Regulation by External K+ in a Maize Inward Shaker Channel Targets Transport Activity in the High Concentration Range

doi:10.1105/tpc.104.030551

Regulation by External K⁺ in a Maize Inward Shaker Channel Targets Transport Activity in the High Concentration Range

Yan-Hua Su¹, Helen North², Claude Grignon, Jean-Baptiste Thibaud, Hervé Sentenac and Anne-Aliénor Véry³

Laboratoire de Biochimie et Physiologie Moléculaire des Plantes, Unité Mixte de Recherche 5004 Agro-M/Centre National de la Recherche Scientifique/Institut National de la Recherche Agronomique/Université Montpellier II, Montpellier, France

^³ To whom correspondence should be addressed. E-mail very{at}ensam.inra.fr; fax 33-467-52-57-37.

ABSTRACT

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

An inward Shaker K⁺ channel identified in Zea mays (maize),ZmK2.1, displays strong regulation by external K⁺ when expressedin Xenopus laevis (African clawed frog) oocytes or COS cells.ZmK2.1 is specifically activated by K⁺ with an apparent K_m closeto 15 mM independent of the membrane hyperpolarization level.In the absence of K⁺, ZmK2.1 appears to enter a nonconductingstate. Thus, whatever the membrane potential, this maize channelcannot mediate K⁺ influx in the submillimolar concentrationrange, unlike its relatives in Arabidopsis thaliana. Its expressionis restricted to the shoots, the strongest signal (RT-PCR) beingassociated with vascular/bundle sheath strands. Based on sequenceand gene structure, the closest relatives of ZmK2.1 in Arabidopsisare K⁺ Arabidopsis Transporter 1 (KAT1) (expressed in guardcells) and KAT2 (expressed in guard cells and leaf phloem).Patch-clamp analyses of guard cell protoplasts reveal a higherfunctional diversity of K⁺ channels in maize than in Arabidopsis.Channels endowed with regulation by external K⁺ similar to thatof ZmK2.1 (channel activity regulated by external K⁺ with aK_m close to 15 mM, regulation independent of external Ca²⁺)constitute a major component of the maize guard cell inwardK⁺ channel population. The presence of such channels in maizemight reflect physiological traits of C4 and/or monocotyledonousplants.

INTRODUCTION

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Potassium can constitute up to 10% of total plant dry weight.Being the most abundant cation in the cytosol, it plays a rolein basic cellular functions such as control of osmotic pressureand membrane potential. Several types of K⁺ transport systems,differing in transport affinity, energetic coupling, voltagesensitivity, or ionic selectivity, have been identified in plantcell membranes by (electro)physiological analyses. The differencesin functional properties and spatial distribution of the transportsystems are thought to allow the fine tuning of K⁺ transportunder varying environmental conditions in different plant tissues.During the past decade, considerable progress has been madein the molecular identification of these transport systems.Coupling molecular approaches with functional analyses has allowedthe identification and characterization of several familiesof K⁺ channels and K⁺ carriers, coding for at least 28 transportsystems in Arabidopsis thaliana, for example (Mäser etal., 2001; Véry and Sentenac, 2003).

Until now, the most extensively characterized family of plantK⁺ transport systems is the Shaker family (Véry and Sentenac,2003). Shaker-like genes, which code for highly K⁺-selectivechannels, have been identified in animals, plants, fungi, andprokaryotes (Jan and Jan, 1997; Chalot et al., 2002; Ruta etal., 2003). In plants, Shaker channels provide major pathwaysfor wholesale K⁺ uptake or secretion in several tissues andcell types. For instance, they have been shown to play crucialroles in root K⁺ uptake from the soil (Hirsch et al., 1998),K⁺ secretion into the xylem sap (Gaymard et al., 1998), K⁺ transportinto or from guard cells during stomatal movements (Kwak etal., 2001; Hosy et al., 2003), and K⁺ uptake in pollen for tubeelongation (Mouline et al., 2002). In Arabidopsis, several inwardShakers have been shown to contribute to K⁺ uptake over a widerange of external K⁺ concentrations, from micromolar to millimolar(Hirsch et al., 1998; Dennison et al., 2001; Mouline et al.,2002). This was unexpected because earlier electrophysiologicalanalyses had led to the hypothesis that inward K⁺ channels contributedto K⁺ uptake only from high external concentrations (Kochianand Lucas, 1988; Maathuis and Sanders, 1996), in the range correspondingto the so-called Epstein mechanism II (Epstein and Rains, 1963).

To date, Arabidopsis is the only plant species for which thecomplete set of Shaker channels has been identified and almostentirely characterized. It is also the only plant species inwhich the functions of plant Shakers have been analyzed by reversegenetics approaches. In other plant species, only a few Shakershave been thoroughly studied. They all have a close relativewithin the Arabidopsis Shaker family, and none of them has beenidentified as displaying major differences in functional propertiescompared with its Arabidopsis counterpart (Véry and Sentenac,2003). This absence of specific functional features has reinforcedthe role of model that Arabidopsis plays in this field.

Here, we characterize a maize (Zea mays) inward Shaker, ZmK2.1,and show that it is strictly devoted to K⁺ uptake in the concentrationrange corresponding to Epstein mechanism II, in contrast withits Arabidopsis relatives. This inward channel is endowed witha regulation not observed previously in related Shakers fromother plant species. Indeed, ZmK2.1 is strongly regulated bythe external concentration of K⁺: a decrease in external K⁺decreases the channel activity, leading, in the absence of K⁺,to a complete nonconducting state. We show that this regulation,which is independent of channel gating by membrane hyperpolarization,occurs within the physiological external K⁺ range, restrictingthe role of this maize channel to low-affinity K⁺ uptake. Thiswork suggests that significant functional differences existbetween related Shaker channels from different plant species,monocots and dicots, which may underlie differences in plantdevelopment and physiology.

RESULTS

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ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Identification of the Maize ZmK2.1 Shaker Channel Gene
Low-stringency screening of a maize cDNA library using a probederived from the Arabidopsis K⁺ channel KAT1 (for K⁺ ArabidopsisTransporter 1) led to the identification of a partial cDNA incompleteat the 3' end. A full-length cDNA (GenBank accession numberAY461584; length of the 5' untranslated region, open readingframe, and 3' untranslated region: 100, 2175, and 124 bp, respectively)was obtained by 3' rapid amplification of cDNA ends. PCR experimentsperformed on maize genomic DNA allowed us to check the cDNAsequence and to determine the structure of the correspondinggene (GenBank accession number AY461583). Sequence analysisand functional characterization of the encoded channel (seebelow) led us to name this gene ZmK2.1 (for Zea mays K⁺ group2 Shaker, according to the nomenclature proposed by Pilot etal. [2003]; see below). DNA gel blot analyses (data not shown)using the radiolabeled full-length cDNA as a probe suggestedthat ZmK2.1 is present as a single copy in the maize genome.

Sequence analyses indicated that ZmK2.1 is a member of the plantShaker family (Mäser et al., 2001; Véry and Sentenac,2003). The deduced polypeptide (725 amino acids, 83 kD) displaysthe typical Shaker channel hydrophobic core (Figure 1A). TheShaker core consists of six probable transmembrane segmentsnamed S1 to S6. S4 carries positive residues, a typical featureallowing this segment to act as a voltage sensor. A pore domain,named P (including the pore helix and the selectivity filter),is present between S5 and S6. The P domain of ZmK2.1 harborsa GYG motif (Figure 1B), a hallmark of highly K⁺-selective channels.The cytosolic C-terminal region of ZmK2.1 comprises a putativecyclic nucleotide binding domain and a K_HA domain (rich in hydrophobicand acidic residues), which are found in all plant Shakers (Véryand Sentenac, 2003). ZmK2.1, like most of its closest relativesin the Shaker family (group 2 channels), does not harbor anyankyrin domain.

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Figure 1. Identification of ZmK2.1, a Maize Inward K⁺ Channel of the Shaker Family.

(A) Topology of the ZmK2.1 polypeptide. The hydrophobic core of Shaker channels typically displays six transmembrane segments, S1 to S6. S4, the channel voltage sensor, carries positively charged residues (+). The pore-forming domain (P) is present between S5 and S6. A putative cyclic nucleotide binding domain (cNBD) and a domain rich in hydrophobic and acidic residues (K_HA) are present in the cytoplasmic C-terminal region.

(B) Comparison of the ZmK2.1 amino acid sequence with that of group 2 Shakers from other plant species (KAT1 and KAT2 from Arabidopsis, KST1 from potato, and VvSIRK from grapevine). Top, Alignment of the pore domains. Middle and bottom, Alignment of the S1-S2, S3-S4, S5-P, and P-S6 extracellular linkers.

