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The protein kinase <scp>SlCIPK23</scp> boosts K<sup>+</sup> and Na<sup>+</sup> uptake in tomato plants

Jesús Amo, Alberto Lara, Almudena Martínez‐Martínez, Vicente Martı́nez, Francisco Rubio, Manuel Nieves‐Cordones

2021Plant Cell & Environment30 citationsDOIOpen Access PDF

Abstract

Abstract Regulation of root transport systems is essential under fluctuating nutrient supply. In the case of potassium (K + ), HAK/KUP/KT K + transporters and voltage‐gated K + channels ensure root K + uptake in a wide range of K + concentrations. In Arabidopsis, the CIPK23/CBL1‐9 complex regulates both transporter‐ and channel‐mediated root K + uptake. However, research about K + homeostasis in crops is in demand due to species‐specific mechanisms. In the present manuscript, we studied the contribution of the voltage‐gated K + channel LKT1 and the protein kinase SlCIPK23 to K + uptake in tomato plants by analysing gene‐edited knockout tomato mutant lines, together with two‐electrode voltage‐clamp experiments in Xenopus oocytes and protein–protein interaction analyses. It is shown that LKT1 is a crucial player in tomato K + nutrition by contributing approximately 50% to root K + uptake under K + ‐sufficient conditions. Moreover, SlCIPK23 was responsible for approximately 100% of LKT1 and approximately 40% of the SlHAK5 K + transporter activity in planta . Mg +2 and Na + compensated for K + deficit in tomato roots to a large extent, and the accumulation of Na + was strongly dependent on SlCIPK23 function. The role of CIPK23 in Na + accumulation in tomato roots was not conserved in Arabidopsis, which expands the current set of CIPK23‐like protein functions in plants.

Topics & Concepts

ArabidopsisXenopusTransporterMutantVoltage clampPotassiumProtein kinase AKinaseBiologyChemistryBiophysicsCell biologyGeneBiochemistryMembrane potentialOrganic chemistryPlant nutrient uptake and metabolismPlant Stress Responses and TolerancePlant Micronutrient Interactions and Effects