Suppression of inward-rectifying K+ channels KAT1 and AKT2 by dominant negative point mutations in the KAT1 alpha-subunit

The Arabidopsis thaliana cDNA, KAT1 encodes a hyperpolarization-activated K+ (K+in) channel. In the present study, we identify and characterize dominant negative point mutations that suppress K+in channel function. Effects of two mutations located in the H5 region of KAT1, at positions 256 (T256R) and 262 (G262K), were studied. The co-expression of either T256R or G262K mutants with KAT1 produced an inhibition of K+ currents upon membrane hyperpolarization. The magnitude of this inhibition was dependent upon the molar ratio of cRNA for wild-type to mutant channel subunits injected. Inhibition of KAT1 currents by the co-expression of T256R or G262K did not greatly affect the ion selectivity of residual currents for Rb+, Na+, Li+, or Cs+. When T256R or G262K were co-expressed with a different K+ channel, AKT2, an inhibition of the channel currents was also observed. Voltage-dependent Cs+ block experiments with co-expressed wild type, KAT1 and AKT2, channels further indicated that KAT1 and AKT2 formed heteromultimers. These data show that AKT2 and KAT1 are able to co-assemble and suggest that suppression of channel function can be pursued in vivo by the expression of the dominant negative K+in channel mutants described here.

Role of farnesyltransferase in ABA regulation of guard cell anion channels and plant water loss

Desiccation of plants during drought can be detrimental to agricultural production. The phytohormone abscisic acid (ABA) reduces water loss by triggering stomatal pore closure in leaves, a process requiring ion-channel modulation by cytoplasmic proteins. Deletion of the Arabidopsis farnesyltransferase gene ERA1 or application of farnesyltransferase inhibitors resulted in ABA hypersensitivity of guard cell anion-channel activation and of stomatal closing. ERA1 was expressed in guard cells. Double-mutant analyses of era1 with the ABA-insensitive mutants abi1 and abi2 showed that era1 suppresses the ABA-insensitive phenotypes. Moreover, era1 plants exhibited a reduction in transpirational water loss during drought treatment.

Recent advances in the regulation of plant calcium channels: evidence for regulation by G-proteins, the cytoskeleton and second messengers

Important aspects of the regulatory properties of plant calcium channels have been discovered during the past few years. These include the control of plasma membrane-bound channels by regulatory proteins and the characterization of a plethora of intracellular calcium release channels. Deciphering the mechanisms of regulation of different Ca2+ channels and the probable co-operation of their activities in response to various stimuli is leading to a better understanding of Ca2+-signalling processes in higher plants.

The plant cDNA LCT1 mediates the uptake of calcium and cadmium in yeast

Nonessential metal ions such as cadmium are most likely transported across plant membranes via transporters for essential cations. To identify possible pathways for Cd2+ transport we tested putative plant cation transporters for Cd2+ uptake activity by expressing cDNAs in Saccharomyces cerevisiae and found that expression of one clone, LCT1, renders the growth of yeast more sensitive to cadmium. Ion flux assays showed that Cd2+ sensitivity is correlated with an increase in Cd2+ uptake. LCT1-dependent Cd2+ uptake is saturable, lies in the high-affinity range (apparent KM for Cd2+ = 33 microM) and is sensitive to block by La3+ and Ca2+. Growth assays demonstrated a sensitivity of LCT1-expressing yeast cells to extracellular millimolar Ca2+ concentrations. LCT1-dependent increase in Ca2+ uptake correlated with the observed phenotype. Furthermore, LCT1 complements a yeast disruption mutant in the MID1 gene, a non-LCT1-homologous yeast gene encoding a membrane Ca2+ influx system required for recovery from the mating response. We conclude that LCT1 mediates the uptake of Ca2+ and Cd2+ in yeast and may therefore represent a first plant cDNA encoding a plant Ca2+ uptake or an organellar Ca2+ transport pathway in plants and may contribute to transport of the toxic metal Cd2+ across plant membranes.

Determination of transmembrane topology of an inward-rectifying potassium channel from Arabidopsis thaliana based on functional expression in Escherichia coli

We report here that the inward-rectifying potassium channels KAT1 and AKT2 were functionally expressed in K+ uptake-deficient Escherichia coli. Immunological assays showed that KAT1 was translocated into the cell membrane of E. coli. Functional assays suggested that KAT1 was inserted topologically correctly into the cell membrane. In control experiments, the inactive point mutation in KAT1, T256R, did not complement for K+ uptake in E. coli. The inward-rectifying K+ channels of plants share a common hydrophobic domain comprising at least six membrane-spanning segments (S1-S6). The finding that a K+ channel can be expressed in bacteria was further exploited to determine the KAT1 membrane topology by a gene fusion approach using the bacterial reporter enzymes, alkaline phosphatase, which is active only in the periplasm, and beta-galactosidase. The enzyme activity from the alkaline phosphatase and beta-galactosidase fusion plasmid showed that the widely predicted S1, S2, S5, and S6 segments were inserted into the membrane. Although the S3 segment in the alkaline phosphatase fusion protein could not function as an export signal, the replacement of a negatively charged residue inside S3 with a neutral amino acid resulted in an increase in alkaline phosphatase activity, which indicates that the alkaline phosphatase was translocated into the periplasm. For membrane translocation of S3, the neutralization of a negatively charged residue in S3 may be required presumably because of pairing with a positively charged residue of S4. These results revealed that KAT1 has the common six transmembrane-spanning membrane topology that has been predicted for the Shaker superfamily of voltage-dependent K+ channels. Furthermore, the functional complementation of a bacterial K+ uptake mutant in this study is shown to be an alternative expression system for plant K+ channel proteins and a potent tool for their topological analysis.

Abscisic acid maintains S-type anion channel activity in ATP-depleted Vicia faba guard cells

The plant hormone abscisic acid (ABA) regulates important developmental and stress responses. Recent data show that ABA activates phosphorylation events, but whether dephosphorylation events are post-translationally regulated by ABA or whether these are constitutive remains unknown. Slow anion channels in the plasma membrane of guard cells have been proposed to play an important role during ABA-induced stomatal closing. Anion channels are deactivated by removal of cytosolic ATP. However, when guard cells were treated with ABA and depleted of ATP, anion currents remained active. Subsequent removal of extracellular ABA caused deactivation of currents. Deactivation of currents was reversed by reintroduction of cytosolic MgATP. These data show that anion channels are regulated by ABA even in the absence of cytosolic ATP required for kinase-induced phosphorylation events and that anion channel activity is maintained by ABA under conditions that favor dephosphorylation-induced deactivation. Furthermore, channel activation proceeded at high ATP concentrations with nanomolar cytosolic Ca2+ showing a Ca2+-independent final step in anion channel activation.