(C) Structure of ZmK2.1. Top, The positions of the 10 introns identified in the ZmK2.1 gene, indicated by black arrowheads, strictly correspond to those of the 10 introns identified in the Arabidopsis KAT2 Shaker channel gene. The open arrowheads below indicate the positions of the eight introns in the Arabidopsis KAT1 Shaker gene. Bottom, Conservation of intron positions within the coding sequence between ZmK2.1 and KAT2. For each intron, the interrupted codon, if any (the arrowheads indicate the positions of the interrupting introns), or the codon just upstream of the intron is given. The corresponding amino acid (single-letter code) and the position of this residue in the predicted sequence are indicated in parentheses.

(D) Yeast complementation tests. The yeast Wagf2 strain deficient for K⁺ uptake was transformed with either the empty pFL61 plasmid (control), ZmK2.1 cDNA in pFL61, or the Arabidopsis KAT1 cDNA in pFL61. Drop tests were performed on selective agar media containing 0.1, 0.2, 2, or 20 mM K⁺ (added as KCl). The plates were photographed after 3 d of incubation at 28°C.

Based on sequence and gene structure analyses, the plant Shakerfamily (nine members in Arabidopsis) has been divided into fivegroups named groups 1 to 5 (Arabidopsis group leaders: ArabidopsisK⁺ Transport System 1 [AKT1], KAT1, AKT2, K⁺ channel 1, andStelar K⁺ Outward Rectifier, respectively) (Pilot et al., 2003

).Phylogenetic analysis indicates that ZmK2.1 belongs to group2. Three Shakers have been characterized in maize: Z. mays K⁺channel 1 (ZMK1), ZMK2, and K⁺ channel Z. mays 1 (KZM1) (Philipparet al., 1999

, 2003

). In addition, a cDNA sequence of a fourthmaize Shaker has been deposited in GenBank (accession numberAJ558238) and named KZM2. ZmK2.1 polypeptide shares approximately40% identity with ZMK1 and ZMK2, which belong to groups 1 and3, respectively, and 51% identity with the (as yet uncharacterized)KZM2 sequence, which belongs to group 2. The percentage of identityis much higher with KZM1 (94%), which also belongs to group2. Although sequence alignment indicates that ZmK2.1 is shorterthan KZM1 by 32 amino acids at its N-terminal end, the highpercentage of identity between the two deduced polypeptides(isolated from different cultivars) and common features in theexpression patterns (see below) suggest that ZmK2.1 and KZM1are different alleles of the same gene. ZmK2.1 shares approximately50% identity over the entire polypeptide sequence with the othergroup 2 channels characterized to date: KAT1 (Anderson et al.,1992

) and KAT2 (Pilot et al., 2001

) from Arabidopsis, K⁺ channelof Solanum tuberosum 1 (KST1) from potato (Müller-Röberet al., 1995

), and Stomatal Inward Rectifying K⁺ channel fromVitis vinifera (VvSIRK; grapevine) (Pratelli et al., 2002

).Within the transmembrane region, the percentage of identitybetween ZmK2.1 and the latter channels is 70 to 80%. The poredomain and the voltage sensor are especially conserved. ZmK2.1has exactly the same P domain as KAT2 and differs from KAT1in this region by only one residue (Figure 1B). The percentageof identity in the voltage sensor reaches 89 to 93%. The mostdivergent regions within the hydrophobic core are the two extracellularlinkers S1-S2 and S3-S4 (less than 25 and 40% identity, respectively;Figure 1B).

Analysis of the intron positions showed that the gene structureis strongly conserved between ZmK2.1 and the Arabidopsis KAT1and KAT2 genes. Eight introns can be identified in KAT1 and10 in KAT2, each of the 8 KAT1 introns having a counterpart,strictly at the same location, in KAT2 (Pilot et al., 2003).Interestingly, 10 introns can be identified in ZmK2.1, exactlyat the same positions, at the nucleotide level in the sequencealignment, as in KAT2 (Figure 1C). Thus, based on gene structureanalysis, ZmK2.1 is closer to KAT2 than to KAT1, and ZmK2.1and KAT2 are closer to each other than are the two Arabidopsisgenes KAT1 and KAT2.

All plant Shaker channels from group 2 characterized to dateare inward rectifiers. As a first step toward functional characterization,ZmK2.1 was expressed in a Saccharomyces cerevisiae (yeast) mutantstrain defective for K⁺ uptake and displaying reduced growthon media containing less than $~$ 50 mM K⁺. Control experimentswere performed using the Arabidopsis KAT1 channel, known toallow yeast growth rescue in the presence of submillimolar K⁺concentrations (Anderson et al., 1992). Expression of ZmK2.1,like that of KAT1, was able to rescue yeast growth (Figure 1D),indicating that ZmK2.1, like other group 2 Shakers, can mediatewholesale K⁺ uptake. However, growth rescue in cells expressingZmK2.1 occurred at a much higher external K⁺ concentration (inthe 2 to 20 mM concentration range) than in cells expressingKAT1.

Localization of ZmK2.1 Expression in the Plant
RNA gel blot experiments revealed the presence of ZmK2.1 transcriptsin shoots (leaves and stem) but not in roots (Figure 2A). Furtheranalysis of ZmK2.1 expression was performed by RT-PCR (Figure 2B),again showing higher transcript levels in leaves than inroots. In leaves, ZmK2.1 transcripts were more abundant in vascular/bundlesheath strands (central vein) than in epidermis (Figure 2B).

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Figure 2. Expression of ZmK2.1 in the Plant.

(A) RNA gel blot analysis. The blot (10 µg of total RNA per lane) was hybridized with ³²P-labeled ZmK2.1 probe.

(B) RT-PCR analysis. r, root; l, leaf without central vascular/bundle sheath strand; e, epidermis; v, central vascular/bundle sheath strand; gen, genomic DNA. Histone H1 was used as a control.

(C) Comparison of ZmK2.1 and KZM2 expression by RT-PCR analysis. l, leaf; r, e, and gen, same as in (B). Actin was used as a control. The actual amplification of KZM2 (GenBank accession number AJ558238) cDNA was checked by sequencing the PCR products.

The expression pattern of KZM2, the as yet uncharacterized likelyparalog of ZmK2.1, was analyzed in parallel experiments, revealingsimilar features. As observed for ZmK2.1, the transcript levelwas much higher in leaves than in roots (Figure 2C). In theformer organs, it was abundant in vascular/bundle sheath strands(data not shown) and in epidermis (Figure 2C). Comparison ofthe relative intensities of signals revealed that ZmK2.1 transcriptswere less abundant than KZM2 transcripts in the epidermis extracts(Figure 2C). Quantification of the transcript levels (ImageGauge 4.0; Fuji Photo Film, Tokyo, Japan) using actin or histoneH1 as a control led to epidermis-to-whole leaf transcript ratiosof 0.3 ± 0.05 (n = 5) for ZmK2.1 and 1.6 ± 0.16(n = 4) for KZM2.

Functional Characterization of ZmK2.1 in Xenopus Oocytes and COS Cells
Expressed in Xenopus laevis oocytes, ZmK2.1 mediated inwardlyrectifying currents when the membrane was clamped at potentialsmore negative than –50 mV (Figure 3A). The magnitude ofthe current was dependent on the external K⁺ concentration (Figure 3B).The relationship between current intensity and K⁺ concentrationsuggested a saturation mechanism with an apparent K_m of approximately40 mM (Figure 3B). ZmK2.1 gating was voltage-dependent. Thevoltage dependence of the relative open probability was independentof the external K⁺ concentration in the 10 to 100 mM range (Figure 3C),as already reported for the other plant inwardly rectifyingShakers (Pratelli et al., 2002; Véry and Sentenac, 2002).Analysis of zero-current potentials in bath solutions containingboth K⁺ and Na⁺ indicated, as expected from the presence ofthe GYG motif in the pore sequence, that ZmK2.1 is selectivefor K⁺ over Na⁺ (Figure 3D). ZmK2.1 currents were blocked byBa²⁺ in a voltage-dependent manner (Figure 3E). Tetraethylammonium(6 mM) or Cs⁺ (0.4 mM) inhibited 50% of ZmK2.1 currents recordedin 50 mM K⁺, independent of voltage (n = 3; data not shown).ZmK2.1 was weakly sensitive to external pH: a 10-mV positiveshift in voltage dependence of activation was observed uponacidification from pH 7.4 to 5.4 (Figure 3F).

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Figure 3. Conduction and Gating Properties of ZmK2.1 Expressed in Xenopus Oocytes ([A] to [F]) or COS Cells ([G] to [I]).

(A) Inwardly rectifying currents recorded in an oocyte expressing ZmK2.1. Voltages applied from a holding potential of –40 mV ranged from –140 to +10 mV with an increment of 10 mV. K⁺ concentration in the bath was 100 mM (pH 7.4).

