Plasmalemma hyperpolarity and culture of sense and antisense abp transgenic tobacco protoplasts

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The auxin-binding protein Nt-ERabp1 alone activates an auxin-like transduction pathway

Hyperpolarization of tobacco protoplasts is amongst the earliest auxin responses described. It has been proposed that the auxin-binding protein, ABP1, or a related protein could be involved in the first step of auxin perception at the plasma membrane. Using for the first time homologous conditions for interaction between the protein Nt-ERabp1 or a synthetic peptide corresponding to the C-terminus and tobacco protoplasts, we have demonstrated that both can induce the hyperpolarization response. The results show that Nt-ERabp1 or the C-terminal peptide alone activates the auxin pathway from the outer face of the plasma membrane.     

An anion current at the plasma membrane of tobacco protoplasts shows ATP-dependent voltage regulation and is modulated by auxin

Plasma membrane ion channels of protoplasts from tobacco cell suspensions were characterized by patch-clamp experiments. In the whole-cell configuration, a voltage-dependent current with a current maximum around −90 mV was observed that displayed a reversal potential close to the Nernst potential for chloride. This whole-cell current was identified as an anion current by replacing the internal Cl⁻ with glutamate. The t obacco s uspension a nion c hannel (TSAC) was characterized by fast activation/deactivation and slow inactivation kinetics with voltage-dependent time constants in the range of milliseconds and seconds, respectively. Among the plant channels, TSAC exhibits original properties in terms of phosphorylation-dependent voltage regulation while sharing similarities with the fast anion channel from stomatal guard cells (GCAC1). The voltage dependence of the whole-cell current reflecting the fast deactivation of the current at potentials of less than −100 mV was observed only in the presence of internal ATP or when ATP was replaced by the protein phosphatase inhibitor okadaic acid, and was suppressed by staurosporine. This suggests that protein phosphorylation may be involved in regulating the activity of the anion channel. As observed on GCAC1 the active auxin 1-NAA caused a time- and concentration-dependent shift of the activation potential of TSAC. In addition, TSAC reacted to the auxin agonist antibody D16 providing evidence for the recognition of the auxin signal at the outer face of the plasma membrane.     

Perception of the auxin signal at the plasma membrane of tobacco mesophyll protoplasts

Auxin-induced variations of transmembrane potential difference have been shown to be a useful tool for analyzing hormone sensitivity in tobacco protoplasts. Using this technique, we demonstrated that protoplasts derived from wild-type, an auxin-resistant mutant and Agrobacterium-rhizogenes transformed plants differed widely in the sensitivity of their electrical response to naphthalene acetic acid. We have used different antibodies, raised to auxin binding proteins (ABP) from maize coleoptiles, or to the axr1 gene product (ABP1), to test whether changes in auxin sensitivity can be correlated with the presence of tobacco proteins immunologically related to this ABP. Titrations indicated that 0.4 nM anti-ABP IgG inhibited 50% of the auxin-specific response of wild-type protoplasts, whereas 0.04 nM or 4 nM anti-ABP IgG were necessary to inhibit the response of mutant and transformed protoplasts, respectively, to the same extent. On wild-type protoplasts, blocking part of the immunoreactive sites with anti-ABP antibodies resulted in a decrease in auxin sensitivity of the electrical response (0.4 nM anti-ABP IgG inducing a 10–fold decrease), whereas addition of maize ABP increased this auxin sensitivity (1 pM ABP1 raised the sensitivity more than 1000–fold). The results obtained suggest that the auxin sensitivity detected by our assay system correlates with the amount of tobacco proteins immunologically related to the axr¹ gene product from maize. A hypothesis accounting for the presence of these proteins at the external surface of tobacco protoplasts and for the effects of hetero-logous maize ABP on auxin sensitivity is proposed.     

