The Ionic Environment Controls the Contribution of the Barley HvHAK1 Transporter to Potassium Acquisition

doi:10.1104/pp.107.114546

The Ionic Environment Controls the Contribution of the Barley HvHAK1 Transporter to Potassium Acquisition¹^,[W]^,[OA]

Fabiana R. Fulgenzi², María Luisa Peralta², Silvina Mangano², Cristian H. Danna³, Augusto J. Vallejo⁴, Pere Puigdomenech and Guillermo E. Santa-María^*

Instituto de Investigaciones Biotecnológicas, Universidad Nacional de San Martín-Consejo Nacional de Investigaciones Científicas y Técnicas, Instituto de Tecnología Industrial, San Martín 1650, Provincia de Buenos Aires, Argentina (F.R.F., M.L.P., S.M., C.H.D., A.J.V., G.E.S.-M.); and Departament de Genètica Molecular, Centro de Investigaciones y Desarrollo-Consejo Superior de Investigaciones Científicas, 08034 Barcelona, Spain (P.G.)

ABSTRACT

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

The control of potassium (K⁺) acquisition is a critical requirementfor plant growth. Although HAK1 (high affinity K⁺ 1) transportersprovide a pathway for K⁺ acquisition, the effect exerted bythe ionic environment on their contribution to K⁺ capture remainsessentially unknown. Here, the influence of the ionic environmenton the accumulation of transcripts coding for the barley (Hordeumvulgare) HvHAK1 transporter as well as on HvHAK1-mediated K⁺capture has been examined. In situ mRNA hybridization studiesshow that HvHAK1 expression occurs in most root cells, beingaugmented at the outermost cell layers. Accumulation of HvHAK1transcripts is enhanced by K⁺ deprivation and transiently byexposure to high salt concentrations. In addition, studies onthe accumulation of transcripts coding for HvHAK1 and its closehomolog HvHAK1b revealed the presence of two K⁺-responsive pathways,one repressed and the other insensitive to ammonium. Experimentswith Arabidopsis (Arabidopsis thaliana) HvHAK1-expressing transgenicplants showed that K⁺ deprivation enhances the capture of K⁺mediated by HvHAK1. A detailed study with HvHAK1-expressingSaccharomyces cerevisiae cells also revealed an increase ofK⁺ uptake after K⁺ starvation. This increase did not occur incells grown at high Na⁺ concentrations but took place for cellsgrown in the presence of NH₄⁺. 3,3'-Dihexyloxacarbocyanine iodideaccumulation measurements indicate that the increased captureof K⁺ in HvHAK1-expressing yeast cells cannot be explained onlyby changes in the membrane potential. It is shown that the yeastprotein phosphatase PPZ1 as well as the halotolerance HAL4/HAL5kinases negatively regulate the HvHAK1-mediated K⁺ transport.

Potassium (K⁺) is the most abundant essential cation in almostall living cells. Besides having several major functions innormal physiology, K⁺ plays an important role protecting plantsduring acclimation to saline-rich and ammonium-rich environments(Flowers and Läuchli, 1983

; Cao et al., 1993

). Acquisitionof K⁺ from the soil solution is primarily dependent on the activityof transport proteins located in the plasma membrane of soilbacteria, fungi, and root epidermal cells of plants. Early on,it was observed that the kinetics and energetics of K⁺ transportin most fungi and plants share some common features that arenot found in animal cells (Kochian and Lucas, 1988

; Rodríguez-Navarro,2000

). This observation led to the concept that in most casesK⁺ uptake is mediated by similar transport proteins in rootsand fungal cells. Providing support for this claim, homologuesof the fungal HAK (high affinity K⁺) and TRK (transport of K⁺)transporters have been identified in plants (Véry andSentenac, 2003

). The possibility that regulatory elements involvedin alkali cation homeostasis are functional in both plants andfungi has also been proposed (Gisbert et al., 2000

; Quinteroet al., 2002

). Unlike their fungal counterparts, the plant homologuesof TRK transporters, named HKT (high-affinity K⁺ transporter),appear to be involved mainly in Na⁺ transport rather than inK⁺ acquisition (Garcíadeblás et al., 2003

; Ruset al., 2004

; Horie et al., 2007

). On the other hand, membersof the HAK1 subgroup of HAK-KUP-KT proteins have been foundto play a major role in K⁺ uptake in plants (Santa-Maríaet al., 1997

; Rubio et al., 2000

; Gierth et al., 2005

), beingan additional route for K⁺ uptake in roots provided by a Shaker-likeinward rectifying K⁺ channel, the Arabidopsis (Arabidopsis thaliana)K⁺ transporter AKT1 (Sentenac et al., 1992

; Hirsch et al., 1998

).Studies in yeasts indicate that K⁺ transport mediated by HAK1transporters is sensitive to the presence of NH₄⁺, while studieswith akt1 mutant plants demonstrate that the AKT1 channel isinvolved in the capture of K⁺ for plants grown at high NH₄⁺concentrations (Hirsch et al., 1998

; Santa-María et al.,2000

). Other studies support the view that the NH₄⁺-sensitivepathway involves the activity of more than a single K⁺ transporter(Spalding et al., 1999

; Gierth et al., 2005

; Vallejo et al.,2005

It has been shown that the acquisition of K⁺ by plants is atightly regulated process. Perception of K⁺ deprivation rapidlyoccurs after K⁺ removal from the growth medium, leading to anenhancement of the K⁺ uptake capacity from diluted K⁺ solutions(Glass, 1976; Kochian and Lucas, 1982), which probably requiresthe accumulation of reactive oxygen species in a discrete rootzone (Shin and Schachtman, 2004). Additionally, the pharmacologicalproperties and thermodynamic constrains of K⁺ uptake from dilutedK⁺ solutions in plants depend on the abundance of K⁺, sodium,and ammonium in the medium encountered by roots during growth(Spalding et al., 1999; Santa-María et al., 2000; Kronzuckeret al., 2003; Nieves-Cordones et al., 2007). When plants aregrown in the presence of high NH₄⁺ or Na⁺ concentrations, theenhancement of the K⁺ uptake capacity resulting from K⁺ deprivationis affected and a change in the contribution of the NH₄⁺-sensitiveand NH₄⁺-insensitive components becomes evident. These resultssuggest a regulatory effect of the ionic environment on thecontribution of AKT1 and HAK1 transporters. A clear influenceof K⁺ starvation on the control of AKT1 activity was reportedrecently (Li et al., 2006; Xu et al., 2006). However, the influenceof the ionic environment found by plants during growth on thecontribution of a HAK1 transporter remains essentially unknown.Here, we introduce evidence for the presence of long-term regulatorymechanisms affecting the abundance of transcripts and the contributionto K⁺ capture of the canonical member of the HAK1 subgroup,the barley (Hordeum vulgare) HvHAK1 transporter.

RESULTS

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

HvHAK1 Is Preferentially Expressed in Cells of the Root Outer Layers

As root cells expressing K⁺ transporters carry out the primaryuptake of K⁺ from the soil, the site of HvHAK1 expression inbarley roots was determined. Because of the existence of severalHAK1 genes in Triticeae genomes and the high similitude amongthem (Santa-María et al., 1997), we used a specific probemainly containing the 3' untranslated region to study HvHAK1expression in transversal sections of roots. In situ hybridizationstudies in seminal barley roots showed that the accumulationof HvHAK1 transcripts occurs in all cell layers, with the expressionaugmented in the outermost layers (Fig. 1A , Supplemental Fig.S1). No signal was detected with the sense probe, showing thesuitability of the technique used (Fig. 1B, Supplemental Fig.S1).

View larger version (114K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 1. In situ hybridization of HvHAK1 mRNA in barley roots. Cross sections of seminal barley roots located 10 to 20 mm from the tip are shown. The expression of HvHAK1 is indicated by dark granules. A, Antisense probe. B, Sense probe. C, cortex; E, endodermis; VC, vascular cylinder. Bars, 100 µm.

