Expression of KT/KUP Genes in Arabidopsis and the Role of Root Hairs in K+ Uptake

doi:10.1104/pp.103.034660

Expression of KT/KUP Genes in Arabidopsis and the Role of Root Hairs in K⁺ Uptake

Sung Ju Ahn , Ryoung Shin , and Daniel P. Schachtman ^*

Donald Danforth Plant Science Center, 975 North Warson Road, St. Louis, Missouri 63132

^* Corresponding author; email: dschachtman{at}danforthcenter.org.

Potassium (K⁺) is the most abundant cation in plants and isrequired for plant growth. To ensure an adequate supply of K⁺,plants have multiple mechanisms for uptake and translocation.However, relatively little is known about the physiologicalrole of proteins encoded by a family of 13 genes, named AtKT/KUP,that are involved in K⁺ transport and translocation. To beginto understand where and under what conditions these transportersfunction, we used reverse transcription-PCR to determine thespatial and temporal expression patterns of each AtKT/KUP geneacross a range of organs and tested whether selected AtKT/KUPcDNAs function as K⁺ transporters in Escherichia coli. ManyAtKT/KUPs were expressed in roots, leaves, siliques, and flowersof plants grown under K⁺-sufficient conditions (1.75 mM KCl)in hydroponic culture. AtHAK5 was the only gene in this familythat was up-regulated upon K⁺ deprivation and rapidly down-regulatedwith resupply of K⁺. Ten AtKT/KUPs were expressed in root hairs,but only five were expressed in root tip cells. This suggestsan important role for root hairs in K⁺ uptake. The growth andrubidium (Rb⁺) uptake of two root hair mutants, trh1-1 (tinyroot hairs) and rhd6 (root hair defective), were studied todetermine the contribution of root hairs to whole-plant K⁺ status.Whole-plant biomass decreased in the root hair mutants onlywhen K⁺ concentrations were low; Rb⁺ (used as a tracer for K⁺)uptake rates were lower in the mutants at all Rb⁺ concentrations.Seven genes encoding AtKUP transporters were expressed in E.coli (AtKT3/KUP4, AtKT/KUP5, AtKT/KUP6, AtKT/KUP7, AtKT/KUP10,AtKT/KUP11, and AtHAK5), and their K⁺ transport function wasdemonstrated.

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