(B) Current-voltage relationships at steady state in different bath K⁺ concentrations (10, 50, or 100 mM, pH 7.4). Inset, Mean currents recorded at –140 mV plotted versus the bath K⁺ concentration were fitted with a Michaelis-Menten equation (solid line), leading to an apparent K_m of 43 mM.

(C) Analysis of ZmK2.1 activation at different external K⁺ concentrations (10, 50, or 100 mM [90, 50, and 0 mM NaCl, respectively], pH 7.4). The solid line is a Boltzmann (bz) fit of the relative open probability (Po/Pomax) versus membrane potential (Véry et al., 1995). z and Ea50, equivalent gating charge and half-activation potential, respectively, obtained from the Boltzmann fit.

(D) Analysis of ZmK2.1 selectivity. Zero-current potentials (E_rev) were determined in bath solutions differing in K⁺ and Na⁺ concentrations (10, 50, or 100 mM K⁺, along with 90, 50, or 0 mM Na⁺, respectively, pH 7.4).

(E) ZmK2.1 blockage by Ba²⁺ at steady state. BaCl₂ was present in the bath at 0, 1, or 5 mM. K⁺ concentration was 50 mM (pH 7.4).

(F) Effect of external pH on ZmK2.1 activation. K⁺ concentration in the bath was 50 mM. Lines are Boltzmann fits.

Data in (B), (D), (E), and (F) are means ± SD (n = 3).

(G) Single-channel current traces recorded in COS cells in the outside-out patch-clamp configuration. External and internal K⁺ concentrations were 50 and 150 mM, respectively. Applied voltages from a holding potential of 0 mV are indicated at right of the traces. Carets mark the current levels corresponding to closed ZmK2.1 channels.

(H) Comparison of ZmK2.1 voltage dependence determined either at the single-channel (sc) or whole cell (wc) level in COS cells. Analyzed single-channel (outside-out patch configuration) and whole cell data were from the same cell. Ionic conditions were as described for (G). The relative open probability data at the single-channel level are means from six successive recordings ± SE.

(I) Single-channel conductance (recording conditions as described for [G]).

ZmK2.1 was also expressed in mammalian COS cells. Its functionalproperties in this expression system were basically very similarto those depicted in Xenopus oocytes. Slight differences inactivation parameters were observed, however, as frequentlyreported when the functional properties of a given channel arecompared in different expression systems (Dreyer et al., 1999

;Decher et al., 2003

). In COS cells, ZmK2.1 activation occurredat more negative membrane potentials than in oocytes (mean half-activationpotential ± SD [n = 11]: –105 ± 7 mV inoocytes versus –141 ± 19 mV in COS cells). Also,the slope of the voltage dependence of activation was slightlyreduced in COS cells (mean apparent gating charge ± SD[n = 11]: 1.3 ± 0.1 in oocytes versus 1.1 ± 0.15in COS cells). Single-channel features of ZmK2.1 were investigatedin COS cells in the outside-out patch configuration (Figures 3G to 3I).ZmK2.1 was identified at the single-channel levelon the basis of a voltage dependence similar to that obtainedat the whole cell level (Figures 3G and 3H) and a selectivityfor K⁺. The channel conductance was 14 pS in the presence of50 mM external K⁺ (Figure 3I). In subsequent experiments, theCOS cell expression system was preferred to the Xenopus oocytesystem because it generally produced fewer endogenous currentsat very hyperpolarized membrane potentials (see Figure 5A, whichshows absence of endogenous current down to at least –200mV).

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Figure 5. Effect of External K⁺ Concentration on ZmK2.1 and KAT1 Activity.

(A) and (B) Current traces recorded in COS cells expressing either ZmK2.1 (A) or KAT1 (B) in the presence of different external K⁺ concentrations: 50, 10, or 1 mM. The internal K⁺ concentration was 150 mM. The voltage-clamp protocol consisted of a channel activation step, with applied voltages ranging from –40 to –200 mV, followed by a deactivation step at 0 mV. At left, full traces are shown. The solutions containing 10 or 1 mM K⁺ were supplemented with 40 or 49 mM NaCl, respectively, for ionic and osmotic strength adjustment. Middle and right, Zoom on deactivation currents recorded at 0 mV after the activation step. In the middle panels (+ Na⁺), the ionic strength of the bath solutions containing 10 or 1 mM K⁺ was adjusted with NaCl (as at left). In the right panels (– Na⁺), no NaCl was added to the bath solutions, the decrease in KCl concentration being compensated for at the osmotic level with mannitol.

(C) to (H) Analysis of ZmK2.1 ([C] to [E]) and KAT1 ([F] to [H]) deactivation currents in the presence of 50, 10, or 1 mM external K⁺. Na⁺, N-methyl-D-glucamine, or mannitol was added to compensate for the changes in external K⁺ concentrations. No difference being observed between the three conditions, the data were pooled. Values shown are means ± SE, with n = 6 in (C) to (E) and n = 5 in (F) to (H).

(C) and (F) Deactivation (tail) currents, recorded at 0 mV at 6 ms after the start of the step, plotted against the activation voltage. Deactivation currents were normalized for each cell by the current recorded in 50 mM K⁺ at –180 mV to suppress current variability caused by differences in cell size and level of expression. Solid lines are Boltzmann (bz) fits.

(D) and (G) Effect of external K⁺ on the G_Kout in ZmK2.1 (D) or KAT1 (G). Initial (outward) deactivation currents were assumed to follow the modified Ohm's law (Blatt, 1992; Hille, 1992): I = G_K (E – E_K), where G_K is the macroscopic K⁺ conductance, E is the membrane potential (here 0 mV), and E_K is the K⁺ equilibrium potential. The G_K values were calculated from deactivation currents recorded after activation at –120, –140, –160, or –180 mV. For each cell, the resulting G_K values were normalized by the value determined in 50 mM external K⁺ at –180 mV to suppress variability attributable to differences in cell size and level of expression. For ZmK2.1, normalized G_K values plotted versus the external K⁺ concentration were fitted with a Michaelis-Menten equation for each of the four activation potentials. Resulting apparent K_m values are shown at the bottom of (D) (means ± SE, n = 5). Solid lines at the top of (D) are mean Michaelis-Menten adjustments (using the mean K_m values indicated at bottom).

(E) and (H) Effect of external K⁺ on the kinetics of current deactivation in ZmK2.1 (E) and KAT1 (H). Deactivation time constants ("Taudeact"; means ± SE, n = 6) were obtained from monoexponential fits of deactivation currents recorded at membrane potentials ranging from –90 to 0 mV. Fits of the voltage dependence of deactivation time constants with a monoexponential function (exp fit; solid lines) were used to determine zc, the equivalent charge involved in channel-closing transitions near the open state (Liman et al., 1991).

ZmK2.1 Requires K⁺ or Rb⁺ in the External Medium to Be in a Conducting State
The effect of external K⁺ substitution by another monovalentcation (Rb⁺, Li⁺, Na⁺, or NH₄⁺) on ZmK2.1 currents was examinedin COS cells (Figures 4A and 4B) and in oocytes (shown for K⁺/Na⁺substitution: Figures 4C and 4D). Similar results were obtainedin both expression systems. ZmK2.1 steady state inward currentswere strongly reduced when 50 mM Rb⁺ replaced 50 mM K⁺. Forinstance, at –160 mV in COS cells, the ratio of currentin the presence of Rb⁺ to that in the presence of K⁺ was 0.08± 0.02 (Figure 4A). No significant inward current wasdetected in the presence of 50 mM Li⁺, Na⁺, or NH₄⁺ (Figures 4A and 4C).Large outward deactivation currents were recordedwhen the membrane potential was switched from activating hyperpolarizedvalues to 0 mV in the presence of 50 mM external K⁺ or Rb⁺ (Figure 4B),as expected, because the reversal potential of currentthrough ZmK2.1 was –25 mV in the presence of K⁺ (K⁺ equilibriumpotential [E_K]) or more negative than –25 mV in the presenceof Rb⁺ (this ion being less permeant than K⁺) (Figure 4A). Interestingly,using the same protocol, no deactivation current was recordedin the presence of Li⁺, Na⁺, or NH₄⁺. The disappearance of inwardand outward ZmK2.1 current upon replacement of K⁺ (or Rb⁺) byLi⁺, Na⁺, or NH₄⁺ was a reversible phenomenon: currents similarin magnitude to those recorded before the substitution wereobserved when K⁺ was reintroduced in the bath (replacing Na⁺,Li⁺, or NH₄⁺). Absence of deactivation current in the presenceof Li⁺, Na⁺, or NH₄⁺ was striking in that the predicted reversalpotential of current through ZmK2.1 should be more negativein the presence of Li⁺, Na⁺, or NH₄⁺ than in the presence ofK⁺ or Rb⁺ (the former ions being less permeant than the latterones) (Figure 4A), and thus K⁺ efflux would be expected to begreater in the presence of the former ions. Together, the absenceof inward steady state current and of outward deactivation currentwhen K⁺ was replaced by Li⁺, Na⁺, or NH₄⁺ in the external mediumcould indicate either that the three latter cations blockedthe channel or that ZmK2.1 was no longer in a conducting statein the absence of K⁺ or Rb⁺ in the external medium—thatis, that no ionic flux could occur, whether inward (Li⁺, Na⁺,or NH₄⁺ inward currents) or outward (outward K⁺ current). Theuse of bath solutions in which a decrease in K⁺ concentrationwas compensated for by Na⁺, N-methyl-D-glucamine, or mannitolallowed us to exclude the former hypothesis (see Figure 5).Thus, ZmK2.1 seemed to require K⁺ or Rb⁺ ions at its externalface to be in a conducting state, or "active." The term "activity"is used (here and throughout the text) at the macroscopic level.Therefore, a loss of activity includes the possibility of aninhibition of the outward unitary conductance or of a reductionin the number of open channels, which could result from a decreasein either the open probability or the number of channels availablefor conduction (see Figure 5E). Whatever the origin of the lossof activity in the absence of K⁺ or Rb⁺, this behavior is insharp contrast with that of the Arabidopsis closest homologsof ZmK2.1, KAT1 (Figures 4C and 4D) (Véry et al., 1995