Patch-clamp analysis establishes a role for an auxin binding protein in the auxin stimulation of plasma membrane current in Zea mays protoplasts

The electrical response of Zea mays protoplasts to different auxins and to antibodies raised against an ER-located auxin binding protein from maize (Zm-ERabp1), was investigated using the patch-clamp technique (whole-cell configuration). Following a lag-phase of 30–40 seconds, indole-3-acetic acid and 1-naphthylacetic acid induced an outwardly directed current of positive charge in a concentration-dependent manner. This current was further increased by the fungal toxin fusicoccin (FC). The current was observed only in the presence of Mg²⁺-ATP in the patch-pipette and was abolished after addition of erythrosin B, an inhibitor of H⁺-ATPase, to the protoplasts indicating that the plasma membrane H⁺-ATPase is activated by auxins and fusicoccin. Addition of antibodies directed against Zm-ERabp1 abolished the current induced by auxins, without affecting the response of protoplasts to fusicoccin. Antibodies directed against a peptide representing part of the putative auxin binding domain of Zm-ERabp1 showed auxin agonist activity, stimulating an outwardly directed membrane current in the absence of auxin. These results suggest that (i) Zm-ERabp1 or antigenically related proteins represent a site for auxin perception through which the plasma membrane H⁺-ATPase is activated, and (ii) that the activation of the H⁺-ATPase by such proteins is initiated from outside the plasma membrane.     

Tracking Auxin Receptors Using Functional Approaches

Functional approaches toward the identification of auxin receptors developed along two major lines: the isolation and characterization of mutants or transgenic plants affected in their responses to the hormone and the study of early auxin effects at the cell level such as expression of specific genes or modifications of plasma membrane properties. The combination of these approaches with those aiming at the molecular characterization of auxin binding proteins as putative auxin receptors allowed to bring further insight into the mechanisms of auxin perception by plant cells. Studies of membrane responses to auxin clearly demonstrated the existence of elementary response chains to auxin at the plasma membrane, the activation of auxin responsive proteins leading to changes in the membrane potential via the stimulation of the proton pump ATPase or the modulation of ion channels. A two-component model is proposed for the organization of functional auxin perception units at the plasma membrane, comprising an auxin-binding moiety related to the major auxin-binding protein from maize (ZmER-abp1), associated to a transmembrane protein. Current research investigates the relevance of this model and tries to assess whether early responses at the plasma membrane share common perception or transduction steps with gene expression responses and participate in more integrated biological responses to auxin.     

Anion channels and hormone signalling in plant cells

Current evidences support a central role in signal transduction and turgor regulation for plasma membrane anion channels. The present review focuses on these channels as putative targets for plant hormones. Various approaches have been developed to investigate the contribution of anion channels to hormone responses at the level of integrated responses of intact cells or organs, or to study directly the hormonal regulation of anion channels at the membrane level. These approaches are mainly discussed for two biological models, stomatal guard cells and hypocotyl or coleoptile cells, both cell types being equipped with several types of anion channels. Membrane potential and anion flux measurements, together with pharmacological studies using anion channel inhibitors, reveal that anion permeabilities are involved in the responses of guard cells or hypocotyl cells to abscisic acid and/or auxin. In a few instances, a modulation of anion channel activity can be detected in voltage-clamp or patch-clamp experiments. From these data and other studies, anion channel activation seems to constitute a very early step in many transduction cascades within response pathways to endogenous hormonal signals, but also to abiotic and biotic environmental signals such as light or molecules involved in plant-pathogen interactions. This points to plasma membrane anion channels as major actors in plant signalling networks.     

Alterations of auxin perception in rolB-transformed tobacco protoplasts. Time course of rolB mRNA expression and increase in auxin sensitivity reveal multiple control by auxin.

