Abscisic Acid Activation of Plasma Membrane Ca²⁺ Channels in Guard Cells Requires Cytosolic NAD(P)H and Is Differentially Disrupted Upstream and Downstream of Reactive Oxygen Species Production in abi1-1 and abi2-1 Protein Phosphatase 2C Mutants

NAD(P)H Requirement for ABA Activation of Ca²+ Channels

To examine whether NAD(P)H may play a role in the ABA stimulation of hyperpolarization-activated calcium-permeable channels, we analyzed ABA effects on I_Ca in the presence or absence of cytosolic NADPH. ABA and H₂O₂ were applied to patch-clamped guard cells, and responses were recorded. The presence of 0.1 mM DTT in the patch clamp pipette and bath solutions inhibited the spontaneous activation of I_Ca currents, as reported previously (Pei et al., 2000). In the absence of DTT, some guard cells showed constitutive I_Ca activity (Pei et al., 2000), which supports the findings that oxidative processes activate these Ca²+ channels.

Arabidopsis guard cells (Landsberg erecta ecotype) were patch clamped for 10 min in the whole-cell mode before extracellular ABA application. When NADPH, the cytoplasm of guard cells, was not included in the patch clamp pipette solution which dialyzes, ABA did not activate I_Ca currents, as shown in Figures 1A and 1B (n = 10). However, when 5 mM NADPH was added to the pipette solution, ABA activated I_Ca currents (n = 13), as reported previously (Figures 1C and 1D) (Pei et al., 2000). Addition of the NADPH oxidase inhibitor DPI (12.5 μM) to the pipette solution inhibited the ABA activation of I_Ca (n = 3; data not shown). ABA also activated I_Ca in the presence of 1 mM NADPH (P < 0.01) (Figures 1E and 1F; n = 8). The average amplitudes of ABA-activated whole-cell I_Ca currents at −198 mV were statistically similar at 1 μM and 5 mM NADPH (P > 0.11).

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Figure 1.

ABA Activation of Ca²+-Permeable I_Ca Currents in Arabidopsis Guard Cell Protoplasts Requires Cytosolic NADPH.

(A) and (B) ABA (50 μM) did not activate I_Ca calcium channels when the pipette solution did not include NADPH or NADH. (B) shows two overlapping traces from a guard cell before and after ABA application.

(C) and (D) ABA (50 μM) activated I_Ca calcium currents when 5 mM NADPH was added to the pipette solution.

(E) and (F) ABA activated I_Ca when 1 mM NADPH was added to the pipette solution.

(A), (C), and (E) show average responses, and (B), (D), and (F) show responses in individual cells before and 5 min after ABA application. ABA was added ∼10 min after establishing whole-cell recordings, and whole-cell currents were measured before ABA application and in the same cells 5 min after extracellular ABA application in all recordings. The numbers of cells averaged are given in the text. Closed circles, before ABA addition to batch solution; open circles, 5 min after ABA addition to the same cells. Error bars represent sem.

In additional sets of experiments, 5 mM cytosolic NADPH caused an activation of I_Ca in the absence of added ABA in some cells, whereas with 1 mM cytosolic NADPH, ABA activation of I_Ca occurred (I.C. Mori, G.J. Allen, and J.I. Schroeder, data not shown). NADPH oxidation has been reported to be similar to NADH oxidation; therefore, not only NADPH but also NADH functions as a substrate of peroxidases to produce ROS in higher plants (Bestwick et al., 1998). When 5 mM NADPH was replaced with 5 mM NADH in the pipette solution, ABA activated I_Ca to a lesser extent, with an average amplitude of −7.8 ± 1.6 pA at −198 mV (n = 9; data not shown).

abi1-1 and abi2-1 PP2C Mutants Disrupt the ABA Activation of I_Ca

To determine whether the abi1-1 and abi2-1 mutations affect the ABA activation of I_Ca, guard cell protoplasts of the abi1-1 and abi2-1 mutants were first patch clamped for ∼10 min in the whole-cell mode. Subsequently, the same cells were treated with ABA by bath perfusion. Figure 2 shows the effects of abi1-1 and abi2-1 on the ABA activation of I_Ca. ABA did not activate I_Ca in either mutant in the presence of 5 mM cytosolic NADPH (n = 5, P > 0.72 for abi1-1; n = 5, P > 0.35 for abi2-1).

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Figure 2.