The Accumulation of Transcripts Coding for HAK1 Transporters Involves Cross Talk between NH₄⁺-Sensitive and NH₄⁺-Insensitive Mechanisms

The specific accumulation of HvHAK1 mRNA was estimated by real-timePCR coupled with reverse transcription (RT). Long-term K⁺ deprivation(no K⁺ added to the complete aerated culture solution) led toincreased accumulation of HvHAK1 transcripts (Fig. 2A ), witha similar pattern observed for plants grown in a MES-Ca²⁺ solutionin the absence of aeration (Supplemental Fig. S2). Experimentswith plants grown at combined levels of NH₄⁺ and K⁺ showed thatthe accumulation of HvHAK1 transcripts following K⁺ deprivationoccurs to the same extent in the presence and absence of a highNH₄⁺ concentration during plant culture (Fig. 2B).

View larger version (6K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 2. Expression of K⁺ transporter-coding genes is enhanced by K⁺ starvation through an ammonium-sensitive and an ammonium-insensitive pathway. A, Accumulation of HvHAK1 and HvHAK1b transcripts in 1-week-old plants grown with or without K⁺ since germination (n = 3). ddCt corresponds to the difference in transcript accumulation between the presence of K⁺ (control condition) and its absence (no K⁺ added). Asterisks denote significant effects of K⁺ deprivation. B and C, Effects of the presence or absence of K⁺ and NH₄⁺ (100 µM and 5 mM, respectively) during a 3-d period on the accumulation of HvHAK1 and HvHAK1b transcripts (n = 6). Error bars represent SE. Different letters indicate significantly different values (P < 0.05 for A and B, P < 0.001 for C).

The accumulation of transcripts coding for HvHAK1b, a very closerelative of HvHAK1, was also enhanced by long-term K⁺ deprivation(Fig. 2A). However, the accumulation of HvHAK1b transcriptsfollowing K⁺ deprivation was significantly lower for plantsgrown at a high NH₄⁺ concentration compared with those grownin the absence of NH₄⁺ (Fig. 2C). These results indicate thatfollowing K⁺ deprivation, the accumulation of transcripts codingfor HAK1 transporters involves two different routes, one ofthem sensitive and the other insensitive to NH₄⁺.

HvHAK1 Transcript Accumulation Is Up-Regulated by NaCl Salinization

Given that exposure to high Na⁺ concentrations interferes withK⁺ nutrition, the effect of NaCl on the accumulation of HvHAK1was analyzed. A 6-h exposure to 100 mM NaCl, in the presenceof 1 mM K⁺, led to a significant increase in the amount of HvHAK1transcripts compared with that measured for control plants,an effect that was reversed at 48 h after salinization (Fig. 3A ).These results indicate a strong and transient NaCl-triggeredHvHAK1 up-regulation at the transcript level, consistent witha possible role of HvHAK1 during the fast response of plantsto salinity. With this possibility in mind, we studied the influenceof Na⁺ on the uptake of Rb⁺, a good analog of K⁺ for HAK1 transporters,following salinization. The quotient between the uptake of Rb⁺measured in the presence of 100 mM NaCl and that measured inthe absence of this salt increased significantly at 6 h aftersalinization (Fig. 3B). These results argue for a parallel controlof K⁺ uptake properties and HvHAK1 mRNA accumulation under salineconditions.

View larger version (10K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 3. Expression of HvHAK1 is transiently enhanced by salinization and parallels changes in the reduction of Na⁺-inhibitory effects on Rb⁺ uptake in barley roots. Plants were exposed to 100 mM NaCl in the presence of 1 mM KCl. A, Accumulation of HvHAK1 transcripts measured at 0, 6, and 48 h since the beginning of salt stress (n = 5). B, Rb⁺ uptake from a 100 µM Rb⁺ solution, after those periods, was measured in both the presence and the absence of 100 mM NaCl, and the quotient between the uptake measured in those conditions is shown (n = 6). Error bars represent SE. Different letters indicate significantly different values (P < 0.005 for A, P < 0.05 for B).

Because of the possibility that the rapid up-regulation of HvHAK1transcript accumulation could be the result of an osmotic shock,the effect of sorbitol was explored. A 6-h exposure to 200 mMsorbitol led to an accumulation of HvHAK1 transcripts not significantlydifferent from that determined for control plants and lowerthan that determined for 100 mM NaCl-treated plants (SupplementalFig. S3). While the contribution of an osmotic component cannotbe ruled out since it could account for 44% of that observedin NaCl-stressed plants, these data indicate that nonosmoticcomponents could be involved in the transient response. In turn,the 6-h effect of 100 mM NaCl on the accumulation of HvHAK1transcripts was not accompanied by a change in the total concentrationof K⁺ in roots. Instead, the concentration of Na⁺ in roots clearlyincreased over that period (Supplemental Fig. S3).

HvHAK1 Transgenic Plants Display an Enhanced Rb⁺ Transport When Subjected to K⁺ Deprivation

The results shown above indicate that K⁺ deprivation exertsa strong effect on the accumulation of transcripts coding fortwo HAK1 transporters (Fig. 2). It seems likely that these transporters,and others not examined here but homologous with those alreadystudied in Arabidopsis (Hirsch et al., 1998; Ahn et al., 2004;Gierth et al., 2005), contribute to the capture of K⁺ by roots.Therefore, in order to study the effect of K⁺ deprivation onthe specific contribution of HvHAK1 to Rb⁺ capture, we performeda stable transformation of Arabidopsis plants with a constructcontaining HvHAK1 under the control of the 35S promoter. Allof the HvHAK1-expressing transgenic lines assayed displayeda similar pattern (Fig. 4A ). A more detailed study performedwith a selected transgenic line (J1) showed that the uptakeof Rb⁺ was just slightly higher for HvHAK1-expressing plantsthan for HvHAK1-nonexpressing plants grown in the presence of1 mM KCl. When plants were deprived of K⁺ for 48 h, the subsequenttransport of Rb⁺ was markedly higher in HvHAK1-expressing plantsthan in HvHAK1-nonexpressing plants (Fig. 4B). These resultsindicate that K⁺ availability controls the contribution of HvHAK1to K⁺ capture in transgenic Arabidopsis plants.

View larger version (13K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 4. Arabidopsis plants expressing HvHAK1 display enhanced Rb⁺ uptake following K⁺ withdrawal. A, Four homozygous HvHAK1-expressing Arabidopsis lines (named J1, B1, A28, and A41) display an enhanced uptake of Rb⁺ from a 100 µM Rb⁺ solution relative to wild-type (WT) plants when deprived of K⁺ for 48 h (on average, n = 7). B, Detailed analysis for the HvHAK1-expressing J1 line. Results are means of 13 experiments (each one consisting of seven independent replicates, on average). Error bars represent SE. Different letters indicate significantly different values (P < 0.05 for A, P < 0.01 for B).

Rb⁺ Uptake in Yeast Cells Expressing HvHAK1 Is Modulated by K⁺ Supply

In order to gain further insight on how the contribution ofHvHAK1 is modulated by the composition of the environment, weperformed a detailed study of Rb⁺ transport in Saccharomycescerevisiae mutants compromised for K⁺ uptake. Expression ofHvHAK1 in a yeast mutant lacking the TRK1 and TRK2 K⁺ transportersshows that after K⁺ deprivation, the uptake of Rb⁺ mediatedby HvHAK1 increased progressively until reaching a plateau (Fig. 5A ).After attaining this plateau, the uptake of Rb⁺ was 3- to 4-foldhigher in K⁺-deprived cells than in cells never subjected toK⁺ starvation. A reciprocal experiment showed that K⁺ resupplyled to a progressive decline of Rb⁺ uptake (Fig. 5B), indicatingthat the modulation of HvHAK1-mediated Rb⁺ transport is reversible.In measuring Rb⁺ uptake under these experimental conditions,special care should be taken to avoid the masking effect causedby the release of K⁺ from cells to the medium during the Rb⁺-loadingprocedure, which may be particularly pronounced at the verybeginning of K⁺ deprivation. We found that 15 and 210 min afterK⁺ deprivation, the concentration of K⁺ in the loading solutionwas 8 and 4 µM, respectively, indicating the presenceof only minor interference of K⁺ on Rb⁺ uptake measurementsmade from a 100 µM Rb⁺ solution after 15 min of K⁺ deprivation.Consequently, further comparisons between K⁺-nonstarved andK⁺-starved cells were done by comparing cells deprived of K⁺for 15 and 210 min, respectively.

