The hypoxia–reoxygenation stress in plants

Abstract Plants are very plastic in adapting growth and development to changing adverse environmental conditions. This feature will be essential for plants to survive climate changes characterized by extreme temperatures and rainfall. Although plants require molecular oxygen (O2) to live, they can o...

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Bibliographic Details
Published inJournal of experimental botany Vol. 72; no. 16; pp. 5841 - 5856
Main Authors León, José, Castillo, Mari Cruz, Gayubas, Beatriz
Format Journal Article
LanguageEnglish
Published UK Oxford University Press 11.08.2021
Subjects
Review Papers
submergence
hypoxia
nitric oxide
reillumination
mitochondria
waterlogging
Development
flooding
oxygen sensing
reoxygenation
oxidative stress
phytohormones
development
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Summary:Abstract Plants are very plastic in adapting growth and development to changing adverse environmental conditions. This feature will be essential for plants to survive climate changes characterized by extreme temperatures and rainfall. Although plants require molecular oxygen (O2) to live, they can overcome transient low-O2 conditions (hypoxia) until return to standard 21% O2 atmospheric conditions (normoxia). After heavy rainfall, submerged plants in flooded lands undergo transient hypoxia until water recedes and normoxia is recovered. The accumulated information on the physiological and molecular events occurring during the hypoxia phase contrasts with the limited knowledge on the reoxygenation process after hypoxia, which has often been overlooked in many studies in plants. Phenotypic alterations during recovery are due to potentiated oxidative stress generated by simultaneous reoxygenation and reillumination leading to cell damage. Besides processes such as N-degron proteolytic pathway-mediated O2 sensing, or mitochondria-driven metabolic alterations, other molecular events controlling gene expression have been recently proposed as key regulators of hypoxia and reoxygenation. RNA regulatory functions, chromatin remodeling, protein synthesis, and post-translational modifications must all be studied in depth in the coming years to improve our knowledge on hypoxia–reoxygenation transition in plants, a topic with relevance in agricultural biotechnology in the context of global climate change. Plant responses to hypoxia and subsequent reoxygenation occur through a network of processes involving oxygen sensing, RNA function, chromatin remodeling, gene expression, and protein synthesis, which together allow plants to either escape or tolerate the stress.
ISSN:0022-0957
1460-2431
DOI:10.1093/jxb/eraa591