Higher Control of Na+ and Cl− Transport to the Shoot Along With K+/Na+ Selectivity is Determinant for Differential Salt Resistance in Grapevine Rootstocks

In this study, a comparative analysis between two grapevine rootstocks was carried out to characterize their salt sensibility in terms of growth, Na + and Cl – exclusion from shoots, and K + /Na + selectivity in the whole plant level associated with photosynthesis efficiency. In the first greenhouse...

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Published inJournal of plant growth regulation Vol. 42; no. 9; pp. 5713 - 5726
Main Authors Silva, Marcela Maria Albuquerque, Santos, Hugo Rafael Bentzen, Silva, Evandro Nascimento, Neto, Juracy Barroso, Hermínio, Pedro José, Ramalho, Thaís Lima, Nunes, Vitor Gomes, Simões, Adriano Nascimento, Souza, Eduardo Soares, Ferreira-Silva, Sérgio Luiz
Format Journal Article
LanguageEnglish
Published New York Springer US 01.09.2023
Springer Nature B.V
Subjects
Agriculture
Assimilation
Biological assimilation
Biomedical and Life Sciences
Carbon dioxide
Carboxylation
Comparative analysis
Electron transport
Homeostasis
Life Sciences
Photosynthesis
Plant Anatomy/Development
Plant Physiology
Plant Sciences
Retention capacity
Ribulose-bisphosphate carboxylase
Rootstocks
Salinity
Salinity effects
Salts
Shoots
Sodium chloride
Water balance
Ionic homeostasis
Rootstocks
Photosynthesis
Vitis vinifera
Salinity
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Summary:In this study, a comparative analysis between two grapevine rootstocks was carried out to characterize their salt sensibility in terms of growth, Na + and Cl – exclusion from shoots, and K + /Na + selectivity in the whole plant level associated with photosynthesis efficiency. In the first greenhouse experiment, the ‘IAC 313’ and ‘Paulsen’ grapevine rootstocks were subjected to salinity (80 mM NaCl) for 15 d followed by a salt recovery period (10 d). Later, a second assay was performed using plants incubated in a liquid medium to evaluate the kinetics of root K + uptake in the absence and presence of NaCl. Salinity affected dry weight (DW) in both rootstocks, but this effect was more severe for ‘Paulsen’ rootstock. Better DW of ‘IAC 313’ under salinity was associated with higher restriction of Na + and Cl – flux for shoots due to better retention capacity of these ions in roots. In addition, ‘IAC 313’ also showed higher K + /Na + selectivity in both root uptake and partitioning processes at the whole plant. Under salinity, maximum CO 2 assimilation ( P Nmax ), maximum electron transport ( J max ), and Rubisco carboxylation ( V cmax ) were also affected more in the ‘Paulsen’ than in ‘IAC 313.’ Our findings show that the characteristic of more favorable ionic homeostasis presented by ‘IAC 313’ rootstock was associated with higher growth, water balance, and carbon assimilation under salinity. In summary, this suggest that the ‘IAC 313’ rootstock is clearly more acclimated to salinity compared to ‘Paulsen’ rootstock.
ISSN:0721-7595
1435-8107
DOI:10.1007/s00344-023-10952-x