View larger version (17K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 5. Rb⁺ uptake is enhanced by K⁺ starvation in HvHAK1-expressing yeast cells. A, Rb⁺ uptake from a 100 µM Rb⁺ solution by HvHAK1-expressing yeast cells grown overnight at 30 mM KCl and deprived of K⁺ (no K⁺ added) for different time periods (n = 6). B, Reciprocal experiment (n = 5) with 210-min K⁺-deprived cells transferred to a 30 mM KCl medium. C, Rb⁺ uptake (n = 6) from a wide range of micromolar Rb⁺ concentrations for K⁺-starved cells (white triangles) and K⁺-nonstarved cells (black triangles). D, Effect of K⁺ deprivation on the accumulation of HvHAK1 transcripts in yeast cells (n = 7). Error bars represent SE.

It has been shown that some HAK-KUP-KT transporters could mediatethe biphasic transport of K⁺ (Fu and Luan, 1998

; Kim et al.,1998

). No evidence for the modulation of HvHAK1 transport involvinga switch between monophasic and biphasic modes of transportwas found (Supplemental Fig. S4). Consistently, a single andsaturable component, operative in the micromolar range of Rb⁺concentrations, was observed (Fig. 5C). Values of V_max were0.66 ± 0.12 and 1.92 ± 0.32 nmol mg^–1 min^–1for K⁺-nonstarved and K⁺-starved cells, respectively, indicatinga 3-fold enhancement of the K⁺ transport capacity. On the otherhand, Rb⁺ K_m increased significantly from 5.6 ± 1.0 to9.6 ± 1.3 µM in HvHAK1-expressing cells duringthe course of K⁺ starvation. Given that the K⁺ concentrationin the loading solution is somewhat higher for K⁺-nonstarvedthan for K⁺-starved cells (due to K⁺ loss), the actual differencein Rb⁺ K_m may be even higher. An important question to addressis whether this increased K_m could be just a by-product of aresponse to K⁺ starvation with no acclimation value. Therefore,we explored whether changes in the Rb⁺ K_m of HvHAK1-mediatedtransport are accompanied by a change in the sensitivity ofRb⁺ transport to Na⁺. The inhibitory effect of 100 mM NaCl onthe transport of Rb⁺ was more pronounced for cells deprivedof K⁺ for 210 min than for K⁺-nonstarved cells (SupplementalFig. S4), a result compatible with a decreased K⁺/Na⁺ selectivityof the HvHAK1 transporter under conditions of K⁺ starvation.Unfortunately, attempts to detect differences in Na⁺ transportbetween K⁺-starved and K⁺-nonstarved HvHAK1-expressing cellsin different yeast mutants failed because of the presence ofyeast low-affinity transporters that dominate the transportof Na⁺ over that attributed to the plant transporter.

An important question to be considered is whether the changesin V_max reported above are linked, at least in part, to changesin the accumulation of HvHAK1 transcripts during the courseof K⁺ deprivation. RT-PCR studies showed that the amount ofHvHAK1 transcripts in HvHAK1-expressing yeasts was not significantlydifferent between K⁺-starved and K⁺-nonstarved cells (Fig. 5D).

The Contribution of HvHAK1 to K⁺ Capture in Yeast Cells Is Modulated by the Concentration of K⁺ and Na⁺, But Not by NH₄⁺, in the Growth Medium

We also tried to gain insight into the S. cerevisiae mechanismsleading to the enhanced HvHAK1 K⁺ transport contribution inK⁺-starved cells. For this purpose, we exposed HvHAK1-expressingcells to a wide range of external alkali cation concentrationsfor 15 or 210 min and measured the subsequent uptake of Rb⁺in a solution with no addition of K⁺, Na⁺, and NH₄⁺. We observeda similar internal K⁺ concentration and a similar uptake ofRb⁺ for cells exposed for 15 min to different external K⁺ concentrations(data not shown). For cells exposed for 210 min, the internalK⁺ concentration was similar at different external K⁺ concentrations(data not shown) but the rate of Rb⁺ uptake depended on thenew external K⁺ concentration in the growth medium (Fig. 6A ).These results are consistent with a role of K⁺ trafficking acrossthe membrane in controlling HvHAK1 transport. In order to performan assessment of the specificity of K⁺ supply on changes inRb⁺ uptake, we next investigated whether or not the inclusionof Na⁺ and NH₄⁺ in the growth medium interferes with the courseof K⁺ deprivation. The addition of Na⁺ during the first 15 minof K⁺ starvation did not exert any effect on the subsequentRb⁺ transport (data not shown). However, the addition of NaClduring a 210-min K⁺ deprivation period resulted in a decreaseof the subsequent Rb⁺ uptake (Fig. 6B), indicating that thepresence of high Na⁺ concentrations during growth interfereswith the stimulatory effect of K⁺ starvation on the HvHAK1 contributionto Rb⁺ transport. However, not all monovalent cations possessedthis capacity. Complementary experiments highlighted that cultureat high NH₄⁺ concentrations did not interfere with the enhancementof HvHAK1-mediated Rb⁺ transport observed in yeast cells after210 min of K⁺ deprivation (Fig. 6C).

View larger version (25K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 6. High sodium, but not high ammonium, concentrations interfere with the increased contribution of HvHAK1 following K⁺ starvation in yeast cells. HvHAK1-expressing yeast cells were grown overnight at 30 mM KCl and then exposed for 210 min to different external concentrations of alkali cations. A, Rb⁺ uptake from a 100 µM Rb⁺ solution after cells were exposed to different external K⁺ concentrations (n = 4). B and C, Rb⁺ uptake for cells exposed for 210 min to the absence of K⁺ in the presence of different Na⁺ concentrations (n = 3) or NH₄⁺ concentrations (n = 5), respectively. D, Accumulation of the fluorescent dye DiOC6 measured in yeast cells grown for 210 min in the absence of K⁺ with or without 30 mM NH₄⁺, 100 mM Na⁺, or 20 µM carbonyl cyanide m-chlorophenylhydrazone (CCCP) uncoupler as well as in the presence of 30 mM KCl (n = 5). Error bars represent SE. Different letters indicate significantly different values (P < 0.05 for A to C, P < 0.005 for D).

The observed dependence of Rb⁺ uptake on the external concentrationof K⁺ used for yeast culture is consistent with the possibilitythat changes in HvHAK1 transport are associated with changesin membrane potential. In order to provide an estimate of changesin membrane potential following K⁺ deprivation, we measuredthe accumulation of the fluorescent dye 3,3'-dihexyloxacarbocyanineiodide (DiOC₆) by flow cytometry, which has been validated asan indicator of membrane potential for yeast cells grown underthe same conditions (Madrid et al., 1998

). HvHAK1-expressingcells deprived of K⁺ for 210 min accumulated more DiOC₆ thanK⁺-nonstarved cells, indicating that hyperpolarization takesplace during K⁺ starvation (Fig. 6D). Addition of the uncouplercarbonyl cyanide m-chlorophenylhydrazone abolished this highaccumulation of DiOC₆, providing a control on the reliabilityof membrane potential measurements performed here. The presenceof high NH₄Cl concentrations during long-term K⁺ deprivation,in turn, affected neither the subsequent membrane potentialdifference nor the transport of Rb⁺ (Fig. 6, D and C, respectively).If the contribution of HvHAK1 were strictly associated withincreased hyperpolarization, it would be expected that any conditionleading to a more negative membrane potential must result inhigher Rb⁺ uptake. However, we found that when cells were long-termdeprived of K⁺ in the presence of 100 mM NaCl, they became hyperpolarizedand exhibited low Rb⁺ transport (Fig. 6, D and B, respectively).Therefore, other factors should contribute to the transportof K⁺ mediated by HvHAK1.

