Linking salinity stress tolerance with tissue-specific Na+ sequestration in wheat roots

Honghong eWu; Lana eShabala; Xiaohui eLiu; Elisa eAzzarello; Camilla ePandolfi; Meixue eZhou; Zhong-Hua eChen; Jayakumar eBose; Stefano eMancuso; Sergey eShabala

doi:10.3389/fpls.2015.00071

Frontiers in Plant Science (Feb 2015)

Linking salinity stress tolerance with tissue-specific Na+ sequestration in wheat roots

Honghong eWu,
Lana eShabala,
Xiaohui eLiu,
Elisa eAzzarello,
Camilla ePandolfi,
Meixue eZhou,
Zhong-Hua eChen,
Jayakumar eBose,
Stefano eMancuso,
Sergey eShabala

Affiliations

Honghong eWu: University of Tasmania
Lana eShabala: University of Tasmania
Xiaohui eLiu: University of Western Sydney
Elisa eAzzarello: University of Florence
Camilla ePandolfi: University of Florence
Meixue eZhou: University of Tasmania
Zhong-Hua eChen: University of Western Sydney
Jayakumar eBose: University of Tasmania
Stefano eMancuso: University of Florence
Sergey eShabala: University of Tasmania

DOI: https://doi.org/10.3389/fpls.2015.00071
Journal volume & issue: Vol. 6

Abstract

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Salinity stress tolerance is a physiologically complex trait that is conferred by the large array of interacting mechanisms. Among these, vacuolar Na+ sequestration has always been considered as one of the key components differentiating between sensitive and tolerant species and genotypes. However, vacuolar Na+ sequestration has been rarely considered in the context of the tissue-specific expression and regulation of appropriate transporters contributing to Na+ removal from the cytosol. In this work, six bread wheat varieties contrasting in their salinity tolerance (three tolerant and three sensitive) were used to understand the essentiality of vacuolar Na+ sequestration between functionally different root tissues, and link it with the overall salinity stress tolerance in this species. Roots of 4-d old wheat seedlings were treated with 100 mM NaCl for 3 days, and then Na+ distribution between cytosol and vacuole was quantified by CoroNa Green fluorescent dye imaging. Our major observations were as follows: 1) salinity stress tolerance correlated positively with vacuolar Na+ sequestration ability in the mature root zone but not in the root apex; 2) Contrary to expectations, cytosolic Na+ levels in root meristem were significantly higher in salt tolerant than sensitive group, while vacuolar Na+ levels showed an opposite trend. These results are interpreted as meristem cells playing a role of the salt sensor; 3) No significant difference in the vacuolar Na+ sequestration ability was found between sensitive and tolerant group in either transition or elongation zones; 4) The overall Na+ accumulation was highest in the elongation zone, suggesting its role in osmotic adjustment and turgor maintenance required to drive root expansion growth. Overall, the reported results suggest high tissue-specificity of Na+ uptake, signalling, and sequestration in wheat root. The implications of these findings for plant breeding for salinity stress tolerance are discussed.

Published in Frontiers in Plant Science

ISSN: 1664-462X (Online)
Publisher: Frontiers Media S.A.
Country of publisher: Switzerland
LCC subjects: Agriculture: Plant culture
Website: https://www.frontiersin.org/journals/plant-science

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