Calcium Regulation of Sodium Hypersensitivities of sos3 and athkt1 Mutants

doi:10.1093/pcp/pcj029

Plant and Cell Physiology Advance Access originally published online on March 15, 2006
Plant and Cell Physiology 2006 47(5):622-633; doi:10.1093/pcp/pcj029

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Calcium Regulation of Sodium Hypersensitivities of sos3 and athkt1 Mutants

Tomoaki Horie, Rie Horie, Wai-Yin Chan, Ho-Yin Leung and Julian I. Schroeder^*

Division of Biological Sciences, Cell and Developmental Biology Section, and Center for Molecular Genetics, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0116, USA

^* Corresponding author: E-mail, julian{at}biomail.ucsd.edu; Fax, +1-858-534-7108.

T-DNA disruption mutations in the AtHKT1 gene have previouslybeen shown to suppress the salt sensitivity of the sos3 mutant.However, both sos3 and athkt1 single mutants show sodium (Na⁺)hypersensitivity. In the present study we further analyzed theunderlying mechanisms for these non-additive and counteractingNa⁺ sensitivities by characterizing athkt1-1 sos3 and athkt1-2sos3 double mutant plants. Unexpectedly, mature double mutantplants grown in soil clearly showed an increased Na⁺ hypersensitivitycompared with wild-type plants when plants were subjected tosalinity stress. The salt sensitive phenotype of athkt1 sos3double mutant plants was similar to that of athkt1 plants, whichshowed chlorosis in leaves and stems. The Na⁺ content in xylemsap samples of soil-grown athkt1 sos3 double and athkt1 singlemutant plants showed dramatic Na⁺ overaccumulation in responseto salinity stress. Salinity stress analyses using basic minimalnutrient medium and Murashige–Skoog (MS) medium revealedthat athkt1 sos3 double mutant plants show a more athkt1 singlemutant-like phenotype in the presence of 3 mM externalCa²⁺, but show a more sos3 single mutant-like phenotype in thepresence of 1 mM external Ca²⁺. Taken together multipleanalyses demonstrate that the external Ca²⁺ concentration stronglyimpacts the Na⁺ stress response of athkt1 sos3 double mutants.Furthermore, the presented findings show that SOS3 and AtHKT1are physiologically distinct major determinants of salinityresistance such that sos3 more strongly causes Na⁺ overaccumulationin roots, whereas athkt1 causes an increase in Na⁺ levels inthe xylem sap and shoots and a concomitant Na⁺ reduction inroots.

(Received November 21, 2005; Accepted March 4, 2006)
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