Results obtained for HvHAK1-expressing yeast cells grown inthe presence of Na⁺ prompted us to analyze the role of Na⁺ exclusionon HvHAK1 activity. For this purpose, we transformed HvHAK1into yeast cells carrying a disruption of the genes coding forthe Na⁺-ATPases ENA1 to ENA4 and the Na⁺/H⁺ antiporter NHA1in addition to the disruption of genes coding for the TRK1 andTRK2 K⁺ transporters. Pretreatment with moderate NaCl concentrationsduring the course of K⁺ deprivation led to a higher relativereduction of the subsequent Rb⁺ uptake by cells lacking thesystems involved in Na⁺ exclusion than by cells in which activeNa⁺ exclusion takes place (Fig. 7 ).

View larger version (16K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 7. Culture at moderate NaCl concentrations affects Rb⁺ transport mediated by HvHAK1 in yeast cells lacking Na⁺ exclusion systems. Rb⁺ uptake from a 100 µM Rb⁺ solution (n = 4) was measured after 210 min of K⁺ starvation in the presence of different NaCl concentrations for HvHAK1-expressing trk1 ${Delta}$ trk2 ${Delta}$ cells (black columns) and trk1 ${Delta}$ trk2 ${Delta}$ ena1-4 ${Delta}$ nha1 ${Delta}$ cells, which lack the Na⁺-excluding systems ENA1 to ENA4 and NHA1 (dotted columns). Data for K⁺-nonstarved cells are included for comparative purposes. Error bars represent SE. Different letters indicate significantly different values (P < 0.01).

Modulation of the HvHAK1 Contribution to K⁺ Capture in Yeast Cells Involves PPZ1 and HAL4/5 Proteins

The results shown above indicate a complex control of the contributionof HvHAK1 to K⁺ transport. In yeast cells, regulation of K⁺influx mediated by TRK transporters involves, among other components,protein phosphatases PPZ1/2 as well as halotolerance HAL4/5kinases. HvHAK1-expressing yeast cells lacking HAL4 and HAL5in addition to the lack of TRK1 and TRK2 showed higher Rb⁺ transportthan that displayed by cells only lacking TRK1 and TRK2 whendeprived of K⁺ for 210 min (Fig. 8A ). Since hal4 ${Delta}$ hal5 ${Delta}$ disruptionin a TRK1-TRK2 background causes membrane hyperpolarization(Mulet et al., 1999), we next tried to determine whether theresults obtained in Rb⁺ uptake experiments could be explainedby differences in membrane potential between trk1 ${Delta}$ trk2 ${Delta}$ hal4 ${Delta}$ hal5 ${Delta}$ and trk1 ${Delta}$ trk2 ${Delta}$ HAL4HAL5 cells expressing HvHAK1. Ruling out thispossibility, we found a similar DiOC₆ accumulation in both kindsof cells (Fig. 8C). As such, we concluded that HAL4/HAL5 proteinsdown-regulate the contribution of HvHAK1 to K⁺ transport.

View larger version (16K):
[in this window]
[in a new window]
[as a PowerPoint slide]

Figure 8. The PPZ1 phosphatase and the HAL4/5 kinases control the inducible transport of Rb⁺ mediated by HvHAK1 in yeast cells. A, Rb⁺ uptake from a 100 µM Rb⁺ solution measured in K⁺-starved (210 min) and K⁺-nonstarved trk1 ${Delta}$ trk2 ${Delta}$ and trk1 ${Delta}$ trk2 ${Delta}$ hal4 ${Delta}$ hal5 ${Delta}$ HvHAK1-expressing yeast cells (n = 5). B, Under the same experimental conditions, Rb⁺ uptake was also measured in trk1 ${Delta}$ trk2 ${Delta}$ and trk1 ${Delta}$ trk2 ${Delta}$ ppz1 ${Delta}$ HvHAK1-expressing yeast cells derived from the DBY746 strain (n = 5). C and D, Accumulation of the DiOC6 fluorescent dye for cells grown in the presence or absence of K⁺ (n = 3). Error bars represent SE. Different letters indicate significantly different values (P $≤$ 0.01 for A and D, P < 0.001 for B and C).

To study the role of PPZ1, we transformed trk1 ${Delta}$ trk2 ${Delta}$ and trk1 ${Delta}$ trk2 ${Delta}$ ppz1 ${Delta}$ cells with a p424 plasmid containing the HvHAK1 cDNA. Expressionof HvHAK1 into p424 did not restore the growth of yeast cellslacking TRK1 and TRK2. However, in a background also lackingPPZ1, expression of HvHAK1 into p424 restored the capacity ofyeast cells to grow at low external K⁺ concentrations, indicatinga control of the HvHAK1 contribution to K⁺ capture (SupplementalFig. S5). The role of PPZ1 was tested directly by measuringRb⁺ uptake after 15 or 210 min of K⁺ starvation in trk1 ${Delta}$ trk2 ${Delta}$ or trk1 ${Delta}$ trk2 ${Delta}$ ppz1 ${Delta}$ HvHAK1-expressing cells. A strong response ofRb⁺ uptake to K⁺ starvation was clearly found in cells lackingPPZ1 (Fig. 8B), suggesting a role of the encoded protein indown-regulating the HvHAK1 contribution to K⁺ capture. Studiesof the accumulation of DiOC₆ revealed that after a 210-min periodof K⁺ starvation, HvHAK1-expressing ppz1 ${Delta}$ trk1 ${Delta}$ trk2 ${Delta}$ cells werehyperpolarized compared with HvHAK1-expressing trk1 ${Delta}$ trk2 ${Delta}$ cells(Fig. 8D).

DISCUSSION

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

The HAK-KT-KUP-type transporters constitute a large family ofproteins thought to play a pivotal role in the maintenance ofK⁺ homeostasis in plants. Here, we introduced evidence demonstratingthat the ionic environment regulates the contribution of theHvHAK1 K⁺ transporter to K⁺ movement. This regulation may becritical to ensure K⁺ capture in K⁺-deficient environments andduring the early response to salinity.

It has been shown previously that HAK1 transporters providea route for K⁺ uptake in HAK1-expressing yeast cells that issimilar to that found previously in plants suffering from K⁺deficiency (Epstein et al., 1963; Santa-María et al.,1997; Rubio et al., 2000). The contribution of HAK1 transportersto high-affinity K⁺ transport was later confirmed in an Arabidopsismutant lacking the HvHAK1 homolog, AtHAK5, which displays reducedcapture of Rb⁺ under conditions of K⁺ starvation (Gierth etal., 2005). The evidence that HvHAK1 accumulation is augmentedin the outermost layers of the root (Fig. 1) supports a roleof the encoded transporter at the boundary between the externalmedium and the roots. This tissue location (Fig. 1), the enhancedaccumulation of HvHAK1 transcripts upon K⁺ deprivation in barleyroots (Fig. 2), as well as the enhanced capture of K⁺ displayedby HvHAK1 transgenic plants following K⁺ withdrawal (Fig. 4),are consistent with a role of this transporter in the induciblecomponent of K⁺ uptake from diluted K⁺ solutions.

Studies with transgenic Arabidopsis plants expressing HvHAK1indicate a strong effect of K⁺ deprivation on the contributionof HvHAK1. Studies with yeast cells expressing HvHAK1 allowedus to dissect the way in which K⁺ deprivation sets the contributionof a HAK-KUP-KT transporter in a model organism in which theendogenous transport of K⁺ from diluted K⁺ solutions is nil.In this organism, changes in the contribution of HvHAK1 to Rb⁺capture following K⁺ starvation are not linked to changes inthe accumulation of HvHAK1 transcripts (Fig. 5D), indicatingthat K⁺ deprivation should act on the amount and/or the activityof the HvHAK1 transporter. A primary phenomenon that takes placein plants and yeasts suffering K⁺ deficiency is plasma membranehyperpolarization (Maathuis and Sanders, 1994; Walker et al.,1996; Hirsch et al., 1998; Madrid et al., 1998). In this context,an important question to address is whether the enhancementof Rb⁺ uptake observed here (Figs. 5A and 6A) results only froma long-term change in the membrane potential. Measurements ofDiOC₆ accumulation indicate that K⁺ starvation in HvHAK1-expressingyeast cells also leads to plasma membrane hyperpolarization(Figs. 6D and 8). These data are consistent with a possiblerole of membrane potential on changes in the transport of Rb⁺mediated by HvHAK1 by affecting either the driving force ora signaling cascade. The evidence offered here (Figs. 6D and8C) indicates that changes in the contribution of HvHAK1 toK⁺ capture cannot be entirely accounted for by changes drivenby membrane potential. Therefore, other mechanisms modulatingthe HvHAK1 contribution to K⁺ capture in yeasts should be considered.

