Biology not elsewhere classified
Antarctica
bryophytes
carbon balance
electron transport rate
mesophyll conductance
net CO2 assimilation
non-photochemical quenching
respiration
Antarctic
East Antarctica
King George Island
Windmill Islands
Antarc*
Schistidium antarctici
Online Access:https://doi.org/10.3389/fpls.2020.01178.s001
https://figshare.com/articles/dataset/Table_1_It_Is_Hot_in_the_Sun_Antarctic_Mosses_Have_High_Temperature_Optima_for_Photosynthesis_Despite_Cold_Climate_docx/12777089
id ftfrontimediafig:oai:figshare.com:article/12777089
record_format openpolar
spelling ftfrontimediafig:oai:figshare.com:article/12777089 2023-05-15T14:04:09+02:00 Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx Alicia V. Perera-Castro Melinda J. Waterman Johanna D. Turnbull Michael B. Ashcroft Ella McKinley Jennifer R. Watling Jessica Bramley-Alves Angelica Casanova-Katny Gustavo Zuniga Jaume Flexas Sharon A. Robinson 2020-08-07T13:49:26Z https://doi.org/10.3389/fpls.2020.01178.s001 https://figshare.com/articles/dataset/Table_1_It_Is_Hot_in_the_Sun_Antarctic_Mosses_Have_High_Temperature_Optima_for_Photosynthesis_Despite_Cold_Climate_docx/12777089 unknown doi:10.3389/fpls.2020.01178.s001 https://figshare.com/articles/dataset/Table_1_It_Is_Hot_in_the_Sun_Antarctic_Mosses_Have_High_Temperature_Optima_for_Photosynthesis_Despite_Cold_Climate_docx/12777089 Botany Plant Biology Plant Systematics and Taxonomy Plant Cell and Molecular Biology Plant Developmental and Reproductive Biology Plant Pathology Plant Physiology Plant Biology not elsewhere classified Antarctica bryophytes carbon balance electron transport rate mesophyll conductance net CO2 assimilation non-photochemical quenching respiration Dataset 2020 ftfrontimediafig https://doi.org/10.3389/fpls.2020.01178.s001 2020-08-12T22:55:36Z The terrestrial flora of Antarctica’s frozen continent is restricted to sparse ice-free areas and dominated by lichens and bryophytes. These plants frequently battle sub-zero temperatures, extreme winds and reduced water availability; all influencing their ability to survive and grow. Antarctic mosses, however, can have canopy temperatures well above air temperature. At midday, canopy temperatures can exceed 15°C, depending on moss turf water content. In this study, the optimum temperature of photosynthesis was determined for six Antarctic moss species: Bryum pseudotriquetrum, Ceratodon purpureus, Chorisodontium aciphyllum, Polytrichastrum alpinum, Sanionia uncinata, and Schistidium antarctici collected from King George Island (maritime Antarctica) and/or the Windmill Islands, East Antarctica. Both chlorophyll fluorescence and gas exchange showed maximum values of electron transport rate occurred at canopy temperatures higher than 20°C. The optimum temperature for both net assimilation of CO 2 and photoprotective heat dissipation of three East Antarctic species was 20–30°C and at temperatures below 10°C, mesophyll conductance did not significantly differ from 0. Maximum mitochondrial respiration rates occurred at temperatures higher than 35°C and were lower by around 80% at 5°C. Despite the extreme cold conditions that Antarctic mosses face over winter, the photosynthetic apparatus appears optimised to warm temperatures. Our estimation of the total carbon balance suggests that survival in this cold environment may rely on a capacity to maximize photosynthesis for brief periods during summer and minimize respiratory carbon losses in cold conditions. Dataset Antarc* Antarctic Antarctica East Antarctica King George Island Schistidium antarctici Windmill Islands Frontiers: Figshare Antarctic East Antarctica King George Island Windmill Islands ENVELOPE(110.417,110.417,-66.350,-66.350)
institution Open Polar
collection Frontiers: Figshare
op_collection_id ftfrontimediafig
language unknown
topic Botany
Plant Biology
Plant Systematics and Taxonomy
Plant Cell and Molecular Biology
Plant Developmental and Reproductive Biology
Plant Pathology
Plant Physiology
Plant Biology not elsewhere classified
Antarctica
bryophytes
carbon balance
electron transport rate
mesophyll conductance
net CO2 assimilation
non-photochemical quenching
respiration
spellingShingle Botany
Plant Biology
Plant Systematics and Taxonomy
Plant Cell and Molecular Biology
Plant Developmental and Reproductive Biology
Plant Pathology
Plant Physiology
Plant Biology not elsewhere classified
Antarctica
bryophytes
carbon balance