ABA Failed to Activate Ca²+ Channel Currents in abi1-1 and abi2-1 PP2C Mutant Guard Cells.

(A) ABA (50 μM) did not activate I_Ca in abi1-1 guard cells with 5 mM NADPH included in the pipette solution (n = 5).

(B) ABA (50 μM) did not activate I_Ca in abi2-1 guard cells with 5 mM NADPH added to the pipette solution (n = 5).

Experiments were performed as described in Figure 1. Error bars represent sem.

H₂O₂-Induced Responses Are Impaired in abi2-1 but Not in abi1-1

To examine whether the abi1-1 and abi2-1 mutations impair the activation of I_Ca upstream or downstream of or parallel to ROS production, we first analyzed H₂O₂ activation of the hyperpolarization-activated Ca²+ channel currents in abi1-1 and abi2-1. H₂O₂ (100 μM) clearly activated I_Ca in abi1-1 guard cells, as shown in Figures 3A and 3B (n = 6, P < 0.04). Interestingly, however, H₂O₂ failed to activate I_Ca in abi2-1 guard cells (Figures 3C and 3D) (n = 5, P > 0.84).

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Figure 3.

H₂O₂ Activates Ca²+-Permeable Currents in abi1-1 but Not abi2-1 Arabidopsis Guard Cell Protoplasts.

(A) and (B) H₂O₂ (100 μM) activates I_Ca in abi1-1 guard cells (n = 6).

(C) and (D) H₂O₂ (100 μM) did not activate I_Ca in abi2-1 guard cells (n = 5). (D) shows two overlapping traces.

Experiments were performed as described in Figure 1 except that H₂O₂ was used instead of ABA. Error bars represent sem.

Exposure of stomates to H₂O₂ induces [Ca²+]_cyt increases and partial stomatal closing in Commelina and Arabidopsis (McAinsh et al., 1996; Pei et al., 2000). To further analyze H₂O₂-mediated signal transduction in abi1-1 and abi2-1, we performed stomatal closing assays in wild-type, abi1-1, and abi2-1 leaves. As reported previously, extracellular Ca²+ is required for H₂O₂ induction of stomatal closing and [Ca²+]_cyt increases (Pei et al., 2000). When 0.1 mM CaCl₂ was added to the bath solution, partial stomatal closing occurred (DeSilva et al., 1985; Allen et al., 1999a). However, buffering the total free Ca²+ concentration to ∼0.1 mM in the cell wall space of epidermal strips with a bath solution containing 0.1 mM EGTA and 0.2 mM Ca²+ minimized Ca²+-induced stomatal closing and allowed analysis of H₂O₂ responses (Pei et al., 2000). H₂O₂ at 100 μM triggered a reduction in stomatal aperture in the wild type (Landsberg erecta ecotype), as illustrated in Figure 4A (n = 3 experiments, P < 0.01). The partial H₂O₂ response compared with the ABA response (Figure 4A) is consistent with the proposed model of parallel branches together mediating early ABA signaling (see Figure 5f in the article by Pei et al., 2000). H₂O₂ also triggered a reduction in stomatal aperture in the abi1-1 mutant (Figure 4B; n = 3, P < 0.02). However, stomatal aperture measurements showed that H₂O₂-induced stomatal closing was impaired in the abi2-1 mutant (Figure 4C; n = 3, P > 0.46). Stomatal movement results were confirmed in additional control and blind experiments (see Methods).

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Figure 4.

Differential Effects of H₂O₂ on Stomatal Apertures of abi1-1 and abi2-1.

(A) Both ABA (50 μM) and H₂O₂ (100 μM) induced stomatal closing in the wild type (Landsberg erecta ecotype).

(B) ABA did not cause stomatal closing, but H₂O₂ elicited partial stomatal closing in abi1-1.

(C) Neither ABA nor H₂O₂ elicited stomatal closing of abi2-1.

Averages from n = three leaf epidermal experiments are shown (60 stomates per bar). Error bars represent sem.

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Figure 5.

Differential Production of ROS in abi1-1 and abi2-1 Guard Cells Treated with ABA.

ABA (50 μM) increased ROS production in the wild type (WT) (four experiments, n = 161 cells before ABA treatment, n = 123 cells after ABA treatment) and abi2-1 (nine experiments, n = 221 cells before ABA treatment, n = 207 cells after ABA treatment). ABA did not increase ROS production in abi1-1 (six experiments, n = 110 cells before ABA treatment, n = 150 cells after ABA treatment). Changes in ROS levels were analyzed by measuring H₂DCF fluorescence levels in guard cells in response to ABA or solvent (0.1% ethanol) control applications. Error bars represent sem.