In most fungi, K⁺ transport results from the activity of TRKand HAK transporters (Benito et al., 2004). The mechanisms controllingK⁺ homeostasis through TRK1 have been deeply explored in S.cerevisiae, revealing that TRK1 is activated by the HAL4 andHAL5 kinases and inhibited by the PPZ1 and PPZ2 phosphatases(Mulet et al., 1999; Yenush et al., 2002). Interestingly, geneticevidence obtained with this work supports the hypothesis thatHAL4/5 kinases act as down-regulators of the HvHAK1 contribution(Fig. 8A), which is opposite to their effect on TRK1. On theother hand, current evidence indicates that PPZ1 is involvedin determining the upper limits of K⁺ accumulation in yeastcells, mainly in a TRK1-dependent manner (Yenush et al., 2005).Our results indicate that PPZ1 could exert this regulatory role,critical for K⁺ homeostasis, by setting the contribution ofa HAK1 transporter to K⁺ capture (Fig. 8B). The fact that bothHAL4/5 kinases and the PPZ1 phosphatase act as down-regulatorsof the contribution of HvHAK1 to K⁺ transport could be explainedby their action at different levels of regulation. Althoughthe precise mode by which PPZ1 and HAL4/5 modulate the HvHAK1contribution is still uncertain, our results illustrate thatboth phosphorylation and dephosphorylation processes act inconcert to determine the uptake of K⁺ mediated by a HAK1 transporterin yeasts. In this context, the search for plant functionalcounterparts of PPZ1 phosphatase and HAL4/5 kinases could helpto determine whether or not the mechanisms setting the contributionof HvHAK1 in yeast cells are operative in plants. Besides, thefinding that a HAK1 transporter is modulated by PPZ1 and HAL4/5in S. cerevisiae, in which no HAK genes have been found, posesimportant questions regarding the conservation of the regulatorynetwork controlling K⁺ homeostasis in fungi.

Transcriptome studies revealed the existence of a cross talkof signals associated with the perception of nitrogen and K⁺status in plants (Wang et al., 2001; Armengaud et al., 2004).Additionally, the presence of high NH₄⁺ concentrations has beenused as a tool to dissect the components involved in K⁺ transport(Hirsch et al., 1998; Spalding et al., 1999; Nieves-Cordoneset al., 2007). In barley, the presence of high NH₄⁺ concentrationsin the growth medium generates a switch on the properties ofRb⁺ uptake from diluted K⁺ solutions (Santa-María etal., 2000). This switch involves two parallel processes, thefirst one being the dominance of channel-like features, partiallyexplained by a thermodynamic gradient favorable to channel participation(Kronzucker et al., 2003). The second process involved in thatswitch is the reduced size of the inducible component of Rb⁺transport sensitive to NH₄⁺. Our results indicate that the reductionof this inducible component does not involve a long-term down-regulationof HvHAK1 transcript accumulation mediated by high ammoniumlevels (Fig. 2B). Therefore, it seems possible that the reducedrelative contribution of the NH₄⁺-sensitive component of Rb⁺transport after long-term growth at high NH₄⁺ supplies couldbe, at least in part, the result of a down-regulation of theaccumulation of transcripts coding for other transporters. Geneexpression studies (Fig. 2C) suggest that HvHAK1b could be atarget for such a regulation. Therefore, the accumulation oftranscripts coding for HAK1 transporters presumably involvedin the NH₄⁺-sensitive pathway of K⁺ transport occurs throughtwo signaling routes: one NH₄⁺-sensitive, acting on HvHAK1b,and the other insensitive to NH₄⁺, acting on HvHAK1.

The effect of sodium salts on K⁺ homeostasis has been a mainsubject in salinity studies (Flowers and Läuchli, 1983).In Arabidopsis, the current evidence indicates that, for plantsgrown in the presence of ammonium, the inhibitory effect ofNa⁺ on K⁺ uptake results from an effect of Na⁺ on the activityof the AKT1 K⁺ channel (Qi and Spalding, 2004). The evidencecontributed here indicates that culturing at high NaCl concentrationsprecludes the subsequent enhancement of K⁺ transport mediatedby a HAK1 transporter in K⁺-deprived yeasts (Fig. 6B and 7).While this effect tends to diminish the contribution of HvHAK1to K⁺ capture, the transient enhanced accumulation of HvHAK1transcripts observed in barley roots after a 6-h exposure toa high external NaCl concentration (Fig. 3) could lead to theopposite outcome and is likely to play a role in determiningthe low inhibitory effect of Na⁺ on Rb⁺ transport observed inbarley roots at 6 h after salinization (Fig. 3). Whereas ourdata (Supplemental Fig. S3) do not allow us to rule out thecontribution of an osmotic component, they indicate a role ofnonosmotic components on the peak of accumulation of HvHAK1transcripts. Evidence for cross talk between osmotic and nonosmoticsignals during the early transcriptome response to salt stresshas been offered for barley plants (Ueda et al., 2004). Theenhancement and decline in the amount of HvHAK1 transcriptsobserved here (Fig. 3) is similar to that reported for a memberof the group II HAK transporters in Mesembryanthemum crystallinum(Su et al., 2002) and essentially mimics that observed formerlyfor the genes implicated in the early coordinated gene responseto salt stress described in the barley close relative speciesLophopyrum elongatum (Gulick and Dvo $r$ ák, 1992; Galvezet al., 1993). Since a similar response is elicited by abscisicacid (Galvez et al., 1993) and a transient change in the balancebetween methyl jasmonate and abscisic acid has been observedduring the first hours of exposure to high NaCl concentrations(Moons et al., 1997), with a prominent role of jasmonic acidin the K⁺-dependent transcriptome also advanced (Armengaud etal., 2004), the possibility that hormone signaling plays a rolein setting the response of HvHAK1 to salt stress should notbe discarded.

In conclusion, this study indicates the presence of mechanismsdriven by the ionic environment that determine the contributionof a HAK1 transporter to K⁺ capture. Furthermore, studies withyeast cells reveal a role of phosphorylation and dephosphorylationprocesses in setting this contribution.

MATERIALS AND METHODS

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Plant Materials and Culture

Seeds of barley (Hordeum vulgare ‘Golden Promise’)were germinated in the dark on moistened filter paper for 48h. Seedlings were then transferred to a 0.8-L plastic pot filledwith a complete nutrient solution of the following composition:1.0 mM Ca(NO₃)₂, 0.5 mM MgSO₄, 0.5 mM H₃PO₄, 50 µM FeEDTA,50 µM CaCl₂, 25 µM H₃BO₃, 2 µM ZnSO₄, 2 µMMnSO₄, 0.5 µM CuSO₄, 0.5 µM molybdic acid, and 2.5mM MES, with or without the addition of 1 mM K⁺, except whereindicated. The pH was brought to 6.0 by the addition of Ca(OH)₂,and the solution was aerated. When added, K⁺, Na⁺, and NH₄⁺were provided as chloride salts. Temperature in the growth chamberwas set to 22°C (day/night), and the relative humidity waskept at 85%. The photon flux density at the plant level wasset at 70 µmol m^–2 s^–1 over a photoperiodof 14 h. Experiments were carried out with 1-week-old plants,except for the experiment reported in Figure 2, B and C, inwhich 13-d-old plants were used. Root and shoot samples wereextracted with 0.5 N HCl to release free cations, and K⁺ (orRb⁺ in Rb⁺ uptake experiments) was determined with a Perkin-ElmerAA 100 spectrophotometer in emission mode. Arabidopsis (Arabidopsisthaliana ecotype Columbia) seeds were sowed on plates containingthe medium described above plus 0.8% agar. After 10 d, seedlingswere transferred to 0.125-L plastic pots in which only rootswere in contact with the nutrient solution. Plants grew foranother 2 weeks, until the experiments were performed.