A transient outward-rectifying K+ channel current down-regulated by cytosolic Ca2+ in Arabidopsis thaliana guard cells

Sustained (noninactivating) outward-rectifying K+ channel currents have been identified in a variety of plant cell types and species. Here, in Arabidopsis thaliana guard cells, in addition to these sustained K+ currents, an inactivating outward-rectifying K+ current was characterized (plant A-type current: IAP). IAP activated rapidly with a time constant of 165 ms and inactivated slowly with a time constant of 7.2 sec at +40 mV. IAP was enhanced by increasing the duration (from 0 to 20 sec) and degree (from +20 to -100 mV) of prepulse hyperpolarization. Ionic substitution and relaxation (tail) current recordings showed that outward IAP was mainly carried by K+ ions. In contrast to the sustained outward-rectifying K+ currents, cytosolic alkaline pH was found to inhibit IAP and extracellular K+ was required for IAP activity. Furthermore, increasing cytosolic free Ca2+ in the physiological range strongly inhibited IAP activity with a half inhibitory concentration of approximately 94 nM. We present a detailed characterization of an inactivating K+ current in a higher plant cell. Regulation of IAP by diverse factors including membrane potential, cytosolic Ca2+ and pH, and extracellular K+ and Ca2+ implies that the inactivating IAP described here may have important functions during transient depolarizations found in guard cells, and in integrated signal transduction processes during stomatal movements.

AtKUP1: an Arabidopsis gene encoding high-affinity potassium transport activity

Because plants grow under many different types of soil and environmental conditions, we investigated the hypothesis that multiple pathways for K+ uptake exist in plants. We have identified a new family of potassium transporters from Arabidopsis by searching for homologous sequences among the expressed sequence tags of the GenBank database. The deduced amino acid sequences of AtKUP (for Arabidopsis thaliana K+ uptake transporter) cDNAs are highly homologous to the non-plant Kup and HAK1 potassium transporters from Escherichia coli and Schwanniomyces occidentalis, respectively. Interestingly, AtKUP1 and AtKUP2 are able to complement the potassium transport deficiency of an E. coli triple mutant. In addition, transgenic Arabidopsis suspension cells overexpressing AtKUP1 showed increased Rb+ uptake at micromolar concentrations with an apparent K(m) of approximately 22 microM, indicating that AtKUP1 encodes a high-affinity potassium uptake activity in vivo. A small, low-affinity Rb+ uptake component was also detected in AtKUP1-expressing cells. RNA gel blot analysis showed that the various members of the AtKUP family have distinct patterns of expression, with AtKUP3 transcript levels being strongly induced by K+ starvation. It is proposed that plants contain multiple potassium transporters for high-affinity uptake and that the AtKUP family may provide important components of high- and low-affinity K+ nutrition and uptake into various plant cell types.

AtKUP1: an Arabidopsis gene encoding high-affinity potassium transport activity

Because plants grow under many different types of soil and environmental conditions, we investigated the hypothesis that multiple pathways for K+ uptake exist in plants. We have identified a new family of potassium transporters from Arabidopsis by searching for homologous sequences among the expressed sequence tags of the GenBank database. The deduced amino acid sequences of AtKUP (for Arabidopsis thaliana K+ uptake transporter) cDNAs are highly homologous to the non-plant Kup and HAK1 potassium transporters from Escherichia coli and Schwanniomyces occidentalis, respectively. Interestingly, AtKUP1 and AtKUP2 are able to complement the potassium transport deficiency of an E. coli triple mutant. In addition, transgenic Arabidopsis suspension cells overexpressing AtKUP1 showed increased Rb+ uptake at micromolar concentrations with an apparent K(m) of approximately 22 microM, indicating that AtKUP1 encodes a high-affinity potassium uptake activity in vivo. A small, low-affinity Rb+ uptake component was also detected in AtKUP1-expressing cells. RNA gel blot analysis showed that the various members of the AtKUP family have distinct patterns of expression, with AtKUP3 transcript levels being strongly induced by K+ starvation. It is proposed that plants contain multiple potassium transporters for high-affinity uptake and that the AtKUP family may provide important components of high- and low-affinity K+ nutrition and uptake into various plant cell types.

Expression of a Cs(+)-resistant guard cell K+ channel confers Cs(+)-resistant, light-induced stomatal opening in transgenic arabidopsis

Inward-rectifying K+ (K+in) channels in the guard cell plasma membrane have been suggested to function as a major pathway for K+ influx into guard cells during stomatal opening. When K+in channels were blocked with external Cs+ in wild-type Arabidopsis guard cells, light-induced stomatal opening was reduced. Transgenic Arabidopsis plants were generated that expressed a mutant of the guard cell K+in channel, KAT1, which shows enhanced resistance to the Cs+ block. Stomata in these transgenic lines opened in the presence of external Cs+. Patch-clamp experiments with transgenic guard cells showed that inward K+(in) currents were blocked less by Cs+ than were K+ currents in controls. These data provide direct evidence that KAT1 functions as a plasma membrane K+ channel in vivo and that K+in channels constitute an important mechanism for light-induced stomatal opening. In addition, biophysical properties of K+in channels in guard cells indicate that components in addition to KAT1 may contribute to the formation of K+in channels in vivo.

Molecular and functional characterization of a novel low-affinity cation transporter (LCT1) in higher plants

The transport of cations across membranes in higher plants plays an essential role in many physiological processes including mineral nutrition, cell expansion, and the transduction of environmental signals. In higher plants the coordinated expression of transport mechanisms is essential for specialized cellular processes and for adaptation to variable environmental conditions. To understand the molecular basis of cation transport in plant roots, a Triticum aestivum cDNA library was used to complement a yeast mutant deficient in potassium (K+) uptake. Two genes were cloned that complemented the mutant: HKT1 and a novel cDNA described in this report encoding a cation transporter, LCT1 (low-affinity cation transporter). Analysis of the secondary structure of LCT1 suggests that the protein contains 8-10 transmembrane helices and a hydrophilic amino terminus containing sequences enriched in Pro, Ser, Thr, and Glu (PEST). The transporter activity was assayed using radioactive isotopes in yeast cells expressing the cDNA. LCT1 mediated low-affinity uptake of the cations Rb+ and Na+, and possibly allowed Ca2+ but not Zn2+ uptake. LCT1 is expressed in low abundance in wheat roots and leaves. The precise functional role of this cation transporter is not known, although the competitive inhibition of cation uptake by Ca2+ has parallels to whole plant and molecular studies that have shown the important role of Ca2+ in reducing Na+ uptake and ameliorating Na+ toxicity. The structure of this higher plant ion transport protein is unique and contains PEST sequences.

