Abstract
Soil salinity adversely affects the growth and yield of crops, including cucumber, one of the most important vegetables in the world. Grafting with salt-tolerant pumpkin as the rootstock effectively improves the growth of cucumber under different salt conditions by limiting Na+ transport from the pumpkin rootstock to the cucumber scion. High-affinity potassium transporters (HKTs) are crucial for the long distance transport of Na+ in plants, but the function of pumpkin HKTs in this process of grafted cucumber plants remains unclear. In this work, we have characterized CmHKT1;1 as a member of the HKT gene family in Cucurbita moschata and observed an obvious upregulation of CmHKT1;1 in roots under NaCl stress conditions. Heterologous expression analyses in yeast mutants indicated that CmHKT1;1 is a Na+-selective transporter. The transient expression in tobacco epidermal cells and in situ hybridization showed CmHKT1;1 localization at plasma membrane, and preferential expression in root stele. Moreover, ectopic expression of CmHKT1;1 in cucumber decreased the Na+ accumulation in the plants shoots. Finally, the CmHKT1;1 transgenic line as the rootstock decreased the Na+ content in the wild type shoots. These findings suggest that CmHKT1;1 plays a key role in the salt tolerance of grafted cucumber by limiting Na+ transport from the rootstock to the scion and can further be useful for engineering salt tolerance in cucurbit crops.
Highlights
Salinity affects approximately 7% of the world’s land including agricultural lands and is a crucial factor limiting over 30% of irrigated and 7% of dryland agriculture worldwide [1]
They are responsible for ionHhKomTseaorsetacsriuscainaldfoNras+aldt itsotlreibrauntcioeninwpitlahnintspallaonntgs w[3i3t,h34o]t.hHerKtTrantrsapnosrpteorrst.erTshaeryeadreivriedsepdoinnstioble for ion homeostasis and Na+ distribution within plants [33,34]
K+ transport capacity was attributed to the presence of two aspartic residues, D207 and D238, in the transmembrane (M2B) and pore (PB) domains
Summary
Salinity affects approximately 7% of the world’s land including agricultural lands and is a crucial factor limiting over 30% of irrigated and 7% of dryland agriculture worldwide [1]. Regulation of Na+ influx, efflux, allocation, and compartmentation is important for plants to cope with Na+ accumulation in the shoots. This process involves a complex network of channels and transporters that participate in ion uptake and compartmentation in plant cells and tissues. High-affinity K+ transporter-1 (HKT1) encodes a Na+ preferential transporter that principally controls root-to-shoot Na+ delivery via the withdrawal of Na+ from the xylem sap [3,4,5,6]. HKT1 transporters are involved in retrieving Na+ from the transpiration stream [8,9,10] by mediating the influx of Na+ into the xylem parenchyma cells in the roots [3].
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