Rb⁺ Uptake Measurements in Plants

Roots of intact plants were transferred for 5 min to a solutionwith the same composition as used for growth but without K⁺.This allows elution of this chemical species from the root apoplastand thus helps to minimize the effect of ionic perturbationson the subsequent measurement. Loading was performed in 50-mLplastic pots containing the complete nutrient solution withno K⁺ added. This solution, heavily aerated, contained 100 µMRb⁺. Loading was extended for 60 min for barley and for 120min for Arabidopsis. Subsequently, roots were washed two timesfor a total of 6 min with the same solution used for loadingbut without Rb⁺. Results are expressed on a fresh weight basis.

Quantitation of Plant mRNAs

For the quantitation of plant mRNAs, RNA extracted from wholebarley roots was used. Extraction of total RNA was performedwith the use of the RNeasy Plant Mini kit (Qiagen). After extraction,total RNA was treated with RQ1 DNase (Promega), and the presenceof contamination from a genomic origin was specifically testedfor by PCR. For each DNA-free RNA sample, several independentRT reactions were performed. RT was carried out with SuperScriptII (Gibco-BRL) on 20 ng of total RNA using Oligonucleotide-dT₁₈as 3' primer. Real-time PCR was performed in duplicate for eachRT reaction using the ABI Prism 5700 sequence detection system(Perkin-Elmer Applied Biosystems) and SYBR Green PCR MasterMix (Perkin-Elmer Applied Biosystems). Primers used for PCRfor each gene, as well as amplicon sizes, have been described(Vallejo et al., 2005). Amplification was carried out with aninitial step at 50°C for 2 min followed by 1 cycle at 95°Cfor 10 min and then by 40 amplification cycles. After each PCR,the dissociation curve of the PCR product was analyzed. ThecDNA content of β-tubulin for each run was also estimated.In addition, two negative controls were included to excludethe possibility of genomic DNA contamination: one of them consistedof a reaction without cDNA, while the other contained an aliquotof the DNA-free RNA sample. Subsequently, the accumulation oftranscripts was estimated by the use of the ${Delta}$ ${Delta}$ Ct method.

In Situ Hybridization

One-week-old barley plants, grown without aeration in a 10 mMMES solution brought to pH 6.0 ± 0.1 with Ca(OH)₂, wereused for in situ hybridization studies. Roots were cut into10-mm-long fragments, from 10 to 60 mm from the root apex. Forthe fixation protocol, roots were treated with 3% (v/v) paraformaldehydeand 0.25% (v/v) glutaraldehyde in 0.1 M sodium phosphate buffer,pH 7.2, at room temperature, dehydrated in graded ethanol andxylene series, and embedded in Paraplast. Sections (2 µmthick) were attached to poly-L-Lys-coated slides. Sections weredeparaffinized with xylene and rehydrated through a graded ethanolseries. They were subsequently pretreated with 1 µg mL^–1proteinase K in 200 mM Tris-HCI, pH 7.5, and 2 mM CaCl₂ at 37°Cfor 30 min and with 0.25% (v/v) acetic anhydride in 0.1 M triethanolamine,pH 8.0, at room temperature for 10 min, dehydrated in a gradedethanol series, and air dried. Sections were hybridized witheither sense or antisense RNA ³⁵S-labeled probes.

A pGEM-T Easy vector (Promega) containing a 325-bp cDNA of theHvHAK1 3' untranslated region was linearized with PstI or NcoIto be used as DNA template for the in vitro synthesis of thesense or antisense RNA probe, respectively. Sense and antisenseRNA probes were synthesized by the incorporation of [ ${alpha}$ -³⁵S]UTPusing an RNA labeling kit following the manufacturer's instructions(Boehringer Mannheim). Southern-blot analyses with barley genomicDNA previously showed a single hybridization band with this325-bp probe. Hybridization and detection of the radioactivesignal were performed as described previously (Langdale et al.,1988). Photographs were taken using an automatic camera coupledto a light microscope (Axiophot; Zeiss).

Yeast Strains and Growth Conditions

The Saccharomyces cerevisiae strains used in this work wereW ${Delta}$ 3 (W303.1A trk1 ${Delta}$ ::LEU2 trk2 ${Delta}$ ::HIS3), which is deficient in theendogenous K⁺ uptake systems TRK1 and TRK2; MA5 (W303.1A trk1 ${Delta}$ ::LEU2trk2 ${Delta}$ ::HIS3 nha1 ${Delta}$ ::LEU2 ena1-4 ${Delta}$ ::HIS3), which is derived from W ${Delta}$ 3and also deficient in the Na⁺ efflux systems ENA1 to ENA4 andNHA1 (Benito et al., 2004); and JM110 (W303.1A trk1 ${Delta}$ ::LEU2 trk2 ${Delta}$ ::HIS3hal4 ${Delta}$ ::TRP1 hal5 ${Delta}$ ::KanMX), also derived from W ${Delta}$ 3, which carriesa disruption on the genes coding for the protein kinases HAL4and HAL5 (Mulet et al., 1999). These strains were the recipientof the pYPGE15 plasmid or its derivative containing the HvHAK1cDNA, pGF718. Strains ESV212 (DBY746 trk1 ${Delta}$ ::LEU2 trk2 ${Delta}$ ::HIS3)and its derivative MAR70 (DBY746 trk1 ${Delta}$ ::LEU2 trk2 ${Delta}$ ::HIS3 ppz1 ${Delta}$ ::URA3),which carries a disruption of the gene coding for the PPZ1 phosphatasein addition to the disruption of TRK1 and TRK2 (Ruiz et al.,2004), were also used. In this case, the HvHAK1 cDNA was clonedinto the p424 plasmid. Yeast cells were grown in Arg (AP) mediumsupplemented with 30 mM KCl (Santa-María et al., 1997).Cells were washed twice and transferred to AP medium withoutadded K⁺. The basal concentration of K⁺ in that medium was 2.5µM. At different times from the beginning of K⁺ deprivation,Rb⁺ uptake measurements were performed. Cells were suspendedin 2% Glc and 10 mM MES buffer brought to pH 6.0 with Ca(OH)₂.Unless indicated specifically (Supplemental Fig. S4B), Rb⁺ uptakemeasurements were performed in the absence of K⁺, Na⁺, or NH₄⁺in the loading solution. Cells were taken at intervals, filteredthrough a 0.8-µm-pore nitrocellulose membrane (Millipore),and washed with 20 mM MgCl₂. Filters were incubated overnightin 0.5 N HCl, and Rb⁺ was determined by atomic emission spectrophotometry.Results are expressed on a cell dry weight basis. V_max and K_mvalues were estimated by nonlinear regression.

Accumulation of DiOC₆ was estimated for yeast cells grown for210 min in the presence or absence of different alkali cations.These cells did not receive any other treatment and were suspendedin MES-Ca²⁺ and exposed to 1 nM DiOC₆ for 30 min at 28°Cin the dark. To test cell viability, propidium iodide was used.Flow cytometry analysis was performed in a FACSCalibur (Becton-Dickinson).

Plant Transformation

The HvHAK1 718 cDNA was cloned into the plant binary vectorpB112 containing the nptII kanamycin resistance marker. Agrobacteriumtumefaciens pgv3101 was the recipient of the HvHAK1-containingplasmid, which was later used to transform Arabidopsis plants,ecotype Col-0, by the floral dip procedure (Clough and Bent,1998). Plants displaying resistance to the marker were selectedfor further analysis. The presence of the transgene was evaluatedby PCR on genomic DNA. To identify homozygous plants, studiesof the segregation of kanamycin resistance were performed. Expressionof HvHAK1 for each homozygous line was determined by RT-PCRusing DNA-free RNA.