ABA Enhances ROS Levels in the Wild Type and abi2-1 but Not in abi1-1

To analyze ABA-dependent ROS production in abi1-1 and abi2-1, ROS levels were analyzed in populations of wild-type, abi1-1, and abi2-1 guard cells using the fluorescent dye 2′,7′-dichlorofluorescin diacetate (H₂DCF-DA), which reports changes in the oxidative state of guard cells (Ohba et al., 1994; Lee et al., 1999; Pei et al., 2000). As shown in Figure 5, the relative fluorescence emission increased after treatment of wild-type guard cells with 50 μM ABA (four experiments, P < 0.02). However, ROS measurements showed that 50 μM ABA did not increase the relative fluorescence emission in abi1-1 guard cells (six experiments). A slight ABA-induced decrease in ROS levels was observed in abi1-1 guard cells, which was not significant in all data sets (P = 0.02 to 0.053) (Figure 5). Conversely, ABA at 50 μM increased the relative fluorescence emission in abi2-1 guard cells (nine experiments, P < 0.001) (Figure 5). Impairment of ABA-induced ROS production in abi1-1 was significant compared with that in the wild type (P < 0.001) and abi2-1 (P < 0.001). Differential ABA-induced fluorescence responses in abi1-1 and abi2-1 were confirmed in additional blind experiments (see Methods).

Cytosolic NADPH Is Necessary for the ABA Activation of I_Ca

ROS is a term for radicals and other reactive species derived from oxygen. ROS have been implicated in numerous signal transduction pathways in both plant and animal cells (Lamb and Dixon, 1997; Rhee et al., 2000). In plants, ROS, including the superoxide radical and H₂O₂, act as important second messengers in defense responses triggered by pathogens and elicitors (Levine et al., 1994; Lamb and Dixon, 1997). Many enzymes can produce ROS in plant cells. Activation of these enzymes is closely associated with oxidative bursts (Lamb and Dixon, 1997). A plasma membrane oxidase generates superoxide (Keller et al., 1998), a peroxidase produces H₂O₂ directly, and an oxalate oxidase also generates H₂O₂ (Baker and Orlandi, 1995). DPI, an inhibitor of neutrophil NADPH oxidases (Cross and Jones, 1986, 1991), partially inhibits ABA-induced stomatal closing (Pei et al., 2000). The elicitors oligogalacturonic acid and chitosan reduce stomatal aperture and induce the production of ROS in tomato and Commelina guard cells (Lee et al., 1999). The ROS activation of I_Ca channels has been proposed to represent a possible joint branch of multiple stress signaling pathways (Pei et al., 2000; Schroeder et al., 2001).

Previous studies have shown that the ABA activation of Ca²+ channels in Vicia guard cells is transient and attenuated (Schroeder and Hagiwara, 1990; Hamilton et al., 2000). In the present study of Arabidopsis guard cells, we obtained ABA activation of I_Ca in patch-clamped whole cells by adding NADPH or NADH via the patch pipette to the cytosol of guard cells. However, no ABA response was found in the relatively small Arabidopsis guard cells when no NAD(P)H was added to the patch pipette. The requirement of NADPH or NADH, ABA-induced ROS production, and the inhibitory effects of DPI suggest that NAD(P)H oxidases and/or redox control of sulfhydryl groups contributes to ABA signal transduction. NAD(P)H is formed by the reduction of NAD(P) via light-supplied energy in guard cell chloroplasts (Shimazaki et al., 1989). A previous study showed that ABA-induced stomatal closing requires guard cell metabolism (Weyers et al., 1982). In this respect, the results presented here indicate a possible link between guard cell metabolism and ion channel regulation. ABA signaling requires hydrolyzable ATP in guard cells (Schmidt et al., 1995) and phosphorylation events as positive transducers of stomatal closing, which also would require intact guard cell metabolism.

