Elevated CO2 improves assimilation rate and growth of tomato plants under progressively higher soil salinity by decreasing abscisic acid and ethylene levels

•Salt stress stimulates ABA and ACC biosynthesis in tomato plants.•The [eCO2] determines the stomatal responses to ABA and ACC under salt stress.•The [eCO2] decreases ABA and ACC biosynthesis in tomato plants under salt stress.•Metabolic alterations contributes to the restoration of plant growth und...

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Published inEnvironmental and experimental botany Vol. 176; p. 104050
Main Authors Brito, Fred A.L., Pimenta, Thaline M., Henschel, Juliane M., Martins, Samuel C.V., Zsögön, Agustín, Ribeiro, Dimas M.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.08.2020
Subjects
Climate change
Hormones
Primary metabolism
Salt stress
Solanum lycopersicum
ABA
ACC
A
Salt stress
E
Solanum lycopersicum
Ci/Ca
qRT-PCR
aCO2
Hormones
gs
NPQ
eCO2
Climate change
RD
DW
TCA
Primary metabolism
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Summary:•Salt stress stimulates ABA and ACC biosynthesis in tomato plants.•The [eCO2] determines the stomatal responses to ABA and ACC under salt stress.•The [eCO2] decreases ABA and ACC biosynthesis in tomato plants under salt stress.•Metabolic alterations contributes to the restoration of plant growth under salinity in [eCO2]. High salinity in the soil hampers crop performance. In this context, elevated atmospheric CO2 concentration can alter plant responses to excess salinity, as shown by studies exposing plants to high concentration of NaCl (osmotic shock) in controlled conditions under constant irradiance and temperature. These experiments, however, may not reflect the conditions that occur in natural environments. Here, we studied the impact of progressively imposed salt stress on tomato plant biomass, hormone biosynthesis and primary metabolism under elevated CO2 concentration with fluctuating irradiance and temperature. Na+ concentration and Na+: K+ ratios in plant tissues were increased by high salinity under both ambient and elevated CO2 concentration. Elevated CO2 led to enhanced growth in tomato plants under salt stress through stimulation of photosynthesis and reduced concentrations of abscisic acid and the ethylene precursor 1-aminocyclopropane-1-carboxylic acid in both leaves and roots. Furthermore, whereas high salinity reduced the concentration of Krebs Cycle intermediates and increased the concentration of photorespiratory metabolites glycine and serine, all were restored to control levels by elevated CO2. Our results demonstrate a beneficial effect of rising atmospheric CO2 concentration for crops and reveal new interactions in the physiological network controlling salinity stress responses.
ISSN:0098-8472
1873-7307
DOI:10.1016/j.envexpbot.2020.104050