Except where indicated, results obtained in this work were analyzedby two-factor ANOVA, with post-hoc comparisons made by Duncan'stest. The analysis was performed using the Statistica 6.0 program(StatSoft*).

Supplemental Data

The following materials are available in the online versionof this article.

Supplemental Figure S1. In situ hybridizationstudies show theaccumulation of HvHAK1 transcripts in mostroot cells.

Supplemental Figure S2. Effect of K⁺ deprivation,in a nonaeratedMES-Ca²⁺ solution, on the accumulation of HvHAK1transcripts.

Supplemental Figure S3. Comparative effect ofsorbitol and NaClon the accumulation of HvHAK1 transcripts,and effect of NaClexposure on the concentration of K⁺ and Na⁺in roots.

Supplemental Figure S4. Rb⁺ uptake properties ofyeast cellsexpressing HvHAK1 following K⁺ withdrawal.

SupplementalFigure S5. HVHAK1-expressing yeast cells lackingthe PPZ1 phosphatasedisplay an enhanced growth capacity atlow K⁺ concentrations.

ACKNOWLEDGMENTS

We express our thanks to Dr. Joaquín Ariño andDr. Amparo Ruíz (Universitat Autónoma de Barcelona),to Dr. Begonia Benito and Dr. Rosario Haro (Universidad Politécnicade Madrid), and to Dr. Ramón Serrano (Universidad Politécnicade Valencia, Spain) for the gift of the yeast strains used inthis work. Thanks are also given to Dr. Fernando Bravo-Almonacid(Instituto de Investigaciones en Ingeniería Genéticay Biología Molecular), Dr. Victoria Busi (Instituto TecnológicoChascomús), and Dr. Diego Gomez-Casati (Instituto TecnológicoChascomús) for generous help with transgenic plants.We also express gratitude to Dr. Amparo Monfort and Dr. MatildeJosé-Estanyol (Departament de Genètica Molecular,Centro de Investigaciones y Desarrollo-Consejo Superior de InvestigacionesCientíficas) for technical assistance during in situhybridization studies.

Received December 5, 2007; accepted March 17, 2008; published March 21, 2008.

FOOTNOTES

¹ This work was supported by the Agencia Nacional de PromociónCientífica y Tecnológica (grant nos. PICT 080005/2000and PICT 20138/2004) of Argentina as well as by a project fromthe Universidad Politécnica de Madrid of Spain to G.E.S.-M.F.R.F. is the recipient of a fellowship from the UniversidadNacional de San Martín. M.L.P. and S.M. are fellows ofthe Consejo Nacional de Investigaciones Científicas yTécnicas, Argentina.

² These authors contributed equally to the article.

³ Present address: Department of Molecular Biology, MassachusettsGeneral Hospital, and Department of Genetics, Harvard MedicalSchool, Boston, MA 02114.

⁴ Present address: IFEVA, Facultad de Agronomía, Universidadde Buenos Aires, 1417 Buenos Aires, Argentina.

The author responsible for distribution of materials integralto the findings presented in this article in accordance withthe policy described in the Instructions for Authors (www.plantphysiol.org)is: Guillermo E. Santa-María (gsantama{at}iib.unsam.edu.ar).

^[W] The online version of this article contains Web-only data.

^[OA] Open Access articles can be viewed online without a subscription.

www.plantphysiol.org/cgi/doi/10.1104/pp.107.114546

^{^*} Corresponding author; e-mail gsantama{at}iib.unsam.edu.ar.

LITERATURE CITED

TOP
ABSTRACT
RESULTS
DISCUSSION
MATERIALS AND METHODS
LITERATURE CITED

Ahn SJ, Shin R, Schachtman DP (2004) Expression of KT/KUP genes in Arabidopsis and the role of root hairs in K⁺ uptake. Plant Physiol 134: 1135–1145[Abstract/Free Full Text]

Armengaud P, Breitling R, Amtmann A (2004) The potassium-dependent transcriptome of Arabidopsis reveals a prominent role of jasmonic acid in nutrient signaling. Plant Physiol 136: 2556–2576[Abstract/Free Full Text]

Benito B, Garciadeblás B, Schreier P, Rodríguez-Navarro A (2004) Novel P-type ATPases mediate high-affinity potassium or sodium uptake in fungi. Eukaryot Cell 3: 359–368[Abstract/Free Full Text]

Cao Y, Glass ADM, Crawford NM (1993) Ammonium inhibition of Arabidopsis thaliana root growth can be reversed by potassium and by auxin resistance mutations aux1, axr1 and axr2. Plant Physiol 102: 983–989[Abstract]

Clough SJ, Bent AF (1998) Floral dip: a simplified method for Agrobacterium-mediated transformation of Arabidopsis thaliana. Plant J 16: 735–743[CrossRef][Web of Science][Medline]

Epstein E, Rains DW, Elzam OE (1963) Resolution of dual mechanisms of potassium absorption by barley roots. Proc Natl Acad Sci USA 49: 684–692[Free Full Text]

Flowers TJ, Läuchli A (1983) Sodium versus potassium: substitution and compartmentation. In A Láuchli, RL Bieleski, eds, Encyclopedia of Plant Physiology, New Series, Vol 15B, Inorganic Plant Nutrition. Springer-Verlag, Berlin, pp 651–681

Fu HH, Luan S (1998) AtKup1: a dual-affinity K⁺ transporter from Arabidopsis thaliana. Plant Cell 10: 63–73[Abstract/Free Full Text]

Galvez AF, Gulick PJ, Dvo $r$ ák J (1993) Characterization of the early stages of genetic salt-stress responses in salt-tolerant Lophopyrum elongatum, salt-sensitive wheat, and their amphiploid. Plant Physiol 103: 257–265[Abstract]

Garcíadeblás B, Senn ME, Bañuelos MA, Rodríguez-Navarro A (2003) Sodium transport and HKT transporters: the rice model. Plant J 34: 1–14[CrossRef][Web of Science][Medline]

Gierth M, Mässer P, Schroeder JI (2005) The potassium transporter AtHAK5 functions in K⁺ deprivation-induced high-affinity K⁺ uptake and AKT1 channel contribution to K⁺ uptake kinetics in Arabidopsis roots. Plant Physiol 137: 1105–1114[Abstract/Free Full Text]

Gisbert C, Rus AM, Bolarín C, López-Coronado M, Arrillaga I, Montesinos C, Caro M, Serrano R, Moreno V (2000) The yeast HAL1 gene improves salt tolerance of transgenic tomato. Plant Physiol 123: 393–402[Abstract/Free Full Text]

Glass ADM (1976) Regulation of potassium absorption in barley roots: an allosteric model. Plant Physiol 58: 33–37[Abstract/Free Full Text]

Gulick PJ, Dvo $r$ ák J (1992) Coordinate gene response to salt stress in Lophopyrum elongatum. Plant Physiol 100: 1384–1388[Abstract/Free Full Text]

Hirsch RE, Lewis BD, Spalding EP, Sussman MR (1998) A role for the AKT1 potassium channel in plant nutrition. Science 280: 918–921[Abstract/Free Full Text]

Horie T, Costa A, Houn Kim T, Jung Han M, Horie R, Leung HY, Miyao A, Hirochika H, An G, Schroeder JI (2007) Rice OsHKT2;1 transporter mediates large Na⁺ influx component into K⁺-starved roots for growth. EMBO J 26: 3003–3014[CrossRef][Web of Science][Medline]

Kim EJ, Kwak JM, Uozumi N, Schroeder JI (1998) AtKup1: an Arabidopsis thaliana gene encoding high-affinity potassium transporter activity. Plant Cell 10: 51–62[Abstract/Free Full Text]

Kochian LV, Lucas WJ (1982) Potassium transport in corn roots: resolution of kinetics into saturable and linear components. Plant Physiol 70: 1723–1731[Abstract/Free Full Text]