)and KAT2 (Lacombe, 2000

), the activity of which is not preventedby the absence of external K⁺. Indeed, KAT1 and KAT2 remainactive when only poorly permeant ions such as Na⁺ are presentin the bath (or in the presence of submillimolar K⁺ concentrations),resulting in outward steady state K⁺ currents at membrane potentialsranging from the channel activation threshold to the currentreversal potential (e.g., from –80 to –160 mV forKAT1 in oocytes in 100 mM NaCl [Figure 4C]) (Véry etal., 1995

). On the contrary, such steady state outward currentswere not observed in ZmK2.1 in the presence of Na⁺, Li⁺, orNH₄⁺ (Figures 4A and 4C).

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Figure 4. Effect of the Nature of the External Monovalent Cation on ZmK2.1 Conductance and Activity.

(A) and (B) Currents mediated by ZmK2.1 in COS cells were recorded in bath solutions successively containing KCl, RbCl, LiCl, NaCl, and NH₄Cl at a concentration of 50 mM.

(A) Current-voltage relationships at steady state. Currents were normalized for each cell by current level in the presence of K⁺ at –160 mV. Values shown are means ± SE (n = 5).

(B) Examples of deactivation currents recorded at 0 mV after activation steps at voltages ranging from –40 to –160 mV. The recordings shown were obtained from the same cell.

(C) and (D) Comparison of currents in oocytes expressing either ZmK2.1 or KAT1 in bath solutions containing 100 mM KCl or 100 mM NaCl.

(C) Current-voltage relationships at steady state.

(D) Deactivation currents recorded at –40 mV after activation steps at voltages ranging from +10 to –160 mV in a bath containing NaCl. The steady state and deactivation currents shown for each channel are from the same oocyte.

Analysis of ZmK2.1 Activation by External K⁺ Reveals a Voltage-Independent K_m in the 10 mM K⁺ Concentration Range
The dependence of ZmK2.1 activity on external K⁺ was analyzedin COS cells using different external K⁺ concentrations: 50,10, and 1 mM (Figure 5A). Parallel experiments were performedon the Arabidopsis KAT1 channel (Figure 5B). As in the experimentdescribed in Figure 4, both inward currents recorded duringactivation steps at hyperpolarized membrane potentials and deactivationcurrents recorded at 0 mV immediately after activation wereanalyzed. The deactivation current at 0 mV could be predictedto be outward in all three ionic conditions, because the E_Kwas –25, –65, and –123 mV when external K⁺was 50, 10, and 1 mM, respectively. Furthermore, the magnitudeof the outward current could be predicted to increase upon reductionin external K⁺ concentration (in the absence of channel sensitivityto external K⁺) as a result of the increase in driving forcefor K⁺ efflux. KAT1 deactivation current followed these predictions:the current was 2.5 times greater in 10 mM external K⁺ and 4.5to 5 times greater in 1 mM K⁺ than in 50 mM K⁺ (Figures 5B and 5F).Results obtained for ZmK2.1 were quite different. The deactivationcurrent was only slightly greater in 10 mM K⁺ than in 50 mMK⁺ ( $~$ 1.4 times) and strongly reduced in 1 mM K⁺ ( $~$ 3.5 times lessthan in 50 mM K⁺) (Figures 5A and 5C). In conjunction with thevery small deactivation current, no steady state inward currentwas detected in 1 mM K⁺ (Figure 5A). Loss of current was immediateupon external K⁺ reduction to 1 mM and was fully reversiblewhen external K⁺ concentration was increased again (data notshown). In these experiments, the decreases in external K⁺ concentrationwere compensated for at the ionic and osmotic strength levelsby NaCl or N-methyl-D-glucamine or only at the osmotic levelby mannitol (Figure 5). Very similar results were obtained inthe three conditions, excluding the hypothesis that the lossof ZmK2.1 current upon external K⁺ reduction was attributableto channel block by the compensating cations. Thus, the wholeset of results indicated that ZmK2.1 activity is dependent onexternal K⁺ concentration.

To quantify the sensitivity of ZmK2.1 activity to external K⁺,the outward macroscopic K⁺ conductance (G_Kout) was extractedfrom deactivation currents using the simple modified Ohm's lawequation [G_K = I/(E – E_K)] (see legend to Figures 5D and 5G).The channels having been activated at a given potential,the G_Kout measured at a membrane potential sufficiently depolarizedfrom E_K should be independent of the external K⁺ concentration,unless external K⁺ regulates the number of open channels orthe outward unitary conductance. In Figures 5D (for ZmK2.1)and 5G (for KAT1), the G_Kout values obtained at 0 mV after activationof the channel at –120, –140, –160, or –180mV are plotted versus the external concentration of K⁺ (1, 10,or 50 mM). In both ZmK2.1 and KAT1, in agreement with the voltagegating (activation by hyperpolarization) of these channels,G_Kout was sensitive to the activation voltage: the more negativethe voltage the greater the number of open channels and hencethe larger the macroscopic conductance, whatever the externalconcentration of K⁺. Despite this common feature, the two channelsclearly differed in sensitivity of G_Kout toward external K⁺.The G_Kout values derived for KAT1 at a given activation voltageappeared weakly dependent on the external K⁺ concentration (Figure 5G),suggesting that neither the number of open channels northe outward unitary conductance (at 0 mV) was noticeably sensitiveto external K⁺ concentration in this channel (at least in the1 to 50 mM range). By contrast, the G_Kout of ZmK2.1 increasedrapidly when the external K⁺ concentration was increased togreater than 1 mM (Figure 5D). Michaelis-Menten hyperbolic functionswere used to fit the data. The resulting apparent K_m value wasclose to 15 mM, whatever the voltage activation of the channel(Figure 5D, bottom). Such a K_m value means that the remainingconductance, expressed in percentage of the maximal value thatwould be observed at saturating K⁺ concentrations, is 7% in1 mM K⁺ and 43% in 10 mM K⁺. In other words, these results indicatethat the external concentration of K⁺ does exert a strong controlon ZmK2.1 activity.

The kinetics of ZmK2.1 current deactivation in the presenceof different external K⁺ concentrations were analyzed to testthe hypothesis that the control of ZmK2.1 activity by externalK⁺ involved an effect of the cation on the channel open probability.A corollary to this hypothesis is that K⁺ affects transitionrate constants near the open state, a phenomenon likely to showup in K⁺ sensitivity of the macroscopic current activation anddeactivation kinetics (Blatt, 1990; Zagotta et al., 1994). Activationkinetics were not analyzed because ZmK2.1 inward currents werebelow the detection level in low ( $≤$ 1 mM) external K⁺ conditions.Deactivation current kinetics were analyzed in both ZmK2.1 (Figure 5E)and KAT1 (Figure 5H) for comparison. Deactivation currentsrecorded in ZmK2.1 and KAT1 at membrane potentials in the –90-to 0-mV range could be well fitted with monoexponential functions,the time constant decreasing exponentially with depolarization(Figures 5E and 5H), as classically observed in voltage-gatedinwardly rectifying channels (Blatt, 1992; Fairley-Grenot andAssmann, 1993; Véry et al., 1995). For both channels,the time constants were independent of external K⁺ in the 1to 50 mM range (Figures 5E and 5H), indicating that the effectof external K⁺ on ZmK2.1 macroscopic activity was probably notthe result of an effect on ZmK2.1 open probability.