Characterization of ion channel modulator effects on ABA- and malate-induced stomatal movements: strong regulation by kinase and phosphatase inhibitors, and relative insensitivity to mastoparans

In the present study abscisic acid-induced stomatal closing, and malate effects on stomatal apertures were analysed in the presence of guard cell ion channel regulators. A recent study has suggested that abscisic acid (ABA) activation of protein kinases and/or inhibition of protein phosphatases may be central to activation of guard cell slow anion channels and mediation of stomatal closing in Vicia faba (Schmidt et al., 1995). These findings were confirmed and extended in the present study showing that both in Vicia faba and in Commelina communis ABA-induced stomatal closings were abolished by kinase inhibitors and enhanced by the protein phosphatase inhibitor okadaic acid. Further detailed studies demonstrate that very high 40 mM extracellular malate concentrations are required to close stomata only partially and that okadaic acid also enhances malate-induced stomatal closing. In addition, when stomata are widely opened, even at 40 mM malate concentrations, no malate effect on stomatal apertures was observed. This finding may be explained by a complete inactivation of guard cell anion channels when stomatal apertures are opened very widely and suggests that extracellular malate cannot function as a primary CO(2) signal in stomatal regulation. The G-protein regulators mastoparan and mas7 as well as neomycin showed no significant effects on light-induced stomatal opening and ABA-induced stomatal closing. Findings reported here correlate closely to recent findings on slow anion channel regulation in guard cells and support the hypothesis that activation of these anion channels by phosphorylation events and complete inactivation by dephosphorylation events is a rate-limiting component in guard cell signal transduction. Furthermore, the presented data support a model in which ABA-activation of protein kinases and/or inhibition of okadaic acidsensitive protein phosphatases is central to ABA regulation of stomatal movements in Vicia faba and Commelina communis.

Differential abscisic acid regulation of guard cell slow anion channels in Arabidopsis wild-type and abi1 and abi2 mutants

Abscisic acid (ABA) regulates vital physiological responses, and a number of events in the ABA signaling cascade remain to be identified. To allow quantitative analysis of genetic signaling mutants, patch-clamp experiments were developed and performed with the previously inaccessible Arabidopsis guard cells from the wild type and ABA-insensitive (abi) mutants. Slow anion channels have been proposed to play a rate-limiting role in ABA-induced stomatal closing. We now directly demonstrate that ABA strongly activates slow anion channels in wild-type guard cells. Furthermore, ABA-induced anion channel activation and stomatal closing were suppressed by protein phosphatase inhibitors. In abi1-1 and abi2-1 mutant guard cells, ABA activation of slow anion channels and ABA-induced stomatal closing were abolished. These impairments in ABA signaling were partially rescued by kinase inhibitors in abi1 but not in abi2 guard cells. These data provide cell biological evidence that the abi2 locus disrupts early ABA signaling, that abi1 and abi2 affect ABA signaling at different steps in the cascade, and that protein kinases act as negative regulators of ABA signaling in Arabidopsis. New models for ABA signaling pathways and roles for abi1, abi2, and protein kinases and phosphatases are discussed.

A novel chloride channel in Vicia faba guard cell vacuoles activated by the serine/threonine kinase, CDPK

Calcium-Dependent Protein Kinases (CDPKs) in higher plants contain a C-terminal calmodulin-like regulatory domain. Little is known regarding physiological CDPK targets. Both kinase activity and multiple Ca2+-dependent signaling pathways have been implicated in the control of stomatal guard cell movements. To determine whether CDPK or other protein kinases could have a role in guard cell signaling, purified and recombinant kinases were applied to Vicia faba guard cell vacuoles during patch-clamp experiments. CDPK activated novel vacuolar chloride (VCL) and malate conductances in guard cells. Activation was dependent on both Ca2+ and ATP. Furthermore, VCL activation occurred in the absence of Ca2+ using a Ca2+-independent, constitutively active, CDPK* mutant. Protein kinase A showed weaker activation (22% as compared with CDPK). Current reversals in whole vacuole recordings shifted with the Nernst potential for Cl-and vanished in glutamate. Single channel recordings showed a CDPK-activated 34 +/- 5 pS Cl- channel. VCL channels were activated at physiological potentials enabling Cl- uptake into vacuoles. VCL channels may provide a previously unidentified, but necessary, pathway for anion uptake into vacuoles required for stomatal opening. CDPK-activated VCL currents were also observed in red beet vacuoles suggesting that these channels may provide a more general mechanism for kinase-dependent anion uptake.

Alkali cation selectivity of the wheat root high-affinity potassium transporter HKT1

The wheat root high-affinity K+ transporter HKT1 functions as a sodium-coupled potassium co-uptake transporter. At toxic millimolar levels of sodium (Na+), HKT1 mediates low-affinity Na+ uptake while potassium (K+) uptake is blocked. In roots, low-affinity Na+ uptake and inhibition of K+ uptake contribute to Na+ toxicity. In the present study, the selectivity among alkali cations of HKT1 expressed in Xenopus oocytes and yeast was investigated under various ionic conditions at steady state. The data show that HKT1 is highly selective for uptake of the two physiologically significant alkali cations, K+ and Na+ over Rb+, Cs+ and Li+. In addition, Rb+ and Cs+, and an excess of extracellular K+ over Na+, are shown to partially reduce or block HKT1-mediated K(+)-Na+ uptake. Furthermore, K+, Rb+ and Cs+ also effectively reduce outward currents mediated by HKT1, thereby causing depolarizations. In yeast, HKT1 can produce high-affinity Rb+ uptake at approximately 15-fold lower rates than for K+. Rb+ influx in yeast can be mediated by the ability of the yeast plasma membrane proton pump to balance the >or= 35-fold lower HKT1 conductance for Rb+. A model for HKT1 activity is presented involving a high-affinity K+ binding site and a high-affinity Na+ binding site, and competitive interactions of K+, Na+ and other alkali cations for binding to these two sites. Possible implications of the presented results for physiological K+ and Na+ uptake in plants are discussed.

