Remobilization of leaf Na+ content and use of nonstructural carbohydrates vary depending on the time when salt stress begins in woody species

Remobilization of leaf Na+ content and use of nonstructural carbohydrates vary depending on the time when salt stress begins in woody species

Basic mechanisms are known to promote salt tolerance in plants: a delay in Na+ uptake or rapid Na+ remobilization from leaf tissue. We measured dynamics of the Na+/K+ ratio and components of carbon metabolism during the first 72 h after saline stress (200 mM NaCl) began in Cenostigma pyramidale, a w...

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Bibliographic Details
Published in:Plant physiology and biochemistry Vol. 158; pp. 385 - 395
Main Authors: Lima, Laís L., Frosi, Gabriella, Lopes, Rafaela, Santos, Mauro Guida
Format: Journal Article
Language:English
Published: France Elsevier Masson SAS 01-01-2021
Subjects:
Carbohydrates - analysis
Fabaceae - chemistry
Fabaceae - physiology
Gas exchange
Hydrogen Peroxide
Plant Leaves - chemistry
Proline
Saline stress
Salt Stress
Sodium - analysis
Sodium recirculation
Starch
Sugar metabolism
Proline
Saline stress
Sugar metabolism
Gas exchange
Starch
Sodium recirculation
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Summary:Basic mechanisms are known to promote salt tolerance in plants: a delay in Na+ uptake or rapid Na+ remobilization from leaf tissue. We measured dynamics of the Na+/K+ ratio and components of carbon metabolism during the first 72 h after saline stress (200 mM NaCl) began in Cenostigma pyramidale, a woody species, under controlled conditions. Saline stress at two times: one plant group at the beginning of the morning and the other in the evening. Stressed plants had three times more Na+ in leaves than did control plants in the first 24 h. However, in the next few hours, despite new applications of saline solution, the Na+/K+ ratio continued to decline. Several samples, including night treatments, provided evidence that this species uses Na+ recirculation mechanisms to endure salt stress. Effects of salt on the traits evaluated differed depending on the time when stress began. Between the two saline treatments, in the first 24 h after saline stress, gas exchange decreased more strongly in morning-stressed plants, when large amounts of Na+ reached the leaf and K+ left this organ. Nevertheless, when stress was applied in the evening, leaf Na+ remobilization was faster, and the soluble sugar/starch ratio remained greater than did the control. Our data suggested that time of the beginning of salt stress could change the level of damage. Morning-stressed plants synthesized greater amounts of proline, H2O2, and malondialdehyde than did night-stressed plants. We recommend that details regarding the time of stress be taken into consideration in physiological studies. •A woody species was subjected to salt stress.•Saline stress changed the species response depending on the time of day it is applied.•The leaves decreased Na+ and recovered K+ concentration quickly.•This woody species prioritized increase soluble sugar/starch ratio under stress.•Proteins and proline content were kept under stress.
ISSN:0981-9428
1873-2690
DOI:10.1016/j.plaphy.2020.11.026