Sensitivity to External K⁺ of ZmK2.1 Activity Is Not Attributable to Block by External Ca²⁺
Inwardly rectifying K⁺ channels displaying some permeabilityto Ca²⁺ and blocked by this cation have been reported in maize(Fairley-Grenot and Assmann, 1992a, 1992b). Furthermore, externalCa²⁺ is a common blocker of plant inwardly rectifying K⁺ channels(Zimmermann et al., 1999). Therefore, we examined whether ablock of ZmK2.1 channels by external Ca²⁺, which is likely tobe more pronounced in the presence of low K⁺ concentrations,could explain the observed sensitivity to external K⁺ of ZmK2.1activity.

A first set of experiments revealed that Ca²⁺, in the presenceof 10 mM K⁺, is very weakly permeant through ZmK2.1 (P_Ca/P_K< 0.05). Increasing the external concentration of Ca²⁺ from0.1 to 10 mM in the presence of 10 mM K⁺ did not significantlyshift the zero current potential from the E_K (Figure 6A).

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Figure 6. Effect of External Ca²⁺ on ZmK2.1 Currents in COS Cells.

(A) ZmK2.1 permeability to Ca²⁺. Example of deactivation currents recorded, after an activation step at –140 mV, at membrane potentials ranging from –92 to –42 mV in bath solutions containing 10 mM K⁺ and successively 0.1, 1, and 10 mM Ca²⁺ [Ca²⁺ added as Ca(OH)₂/Mes, pH 6.0]. E_K was –64 mV when the cell was bathed with the solution containing 0.1 or 1 mM Ca²⁺ and was –65.5 mV in the solution containing 10 mM Ca²⁺. Mean zero-current potentials (±SE, n = 4) recorded in the latter solutions were –63 ± 0.5 mV, –63 ± 1 mV, and –65 ± 1 mV, respectively.

(B) Sensitivity of ZmK2.1 steady state inward current to external Ca²⁺. ZmK2.1 whole cell currents were recorded in bath solutions containing 10 mM KCl and successively 0.1, 1, and 10 mM Ca²⁺ (same solutions as in [A]). I/I_Ca1, magnitude of the steady state currents recorded at –140 mV in 0.1, 1, and 10 mM Ca²⁺ standardized by the magnitude of the corresponding current in 1 mM Ca²⁺ (means ± SE; n = 5).

(C) to (F) Effects of external Ca²⁺ on ZmK2.1 sensitivity to external K⁺. Typical examples from four experiments are shown.

(C) Example of whole cell currents recorded successively in different external K⁺ concentrations (50, 10, and 1 mM) in the presence of either 1 or 0.1 mM external Ca²⁺ (Ca 1 and Ca 0.1, respectively). In solutions in which K⁺ concentration was 10 or 1 mM or Ca²⁺ was 0.1 mM, NaCl was added for ionic and osmotic strength adjustment. The voltage-clamp protocol was the same as described for Figure 5A.

(D) Magnification of deactivation currents recorded at 0 mV.

(E) Effect of external Ca²⁺ on ZmK2.1 I/V relationships at steady state. The bath solution contained 50, 10, or 1 mM K⁺ and either 1 or 0.1 mM Ca²⁺.

(F) Effect of external Ca²⁺ on the outward macroscopic conductance at 0 mV (see legend to Figure 5).

Solid lines indicate Michaelis-Menten adjustments using the mean K_m value (15 mM) determined for ZmK2.1 in COS cells (see Figure 5D).

A second set of experiments was aimed at testing whether activeZmK2.1 channels were sensitive to Ca²⁺. In the presence of 10mM K⁺, an increase in Ca²⁺ concentration from 0.1 to 1 mM (i.e.,an increase in the Ca²⁺/K⁺ concentration ratio from 0.01 to0.1) had very little effect (3% ± 1% decrease) on ZmK2.1steady state inward current at –140 mV (Figure 6B). Afurther increase in Ca²⁺ concentration, from 1 to 10 mM (Ca²⁺/K⁺concentration ratio increase from 0.1 to 1), induced a currentdecrease of 22% ± 5% at –140 mV (Figure 6B). Thus,ZmK2.1 channels were moderately sensitive to external Ca²⁺.This finding suggested that the absence of inward current atlow external K⁺ (1 mM) in the presence of 1 mM Ca²⁺ (Figure 5A)did not merely result from Ca²⁺-induced block.

This hypothesis was further assessed by comparing ZmK2.1 activityin the presence of 1 mM K⁺ and either 1 or 0.1 mM Ca²⁺, thelatter condition (Ca²⁺/K⁺ concentration ratio of 0.1) beingexpected to result in little if any Ca²⁺ block (from the datashown in Figure 6B). Reduction of external Ca²⁺ led neitherto the reappearance of ZmK2.1 inward currents in 1 mM externalK⁺ (Figures 6C and 6E) nor to a significant increase in outwarddeactivation currents (Figure 6D). Thus, the absence of inwardcurrent recorded in these conditions mostly resulted from aCa²⁺-independent process. Furthermore, the absence of an effectof Ca²⁺ on outward deactivation currents suggested that externalCa²⁺ did not block outward currents; therefore, the regulationby external K⁺ of ZmK2.1 activity (indicated by analysis ofoutward deactivation currents) was completely independent ofexternal Ca²⁺ (Figure 6F).

Activity of Inwardly Rectifying Channels in Maize Guard Cells Is Regulated by External K⁺
The strong sensitivity to external K⁺ displayed by ZmK2.1 appearedas a unique feature among the plant inwardly rectifying Shakers(groups 1 and 2) (Pilot et al., 2003) cloned and characterizedto date. Furthermore, no indication of in planta activity ofa channel endowed with such regulation could be identified inpublished electrophysiological analyses. To search for an inplanta K⁺ channel activity similar to that of ZmK2.1, the effectof external K⁺ on inwardly rectifying channel activity was investigatedin maize guard cell protoplasts (Figures 7A to 7C). Guard cellsappeared as a good candidate for the expression of ZmK2.1 orZmK2.1-like channels, because all group 2 Shakers characterizedin other plant species are expressed in this cell type (Véryand Sentenac, 2003).

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Figure 7. Effect of External K⁺ Concentration on Maize and Arabidopsis Guard Cell Inwardly Rectifying Channel Activity.

(A) and (D) Typical current traces recorded in maize (A) and Arabidopsis (D) guard cell protoplasts in bath solutions successively containing 50, 10, and 1 mM K⁺ (decrease in K⁺ concentration adjusted at the osmotic level with mannitol). The internal K⁺ concentration was 125 mM. The voltage-clamp protocol was identical to that described for Figure 5.

(B), (C), (E), and (F) Analysis of deactivation currents in maize ([B] and [C]) and Arabidopsis ([E] and [F]). Data presented in (B) and (C) (and [E] and [F], respectively) were obtained from the recordings shown in (A) (and [D], respectively).

(B) and (E) Deactivation (tail) currents measured 10 ms after the start of the deactivation pulse, plotted versus the activation potential. Solid lines are Boltzmann (bz) fits.

(C) and (F) Outward macroscopic conductance (G_Kout = I_tail/(E – E_K)) at 0 mV plotted versus external K⁺ concentration (see legend to Figure 5). Conductance values were calculated for the three activation potentials –200, –180, and –160 mV. In (C), the data were fitted (solid lines) based on the assumption that the conductance results from the activity of two kinds of voltage-gated channels: ZmK2.1-like channels displaying regulation by external K⁺ with the same K_m as that determined for ZmK2.1 in COS cells (15 mM; see Figure 5D and text), and channels not regulated by external K⁺, providing a constant contribution to the conductance over the entire K⁺ concentration range.

(G) to (I) Effect of external Ca²⁺ on inwardly rectifying channel activity in maize guard cells.

(G) Comparison of protoplast inward current in bath solutions containing either 1 or 0.1 mM Ca²⁺. The bath K⁺ concentration was successively 50, 10, and 1 mM. The voltage-clamp protocol was as described for (A).

(H) Effect of external Ca²⁺ on I/V relationships at steady state.

(I) Effect of external Ca²⁺ on the outward macroscopic conductance at 0 mV (same analysis as described for [C]).