Expression and physiological effects of the root-inducing rolB gene of Agrobacterium rhizogenes T-DNA were studied simultaneously in tobacco (Nicotiana tabacum) mesophyll protoplasts. The kinetic study of the expression of rolB mRNA following exogenous auxin application showed that auxin transiently stimulated rolB expression, with mRNA levels starting to accumulate 6 to 9 h after auxin was supplied and increasing 300-fold after 12 to 18 h. The parallel study of the auxin sensitivity of rolB-transformed protoplasts, as assayed by their electrical response to the hormone, showed that the auxin treatment generated an increase in sensitivity by a factor of up to 100,000, whereas in untransformed protoplasts the same auxin treatment induced an increase in auxin sensitivity that never exceeded 30- to 50-fold. This reflects a strong cooperative effect of auxin and rolB in transformed protoplasts. Surprisingly, the maximal increase in sensitivity was observed several hours before the maximal accumulation of rolB mRNA, suggesting that the dramatic control of auxin sensitivity by auxin in rolB-transformed protoplasts requires only low levels of rolB expression. Antibodies directed against ZmER-abp1, the major auxin-binding protein from maize, differentially altered the auxin sensitivity of the electrical response of rolB-transformed and normal protoplasts. This suggests that alterations of the auxin reception-transduction pathway at the plasma membrane of rolB-transformed protoplasts may account for their increased auxin sensitivity.     

A novel immunological approach establishes that the auxin-binding protein, Nt-abp1, is an element involved in auxin signaling at the plasma membrane.

Interactions of a collection of monoclonal antibodies (mAbs) to the recombinant Nicotiana tabacum auxin-binding protein 1 (Nt-abp1) were extensively characterized using surface plasmon resonance. Dynamic interaction studies using combinations of Nt-abp1, synthetic peptides corresponding to conserved sequences within auxin-binding proteins, and the mAbs have shown that a number of the mAbs recognized discontinuous epitopes revealing the junction of distinct domains in the folded protein. In particular, the two putative auxin binding domains and the C terminus of the protein were shown to interact with each other in the folded protein. Using the auxin-induced electrical response of tobacco protoplasts as a functional assay, all the mAbs exhibited either auxin antagonist or hormonomimetic properties. These effects, measured for the first time in homologous conditions, confirm that Nt-abp1 is present at the plasma membrane and is involved in the activation of the auxin-dependent electrical response of tobacco protoplasts. Based on our surface plasmon resonance data, we propose that the key event leading to the activation of this auxin electrical response consists of a conformational change in Nt-abp1.     

Antibodies to the CFTR modulate the turgor pressure of guard cell protoplasts via slow anion channels

The plasma membrane guard cell slow anion channel is a key element at the basis of water loss control in plants allowing prolonged osmolite efflux necessary for stomatal closure. This channel has been extensively studied by electrophysiological approaches but its molecular identification is still lacking. Recently, we described that this channel was sharing some similarities with the mammalian ATP-binding cassette protein, cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel [Leonhardt, N. et al. (1999) Plant Cell 11, 1141-1151]. Here, using the patch-clamp technique and a bioassay, consisting in the observation of the change in guard cell protoplasts volume, we demonstrated that a functional antibody raised against the mammalian CFTR prevented ABA-induced guard cell protoplasts shrinking and partially inhibited the slow anion current. Moreover, this antibody immunoprecipitated a polypeptide from guard cell protein extracts and immunolabeled stomata in Vicia faba leaf sections. These results indicate that the guard cell slow anion channel is, or is closely controlled by a polypeptide, exhibiting one epitope shared with the mammalian CFTR.     