Two plasma membrane H(+)-ATPase genes expressed in guard cells of Vicia faba are also expressed throughout the plant

Guard cells modulate stomatal apertures in response to hormones, metabolic demands and environmental stimuli. The guard cell PM H(+)-ATPases play a critical role in this process by generating the electrochemical gradient to drive solute transport and concomitant water flux. The PM H(+)-ATPase activity is specifically regulated by red and blue light, fungal toxins and auxin. To determine if the unique responsiveness of the guard cell PM H(+)-ATPase is due to the expression of a cell-specific isoform, we amplified by PCR, and cloned portions of PM H(+)-ATPase genes VHA1 and VHA2, which are expressed in guard cell protoplasts (GCP). In situ hybridization to leaf tissue sections indicated that VHA1 and VHA2 genes were expressed in guard cells and mesophyll cells but not in epidermal cells or vascular tissues. Furthermore, a gene-specific quantitative reverse transcription (RT)-PCR detected VHA1 and VHA2 mRNAs in both GCP and mesophyll cell protoplast mRNA as well as in mRNA isolated from roots, leaves, stems and flowers. Thus, two PM H(+)-ATPase genes expressed in guard cells are also expressed in many other tissues and cell types. This suggests that the unique responsiveness of the guard cell PM H(+)-ATPases to environmental stimuli results from cell-specific signal transduction pathways rather than the expression of a cell-specific PM H(+)-ATPase.

Increased resistance to extracellular cation block by mutation of the pore domain of the Arabidopsis inward-rectifying K+ channel KAT1

Inward-rectifying potassium channels in plant cells provide important mechanisms for low-affinity K+ uptake and membrane potential control in specific cell types, including guard cells, pulvinus cells, aleurone cells and root hair cells. K+ channel blockers are potent tools for studying the physiological functions and structural properties of K+ channels. In the present study the structural and biophysical mechanisms of Cs+ and TEA+ block of a cloned Arabidopsis inward-rectifying K+ channel (KAT1) were analyzed. Effects of the channel blockers Cs+ and TEA+ were characterized both extracellularly and intracellularly. Both external Cs+ and TEA+ block KAT1 currents. A mutant of KAT1 ("m2KAT1"; H267T, E269V) was produced by site-directed mutagenesis of two amino acid residues in the C-terminal portion of the putative pore (P) domain. This mutant channel was blocked less by external Cs+ and TEA+ than the wild-type K+ channel. Internal TEA+ and Cs+ did not significantly block either m2KAT1 or KAT1 channels. Other properties, such as cation selectivity, voltage-dependence and proton activation did not show large changes between m2KAT1 and KAT1, demonstrating the specificity of the introduced mutations. These data suggest that the amino acid positions mutated in the inward-rectifying K+ channel, KAT1, are accessible to external blockers and may be located on the external side of the membrane, as has been suggested for outward-rectifying K+ channels.

Sodium-driven potassium uptake by the plant potassium transporter HKT1 and mutations conferring salt tolerance

Sodium (Na+) at high millimolar concentrations in soils is toxic to most higher plants and severely reduces agricultural production worldwide. However, the molecular mechanisms for plant Na+ uptake remain unknown. Here, the wheat root high-affinity potassium (K+) uptake transporter HKT1 was shown to function as a high-affinity K(+)-Na+ cotransporter. High-affinity K+ uptake was activated by micromolar Na+ concentrations; moreover, high-affinity Na+ uptake was activated by K+ (half-activation constant, 2.8 microM K+). However, at physiologically detrimental concentrations of Na+, K+ accumulation mediated by HKT1 was blocked and low-affinity Na+ uptake occurred (Michaelis constant, approximately 16 mM Na+), which correlated to Na+ toxicity in plants. Point mutations in the sixth putative transmembrane domain of HKT1 that increase Na+ tolerance were isolated with the use of yeast as a screening system. Na+ uptake and Na+ inhibition of K+ accumulation indicate a possible role for HKT1 in physiological Na+ toxicity in plants.

Multiple genes, tissue specificity, and expression-dependent modulationcontribute to the functional diversity of potassium channels in Arabidopsis thaliana

K+ channels play diverse roles in mediating K+ transport and in modulating the membrane potential in higher plant cells during growth and development. Some of the diversity in K+ channel functions may arise from the regulated expression of multiple genes encoding different K+ channel polypeptides. Here we report the isolation of a novel Arabidopsis thaliana cDNA (AKT2) that is highly homologous to the two previously identified K+ channel genes, KAT1 and AKT1. This cDNA mapped to the center of chromosome 4 by restriction fragment length polymorphism analysis and was highly expressed in leaves, whereas AKT1 was mainly expressed in roots. In addition, we show that diversity in K+ channel function may be attributable to differences in expression levels. Increasing KAT1 expression in Xenopus oocytes by polyadenylation of the KAT1 mRNA increased the current amplitude and led to higher levels of KAT1 protein, as assayed in western blots. The increase in KAT1 expression in oocytes produced shifts in the threshold potential for activation to more positive membrane potentials and decreased half-activation times. These results suggest that different levels of expression and tissue-specific expression of different K+ channel isoforms can contribute to the functional diversity of plant K+ channels. The identification of a highly expressed, leaf-specific K+ channel homolog in plants should allow further molecular characterization of K+ channel functions for physiological K+ transport processes in leaves.

Identification of strong modifications in cation selectivity in an Arabidopsis inward rectifying potassium channel by mutant selection in yeast

The Arabidopsis thaliana cDNA, KAT1, encodes a hyperpolarization-activated K+ channel. In the present study, we utilized a combination of random site-directed mutagenesis, genetic screening in a potassium uptake-deficient yeast strain, and electrophysiological analysis in Xenopus oocytes to identify strong modifications in cation selectivity of the inward rectifying K+ channel KAT1. Threonine at position 256 was replaced by 11 other amino acid residues. Six of these mutated KAT1 cDNAs complemented a K+ uptake-deficient yeast strain at low concentrations of potassium. Among these, two mutants (T256D and T256G) showed a sensitivity of yeast growth toward high ammonium concentrations and a dramatic increase in current amplitudes of rubidium and ammonium ions relative to K+ by 39-72-fold. These single site mutations gave rise to Rb+- and NH4(+)-selective channels with Rb+ and NH4+ currents that were approximately 10-13-fold greater in amplitude than K+ currents, whereas the NH4+ to K+ current amplitude ratio of wild type KAT1 was 0.28. This strong conversion in cation specificity without loss of general selectivity exceeds those reported for other mutations in the pore domain of voltage-dependent K+ channels. Yeast growth was greatly impaired by sodium in two other mutants at this site (T256E and T256Q), which were blocked by millimolar sodium (K1/2 = 1.1 mM for T256E), although the wild type channel was not blocked by 110 mM sodium. Interestingly, the ability of yeast to grow in the presence of toxic cations correlated to biophysical properties of KAT1 mutants, illustrating the potential for qualitative K+ channel mutant selection in yeast. These data suggest that the size of the side chain of the amino acid at position 256 in KAT1 is important for enabling cation permeation and that this site plays a crucial role in determining the cation selectivity of hyperpolarization-activated potassium channels.