Experiments similar to those performed in COS cells (Figure 5)were performed on maize guard cell protoplasts (Figure 7A).Analysis of deactivation currents (Figures 7B and 7C) revealedthat the activity of maize guard cell inwardly rectifying channelswas, like that of ZmK2.1, regulated by external K⁺ concentration.Analysis of the derived values of G_Kout (Figure 7C), however,indicated that the loss of channel activity upon reduction ofexternal K⁺ was less pronounced in guard cells than in COS cellsexpressing ZmK2.1: the decrease in G_Kout attributable to reductionof external K⁺ from 50 to 1 mM was 48% in maize guard cellsversus 72% in ZmK2.1-expressing COS cells (percentage computedfrom the experimental data shown in Figures 7C and 5D, respectively).One possible explanation for the lower sensitivity to externalK⁺ of inwardly rectifying channel activity in guard cells isthat ZmK2.1 or ZmK2.1-like channels are coexpressed in thiscell type with other inward K⁺ channels that are not sensitiveto external K⁺. The presence of at least two types of inwardlyrectifying K⁺ channels in maize guard cells was suggested bythe observation that the level of remaining current in 1 mMexternal K⁺ compared with the current level in 50 mM externalK⁺ was quite variable within a 10-fold range (from 1.5 to 15.5%[n = 10]; mean, 7%; corresponding value for the recordings shownin Figure 7A, 9.5%). Within the framework of the hypothesisdescribed above, two components were assumed to contribute toG_Kout in maize guard cells: one component (offset) was strictlyinsensitive to the external concentration of K⁺, and a secondcomponent was sensitive to this concentration and followed aMichaelis-Menten hyperbolic function with the same K_m value(15 mM) as that derived for ZmK2.1 in COS cells (Figure 5D).This assumption provided satisfactory fits to the G_Kout values(Figure 7C). Thus, channels with sensitivity to external K⁺are active in maize guard cells. Their relative contributionto the guard cell inward K⁺ conductance is important at highK⁺ concentrations, reaching 70% at saturating concentrationsin the example shown in Figure 7A. In Arabidopsis, on the otherhand, the guard cell inwardly rectifying K⁺ channel activitywas found, in parallel experiments, to be poorly sensitive toexternal K⁺ (Figures 7D to 7F), in agreement with the fact thatthe channels thought to be the two major contributors to theguard cell inward K⁺ conductance, KAT1 and KAT2 (Pilot et al.,2001

; Szyroki et al., 2001

), are not sensitive to external K⁺.

As in many other plant species, the guard cell inwardly rectifyingK⁺ conductance of maize is sensitive to external Ca²⁺ (Fairley-Grenotand Assmann, 1992a, 1992b). Calcium block of the inward K⁺ currentwas observed in our experiments. In the presence of 50 mM K⁺,a clear voltage-dependent block of the inward K⁺ current resultingin a decrease in current intensity of 11% ± 5% at –200mV (n = 5; data not shown) appeared when the concentration ofthe bivalent was increased to 10 mM (Ca²⁺/K⁺ concentration ratioof 0.2). In presence of 1 mM K⁺, the inward K⁺ current appearedless sensitive to Ca²⁺, the voltage-dependent block being 7%± 2% at –200 mV (21% ± 2% at –220mV [n = 4]) in presence of 1 mM Ca²⁺ (Ca²⁺/K⁺ concentrationratio of 1). This difference in external Ca²⁺ sensitivity providesfurther support for the hypothesis of two types of inwardlyrectifying K⁺ channels in maize guard cells, one with strongcontribution to the K⁺ conductance at low external K⁺ and theother at high external K⁺, as discussed above.

In this context, we examined whether the sensitivity to externalK⁺ of the inwardly rectifying K⁺ channel activity in guard cells(Figure 7C) was, like that of ZmK2.1 in COS cells, independentof external Ca²⁺ (Figures 7G to 7I). Consistent with the resultsdescribed above, decreasing the external concentration of Ca²⁺from 1 to 0.1 mM had little effect on the inward K⁺ currentwhen external K⁺ was 10 or 50 mM, and it suppressed the (slight)voltage-dependent block when external K⁺ was 1 mM (Figures 7G and 7H).Deactivation currents recorded in these two externalCa²⁺ conditions were very similar, which indicated that externalCa²⁺ did not block outward deactivation K⁺ currents. Thus, activityregulation by external K⁺ of inward K⁺ channels in maize guardcells indicated by the analysis of deactivation currents was,like that of ZmK2.1 in COS cells, an external Ca²⁺-independentprocess (Figure 7I).

In conclusion, K⁺ channels endowed with regulation by externalK⁺ similar to that of ZmK2.1 (hyperbolic relationships betweenchannel activity and external K⁺ concentration with a K_m valueclose to 15 mM, regulation mechanism independent of externalCa²⁺) can be detected in planta. In maize guard cells, suchchannels constitute a major component of the inwardly rectifyingK⁺ channel population.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Comparison of ZmK2.1 with Other Plant Shaker Genes of the Group 2 Subfamily
ZmK2.1 belongs to group 2 of the plant Shaker-like K⁺ channelfamily. At least one other group 2 channel, named KZM2 (GenBankaccession number CAD90161), as yet uncharacterized, exists inmaize. KZM1 (Philippar et al., 2003) is likely to be encodedby an allele of ZmK2.1, because the two sequences display highidentity (94%) and common features in their expression patterns(see below). It should be noted, however, that the two channelsdiffer in their sensitivity to external pH, because KZM1 isnot activated by acidification (Philippar et al., 2003).

Only a few genes from Shaker group 2 have been characterizedto date: KAT1 and KAT2 from Arabidopsis, VvSIRK from grapevine,and ZmK2.1. The gene structure of group 2 plant Shakers hasweakly evolved since the separation between dicots and monocots(Figure 1C). ZmK2.1 displays the same structure as KAT2 andVvSIRK, with the same number of introns (10) and the same intronpositions. KAT1 has the same structure except that it has losttwo introns (Pilot et al., 2003).

All group 2 Shakers characterized to date are expressed in aerialparts of the plant. Detailed expression patterns have been obtainedfor a few genes, KAT1, KAT2, VvSIRK, and the potato KST1, usingthe ß-glucuronidase reporter gene and/or in situ hybridizationmethods. KAT1 is essentially expressed in guard cells (Nakamuraet al., 1995). KAT2 is expressed in guard cells and in minorvein phloem tissues (Pilot et al., 2001). Expression of VvSIRKseems to be restricted to guard cells, and that of KST1 to guardcells and tissues at the flower base (Müller-Röberet al., 1995; Plesch et al., 2001). Thus, the four group 2 ShakerK⁺ channel genes for which detailed expression pattern informationis available are all expressed in guard cells, where they arebelieved to play major roles in K⁺ uptake during stomatal opening(Assmann and Wang, 2001; Véry and Sentenac, 2003). Likethese group 2 Shakers, ZmK2.1 and KZM2 are expressed mainlyin the aerial parts of the plant (Figure 2). The transcriptlevels of both ZmK2.1 and KZM2 were high in vascular/bundlesheath strands (Figure 2B for ZmK2.1, as reported previouslyfor KZM1 [Philippar et al., 2003]), suggesting both that theexpression patterns of ZmK2.1 and KZM2 might be similar to thoseof the Arabidopsis KAT2 gene and that expression in phloem vasculaturemight correspond to an ancient trait of this channel type. Expressionof ZmK2.1 in guard cells cannot be ascertained based on ourexpression data, but ZmK2.1-type channels displaying regulationof activity by external K⁺ are major components of the guardcell inwardly rectifying channel population (see below).

ZmK2.1 Displays Unique Functional Properties among Plant Inward Shakers
Comparison of functional properties between ZmK2.1 and othermembers of Shaker group 2 reveals both similarities and differences.Like all group 2 Shakers characterized to date, ZmK2.1 is aK⁺-selective, voltage-gated, inwardly rectifying channel (Figure 3).The sequence of its pore domain is exactly the same as thatof KAT2 (Figure 1B). However, the single-channel conductanceof ZmK2.1 is more than twice that of KAT2 (Figures 3G and 3I)(Pilot et al., 2001). Another difference is the sensitivityto Ba²⁺, which is strongly voltage dependent in ZmK2.1 (Figure 3E)but weakly voltage dependent in KAT2 (Pilot et al., 2001),suggesting that Ba²⁺ enters deeper into the pore in ZmK2.1 thanin KAT2. This further highlights the fact that the P domainis not alone in determining conduction properties such as unitaryconductance or voltage-dependent block (Aiyar et al., 1994;Lopez et al., 1994; Liu and Joho, 1998; Zei et al., 1999; Pilotet al., 2001).

The most striking property of ZmK2.1 is certainly the strongsensitivity of its activity to the concentration of K⁺ in theexternal medium (Figure 5). For instance, the channel displaysonly 7% residual activity in 1 mM K⁺ (with respect to activityat saturating K⁺). Total absence of K⁺ from the external solution(a nonphysiological situation) was shown to result in the lossof outward deactivating currents in the maize KZM1 channel (Philipparet al., 2003), suggesting that this channel is endowed, likeZmK2.1, with sensitivity to external K⁺, consistent with thehypothesis that the two proteins are encoded by different allelesof the same gene. To date, sensitivity of channel activity toexternal K⁺ has not been reported for any other cloned inwardlyrectifying (group 1 or 2) plant Shaker.