Plasma Membrane Ca²+ Channel Activity in Guard Cells

Guard cells show spontaneous activity of hyperpolarization-induced Ca²+ increases (Gilroy et al., 1991; Grabov and Blatt, 1998; Allen et al., 1999b) and spontaneous activity of plasma membrane Ca²+ currents (Hamilton et al., 2000; Pei et al., 2000). Whether the spontaneous Ca²+ influx and I_Ca are mediated by the same Ca²+ channel remains unknown. Interestingly, the spontaneous activity of hyperpolarization-induced Ca²+ currents was inhibited by adding DTT to the patch clamp pipette (cytosolic) solution and bath solutions (Pei et al., 2000; this study).

Fungal elicitors have been shown to induce hyperpolarization-activated Ca²+ channels in tomato suspension culture cells (Gelli et al., 1997). These Ca²+ channels show a similar I_Ca-like activation by hyperpolarization and a more pronounced time-dependent activation. Interestingly, in some tomato cells, spontaneous activity of hyperpolarization-activated Ca²+ channels was observed, which also was inhibited by 1 mM DTT (A. Gelli and E. Blumwald, personal communication). Pathogenic elicitors cause ROS production in plants, with Ca²+ influx occurring both before and after ROS production (Knight et al., 1991; Price et al., 1994; Lamb and Dixon, 1997; Kawano et al., 1998), suggesting that more than one Ca²+ channel or activation mechanism may contribute to this response. I_Ca-like Ca²+ channels may contribute to the secondary response that follows ROS production.

Interestingly, hyperpolarization-activated Ca²+ channels also have been identified in Arabidopsis cells from the cortical elongation zone of roots and the epidermis of the growing root tip, but not in mature epidermis or in pericycle cells (Kiegle et al., 2000) or in the apex of Arabidopsis root hair cells (Very and Davies, 2000). These studies suggest that hyperpolarization-activated Ca²+ channels may contribute to various signal transduction and growth processes in plants, and their opposite voltage dependence compared with depolarization-activated Ca²+ channels (Huang et al., 1994; Marshall et al., 1994; Thuleau et al., 1994) suggests activation during different signaling processes.

Differential Disruption by abi1-1 and abi2-1 PP2Cs

Stomata of the abi1-1 and abi2-1 mutants are insensitive to ABA (Finkelstein and Somerville, 1990; Roelfsema and Prins, 1995; Pei et al., 1997). ABA regulation of K⁺ channels is impaired by abi1-1 expression (Armstrong et al., 1995), and ABA activation of S-type anion channels is impaired in abi1-1 and abi2-1 (Pei et al., 1997). The Arabidopsis abi1-1 and abi2-1 mutations impair ABA-induced cytoplasmic Ca²+ increases in guard cells (Allen et al., 1999a). ABA induces both Ca²+ release from intracellular stores and Ca²+ influx from the extracellular space. However, it remained unknown which Ca²+ increase mechanisms were affected by abi1-1 and abi2-1. The identification of ROS and I_Ca as early ABA signaling intermediates has allowed a direct analysis of the effects of the abi PP2C mutations on early signal transduction mechanisms.

Here, we show that the PP2C mutations abi1-1 and abi2-1 both disrupt the ABA activation of I_Ca. ABA did not induce the production of ROS in the abi1-1 mutant. H₂O₂-activated I_Ca and H₂O₂-induced stomatal closing were not impaired in abi1-1. These findings suggest that the abi1-1 mutation disrupts ABA signaling upstream of ROS production, as illustrated in Figure 6 . In contrast, ABA elicited ROS production in the abi2-1 mutant, but H₂O₂ did not activate I_Ca and did not induce stomatal closing in abi2-1. These data suggest that the abi2-1 mutation impairs ABA signaling downstream of ROS production (Figure 6). These data lead to a simple model for the positioning of I_Ca, ROS production, and the abi1-1 and abi2-1 protein phosphatases in the ABA signal transduction cascade in Arabidopsis guard cells, as illustrated in Figure 6. Note that ABA may function by downregulating ROS-scavenging enzymes such as catalase. The data further suggest that abi1-1 interacts with early signal transduction mechanisms upstream of ROS production. Previous studies have suggested that abi1-1 and abi2-1 have distinct functions, even though they both disrupt ABA signaling in general (Gilmour and Thomashow, 1991; Vartanian et al., 1994; Gosti et al., 1995; Bruxelles et al., 1996; Söderman et al., 1996; Pei et al., 1997; Strizhov et al., 1997). Our data are consistent with these findings and provide a working model for the ABA signal transduction pathway to explain the differential effects of abi1-1 and abi2-1 (Figure 6).