Strong regulation of slow anion channels and abscisic acid signaling in guard cells by phosphorylation and dephosphorylation events

Recent evidence suggests that slow anion channels in guard cells need to be activated to trigger stomatal closing and efficiently inactivated during stomatal opening. The patch-clamp technique was employed here to determine mechanisms that produce strong regulation of slow anion channels in guard cells. MgATP in guard cells, serving as a donor for phosphorylation, leads to strong activation of slow anion channels. Slow anion-channel activity was almost completely abolished by removal of cytosolic ATP or by the kinase inhibitors K-252a and H7. Nonhydrolyzable ATP, GTP, and guanosine 5'-[gamma-thio]triphosphate did not replace the ATP requirement for anion-channel activation. In addition, down-regulation of slow anion channels by ATP removal was inhibited by the phosphatase inhibitor okadaic acid. Stomatal closures in leaves induced by the plant hormone abscisic acid (ABA) and malate were abolished by kinase inhibitors and/or enhanced by okadaic acid. These data suggest that ABA signal transduction may proceed by activation of protein kinases and inhibition of an okadaic acid-sensitive phosphatase. This modulation of ABA-induced stomatal closing correlated to the large dynamic range for up- and down-regulation of slow anion channels by opposing phosphorylation and dephosphorylation events in guard cells. The presented opposing regulation by kinase and phosphatase modulators could provide important mechanisms for signal transduction by ABA and other stimuli during stomatal movements.

Amino terminus and the first four membrane-spanning segments of the Arabidopsis K+ channel KAT1 confer inward-rectification property of plant-animal chimeric channels

The Arabidopsis hyperpolarization-activated (inward-rectifying) K+ channel KAT1 is structurally more similar to animal depolarization-activated (outward-rectifying) K+ channels than to animal hyperpolarization-activated K+ channels. To gain insight into the structural basis for the opposite voltage dependences of plant inward-rectifying and animal outward-rectifying K+ channels, we constructed recombinant chimeric channels between the hyperpolarization-activated K+ channel KAT1 and a Xenopus depolarization-activated K+ channel. We report here that two of the chimeric constructs, which contain the first third of the KAT1 sequence, including the first four membrane-spanning segments (S1-S4) and the linker sequence between the fourth and fifth membrane-spanning segments, express functional channels that retain activation by hyperpolarization, but not depolarization. These two chimeric channels are no longer selective for K+. The chimeras are selective for cations over anions and are permeable to Ca2+. Therefore, unlike animal hyperpolarization-activated K+ channels, in which the carboxyl terminus is important for inward rectification induced by Mg2+ and polyamine block, the plant KAT1 channel has its major determinants for inward rectification in the amino-terminal region, which ends at the end of the S4-S5 linker.

Anion channels as central mechanisms for signal transduction in guard cells and putative functions in roots for plant-soil interactions

In higher plants anion channels have recently been suggested to play key roles in controlling cellular functions, including turgor- and osmoregulation, stomatal movements, anion transport, signal transduction and possibly also signal propagation. In guard cells and roots, physiological functions of anion channels have been proposed which will be discussed here. In initial investigations it was proposed that anion channels in the plasma membrane of guard cells provide a prominent control mechanism for stomatal closing. The proposed model suggests that anion channel activation and the resulting anion efflux from guard cells cause membrane depolarization, thereby driving K+ efflux through outward-rectifying K+ channels required for stomatal closing. This article provides a brief review of new and recent insights into the molecular properties and cell biological functions of anion channels in guard cells. Furthermore, recently implicated putative functions of anion channels in roots during salt stress, xylem loading and Al3+ tolerance are addressed.

Magnesium-independent activation of inward-rectifying K+ channels in Vicia faba guard cells

The activation of inward-rectifying K+ channels in guard cells at membrane potentials negative of the K+ equilibrium potential is important for their cellular function as proton pump-driven K+ uptake pathways during stomatal opening. In animal cells the voltage-dependence of inward-rectifying K+ channels is produced to a large extent by intracellular magnesium block. In guard cells, when cytosolic Mg2+ was either 3 mM or < 1 microM, activation times, deactivation times and the steady-state voltage-dependence of K+ channels remained unchanged. It is discussed that the activation mechanism of inward-rectifying K+ channels in guard cells is independent of intracellular Mg2+ block.

Recruitment of plasma membrane voltage-dependent calcium-permeable channels in carrot cells

Numerous biological assays and pharmacological studies have led to the suggestion that depolarization-activated plasma membrane Ca2+ channels play prominent roles in signal perception and transduction processes during growth and development of higher plants. The recent application of patch-clamp techniques to isolated carrot protoplasts has led to direct voltage-clamp evidence for the existence of Ca2+ channels activated by physiological depolarizations in the plasma membrane of higher plant cells. However, these voltage-dependent Ca2+ channels were not stable and their activities decreased following the establishment of whole-cell recordings. We show here that large pre-depolarizing pulses positive to 0 mV induced not only the recovery of Ca2+ channel activities, but also the activation of initially quiescent voltage-dependent Ca2+ channels in the plasma membrane (recruitment). This recruitment was dependent on the intensity and duration of membrane depolarizations, i.e. the higher and longer the pre-depolarization, the greater the recruitment. Pre-depolarizing pulses to +118 mV during 30 s increased the initial calcium currents 5- to 10-fold. The recruited channels were permeable to Ba2+ and Sr2+ ions. The data suggested that voltage-dependent Ca(2+)-permeable channels are regulated by biological mechanisms which might be induced by large pre-depolarizations of the plasma membrane. In addition, this study provides evidence for the existence in the plasma membrane of higher plant cells of a large number of voltage-dependent Ca2+ channels of which a major part are inactive and quiescent. It is suggested that quiescent Ca2+ channels can be rapidly recruited for Ca(2+)-dependent signal transduction.

Structure and transport mechanism of a high-affinity potassium uptake transporter from higher plants

Potassium is the most abundant cation in higher plants and is crucial for plant nutrition, growth, tropisms, enzyme homeostasis and osmoregulation. K+ accumulation can be rate-limiting for agricultural production. K+ uptake from soils into roots is largely mediated by high-affinity K+ uptake (Km approximately 10-40 microM) (refs 1, 2, 5-7). But although K+ channels allow low-affinity K+ uptake, both the transport mechanism and structure of the high-affinity K+ nutrition pathway remain unknown. Here we use expression cloning to isolate a complementary DNA encoding a membrane protein (HKT1) from wheat roots which confers the ability to take up K+. The substrate affinity, saturation and cation selectivity of HKT1 correspond to hallmark properties of classical high-affinity K+ uptake in plants. The transport mechanism of HKT1 uses K(+)-H+ co-uptake. Expression of HKT1 is localized to specific root and leaf regions which represent primary sites for K+ uptake in plants. HKT1 is important for plant nutrition and could possibly contribute to environmental alkali metal toxicities.