Initially, low-affinity uptake (Epstein mechanism II) was proposedto involve channels, whereas high-affinity uptake, from concentrationsbelow a few tens to a few hundred micromolar (Epstein mechanismI), was believed to involve cotransporters (Kochian and Lucas,1988; Maathuis and Sanders, 1996). It is now known that Arabidopsisinward rectifiers from Shaker groups 1 and 2 can play a rolein cell K⁺ uptake in a wide range of external K⁺ concentrations,from tens of millimolar to a few micromolar, provided that themembrane potential is more negative than E_K (Anderson et al.,1992; Sentenac et al., 1992; Hirsch et al., 1998; Brüggemannet al., 1999; Mouline et al., 2002). On the other hand, suchinward rectifiers can also mediate outward K⁺ fluxes, as shownin Figure 4C for KAT1, when they are faced with submillimolarK⁺ concentrations and opened by a membrane potential more negativethan their activation potential but less negative than E_K (e.g.,more negative than –80 mV and less negative than approximatively–170 mV for KAT1 in Figure 4C). In these conditions, suchchannels can behave as leak-like channels at membrane potentialsaround E_K, a behavior that might allow the channel to play arole in the control of cell membrane polarization close to E_K.Facing the same conditions, ZmK2.1 does not mediate K⁺ efflux(Figure 4C) because of its sensitivity to external K⁺. In agreementwith the electrophysiological analysis, yeast complementationtests showing no growth rescue by ZmK2.1 in the presence ofsubmillimolar external K⁺ concentrations (Figure 1D) providefurther support for the conclusion that ZmK2.1 activity is restrictedto K⁺ concentrations in the high (millimolar) range. Thus, bysensitizing the activity of an inward Shaker to both the membranepotential and the external concentration of K⁺, the plant hasproduced a channel strictly devoted to K⁺ uptake from high concentrations,whatever the level of membrane hyperpolarization. This functionalproperty is unique among the plant transport systems characterizedto date.

As discussed above, ZmK2.1 is expressed in leaf tissues. The(local) concentration of K⁺ in the leaf apoplast is determinedby the relative rates of import via the xylem, export via thephloem, and transport across plasma membrane into/from the symplast.Because the relative volume of the apoplast is small, largeconcentration changes can result from small changes in net membranefluxes. Using selective microelectrodes to probe local K⁺ concentrationin the leaf apoplast, it has been shown that steep concentrationgradients can settle (Bowling, 1987). Three orders of magnitudeseparate the lowest values of local K⁺ activity recorded inthe apoplast (in the 10 to 100 µM range) from the highestvalues (10 to 100 mM) (Blatt, 1985; Bowling, 1987; Bowling andSmith, 1990; Grignon and Sentenac, 1991). Using the infiltration–centrifugationmethod, which averages local differences, variations within1 order of magnitude, from 1 to 10 mM, were detected in responseto both plant K⁺ nutrition status and light/dark period (Mühlingand Läuchli, 1999). In other words, because the apoplasticconcentration of K⁺ in the leaf can vary in a wide range, regulationof ZmK2.1-type channels by external K⁺ with an apparent K_m closeto 15 mM can be predicted to have physiological meaning.

Regulation of ZmK2.1 Activity by External K⁺ Involves a Low-Affinity Binding Site Outside the P Domain
As the modulation of ZmK2.1 activity by external cations displaysstrong selectivity (for K⁺ and Rb⁺ and against Na⁺, Li⁺, andNH₄⁺) and saturation at high external K⁺ concentration (Figures 4and 5), we propose that a K⁺ binding site, the occupancy ofwhich depends on external K⁺ concentration, is involved in thiscontrol. Two different sets of results strongly suggest thatthe effect of external K⁺ on ZmK2.1 activity is independentof the level of voltage activation of the channel. First, thesame value of the K_m parameter could be used to describe theincrease in channel activity with external K⁺ regardless ofthe voltage of the activation prepulse (Figure 5D). Second,no effect of external K⁺ was observed on the voltage dependenceof the relative open probability of the channel (Figure 3C).Thus, the control of ZmK2.1 activity by external K⁺ is not likelyto be linked to voltage gating.

The Arabidopsis weak inward rectifier AKT2 (Lacombe et al.,2000), which belongs to plant Shaker group 3 (Pilot et al.,2003), has been shown to be inhibited by total withdrawal ofK⁺ from the external solution (Geiger et al., 2002). A pointmutation in the P domain of this channel, replacing a Ser witha Glu four residues downstream from the GYGD motif, suppressedthe channel sensitivity to the absence of external K⁺. It isworth noting that, after this substitution, the correspondingregion of the AKT2 P domain was identical to that of all characterizedgroup 2 Shakers, including ZmK2.1. The molecular basis of K⁺regulation of channel activity in ZmK2.1, therefore, is differentfrom that seen in AKT2. In fact, because the entire P domainof ZmK2.1 is identical to that of KAT2, which does not displayinhibition of activity by low external K⁺ (Lacombe, 2000), themolecular determinants of ZmK2.1 regulation by external K⁺ arecertainly not situated in the P domain. Similarly, these determinantsare not situated in the P-S6 linker, because this region isidentical in ZmK2.1 and other group 2 Shakers that are not inhibitedby low external K⁺ (KAT1, KST1, and VvSIRK; Figure 1B). Themost divergent regions accessible to external K⁺ between ZmK2.1and non-K⁺-regulated group 2 Shakers, in terms of global chargeand residue identity, are the S1-S2 linker and, to a lesserextent, the S3-S4 linker (Figure 1B). These linkers have beenproposed, in a few studies on animal and bacterial Shaker channels,to be located close to the channel pore, possibly overhangingthe external vestibule (Blaustein et al., 2000; Jiang et al.,2003a, 2003b). Their involvement in channel conduction propertiesis unknown at present.

External K⁺ is known to regulate some animal K⁺ channels, amongthem several outwardly rectifying channels of the Shaker family.Several K⁺ binding sites have been identified in the narrowregion forming the selectivity filter (Doyle et al., 1998; Harriset al., 1998; Vergara et al., 1999) but also in the outer andinner vestibules of K⁺ channels (Thompson and Begenisich, 2001;Consiglio et al., 2003; Kuo et al., 2003). It has been proposedthat the occupancy of some of these K⁺ binding sites (e.g.,the external "lock-in" site situated at the external side ofthe selectivity filter) is dependent on external K⁺ concentration(Kiss and Korn, 1998; Immke et al., 1999; Kiss et al., 1999;Vergara et al., 1999; Morais-Cabral et al., 2001). The absenceof K⁺ binding would result in conformational changes withinthe pore, thereby modifying some of the channel conduction properties.Two positively charged residues, the first in the outer vestibuleat a position close to the selectivity filter and the secondin the so-called turret lining more external regions of theouter vestibule, have been shown in some animal Shakers to makethe whole cell outward current highly sensitive to externalK⁺ (Pardo et al., 1992; Jäger et al., 1998; Jägerand Grissmer, 2001), probably by controlling the occupancy ofthe external K⁺ lock-in site, a positive charge favoring expulsionof K⁺ from the binding site, and the resulting conformationalchanges affecting channel activity. However, the two amino acidsinvolved in this phenomenon have no counterpart in the sequenceof ZmK2.1. Furthermore, no other closely located positivelycharged residue (in the P domain, the S5-P linker or P-S6 linker)present in ZmK2.1 but not in other plant Shakers not regulatedby external K⁺ have been found. Therefore, the molecular basisof activity control by external K⁺ in ZmK2.1 is certainly differentfrom that seen in animal Shaker channels.

A Larger Diversity of K⁺ Channel Types in Maize Than in Arabidopsis
Sensitivity to external K⁺ is not a feature shared by everyinwardly rectifying channel in maize. Indeed, the major inwardconductance active in root cortical cells does not display anyinhibition of activity upon reduction in external K⁺ concentration(Roberts and Tester, 1995). On the other hand, channels suchas ZmK2.1, with activity regulated by external K⁺, can dominatethe membrane conductance of some maize cells at high externalK⁺ concentrations, as shown by patch-clamp recordings in guardcells (Figure 7).

