Oxygen deprivation stress in a changing environment
Past research into flooding tolerance and oxygen shortages in plants has been motivated largely by cultivation problems of arable crops. Unfortunately, such species are unsuitable for investigating the physiological and biochemical basis of anoxia-tolerance as selection has reduced any tolerance of...
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2017
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ftreroch:oai:doc.rero.ch:290762 2023-05-15T15:11:38+02:00 Oxygen deprivation stress in a changing environment Crawford, R.M.M. Braendle, R. 2017-08-02T19:33:06Z http://doc.rero.ch/record/290762/files/47-2-145.pdf eng eng http://doc.rero.ch/record/290762/files/47-2-145.pdf 2017 ftreroch 2023-02-16T17:27:45Z Past research into flooding tolerance and oxygen shortages in plants has been motivated largely by cultivation problems of arable crops. Unfortunately, such species are unsuitable for investigating the physiological and biochemical basis of anoxia-tolerance as selection has reduced any tolerance of anaerobiosis and anaerobic soil conditions that their wild ancestors might have possessed. Restoration of anoxia-tolerance to species that have lost this property is served better by physiological and molecular studies of the mechanisms that are employed in wild species that still possess long-term anoxia-tolerance. Case studies developing these arguments are presented in relation to a selection of crop and wild species. The flooding sensitivity and metabolism of maize is compared in relation to rice in its capacity for anaerobic germination. The sensitivity of potato to flooding is related to its disturbed energy metabolism and inability to maintain functioning membranes under anoxia and postinoxia. By contrast, long-term anoxia-tolerance in the American cranberry (Vaccinium macrocarpon) and the arctic grass species Deschampsia beringensis can be related to the provision and utilization of carbohydrate reserves. Among temperate species, the sweet flag (Acorus calamus) shows a remarkable tolerance of anoxia in both shoots and roots and is also able to mobilize carbohydrate and maintain ATP levels during anoxia as well as preserving membrane lipids against anoxic and post-anoxic injury. Phragmites australis and Spartina alterniflora, although anoxia-tolerant, are both sulphide-sensitive species which can pre-dispose them to the phenomenon of die-back in stagnant, nutrient-rich water. Glyceria maxima adapts to flooding through phenological adaptations with a seasonal metabolic tolerance of anoxia confined to winter and spring which, combined with a facility for root aeration and early spring growth, allows rapid colonization of sites with only shallow flooding. The diversity of responses to flooding in wild plants ... Other/Unknown Material Arctic RERO DOC Digital Library Arctic |
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ftreroch |
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English |
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Past research into flooding tolerance and oxygen shortages in plants has been motivated largely by cultivation problems of arable crops. Unfortunately, such species are unsuitable for investigating the physiological and biochemical basis of anoxia-tolerance as selection has reduced any tolerance of anaerobiosis and anaerobic soil conditions that their wild ancestors might have possessed. Restoration of anoxia-tolerance to species that have lost this property is served better by physiological and molecular studies of the mechanisms that are employed in wild species that still possess long-term anoxia-tolerance. Case studies developing these arguments are presented in relation to a selection of crop and wild species. The flooding sensitivity and metabolism of maize is compared in relation to rice in its capacity for anaerobic germination. The sensitivity of potato to flooding is related to its disturbed energy metabolism and inability to maintain functioning membranes under anoxia and postinoxia. By contrast, long-term anoxia-tolerance in the American cranberry (Vaccinium macrocarpon) and the arctic grass species Deschampsia beringensis can be related to the provision and utilization of carbohydrate reserves. Among temperate species, the sweet flag (Acorus calamus) shows a remarkable tolerance of anoxia in both shoots and roots and is also able to mobilize carbohydrate and maintain ATP levels during anoxia as well as preserving membrane lipids against anoxic and post-anoxic injury. Phragmites australis and Spartina alterniflora, although anoxia-tolerant, are both sulphide-sensitive species which can pre-dispose them to the phenomenon of die-back in stagnant, nutrient-rich water. Glyceria maxima adapts to flooding through phenological adaptations with a seasonal metabolic tolerance of anoxia confined to winter and spring which, combined with a facility for root aeration and early spring growth, allows rapid colonization of sites with only shallow flooding. The diversity of responses to flooding in wild plants ... |
| author |
Crawford, R.M.M. Braendle, R. |
| spellingShingle |
Crawford, R.M.M. Braendle, R. Oxygen deprivation stress in a changing environment |
| author_facet |
Crawford, R.M.M. Braendle, R. |
| author_sort |
Crawford, R.M.M. |
| title |
Oxygen deprivation stress in a changing environment |
| title_short |
Oxygen deprivation stress in a changing environment |
| title_full |
Oxygen deprivation stress in a changing environment |
| title_fullStr |
Oxygen deprivation stress in a changing environment |
| title_full_unstemmed |
Oxygen deprivation stress in a changing environment |
| title_sort |
oxygen deprivation stress in a changing environment |
| publishDate |
2017 |
| url |
http://doc.rero.ch/record/290762/files/47-2-145.pdf |
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Arctic |
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Arctic |
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Arctic |
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Arctic |
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http://doc.rero.ch/record/290762/files/47-2-145.pdf |
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