Voltage-dependent calcium-permeable channels in the plasma membrane of a higher plant cell

Numerous biological assays and pharmacological studies on various higher plant tissues have led to the suggestion that voltage-dependent plasma membrane Ca2+ channels play prominent roles in initiating signal transduction processes during plant growth and development. However, to date no direct evidence has been obtained for the existence of such depolarization-activated Ca2+ channels in the plasma membrane of higher plant cells. Carrot suspension cells (Daucus carota L.) provide a well-suited system to determine whether voltage-dependent Ca2+ channels are present in the plasma membrane of higher plants and to characterize the properties of putative Ca2+ channels. It is known that both depolarization, caused by raising extracellular K+, and exposure to fungal toxins or oligogalacturonides induce Ca2+ influx into carrot cells. By direct application of patch-clamp techniques to isolated carrot protoplasts, we show here that depolarization of the plasma membrane positive to -135 mV activates Ca(2+)-permeable channels. These voltage-dependent ion channels were more permeable to Ca2+ than K+, while displaying large permeabilities to Ba2+ and Mg2+ ions. Ca(2+)-permeable channels showed slow and reversible inactivation. The single-channel conductance was 13 pS in 40 mM CaCl2. These data provide direct evidence for the existence of voltage-dependent Ca2+ channels in the plasma membrane of a higher plant cell and point to physiological mechanisms for plant Ca2+ channel regulation. The depolarization-activated Ca(2+)-permeable channels identified here could constitute a regulated pathway for Ca2+ influx in response to physiologically occurring stimulus-induced depolarizations in higher plant cells.

Functional characterization of the Escherichia coli glycerol facilitator, GlpF, in Xenopus oocytes

The glycerol facilitator of Escherichia coli, GlpF, is a putative nonselective transport channel in the inner membrane of this Gram-negative bacterium. It is a member of the major intrinsic protein (MIP) family of transmembrane channel proteins. Its characterization has been hampered by the lack of a heterologous test system in which its activity can be examined in the absence of other bacterial proteins. Transport of glycerol mediated by this protein was characterized following injection of glpF mRNA into Xenopus laevis oocytes. The properties of GlpF were compared with those of the homologous plant water channel protein, gamma tonoplast intrinsic protein (gamma TIP), as well as the nonhomologous Xenopus K+ channel, Xsha. GlpF selectively transported glycerol but not water or ions, while gamma TIP and Xsha were specific for water and K+, respectively. Voltage clamp experiments showed that GlpF was not voltage-activated for ion transport. Glycerol transport via GlpF proved to be nonsaturable up to 200 mM and exhibited a low temperature of activation (Ea = 4.5 kcal/mol), consistent with the conclusion of Heller et al. (Heller, K. B., Lin, E. C. C., and Wilson, T. H. (1980) J. Bacteriol. 144, 274-278) that GlpF mediates glycerol diffusion via a pore type mechanism. GlpF-mediated transport of glycerol was blocked by mercuric ions (Hg2+) but not N-ethylmaleimide. The inhibitory effect of Hg2+ was partially prevented by inclusion of a high concentration of glycerol and reversed by mercaptoethanol. The results serve to characterize the transport properties of the E. coli glycerol facilitator.

The vacuolar membrane protein gamma-TIP creates water specific channels in Xenopus oocytes

The vacuolar membrane (tonoplast) of higher plant cells contains an abundant 27 kDa protein called TIP (tonoplast intrinsic protein) that occurs in different isoforms and belongs to a large family of homologous channel-like proteins found in bacteria, plants and animals. In the present study, we identified and characterized the function of gamma-TIP from Arabidopsis thaliana by expression of the protein in Xenopus oocytes. gamma-TIP increased the osmotic water permeability of oocytes 6- to 8-fold, to values in the range 1-1.5 x 10(-2) cm/s. Similar results were obtained with the homologous human erythrocyte protein CHIP28, recently identified as the erythrocyte water channel. The bacterial homolog GlpF did not affect the osmotic water permeability of oocytes, but facilitated glycerol uptake, in accordance with its known function. By contrast, gamma-TIP did not promote glycerol permeability. Voltage clamp experiments provided evidence showing that gamma-TIP induced no electrogenic ion transport in oocytes, especially during osmotic challenge that resulted in massive transport of water. These results allow us to conclude that the various protein members of the MIP family have unique and specific transport functions and that the plant protein gamma-TIP likely functions as a water specific channel in the vacuolar membrane.

The herbicide sensitivity gene CHL1 of Arabidopsis encodes a nitrate-inducible nitrate transporter

This paper reports the identification and functional expression of a gene that is involved in nitrate uptake in plants, a process essential for the assimilation of nitrate and the biological removal of nitrate from the soil solution. The CHL1 gene of Arabidopsis, which when mutated confers resistance to the herbicide chlorate and a decrease in nitrate uptake, was isolated and found to encode a protein with 12 putative membrane-spanning segments. Injection of CHL1 mRNA into Xenopus oocytes produces a nitrate- and pH-dependent membrane depolarization, inward current, and nitrate uptake. These data show that the CHL1 gene encodes an electrogenic nitrate transporter. CHL1 mRNA is found predominantly in roots and displays nitrate- and pH-dependent regulation.

Solubilized proteins from carrot (Daucus carota L.) membranes bind calcium channel blockers and form calcium-permeable ion channels

Calcium channels have been suggested to play a major role in the initiation of a large number of signal transduction processes in higher plant cells. However, molecular components of higher plant Ca2+ channels remain unidentified to date. Calcium channel blockers of the phenylalkylamine family and bepridil specifically inhibit Ca2+ influx into carrot (Daucus carota L.) cells. By using a phenylalkylamine azido derivative, a 75-kDa carrot membrane protein has been previously identified. Here we have partially purified this Ca2+ channel blocker-binding protein by lectin-affinity and ion-exchange chromatographies. The protein fraction containing the 75-kDa binding protein was incorporated into giant liposomes. Single-channel patch-clamp studies on these proteoliposomes showed the presence of Ca2+-permeable channel currents. These Ca2+-permeable channels were not stable. Recordings after durations of 2-10 min showed the appearance of nonselective ion channels with a permeability to calcium and chloride ions. These nonselective Ca2+-permeable ion channels, in contrast, were stable and were recorded for extended durations. The addition of the Ca2+ channel-blocker bepridil (10 M) led to the inhibition of these nonselective Ca2+-permeable channels by reducing the probability of channel opening. These results suggest that the 75-kDa Ca2+ channel blocker-binding protein from carrot cells plays a role in channel sensitivity to Ca2+ channel inhibitors and may constitute one of the components of Ca2+ channels in higher plants.