Investigation with the patch-clamp technique of the diversityof K⁺ channels in maize guard cells indicates that channelsregulated by K⁺, such as ZmK2.1, are active at the plasma membrane,together with channels that are not regulated by K⁺. The ZmK2.1-typechannels are major components of the guard cell inward K⁺ channelpopulation, although their relative contribution to membraneconductance is variable. They strongly contribute to whole cellinward K⁺ conductance at "high" external K⁺ (>10 mM), whereaschannels that are not regulated by K⁺ have a preponderant roleat low external K⁺ concentrations, compensating for the lackof ZmK2.1-type activity in these conditions. Furthermore, thefact that the guard cell inwardly rectifying conductance athigh K⁺ concentrations is permeable to Ca²⁺ (Fairley-Grenotand Assmann, 1992a, 1992b) but ZmK2.1 is not permeable to thiscation (Figure 6A) suggests that at least part of the inwardK⁺ channels active at high external K⁺ in maize guard cellsare different from ZmK2.1. Thus, it is clear that the situationis more complex in maize than in the model plant Arabidopsis,in which a single type of inward K⁺ channels, not regulatedby external K⁺, is active (Figures 6D to 6F) and mediates K⁺influx in the whole range of physiological situations, frommicromolar to millimolar concentrations (Brüggemann etal., 1999).

At the molecular level, ZmK2.1 might contribute to the expressionof guard cell inward conductance regulated by external K⁺, becauseRT-PCR analyses reveal that transcripts of this gene are presentin leaf epidermal peels. However, a more significant contributionof KZM2 can be predicted. Indeed, owing to the sequence similarityin the transmembrane region and external linkers between ZmK2.1and KZM2, it is likely that KZM2 is endowed, like ZmK2.1, withregulation by external K⁺. Furthermore, based on the RT-PCRdata, KZM2 should be more strongly expressed in guard cellsthan ZmK2.1 (Figure 2C). Components of the guard cell inwardconductance not regulated by external K⁺ might be encoded byShaker genes from group 1, such as ZMK1 (Philippar et al., 1999),which has been reported to be highly expressed in leaf epidermis(Büchsenschütz et al., 2004).

In conclusion, the regulation of K⁺ transport seems to requirea higher functional diversity of K⁺ channels in maize than inArabidopsis, with regard to sensitivity to the apoplastic concentrationof K⁺. Functional characterization of the set of inward Shakersin rice should reveal whether this type of diversity existsin other species and allow us to further analyze its physiologicalsignificance. If present in rice, it might be a common traitof monocots, linked for example to their lower cell wall cation-exchangecapacity (Grignon and Sentenac, 1991). If absent, it might reflecta specific feature of C4 plants.

METHODS

TOP
ABSTRACT
INTRODUCTION
RESULTS
DISCUSSION
METHODS
REFERENCES

Cloning of ZmK2.1 cDNA
A partial K⁺ channel cDNA was isolated by screening of a maize(Zea mays cv AM0406; Maïsadour, Mont-de-Marsan, France)cDNA library constructed using the ZAP-cDNA Gigapack II Goldcloning kit (Stratagene, La Jolla, CA) with a probe generatedfrom transmembrane regions (S4 to S6) of the Arabidopsis thalianaKAT1 K⁺ channel cDNA. ZmK2.1 full-length cDNA was obtained by3' rapid amplification of cDNA ends.

In Planta Expression Studies
Maize seedlings were grown hydroponically on air-bubbled solution(pH 5.5) containing 1 mM KH₂PO₄, 1 mM Ca(NO₃)₂, 1 mM MgCl₂,and micronutrients. Total RNAs were isolated from 15-d-old tissues.RNA gel blot analysis was performed according to Church andGilbert (1984) using radiolabeled ZmK2.1 full-length cDNA asa probe. 25S rRNA staining on gel was used as a control forRNA loading. For RT-PCR experiments, 10 µg of total RNAwas used for first-strand synthesis by Moloney murine leukemiavirus RT (final volume, 25 µL; Promega, Madison, WI),and 0.5 µL of RT products was used for PCR. Specific primerssurrounding introns (sequences available upon request) wereused for ZmK2.1 and KZM2 (GenBank accession number AJ558238)amplification. Expression of histone H1 or actin was monitoredas a control (Savino et al., 1997; Philippar et al., 2003).

Expression in Yeast
ZmK2.1 and KAT1 cDNAs were cloned into the yeast expressionvector pFL61 (Bonneaud et al., 1991) and transferred into theK⁺ uptake–defective yeast strain Wagf2 (MATa; trk1 ${Delta}$ ::LEU2;trk2 ${Delta}$ ::TRP; ade2-101; his3-11, 15; leu2-3, 112; trp1-1; ura3-1;can^r) (Ros et al., 1999). Complementation tests were performedon minimal medium supplemented with 20 mg/L adenine and differentconcentrations of KCl, with 15 µL of cell suspension (A₆₀₀= 0.3) being spotted on agar plates (drop tests).

Expression in Xenopus Oocytes and COS Cells
ZmK2.1 and KAT1 cDNA open reading frames were amplified (PCR)and cloned into pCI vector (Promega). The pCI-ZmK2.1 constructwas used for expression in both Xenopus laevis oocytes and COScells. The pCI-KAT1 construct was used for expression in COScells, whereas in vitro transcribed KAT1 copy RNA (pBSTA vector)(Véry et al., 1994) was used for oocyte studies. Oocyteswere injected with 30 ng of pCI-ZmK2.1 or KAT1 copy RNA (1 µg/µLin water). Control oocytes were injected with 30 nL of water.Two-electrode voltage-clamp measurements on oocytes and analysisof the data were performed as described previously (Véryet al., 1995). Recording solutions contained 1.8 mM CaCl₂, 1mM MgCl₂, 5 mM Hepes/NaOH, pH 7.4, or 5 mM Mes/NaOH, pH 6.4or 5.4, and KCl as indicated. K⁺ was added as a Cl^– salt,and the ionic strength (constant in all solutions) was adjustedwith NaCl. Expression and patch-clamp experiments in COS cellswere performed as described by Mouline et al. (2002). All patch-clampsolutions were adjusted to 300 mosmol with mannitol. The pipettesolution (cell internal medium) contained 150 mM KCl, 2 mM MgCl₂,5 mM MgATP, 5 mM EGTA, and 10 mM Hepes/Tris, pH 7.2. All bathsolutions contained a background of 2 mM MgCl₂, 1 mM CaCl₂ (unlessotherwise stated), and 10 mM Mes/Tris, pH 6.0. K⁺ was addedas a Cl^– salt.

Patch Clamp on Guard Cell Protoplasts
Maize seedlings were grown hydroponically for 2 to 3 weeks asdescribed above. Guard cell protoplasts were isolated from leafepidermal peels using the enzymatic digestion protocol describedby Fairley-Grenot and Assmann (1992a). Growth of Arabidopsisplants (Wassilewskija ecotype) and isolation of Arabidopsisguard cell protoplasts were performed as described by Hosy etal. (2003). Patch-clamp recordings on guard cell protoplastswere performed as described for COS cells (see above). Patch-clampbath solutions contained 1 or 0.1 mM CaCl₂, 4 or 4.9 mM MgCl₂,respectively, 10 mM Mes/Tris, pH 5.8, and K⁺ glutamate as indicated.In experiments comparing maize and Arabidopsis, the pipettesolution contained 100 mM K⁺ glutamate, 5 mM EGTA, 1 mM CaCl₂(45 nM free Ca²⁺), 0.5 mM MgCl₂, 2 mM MgATP, 20 mM Hepes, and25 mM KOH, pH 7.25. In experiments addressing the effect ofexternal Ca²⁺, free Ca²⁺ in the pipette solution was less than5 nM (no CaCl₂ added), MgCl₂ concentration was increased to1 mM, and pH was decreased to 7.0 (KOH = 15 mM). The osmolarityof bath and pipette solutions was adjusted with mannitol to500 and 530 mosmol, respectively.

Sequence data from this article have been deposited with theEMBL/GenBank data libraries under accession numbers AY461583and AY461584.

Acknowledgments

We thank Jossia Boucherez for technical assistance, StéphaneLobréaux for the gift of the maize histone H1 cDNA, andIsabel Lefèvre and Sabine Zimmermann for critical readingof the manuscript. This work was supported in part by fellowshipsfrom the Institut National de la Recherche Agronomique and theAssociation Franco-Chinoise pour la Recherche Scientifique etTechnique to Y.-H.S. and by the European Community BIOTECH Program(BIO4-CT96).

Footnotes

¹ Current address: Department of Biology, University of Pennsylvania,415 South University Avenue, Philadelphia, PA 19104.

² Current address: Laboratoire de Biologie des Semences, INRA,Route de Saint Cyr, 78026 Versailles Cedex, France.

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.plantcell.org)is: Anne-Aliénor Véry (very{at}ensam.inra.fr).

Article, publication date, and citation information can be foundat www.plantcell.org/cgi/doi/10.1105/tpc.104.030551.

Received December 23, 2004; accepted February 18, 2005.

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