AUTHOR=Wu Honghong , Shabala Lana , Liu Xiaohui , Azzarello Elisa , Zhou Meixue , Pandolfi Camilla , Chen Zhong-Hua , Bose Jayakumar , Mancuso Stefano , Shabala Sergey 

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

JOURNAL=Frontiers in Plant Science

VOLUME=6

YEAR=2015

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2015.00071

DOI=10.3389/fpls.2015.00071

ISSN=1664-462X

ABSTRACT=<p>Salinity stress tolerance is a physiologically complex trait that is conferred by the large array of interacting mechanisms. Among these, vacuolar Na<sup>+</sup> sequestration has always been considered as one of the key components differentiating between sensitive and tolerant species and genotypes. However, vacuolar Na<sup>+</sup> sequestration has been rarely considered in the context of the tissue-specific expression and regulation of appropriate transporters contributing to Na<sup>+</sup> 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<sup>+</sup> sequestration between functionally different root tissues, and link it with the overall salinity stress tolerance in this species. Roots of 4-day old wheat seedlings were treated with 100 mM NaCl for 3 days, and then Na<sup>+</sup> 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<sup>+</sup> sequestration ability in the mature root zone but not in the root apex; (2) contrary to expectations, cytosolic Na<sup>+</sup> levels in root meristem were significantly higher in salt tolerant than sensitive group, while vacuolar Na<sup>+</sup> 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<sup>+</sup> sequestration ability was found between sensitive and tolerant groups in either transition or elongation zones; (4) the overall Na<sup>+</sup> 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<sup>+</sup> uptake, signaling, and sequestration in wheat roots. The implications of these findings for plant breeding for salinity stress tolerance are discussed.</p>