electron transport rate
mesophyll conductance
net CO2 assimilation
non-photochemical quenching
respiration
Alicia V. Perera-Castro
Melinda J. Waterman
Johanna D. Turnbull
Michael B. Ashcroft
Ella McKinley
Jennifer R. Watling
Jessica Bramley-Alves
Angelica Casanova-Katny
Gustavo Zuniga
Jaume Flexas
Sharon A. Robinson
Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
topic_facet Botany
Plant Biology
Plant Systematics and Taxonomy
Plant Cell and Molecular Biology
Plant Developmental and Reproductive Biology
Plant Pathology
Plant Physiology
Plant Biology not elsewhere classified
Antarctica
bryophytes
carbon balance
electron transport rate
mesophyll conductance
net CO2 assimilation
non-photochemical quenching
respiration
description The terrestrial flora of Antarctica’s frozen continent is restricted to sparse ice-free areas and dominated by lichens and bryophytes. These plants frequently battle sub-zero temperatures, extreme winds and reduced water availability; all influencing their ability to survive and grow. Antarctic mosses, however, can have canopy temperatures well above air temperature. At midday, canopy temperatures can exceed 15°C, depending on moss turf water content. In this study, the optimum temperature of photosynthesis was determined for six Antarctic moss species: Bryum pseudotriquetrum, Ceratodon purpureus, Chorisodontium aciphyllum, Polytrichastrum alpinum, Sanionia uncinata, and Schistidium antarctici collected from King George Island (maritime Antarctica) and/or the Windmill Islands, East Antarctica. Both chlorophyll fluorescence and gas exchange showed maximum values of electron transport rate occurred at canopy temperatures higher than 20°C. The optimum temperature for both net assimilation of CO 2 and photoprotective heat dissipation of three East Antarctic species was 20–30°C and at temperatures below 10°C, mesophyll conductance did not significantly differ from 0. Maximum mitochondrial respiration rates occurred at temperatures higher than 35°C and were lower by around 80% at 5°C. Despite the extreme cold conditions that Antarctic mosses face over winter, the photosynthetic apparatus appears optimised to warm temperatures. Our estimation of the total carbon balance suggests that survival in this cold environment may rely on a capacity to maximize photosynthesis for brief periods during summer and minimize respiratory carbon losses in cold conditions.
format Dataset
author Alicia V. Perera-Castro
Melinda J. Waterman
Johanna D. Turnbull
Michael B. Ashcroft
Ella McKinley
Jennifer R. Watling
Jessica Bramley-Alves
Angelica Casanova-Katny
Gustavo Zuniga
Jaume Flexas
Sharon A. Robinson
author_facet Alicia V. Perera-Castro
Melinda J. Waterman
Johanna D. Turnbull
Michael B. Ashcroft
Ella McKinley
Jennifer R. Watling
Jessica Bramley-Alves
Angelica Casanova-Katny
Gustavo Zuniga
Jaume Flexas
Sharon A. Robinson
author_sort Alicia V. Perera-Castro
title Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
title_short Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
title_full Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
title_fullStr Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
title_full_unstemmed Table_1_It Is Hot in the Sun: Antarctic Mosses Have High Temperature Optima for Photosynthesis Despite Cold Climate.docx
title_sort table_1_it is hot in the sun: antarctic mosses have high temperature optima for photosynthesis despite cold climate.docx
publishDate 2020
url https://doi.org/10.3389/fpls.2020.01178.s001
https://figshare.com/articles/dataset/Table_1_It_Is_Hot_in_the_Sun_Antarctic_Mosses_Have_High_Temperature_Optima_for_Photosynthesis_Despite_Cold_Climate_docx/12777089
long_lat ENVELOPE(110.417,110.417,-66.350,-66.350)
geographic Antarctic
East Antarctica
King George Island
Windmill Islands
geographic_facet Antarctic
East Antarctica
King George Island
Windmill Islands
genre Antarc*
Antarctic
Antarctica
East Antarctica
King George Island
Schistidium antarctici
Windmill Islands
genre_facet Antarc*
Antarctic
Antarctica
East Antarctica
King George Island
Schistidium antarctici
Windmill Islands
op_relation doi:10.3389/fpls.2020.01178.s001
https://figshare.com/articles/dataset/Table_1_It_Is_Hot_in_the_Sun_Antarctic_Mosses_Have_High_Temperature_Optima_for_Photosynthesis_Despite_Cold_Climate_docx/12777089
op_doi https://doi.org/10.3389/fpls.2020.01178.s001
_version_ 1766275165932486656

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