Expression of an inward-rectifying potassium channel by the Arabidopsis KAT1 cDNA

Inward-rectifying potassium channels located in the plasma membrane of higher plant and animal cells contribute to cellular homeostasis and excitability. The genes encoding this specific class of K+ channels have not been functionally identified. This report shows that a single messenger RNA transcript from the Arabidopsis thaliana KAT1 complementary DNA confers the functional expression of a hyperpolarization-activated K+ channel in Xenopus oocytes. The channels encoded by KAT1 are highly selective for K+ over other monovalent cations, are blocked by tetraethylammonium and barium, and have a single channel conductance of 28 +/- 7 picosiemens with 118 millimolar K+ in the bathing solution. These functional characteristics, typical of inward-rectifying K+ channels in eukaryotic cells, demonstrate that KAT1 encodes an inward-rectifying K+ channel.

Expression of an outward-rectifying potassium channel from maize mRNA and complementary RNA in Xenopus oocytes

Injection of Xenopus oocytes with poly(A)+ mRNA isolated from different plants (maize, cucumber, and squash) results in the appearance of a voltage- and time-dependent, potassium-selective, outward current that is similar to the outward-rectifying potassium current recorded in many higher plant cells. Maize shoots were found to be especially enriched in mRNA encoding such activity. A cDNA library of maize shoot mRNA was constructed in the vector lambda ZAPII and was used to synthesize RNA complementary to the cDNA (cRNA). Injection of the cRNA gave rise to an outward-rectifying potassium current with properties similar to the currents obtained by poly(A)+ mRNA injection. These results demonstrate that higher plant mRNA can be properly translated into a product that produces a voltage-regulated potassium channel in the plasma membrane of Xenopus oocytes. Thus, Xenopus oocytes can be used as a heterologous expression system for the functional identification and isolation of plant ion channel genes as well as for the study of structure-function relationship of plant ion channels.

Two types of anion channel currents in guard cells with distinct voltage regulation

Transpirational water loss by plants is reduced by closing of stomatal pores in the leaf epidermis. Anion channels in the plasma membrane of guard cells may provide a key molecular mechanism for control of stomatal closing in leaves. However, central questions regarding the regulation, diversity, and function of anion channels in guard cells and other higher plant cells remain unanswered. We show here that two highly distinct types of depolarization-activated anion currents operate in the plasma membrane of Vicia faba guard cells. One described type of anion channel was activated rapidly within 50 ms by depolarization, inactivated during prolonged stimulation, and deactivated rapidly at hyperpolarized potentials (R-type anion current). The other depolarization-activated anion current showed extremely slow voltage-dependent activation and deactivation (S-type anion current) and lacked inactivation. The distinct voltage and time dependencies of R-type and S-type anion channels suggest that they may play a role during depolarization-associated signal transduction in higher plant cells and that these anion channels may contribute to different processes in the regulation of stomatal movements. In particular, the slow and sustained nature of S-type anion channel activation revealed here leads us to hypothesize that S-type anion channels may provide a central molecular mechanism for control of stomatal closing, which is accompanied by long-term anion efflux and depolarization.

Expression of Ca2+ receptors in Xenopus oocytes injected with poly(A)+ mRNA from a rat calcitonin-secreting cell line

Poly(A)+ mRNA extracted from rat calcitonin-secreting cells (rMTC 44-2) was injected into Xenopus oocytes. In mRNA-injected oocytes the intracellular Ca2+ concentration ([Ca2+]i), measured with the Ca2+ indicator dye, fura2, increased in response to an elevation of the extracellular Ca2+ ions ([Ca2+]o). In some oocytes [Ca2+]i transiently increased in high [Ca2+]o but it did not respond to the subsequent alterations of [Ca2+]o. The addition of 10 microM carbonyl cyanide m-chlorphenylhydrazone (CCCP) to the extracellular medium restored the dependence of [Ca2+]i on [Ca2+]o in such cells. It was concluded that rMTC 44-2 cells possessed a receptor which recognizes changes in [Ca2+]o and that these receptors can be functionally expressed by microinjection of messenger RNA from rMTC 44-2 cells into Xenopus oocytes.

Inward-rectifying K+ channels in guard cells provide a mechanism for low-affinity K+ uptake

The molecular mechanisms by which higher plant cells take up K+ across the plasma membrane (plasmalemma) remain unknown. Physiological transport studies in a large number of higher plant cell types, including guard cells, have suggested that at least two distinct types of K(+)-uptake mechanisms exist, permitting low-affinity and high-affinity K+ accumulation, respectively. Recent patch clamp studies have revealed the presence of inward-conducting (inward-rectifying) K+ channels in the plasma membrane of higher plant cells. Research on guard cells has suggested that these K+ channels provide a major pathway for proton pump-driven K+ uptake during stomatal opening. In the present study the contribution of inward-rectifying K+ channels to higher plant cell K+ uptake was investigated by examining kinetic properties of guard cell K+ channels in Vicia faba in response to changes in the extracellular K+ concentration. Increasing the extracellular K+ concentration in the range from 0.3 mM to 11.25 mM led to enhancement of inward K+ currents and changes in current-voltage characteristics of K+ channels. The increase in K+ conductance as a function of the extracellular K+ concentration revealed a K(+)-equilibrium dissociation constant (Km) of approximately 3.5 mM, which suggests that inward-rectifying K+ channels can function as a molecular mechanism for low-affinity K+ uptake. Lowering the extracellular K+ concentration in the range from 11 mM to 1 mM induced negative shifts in the activation potential of K+ channels, such that these channels function as a K+ sensor, permitting only K+ uptake. At low extracellular K+ concentrations of 0.3 mM K+, inward-rectifying K+ channels induce hyperpolarization. Results from the present study suggest that inward-rectifying K+ channels constitute an essential molecular mechanism for plant nutrition and growth control by providing a K(+)-sensing and voltage-dependent pathway for low-affinity K+ uptake into higher plant cells and additionally by contributing to plasma membrane potential regulation.

