Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species
<i>Ranunculus glacialis</i> grows and reproduces successfully, although the snow-free time period is short (2–3 months) and night frosts are frequent. At a nival site (3185 m a.s.l.), we disentangled the interplay between the atmospheric temperature, leaf temperatures, and leaf freezing...
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2020-09-01
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| Series: | International Journal of Molecular Sciences |
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| Online Access: | https://www.mdpi.com/1422-0067/21/19/7042 |
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doaj-ab67225f94954b6c9a32f81c514ebdce2020-11-25T03:12:06ZengMDPI AGInternational Journal of Molecular Sciences1661-65961422-00672020-09-01217042704210.3390/ijms21197042Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival SpeciesMatthias Stegner0Barbara Lackner1Tanja Schäfernolte2Othmar Buchner3Nannan Xiao4Notburga Gierlinger5Andreas Holzinger6Gilbert Neuner7Department of Botany, University of Innsbruck, 6020 Innsbruck, AustriaDepartment of Botany, University of Innsbruck, 6020 Innsbruck, AustriaDepartment of Botany, University of Innsbruck, 6020 Innsbruck, AustriaDepartment of Biosciences, University of Salzburg, 5020 Salzburg, AustriaInstitute for Biophysics, University of Natural Resources and Life Sciences (BOKU), 1190 Vienna, AustriaInstitute for Biophysics, University of Natural Resources and Life Sciences (BOKU), 1190 Vienna, AustriaDepartment of Botany, University of Innsbruck, 6020 Innsbruck, AustriaDepartment of Botany, University of Innsbruck, 6020 Innsbruck, Austria<i>Ranunculus glacialis</i> grows and reproduces successfully, although the snow-free time period is short (2–3 months) and night frosts are frequent. At a nival site (3185 m a.s.l.), we disentangled the interplay between the atmospheric temperature, leaf temperatures, and leaf freezing frequency to assess the actual strain. For a comprehensive understanding, the freezing behavior from the whole plant to the leaf and cellular level and its physiological after-effects as well as cell wall chemistry were studied. The atmospheric temperatures did not mirror the leaf temperatures, which could be 9.3 °C lower. Leaf freezing occurred even when the air temperature was above 0 °C. Ice nucleation at on average −2.6 °C started usually independently in each leaf, as the shoot is deep-seated in unfrozen soil. All the mesophyll cells were subjected to freezing cytorrhysis. Huge ice masses formed in the intercellular spaces of the spongy parenchyma. After thawing, photosynthesis was unaffected regardless of whether ice had formed. The cell walls were pectin-rich and triglycerides occurred, particularly in the spongy parenchyma. At high elevations, atmospheric temperatures fail to predict plant freezing. Shoot burial prevents ice spreading, specific tissue architecture enables ice management, and the flexibility of cell walls allows recurrent freezing cytorrhysis. The peculiar patterning of triglycerides close to ice rewards further investigation.https://www.mdpi.com/1422-0067/21/19/7042alpine plantscold hardinessfreeze dehydrationice nucleationice managementlow temperature |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Matthias Stegner Barbara Lackner Tanja Schäfernolte Othmar Buchner Nannan Xiao Notburga Gierlinger Andreas Holzinger Gilbert Neuner |
| spellingShingle |
Matthias Stegner Barbara Lackner Tanja Schäfernolte Othmar Buchner Nannan Xiao Notburga Gierlinger Andreas Holzinger Gilbert Neuner Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species International Journal of Molecular Sciences alpine plants cold hardiness freeze dehydration ice nucleation ice management low temperature |
| author_facet |
Matthias Stegner Barbara Lackner Tanja Schäfernolte Othmar Buchner Nannan Xiao Notburga Gierlinger Andreas Holzinger Gilbert Neuner |
| author_sort |
Matthias Stegner |
| title |
Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species |
| title_short |
Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species |
| title_full |
Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species |
| title_fullStr |
Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species |
| title_full_unstemmed |
Winter Nights during Summer Time: Stress Physiological Response to Ice and the Facilitation of Freezing Cytorrhysis by Elastic Cell Wall Components in the Leaves of a Nival Species |
| title_sort |
winter nights during summer time: stress physiological response to ice and the facilitation of freezing cytorrhysis by elastic cell wall components in the leaves of a nival species |
| publisher |
MDPI AG |
| series |
International Journal of Molecular Sciences |
| issn |
1661-6596 1422-0067 |
| publishDate |
2020-09-01 |
| description |
<i>Ranunculus glacialis</i> grows and reproduces successfully, although the snow-free time period is short (2–3 months) and night frosts are frequent. At a nival site (3185 m a.s.l.), we disentangled the interplay between the atmospheric temperature, leaf temperatures, and leaf freezing frequency to assess the actual strain. For a comprehensive understanding, the freezing behavior from the whole plant to the leaf and cellular level and its physiological after-effects as well as cell wall chemistry were studied. The atmospheric temperatures did not mirror the leaf temperatures, which could be 9.3 °C lower. Leaf freezing occurred even when the air temperature was above 0 °C. Ice nucleation at on average −2.6 °C started usually independently in each leaf, as the shoot is deep-seated in unfrozen soil. All the mesophyll cells were subjected to freezing cytorrhysis. Huge ice masses formed in the intercellular spaces of the spongy parenchyma. After thawing, photosynthesis was unaffected regardless of whether ice had formed. The cell walls were pectin-rich and triglycerides occurred, particularly in the spongy parenchyma. At high elevations, atmospheric temperatures fail to predict plant freezing. Shoot burial prevents ice spreading, specific tissue architecture enables ice management, and the flexibility of cell walls allows recurrent freezing cytorrhysis. The peculiar patterning of triglycerides close to ice rewards further investigation. |
| topic |
alpine plants cold hardiness freeze dehydration ice nucleation ice management low temperature |
| url |
https://www.mdpi.com/1422-0067/21/19/7042 |
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