Kochian LV, Lucas WJ (1988) Potassium transport in roots. Adv Bot Res 15: 93–178

Kronzucker HJ, Szczerba MW, Britto DT (2003) Cytosolic potassium homeostasis revisited: ⁴²K-tracer analysis in Hordeum vulgare L. reveals set-point variations in K⁺. Planta 217: 540–546[CrossRef][Web of Science][Medline]

Langdale JA, Rothermel BA, Nelson T (1988) Cellular pattern of photosynthetic gene expression in developing maize leaves. Genes Dev 2: 106–115[Abstract/Free Full Text]

Li L, Kim BG, Cheong YH, Pandey GK, Luan S (2006) A Ca²⁺-signaling pathway regulates a K-channel for low-K response in Arabidopsis. Proc Natl Acad Sci USA 103: 12625–12630[Abstract/Free Full Text]

Maathuis FJM, Sanders D (1994) Mechanism of high-affinity potassium uptake in roots of Arabidopsis thaliana. Proc Natl Acad Sci USA 91: 9272–9276[Abstract/Free Full Text]

Madrid R, Gómez MJ, Ramos J, Rodríguez-Navarro A (1998) Ectopic potassium uptake in trk1 trk2 mutants of Saccharomyces cerevisiae correlates with a highly hyperpolarized membrane potential. J Biol Chem 273: 14838–14844[Abstract/Free Full Text]

Moons A, Prinsen E, Bauw G, Van Montagu M (1997) Antagonistic effects of abscisic acid and jasmonates on salt stress-inducible transcripts in rice roots. Plant Cell 9: 2243–2259[Abstract]

Mulet JM, Leube MP, Kron SJ, Rios G, Fink GR, Serrano R (1999) A novel mechanism of ion homeostasis and salt tolerance in yeast: The Hal4 and Hal5 protein kinases modulate the Trk1-Trk2 potassium transporter. Mol Cell Biol 19: 3328–3337[Abstract/Free Full Text]

Nieves-Cordones M, Martínez-Cordero MA, Martínez V, Rubio F (2007) An NH₄⁺-sensitive component dominates high-affinity K⁺ uptake in tomato plants. Plant Sci 172: 273–280

Qi Z, Spalding EP (2004) Protection of plasma membrane K⁺ transport by the salt overly sensitive 1 Na⁺-H⁺ antiporter during salinity stress. Plant Physiol 136: 2548–2555[Abstract/Free Full Text]

Quintero FJ, Ohta M, Shi H, Zhu JK, Pardo JM (2002) Reconstitution in yeast of the Arabidopsis SOS signaling pathway for Na⁺ homeostasis. Proc Natl Acad Sci USA 99: 9061–9066[Abstract/Free Full Text]

Rodríguez-Navarro A (2000) Potassium transport in fungi and plants. Biochim Biophys Acta 1469: 1–30[Medline]

Rubio F, Santa-María GE, Rodríguez-Navarro A (2000) Cloning of Arabidopsis and barley cDNAs encoding HAK potassium transporters in root and shoot cells. Physiol Plant 109: 34–44[CrossRef]

Ruiz A, Ruiz MC, Sánchez-Garrido MA, Ariño J, Ramos J (2004) The Ppz protein phosphatases regulate Trk-independent potassium influx in yeast. FEBS Lett 578: 58–62[CrossRef][Web of Science][Medline]

Rus A, Lee BH, Muñoz-Mayor A, Sharkhuu A, Zhu JK, Bressan RA, Hasegawa PM (2004) AtHKT1 facilitates Na⁺ homeostasis and K⁺ nutrition in planta. Plant Physiol 136: 2500–2511[Abstract/Free Full Text]

Santa-María GE, Danna CH, Czibener C (2000) High-affinity potassium transport in barley roots: ammonium-sensitive and -insensitive pathways. Plant Physiol 123: 297–306[Abstract/Free Full Text]

Santa-María GE, Rubio F, Dubcovsky J, Rodríguez-Navarro A (1997) The HAK1 gene of barley belongs to a large gene family and encodes a high-affinity potassium transporter. Plant Cell 9: 2281–2289[Abstract]

Sentenac H, Bonneaud N, Minet M, Lacroute F, Salmon JM, Gaymard F, Grignon C (1992) Cloning and expression in yeast of a plant potassium ion transport system. Science 256: 663–665[Abstract/Free Full Text]

Shin R, Schachtman DP (2004) Hydrogen peroxide mediates plant root cell response to nutrient deprivation. Proc Natl Acad Sci USA 101: 8827–8832[Abstract/Free Full Text]

Spalding EP, Hirsch RE, Lewis DR, Qi Z, Sussman MR, Lewis BD (1999) Potassium uptake supporting plant growth in the absence of AKT1 channel activity: inhibition by ammonium and stimulation by sodium. J Gen Physiol 113: 909–918[Abstract/Free Full Text]

Su H, Golldack D, Zhao C, Bohnert HJ (2002) The expression of HAK-type K⁺ transporters is regulated in response to salinity stress in common ice plant. Plant Physiol 129: 1482–1493[Abstract/Free Full Text]

Ueda A, Kathiresan A, Inada M, Narita Y, Nakamura T, Shi W, Takabe T, Bennett J (2004) Osmotic stress in barley regulates expression of a different set of genes than salt stress does. J Exp Bot 55: 2213–2218[Abstract/Free Full Text]

Vallejo AJ, Peralta ML, Santa-María GE (2005) Expression of potassium-transporter coding genes, and kinetics of rubidium uptake, along a longitudinal root axis. Plant Cell Environ 28: 850–862[CrossRef]

Véry AA, Sentenac H (2003) Molecular mechanisms and regulation of K⁺ transport in higher plants. Annu Rev Plant Biol 54: 575–603[CrossRef][Medline]

Walker DJ, Leigh RA, Miller AJ (1996) Potassium homeostasis in vacuolated plant cells. Proc Natl Acad Sci USA 93: 10510–10514[Abstract/Free Full Text]

Wang YH, Garvin DF, Kochian LV (2001) Nitrate-induced genes in tomato roots. Array analysis reveals novel genes that may play a role in nitrogen nutrition. Plant Physiol 127: 345–359[Abstract/Free Full Text]

Xu J, Li HD, Chen LQ, Liu LL, He L, Wu WH (2006) A protein kinase, interacting with two calcineurin B-like proteins, regulates K⁺ transporter AKT1 in Arabidopsis. Cell 125: 1347–1360[CrossRef][Web of Science][Medline]

Yenush L, Merchan S, Holmes J, Serrano R (2005) pH-responsive, posttranslational regulation of the Trk1 potassium transporter by the type 1-related Ppz1 phosphatase. Mol Cell Biol 25: 8683–8692[Abstract/Free Full Text]

Yenush L, Mulet JM, Ariño J, Serrano R (2002) The Ppz protein phosphatases are key regulators of K⁺ and pH homeostasis: implications for salt tolerance, cell wall integrity and cell cycle progression. EMBO J 21: 920–929[CrossRef][Web of Science][Medline]

This Article

Free via Open Access: OA

OA Abstract

Full Text (PDF)

Supplemental Data

OA All Versions of this Article:
147/1/252 most recent
pp.107.114546v1

Alert me when this article is cited

Alert me if a correction is posted

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via CrossRef

Citing Articles via ISI Web of Science (3)

Citing Articles via Google Scholar

Google Scholar

Articles by Fulgenzi, F. R.

Articles by Santa-María, G. E.

Search for Related Content

PubMed

PubMed Citation

Articles by Fulgenzi, F. R.

Articles by Santa-María, G. E.

Agricola

Articles by Fulgenzi, F. R.

Articles by Santa-María, G. E.

The Ionic Environment Controls the Contribution of the Barley HvHAK1 Transporter to Potassium Acquisition1,[W],[OA]

The Ionic Environment Controls the Contribution of the Barley HvHAK1 Transporter to Potassium Acquisition¹^,[W]^,[OA]