Repetitive increases in cytosolic Ca2+ of guard cells by abscisic acid activation of nonselective Ca2+ permeable channels

Many signal-transduction processes in higher plant cells have been suggested to be triggered by signal-induced opening of Ca2+ channels in the plasma membrane. However, direct evidence for activation of plasma-membrane Ca2+ channels by physiological signals in higher plants has not yet been obtained. In this context, several lines of evidence suggest that Ca2+ flux into the cytosol of guard cells is a major factor in the induction of stomatal closing by abscisic acid (ABA). ABA closes stomatal pores, thereby reducing transpirational loss of water by plants under drought conditions. To directly investigate initial events in ABA-induced signal transduction in guard cells, we devised an experimental approach that allows simultaneous photometric measurements of cytosolic Ca2+ and patch-clamp recordings of ion currents across the plasma membrane of single Vicia faba guard cells. Using this approach, we found that the resting cytosolic Ca2+ concentration was 0.19 +/- 0.09 microM (n = 19). In responsive guard cells, external exposure to ABA produced transient repetitive increases in the cytosolic free Ca2+ concentration. These Ca2+ transients were accompanied by concomitantly occurring increases in an inward-directed ion current. Depolarization of the membrane terminated both repetitive elevations in cytosolic Ca2+ and inward-directed ion currents, suggesting that ABA-mediated Ca2+ transients were produced by passive influx of Ca2+ from the extracellular space through Ca2(+)-permeable channels. Detailed voltage-clamp measurements revealed that ABA-activated ion currents could be reversed by depolarizations more positive than -10 mV. Interestingly, reversal potentials of ABA-induced currents show that these currents are not highly Ca2(+)-selective, thereby permitting permeation of both Ca2+ and K+. These results provide direct evidence for ABA activation of Ca2(+)-permeable ion channels in the plasma membrane of guard cells. ABA-activated ion channels allow repetitive elevations in the cytosolic Ca2+ concentration, which, in turn, can modulate cellular responses promoting stomatal closure.

Involvement of ion channels and active transport in osmoregulation and signaling of higher plant cells

The transport of inorganic and organic ions across the plasma membrane and organelle membranes of higher plants by ion channels, electrogenic pumps and co-transporters is essential to vital processes such as osmoregulation, growth, development, signal transduction and the storage of solutes. Recent studies have led to the identification of specialized transport proteins in the plasma membrane and vacuolar membrane of higher plant cells. Here we have integrated the functional aspects of these membrane proteins into a model which proposes a novel basis for ion transport processes involved in the regulation of gas exchange in leaves.

Quantitative analysis of outward rectifying K+ channel currents in guard cell protoplasts from Vicia faba

A quantitative analysis of the time and voltage dependence of outward-rectifying K+ currents (IK+, out) in guard cells from Vicia faba is described using the whole-cell patch-clamp technique. After step depolarizations from -75 mV to potentials positive to -40 mV, time-dependent outward currents were produced, which have recently been identified as K+ channel currents. This K+ current was characterized according to its time dependence and its steady-state activation. IK+, out could be described in terms of a Hodgkin-Huxley type conductance. Activation of the current in time was sigmoid and was well fitted by raising the activation variable to the second power. Deactivating tail currents were single exponentials, which suggests that only one conductance underlies this slow outward K+ current. Rates of channel closing were strongly dependent on the membrane potential, while rates of channel opening showed only limited voltage dependence leading to a highly asymmetric voltage dependence for channel closing and opening. The presented analysis provides a quantitative basis for the understanding of IK+, out channel gating and IK+, out channel functions in plant cells.

Channel-mediated K(+) flux in barley aleurone protoplasts

Gibberellic acid (GA3) stimulates K(+) efflux from the barley (Hordeum vulgare L. cv. Himalaya) aleurone. We investigated the mechanism of K(+) flux across the plasma membrane of aleurone protoplasts using patch-clamp techniques. Potassium-ion currents, measured over the entire surface of the protoplast plasma membrane, were induced when the electrochemical gradient for K(+) was inward (into the cytoplasm). The magnitude and voltage-dependence of this inward current were the same in protoplasts treated with GA3 and in control protoplasts (no GA3). Inward currents activated by negative shifts in the membrane potential (EM) from the Nernst potential for K(+) (EK) showed membrane conductance to be a function of the electrochemical gradient (i.e. EM-EK). Single-channel influx currents of K(+) were recorded in small patches of the plasma membrane. These channels had a single-channel conductance of 5-10 pS with 100 mM K(+) on the inside and 10 mM K(+) on the outside of the plasma membrane. Single-channel currents, like whole-cell currents, were the same in protoplasts treated with GA3 and control protoplasts. Voltage-gated efflux currents were found only in protoplasts tha thad been incubated without GA3. We conclude that K(+) influx in the aleurone is mediated by channels and these membrane proteins are not greatly effected by GA3.

K+ transport properties of K+ channels in the plasma membrane of Vicia faba guard cells

Electrical properties of the plasma membrane of guard cell protoplasts isolated from stomates of Vicia faba leaves were studied by application of the whole-cell configuration of the patch-clamp technique. The two types of K+ currents that have recently been identified in guard cells may allow efflux of K+ during stomatal closing, and uptake of K+ during stomatal opening (Schroeder et al., 1987). A detailed characterization of ion transport properties of the inward-rectifying (IK+,in) and the outward-rectifying (IK+,out) K+ conductance is presented here. The permeability ratios of IK+,in and IK+,out currents for K+ over monovalent alkali metal ions were determined. The resulting permeability sequences (PK+ greater than PRb+ greater than PNa+ greater than PLi+ much greater than PCs+) corresponded closely to the ion specificity of guard cell movements in V. faba. Neither K+ currents exhibited significant inactivation when K+ channels were activated for prolonged periods (greater than 10 min). The absence of inactivation may permit long durations of K+ fluxes, which occur during guard cell movements. Activation potentials of inward K+ currents were not shifted when external K+ concentrations were changed. This differs strongly from the behavior of inward-rectifying K+ channels in animal tissue. Blue light and fusicoccin induce hyperpolarization by stimulation of an electrogenic pump. From slow-whole-cell recordings it was concluded that electrogenic pumps require cytoplasmic substrates for full activation and that the magnitude of the pump current is sufficient to drive K+ uptake through IK+,in channels. First, direct evidence was gained for the hypothesis that IK+,in channels are a molecular pathway for K+ accumulation by the finding that IK+,in was blocked by Al3+ ions, which are known to inhibit stomatal opening but not closing. The results presented in this study strongly support a prominent role for IK+,in and IK+,out channels in K+ transport across the plasma membrane of guard cells.