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http://dx.doi.org/10.1186/s41610-019-0127-2

Waterlogging induced oxidative stress and the mortality of the Antarctic plant, Deschampsia antarctica  

Park, Jeong Soo (Alien Species Research Team, National Institute of Ecology)
Lee, Eun Ju (School of Biological Sciences, Seoul National University)
Publication Information
Journal of Ecology and Environment / v.43, no.3, 2019 , pp. 289-296 More about this Journal
Abstract
We investigated the mortality and the oxidative damages of Deschampsia antarctica in response to waterlogging stress. In field, we compared the changes in the density of D. antarctica tuft at the two different sites over 3 years. The soil water content at site 2 was 6-fold higher than that of site 1, and the density of D. antarctica tuft decreased significantly by 55.4% at site 2 for 3 years, but there was no significant change at site 1. Experimental results in growth chamber showed that the $H_2O_2$ and malondialdehyde content increased under root-flooding treatment (hypoxic conditions-deficiency of $O_2$), but any significant change was not perceptible under the shoot-flooding treatment (anoxic condition-absence of $O_2$). However, total chlorophyll, soluble sugar, protein content, and phenolic compound decreased under the shoot-flooding treatment. In addition, the catalase activity increased significantly on the 1st day of flooding. These results indicate that hypoxic conditions may lead to the overproduction of reactive oxygen species, and anoxic conditions can deplete primary metabolites such as sugars and protein in the leaf tissues of D. antarctica. Under present warming trend in Antarctic Peninsula, D. antarctica tuft growing near the shoreline might more frequently experience flooding due to glacier melting and inundation of seawater, which can enhance the risk of this plant mortality.
Keywords
Waterlogging; Deschampsia antarctica; Antarctica; Flooding; Reactive oxygen species; Antioxidant enzyme activity;
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