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Figure 6.

Model Summarizing the Differential Disruption of ABA Activation of I_Ca Ca²+ Channels by the Two abi1-1 and abi2-1 PP2C Mutants.

ABA activation of Ca²+ channels required cytosolic NAD(P)H, was inhibited by DPI, and was accompanied by ROS production.

It remains unknown whether abi1-1 and abi2-1 additionally affect Ca²+ release from intracellular stores and a possible parallel Ca²+-independent pathway (Allan et al., 1994; Allen et al., 1999a). Ca²+ release can occur parallel to Ca²+ influx at low ABA concentrations (MacRobbie, 2000), and perhaps also downstream of I_Ca activation, based on Ca²+ activation of plant phospholipase C isoforms (Staxen et al., 1999) and on the proposed Ca²+-induced Ca²+ release via vacuolar slow vacuolar (SV) channels (Ward and Schroeder, 1994; Bewell et al., 1999). If abi1-1 impairs an ABA receptor, parallel mechanisms could be accounted for by one effect of abi1-1. Note that the abi1-1 and abi2-1 PP2Cs may interact with more than one protein. Future research is needed to analyze the effects of abi1-1 and abi2-1 on Ca²+ release mechanisms.

In summary, the present study provides strong support for the new model that ABA-induced ROS production and I_Ca Ca²+-permeable channel activation are important components of ABA signal transduction. The cytosolic NAD(P)H requirement for ABA activation of I_Ca channels, together with DTT and DPI inhibition of I_Ca, suggests that NAD(P)H oxidases and/or redox control of sulfhydryl groups contributes to early ABA signaling. Furthermore, abi1-1 and abi2-1 interact with important and distinct transducers of this early ABA signaling branch upstream and downstream of ROS production, respectively.

Isolation of Arabidopsis Guard Cells

Arabidopsis thaliana wild type (Landsberg erecta ecotype) and the abi1-1 and abi2-1 mutant lines were used in this study. The mutant genotypes and homozygosity were confirmed using a previously described polymerase chain reaction method (Leung et al., 1997). The abscisic acid (ABA) insensitivity was further confirmed in seed germination assays (Pei et al., 1997; Allen et al., 1999a). Note that during the course of this work, a separate set of abi1-1 and abi2-1 seed was obtained from the Arabidopsis stock center (Ohio State University, Columbus). However, seed germination and polymerase chain reaction tests showed that these consisted of a mixed population. The stock center was informed, and these seed were not used further. Plants were grown in soil in plant growth chambers with a 16-hr-light (80 μE light fluence rate) and 8-hr-dark regimen and watered with deionized water every day. Arabidopsis guard cell protoplasts were isolated enzymatically from leaf epidermal strips of 4- to 6-week-old plants. Arabidopsis rosette leaves were blended in a commercial blender in deionized water three times for 5 sec each and collected using a nylon mesh (pore size, 62 μm). The collected epidermal tissue was incubated in 10 mL of medium containing 1% Cellulase R-10, 0.5% Macerozyme R-10 (Yakult, Japan), 0.5% BSA, 0.5 M mannitol, 0.1 mM KCl, 0.1 mM CaCl₂, 10 mM ascorbic acid, and 0.1% kanamycin sulfate, pH 5.5 (with KOH), for 15 to 17 hr at 24°C on a shaker. Isolated guard cell protoplasts were collected and washed twice as described previously (Pei et al., 1997).

Patch Clamp and Data Acquisition

Whole-cell patch clamp recordings from Arabidopsis guard cells were made using Axopatch 200 and 200A amplifiers (Axon Instruments, Union City, CA) that were connected to microcomputers via interfaces as described (Pei et al., 1997). Seal resistances were >10 GΩ. Liquid junction potentials were corrected (Ward and Schroeder, 1994). Initially, upon establishment of whole-cell recordings, a current was observed in some guard cells. This current, however, disappeared within 30 sec to 4 min after establishing whole-cell recordings in 90% of the guard cells analyzed. The frequency of occurrence of this initial current varied from cell preparation to cell preparation. After the initial current had vanished and ∼10 min after establishing whole-cell recordings, ABA and H₂O₂ were applied by bath perfusion to patch-clamped guard cells and responses were recorded. pClamp software (Axon Instruments) was used to acquire and analyze whole-cell currents. The standard voltage protocol ramped from −18 to −198 mV (ramp speed, 180 mV/sec). The interpulse period was 1 min. Whole-cell currents were not leak subtracted. Data were analyzed using Axograph software (Axon Instruments, Inc., Foster City, CA). The bath solution used in patch clamp experiments contained 100 mM BaCl₂, 0.1 mM DTT, and 10 mM Mes titrated to pH 5.6 with Tris, and the pipette solution was composed of 10 mM BaCl₂, 0.1 mM DTT, 4 mM EGTA, 10 mM Hepes adjusted to pH 7.1, and Tris. To investigate the effects of ABA on a Ca²⁺-permeable, non-selective cation current (I_Ca), NADPH or NADH was added to the pipette solution at the indicated concentrations in the text. To analyze the hyperpolarization-activated currents, we used Ba²+ ions, which are permeable to I_Ca channels (Pei et al., 2000).