Molecular analysis of auxin-specific signal transduction

The auxin-binding protein (ABP1) of maize has been purified, cloned and sequenced. Homologues have been found in a wide range of plants and at least seven ABP sequences from four different species are now known. We have developed a range of anti-ABP antibodies and these have been applied to analysis of the structure, localization and receptor function of ABP. ABP1 is a glycoprotein with two identical subunits of apparent M _r =22 kDa. The regions recognised by our five monoclonal antibodies (MAC 256–260) and by polyclonal antisera from our own and other laboratories have been specified by epitope mapping and fragmentation studies. All polyclonal anti-ABP sera recognise two or three dominant epitopes around the single glycosylation site. Two monoclonals (MAC 256, 259) are directed at the endoplasmic reticulum (ER) retention sequence KDEL at the C-terminus. Early biochemical data pointed to six amino acids likely to be involved in the auxin binding site. Inspection of the deduced sequence of ABP1 showed a hexapeptide (HRHSCE) containing five of these residues. Antibodies were raised against a polypeptide embracing this region and recognised ABP homologs in many species, suggesting that the region is highly conserved. This is confirmed by more recent information showing that the selected polypeptide contains the longest stretch of wholly conserved sequence in ABP1. Most strikingly, the antibodies show auxin agonist activity against protoplasts in three different electrophysiological systems-hyperpolarization of tobacco transmembrane potential; stimulation of outward ATP-dependent H⁺ current in maize; modulation of anion channels in tobacco. The biological activity of these antibodies indicates that the selected peptide does form a functionally important part of the auxin binding site and strongly supports a role for ABP1 as an auxin receptor. Although ABP contains a KDEL sequence and is located mainly in the ER lumen, the electrophysiological evidence shows clearly that some ABP must reach the outer face of the plasma membrane. One possible mechanism is suggested by our earlier demonstration that the ABP C-terminus recognised by MAC 256 undergoes an auxin-induced conformational change, masking the KDEL epitope and it is of interest that this C-terminal region appears to be important in auxin signalling [22]. So far we have been unable to detect the secretion of ABP into the medium of maize cell (bms) cultures reported by Jones and Herman [7]. However, recent silver enhanced immunogold studies on maize protoplasts have succeeded in visualizing ABP at the cell surface, as well as auxin-specific clustering of the signal induced within 30 minutes. The function of ABP in the ER, as well as the mechanisms of auxin signal transduction both at plasma membrane and gene levels remain to be elucidated.     

Identification of High-Affinity Slow Anion Channel Blockers and Evidence for Stomatal Regulation by Slow Anion Channels in Guard Cells

Slow anion channels in the plasma membrane of guard cells have been suggested to constitute an important control mechanism for long-term ion efflux, which produces stomatal closing. Identification of pharmacological blockers of these slow anion channels is instrumental for understanding plant anion channel function and structure. Patch clamp studies were performed on guard cell protoplasts to identify specific extracellular inhibitors of slow anion channels. Extracellular application of the anion channel blockers NPPB and IAA-94 produced a strong inhibition of slow anion channels in the physiological voltage range with half inhibition constants (K1/2) of 7 and 10 [mu]M, respectively. Single slow anion channels that had a high open probability at depolarized potentials were identified. Anion channels had a main conductance state of 33 [plus or minus] 8 pS and were inhibited by IAA-94. DIDS, which has been shown to be a potent blocker of rapid anion channels in guard cells (K1/2 = 0.2 [mu]M), blocked less than 20% of peak slow anion currents at extracellular or cytosolic concentrations of 100 [mu]M. The pharmacological properties of slow anion channels described here differ from those recently described for rapid anion channels in guard cells, fortifying the finding that two highly distinct types or modes of voltage- and second messenger-dependent anion channel currents coexist in the guard cell plasma membrane. Bioassays using anion channel blockers provide evidence that slow anion channel currents play a substantial role in the regulation of stomatal closing. Interestingly, slow anion channels may also function as a negative regulator during stomatal opening under the experimental conditions applied here. The identification of specific blockers of slow anion channels reported here permits detailed studies of cell biological functions, modulation, and structural components of slow anion channels in guard cells and other higher plant cells.     

