Table 2.
List of all HKT2 transporters isolated and characterized.
| Transporter | Expression in planta | Ref. | Function in planta | Ref. | Transport selectivity when heterologous expressed | Ref. |
|---|---|---|---|---|---|---|
| OsHKT2;1 | In the roots: epidermis, exodermis, cortex differentiated into aerenchyma, stele (mainly in the phloem); In the leaves: bulliform cells, xylem, phloem, mesophyll cells | [22] | Nutritional Na+ uptake from the external medium | [11] | Na+ and K+ transport (Xenopus oocytes) | [22,30,31] |
| Na+ transport (S. cerevisiae cells) | [18,30] | |||||
| K+ transport (S. cerevisiae cells) | [31] | |||||
| OsHKT2;2 | Expressed only in the roots | [32] | Na+/K+ symporter in BY2 tobacco cells | [33] | Na+, K+, (S. cerevisiae and Xenopus oocytes) | [30,34] |
| Expected to co-transport both Na+ and K+ in conditions of K+ starvation | [32] | |||||
| OsHKT2;2/1 | Expressed only in the roots | [32] | Expected to co-transport both Na+ and K+ in the roots in conditions of low K+ and under salt stress | [32] | Na+ and K+ transport (S. cerevisiae cells and Xenopus oocytes) | [32] |
| OsHKT2;3 | Marginally expressed in the roots in comparison to the shoots | [34] | No currents or uptake observed in Xenopus oocytes or S. cerevisiae cells | [34] | ||
| OsHKT2;4 | Vasculature of primary/ lateral root cells, leaf sheaths, spikelets and the base of stems. Expressed also in mesophyll cells | [35] | Possible role in K+ homeostasis as a K+ transporter/channel | [34] | Permeable to NH4+, Li+, Na+, K+, Ca2+, Mg2+ Zn2+, Mn2+, Cu2+, Fe2+, Cd2+ (Xenopus oocytes) | [35] |
| Possible redundant role in planta as oshkt2;4 mutants show no phenotype | [35] | Permeable to Na+, K+, Mg2+, Ca2+ (Xenopus oocytes) | [34] | |||
| K+ transport (S. cerevisiae cells) | ||||||
| Proposed to function as a K+ transporter involved in both nutritional K+ uptake and long-distance K+ transport | [36] | Na+ and K+ transport (Xenopus oocytes) | [36] | |||
| TaHKT2;1 | Root cortical and stele cells Vascular tissue of mesophyll cells | [14] | Na+ uptake from the external medium | [37] | Permeable to Na+, K+, Cs+ and Rb+ (Xenopus oocytes) | [14] |
| K+ transport (S. cerevisiae cells) | ||||||
| Na+ and K+ transport (S. cerevisiae cells) | [38,39] | |||||
| Na+ and K+ transport (Xenopus oocytes) | ||||||
| Permeable to Na+, K+ and Mg+ (Xenopus oocytes) | [34] | |||||
| PutHKT2;1 | Mainly in roots | [40] | Possible high affinity K+ transporter | [40] | Na+ and K+ transport (S. cerevisiae cells) | [40] |
| HvHKT2;1 | Root cortex, leaf blades and leaf sheaths | [41,42] | Possible involvement in the root K+ (re)absorption at very low K+ concentrations | [41,42] | Na+ and K+ transporter (S. cerevisiae and Xenopus oocytes) | [41–43] |
| Possible uptake of Na+ in the roots | ||||||
| PhaHKT2;1 | Roots and shoots | [44] | Na+ and K+ transport (S. cerevisiae cells) | [40,44] | ||
| PpHKT1 | ------- | ------- | Na+ and K+ uptake (S. cerevisiae cells) | [45] |