Stomatal Aperture Measurements

Stomatal movement analyses were performed as described previously (Pei et al., 2000). Rosette leaves from 4- to 6-week-old plants were exposed to white light (125 μE fluence rate) while floating in a solution containing 10 mM KCl, 0.2 mM CaCl₂, 0.1 mM EGTA (free extracellular Ca²+ concentration buffered to ∼0.1 mM), and 10 mM Mes titrated to pH 6.15 with KOH. Subsequently, 100 μM H₂O₂ and 50 μM ABA were added to the bath solution as indicated in the Figures and text. After treatment for 2 hr in white light (125 μE fluence rate), leaves were blended and stomatal apertures were measured by focusing on the inner lips of stomates (away from the focal plane of guard cells) as described (Ichida et al., 1997). In each epidermal peel experiment, 20 stomatal apertures were measured at each condition. In additional control and blind experiments, the ability of H₂O₂ to cause stomatal closing in wild-type and abi1-1 leaves, but not abi2-1 leaves, was reproduced (n = 3 experiments per line; wild type ± H₂O₂, P < 0.03; abi1-1 ± H₂O₂, P < 0.02; abi2-1 ± H₂O₂, P > 0.36). Standard errors were determined relative to the square root of the number of epidermal strip experiments, as in previous studies (Ichida et al., 1997; Pei et al., 2000). All statistical analyses were performed using the TTEST program in Excel 5.0 software (Microsoft, Redmond, WA). Values of P < 0.05 were considered to show statistically significant differences.

Reactive Oxygen Species Detection in Guard Cells

Reactive oxygen species (ROS) production in guard cells was analyzed using 2′,7′-dichlorofluorescin diacetate (H₂DCF-DA) (Ohba et al., 1994; Lee et al., 1999). This nonfluorescent compound is permeable to the plasma membrane and is converted to dichlorofluorescin (H₂DCF), which is impermeable. H₂DCF can be oxidized by peroxidases and H₂O₂. Epidermal tissues were isolated from 6-week-old plants with a commercial blender. The epidermal tissues were incubated in 30 mM KCl and 10 mM Mes-KOH, pH 6.15, in the light at room temperature for 2 hr (Pei et al., 2000). Note that immediately after epidermal tissue isolations, guard cells showed increased ROS levels, likely as a result of mechanical perturbation from epidermis excision. However, after 2-hr incubations of epidermal tissues in white light (125 μE), ROS levels decreased. Fifty micromolar H₂DCF-DA was added to the incubation medium and then either 0.1% ethanol (control) or 50 μM ABA was added to the incubation medium after 20 to 30 min of dye loading. The epidermal tissues were collected using a nylon mesh and washed with distilled water twice after 20 to 30 min of ABA or ethanol control treatments. Guard cells were observed under a fluorescence microscope equipped with a cooled charge-coupled device camera. Note that prolonged exposure of H₂DCF-loaded guard cells to excitation light led to a transient increase in ROS and subsequent bleaching of the dye. Therefore, to compare fluorescence responses in control and ABA-treated samples, excitation light exposure was reduced using neutral density filters and limited to a 10-sec exposure, and only one image was captured per sample. All experiments reported here (Figure 5) were confirmed in additional blind experiments (abi2-1 ± ABA, five experiments, n = 234 guard cells, P < 0.01). abi1-1 showed a slight but statistically insignificant ABA-induced reduction in ROS (five experiments, n = 152 guard cells, P = 0.053). Images were acquired and the fluorescence emission of guard cells was analyzed using Adobe Photoshop 5.0 (Mountain View, CA).