Dynamics in PIN2 auxin carrier ubiquitylation in gravity-responding Arabidopsis roots

Plant tropisms are decisively influenced by dynamic adjustments in spatiotemporal distribution of the growth regulators auxin. Polar auxin transport requires activity of PIN-type auxin carrier proteins, with their distribution at the plasma membrane significantly contributing to the directionality of auxin flow. Control of PIN protein distribution involves regulation of their endocytosis and further sorting into the lytic vacuole for degradation and recently, protein ubiquitylation has been demonstrated to control degradative sorting of plasma membrane proteins in plants.1-6 Here we show dynamic adjustments in PIN2 ubiquitylation in gravity-stimulated roots, a response that coincides with establishment of a lateral PIN2 expression gradient. Our results imply that perception and transduction of gravity signals triggers differential ubiquitylation of PIN2, which might feed back on the coordination of auxin distribution in root meristems.     

Barley mildew and its elicitor chitosan promote closed stomata by stimulating guard-cell S-type anion channels

Stomatal closure is known to be associated with early defence responses of plant cells triggered by microbe-associated molecular patterns (MAMPs). However, the molecular mechanisms underlying these guard-cell responses have not yet been elucidated. We therefore studied pathogen-induced changes in ion channel activity in Hordeum vulgare guard cells. Barley mildew (Blumeria graminis) hyphae growing on leaves inhibited light-induced stomatal opening, starting at 9 h after inoculation, when appressoria had developed. Alternatively, stomatal closure was induced by nano-infusion of chitosan via open stomata into the sub-stomatal cavity. Experiments using intracellular double-barreled micro-electrodes revealed that mildew stimulated S-type (slow) anion channels in guard cells. These channels enable the efflux of anions from guard cells and also promote K(+) extrusion by altering the plasma membrane potential. Stimulation of S-type anion channels was also provoked by nano-infusion of chitosan. These data suggest that MAMPs of mildew hyphae penetrating the cuticle provoke activation of S-type anion channels in guard cells. In response, guard cells extrude K(+) salts, resulting in stomatal closure. Plasma membrane anion channels probably represent general targets of MAMP signaling in plants, as these elicitors depolarize the plasma membrane of various cell types.     

Two calcium-dependent protein kinases enhance maize drought tolerance by activating anion channel ZmSLAC1 in guard cells

Stomatal closure is an important process to prevent water loss in plants response to drought stress, which is finely modulated by ion channels together with their regulators in guard cells, especially the S-type anion channel AtSLAC1 in Arabidopsis. However, the functional characterization and regulation analyses of anion channels in gramineous crops, such as in maize guard cells are still limited. In this study, we identified an S-type anion channel ZmSLAC1 that was preferentially expressed in maize guard cells and involved in stomatal closure under drought stress. We found that two Ca²⁺-dependent protein kinases ZmCPK35 and ZmCPK37 were expressed in maize guard cells and localized on the plasma membrane. Lesion of ZmCPK37 resulted in drought-sensitive phenotypes. Mutation of ZmSLAC1 and ZmCPK37 impaired ABA-activated S-type anion currents in maize guard cells, while the S-type anion currents were increased in the guard cells of ZmCPK35- and ZmCPK37-overexpression lines. Electrophysiological characterization in maize guard cells and Xenopus oocytes indicated that ZmCPK35 and ZmCPK37 could activate ZmSLAC1-mediated Cl^- and NO₃^- currents. The maize inbred and hybrid lines overexpressing ZmCPK35 and ZmCPK37 exhibited enhanced tolerance and increased yield under drought conditions. In conclusion, our results demonstrate that ZmSLAC1 plays crucial roles in stomatal closure in maize, whose activity is regulated by ZmCPK35 and ZmCPK37. Elevation of ZmCPK35 and ZmCPK37 expression levels is a feasible way to improve maize drought tolerance as well as reduce yield loss under drought stress.     

Identification and modulation of a voltage-dependent anion channel in the plasma membrane of guard cells by high-affinity ligands.

Guard cell anion channels (GCAC1) catalyze the release of anions across the plasma membrane during regulated volume decrease and also seem to be involved in the targeting of the plant growth hormones auxins. We have analyzed the modulation and inhibition of these voltage-dependent anion channels by different anion channel blockers. Ethacrynic acid, a structural correlate of an auxin, caused a shift in activation potential and simultaneously a transient increase in the peak current amplitude, whereas other blockers shifted and blocked the voltage-dependent activity of the channel. Comparison of dose-response curves for shift and block imposed by the inhibitor, indicate two different sites within the channel which interact with the ligand. The capability to inhibit GCAC1 increases in a dose-dependent manner in the sequence: probenecid less than A-9-C less than ethacrynic acid less than niflumic acid less than IAA-94 less than NPPB. All inhibitors reversibly blocked the anion channel from the extracellular side. Channel block on the level of single anion channels is characterized by a reduction of long open transitions into flickering bursts, indicating an interaction with the open mouth of the channel. IAA-23, a structural analog of IAA-94, was used to enrich ligand-binding polypeptides from the plasma membrane of guard cells by IAA-23 affinity chromatography. From this protein fraction a 60 kDa polypeptide crossreacted specifically with polyclonal antibodies raised against anion channels isolated from kidney membranes. In contrast to guard cells, mesophyll plasma membranes were deficient in voltage-dependent anion channels and lacked crossreactivity with the antibody.     

Trafficking of the plant potassium inward rectifier KAT1 in guard cell protoplasts of Vicia faba

Trafficking of K+ inward (Kin+) rectifying channels was analyzed in guard cells of Vicia faba transfected with the Kin+ rectifier from Arabidopsis thaliana KAT1 fused to the green fluorescent protein (GFP). Confocal images and whole-cell patch-clamp measurements confirmed the incorporation of active KAT1 channels into the plasma membrane of transfected guard cell protoplasts. The Kin+ rectifier current density of the plasma membrane was much larger in transfected protoplasts than in wild-type (wt) protoplasts. This shows a coupling between K+ channel synthesis and incorporation of the channel into the plasma membrane. Pressure-driven increase and decrease in surface area led to the incorporation and removal of vesicular membrane carrying active Kin+ rectifier in wt and transfected protoplasts. These vesicular membranes revealed a higher channel density than the plasma membrane, suggesting that Kin+ rectifier remains in clusters during trafficking to and from the plasma membrane. The observed results can be explained by a model illustrating that vesicles of a pre-plasma membrane pool carry K+ channels preferentially in clusters during constitutive and pressure-driven exo- and endocytosis.     

The rolB Gene of Agrobacterium rhizogenes Does Not Increase the Auxin Sensitivity of Tobacco Protoplasts by Modifying the Intracellular Auxin Concentration

Phenotypical alterations observed in rolB-transformed plants have been proposed to result from a rise in intracellular free auxin due to a RolB-catalyzed hydrolysis of auxin conjugates(J.J. Estruch, J. Schell, A. Spena [1991] EMBO J 10: 3125-3128).We have investigated this hypothesis in detail using tobacco (Nicotiana tabacum) mesophyll protoplasts isolated from plants transformed with the rolB gene under the control of its own promoter (BBGUS 6 clone) or the cauliflower mosaic virus 35S promoter (CaMVBT 3 clone). Protoplasts expressing rolB showed an increased sensitivity to the auxin-induced hyperpolarization of the plasma membrane when triggered with exogenous auxin. Because this phenotypical trait was homogeneously displayed over the entire population, protoplasts were judged to be a more reliable test system than the tissue fragments used in previous studies to monitor rolB gene effects on cellular auxin levels. Accumulation of free 1-[3H]-naphthaleneacetic acid (NAA) was equivalent in CaMVBT 3, BBGUS 6, and wild-type protoplasts, Naphthyl-[beta]-glucose ester, the major NAA metabolite in protoplasts, reached similar levels in CaMVBT 3 protoplasts, reached similar levels in CaMVBT 3 and normal protoplasts and was hydrolyzed at the same rate in BBGUS 6 and normal protoplasts. Furthermore, NAA accumulation and metabolism in BBGUS 6 protoplasts were independent of the rolB gene expression level. Essentially similar results were obtained with indoleacetic acid. Thus, it was concluded that the rolB-dependent behavior of transgenic tobacco protoplasts is not a consequence of modifying the intracellular auxin concentration but likely results from changes in the auxin perception pathway.     

Selective mobility and sensitivity to SNAREs is exhibited by the Arabidopsis KAT1 K+ channel at the plasma membrane

Recent findings indicate that proteins in the SNARE superfamily are essential for cell signaling, in addition to facilitating vesicle traffic in plant cell homeostasis, growth, and development. We previously identified SNAREs SYP121/Syr1 from tobacco (Nicotiana tabacum) and the Arabidopsis thaliana homolog SYP121 associated with abscisic acid and drought stress. Disrupting tobacco SYP121 function by expressing a dominant-negative Sp2 fragment had severe effects on growth, development, and traffic to the plasma membrane, and it blocked K(+) and Cl(-) channel responses to abscisic acid in guard cells. These observations raise questions about SNARE control in exocytosis and endocytosis of ion channel proteins and their organization within the plane of the membrane. We have used a dual, in vivo tagging strategy with a photoactivatable green fluorescent protein and externally exposed hemagglutinin epitopes to monitor the distribution and trafficking dynamics of the KAT1 K(+) channel transiently expressed in tobacco leaves. KAT1 is localized to the plasma membrane within positionally stable microdomains of approximately 0.5 microm in diameter; delivery of the K(+) channel, but not of the PMA2 H(+)-ATPase, to the plasma membrane is suppressed by Sp2 fragments of tobacco and Arabidopsis SYP121, and Sp2 expression leads to profound changes in KAT1 distribution and mobility within the plane of the plasma membrane. These results offer direct evidence for SNARE-mediated traffic of the K(+) channel and a role in its distribution within subdomains of the plasma membrane, and they implicate a role for SNAREs in positional anchoring of the K(+) channel protein.     

AtALMT12 represents an R‐type anion channel required for stomatal movement in Arabidopsis guard cells

Stomatal pores formed by a pair of guard cells in the leaf epidermis control gas exchange and transpirational water loss. Stomatal closure is mediated by the release of potassium and anions from guard cells. Anion efflux from guard cells involves slow (S‐type) and rapid (R‐type) anion channels. Recently the SLAC1 gene has been shown to encode the slow, voltage‐independent anion channel component in guard cells. In contrast, the R‐type channel still awaits identification. Here, we show that AtALMT12, a member of the aluminum activated malate transporter family in Arabidopsis, represents a guard cell R‐type anion channel. AtALMT12 is highly expressed in guard cells and is targeted to the plasma membrane. Plants lacking AtALMT12 are impaired in dark‐ and CO₂‐induced stomatal closure, as well as in response to the drought‐stress hormone abscisic acid. Patch‐clamp studies on guard cell protoplasts isolated from atalmt12 mutants revealed reduced R‐type currents compared with wild‐type plants when malate is present in the bath media. Following expression of AtALMT12 in Xenopus oocytes, voltage‐dependent anion currents reminiscent to R‐type channels could be activated. In line with the features of the R‐type channel, the activity of heterologously expressed AtALMT12 depends on extracellular malate. Thereby this key metabolite and osmolite of guard cells shifts the threshold for voltage activation of AtALMT12 towards more hyperpolarized potentials. R‐Type channels, like voltage‐dependent cation channels in nerve cells, are capable of transiently depolarizing guard cells, and thus could trigger membrane potential oscillations, action potentials and initiate long‐term anion and K⁺ efflux via SLAC1 and GORK, respectively.