RIN4 Functions with Plasma Membrane H+-ATPases to Regulate Stomatal Apertures during Pathogen Attack

Pathogen perception by the plant innate immune system is of central importance to plant survival and productivity. The Arabidopsis protein RIN4 is a negative regulator of plant immunity. In order to identify additional proteins involved in RIN4-mediated immune signal transduction, we purified components of the RIN4 protein complex. We identified six novel proteins that had not previously been implicated in RIN4 signaling, including the plasma membrane (PM) H⁺-ATPases AHA1 and/or AHA2. RIN4 interacts with AHA1 and AHA2 both in vitro and in vivo. RIN4 overexpression and knockout lines exhibit differential PM H⁺-ATPase activity. PM H⁺-ATPase activation induces stomatal opening, enabling bacteria to gain entry into the plant leaf; inactivation induces stomatal closure thus restricting bacterial invasion. The rin4 knockout line exhibited reduced PM H⁺-ATPase activity and, importantly, its stomata could not be re-opened by virulent Pseudomonas syringae. We also demonstrate that RIN4 is expressed in guard cells, highlighting the importance of this cell type in innate immunity. These results indicate that the Arabidopsis protein RIN4 functions with the PM H⁺-ATPase to regulate stomatal apertures, inhibiting the entry of bacterial pathogens into the plant leaf during infection.     

Investigating the functions of the RIN4 protein complex during plant innate immune responses

Pathogen recognition by the plant innate immune system invokes a sophisticated signal transduction network that culminates in disease resistance. The Arabidopsis protein RIN4 is a well-known regulator of plant immunity. However, the molecular mechanisms by which RIN4 controls multiple immune responses have remained elusive. in our recently published study, we purified components of the RIN4 protein complex from A. thaliana and identified several novel RIN4-associated proteins.¹ we found that one class of RIN4-associated proteins, the plasma membrane H⁺-ATPases AHA1 and AHA2, play a crucial role in resisting pathogen invasion. Plants use RIN4 to regulate H⁺-ATPase activity during immune responses, thereby controlling stomatal apertures during pathogen attack. Stomata were previously identified as active regulators of plant immune responses during pathogen invasion, but how the plant innate immune system coordinates this response was unknown.^2,3 Our investigations have revealed a novel function of rin4 during pathogenesis. Here, we discuss the rin4-AHA1/2 interaction and highlight additional RIN4-associated proteins (RAPs) as well as speculate on their potential roles in plant innate immunity.Key words: RIN4, PAMP-triggered immunity, effector-triggered immunity, protein complex, innate immunity     

Phosphorylation of the Plant Immune Regulator RPM1-INTERACTING PROTEIN4 Enhances Plant Plasma Membrane H+-ATPase Activity and Inhibits Flagellin-Triggered Immune Responses in Arabidopsis

The Pseudomonas syringae effector AvrB targets multiple host proteins during infection, including the plant immune regulator RPM1-INTERACTING PROTEIN4 (RIN4) and RPM1-INDUCED PROTEIN KINASE (RIPK). In the presence of AvrB, RIPK phosphorylates RIN4 at Thr-21, Ser-160, and Thr-166, leading to activation of the immune receptor RPM1. Here, we investigated the role of RIN4 phosphorylation in susceptible Arabidopsis thaliana genotypes. Using circular dichroism spectroscopy, we show that RIN4 is a disordered protein and phosphorylation affects protein flexibility. RIN4 T21D/S160D/T166D phosphomimetic mutants exhibited enhanced disease susceptibility upon surface inoculation with P. syringae, wider stomatal apertures, and enhanced plasma membrane H⁺-ATPase activity. The plasma membrane H⁺-ATPase AHA1 is highly expressed in guard cells, and its activation can induce stomatal opening. The ripk knockout also exhibited a strong defect in pathogen-induced stomatal opening. The basal level of RIN4 Thr-166 phosphorylation decreased in response to immune perception of bacterial flagellin. RIN4 Thr166D lines exhibited reduced flagellin-triggered immune responses. Flagellin perception did not lower RIN4 Thr-166 phosphorylation in the presence of strong ectopic expression of AvrB. Taken together, these results indicate that the AvrB effector targets RIN4 in order to enhance pathogen entry on the leaf surface as well as dampen responses to conserved microbial features.     

Fusicoccin Binding to Its Plasma Membrane Receptor and the Activation of the Plasma Membrane H+-ATPase : IV. Fusicoccin Induces the Association between the Plasma Membrane H+-ATPase and the Fusicoccin Receptor

Different approaches were utilized to investigate the mechanism by which fusicoccin (FC) induces the activation of the H⁺-ATPase in plasma membrane (PM) isolated from radish (Raphanus sativus L.) seedlings treated in vivo with (FC-PM) or without (C-PM) FC. Treatment of FC-PM with different detergents indicated that PM H⁺-ATPase and the FC-FC-binding-protein (FCBP) complex were solubilized to a similar extent. Fractionation of solubilized FC-PM proteins by a linear sucrose-density gradient showed that the two proteins comigrated and that PM H⁺-ATPase retained the activated state induced by FC. Solubilized PM proteins were also fractionated by a fast-protein liquid chromatography anion-exchange column. Comparison between C-PM and FC-PM indicated that in vivo treatment of the seedlings with FC caused different elution profiles; PM H⁺-ATPase from FC-PM was only partially separated from the FC-FCBP complex and eluted at a higher NaCl concentration than did PM H⁺-ATPase from C-PM. Western analysis of fast-protein liquid chromatography fractions probed with an anti-N terminus PM H⁺-ATPase antiserum and with an anti-14–3-3 antiserum indicated an FC-induced association of FCBP with the PM H⁺-ATPase. Analysis of the activation state of PM H⁺-ATPase in fractions in which the enzyme was partially separated from FCBP suggested that the establishment of an association between the two proteins was necessary to maintain the FC-induced activation of the enzyme.     

Purification of the Plasma Membrane Ca2+-ATPase from Radish Seedlings by Calmodulin-Agarose Affinity Chromatography

The Ca²⁺-ATPase of the plasma membrane (PM) of germinating radish (Raphanus sativus L.) seeds was purified by calmodulin (CaM)-affinity chromatography using a batch procedure. PM purified by aqueous two-phase partitioning was solubilized with n-dodecyl β-d-maltoside and applied to a CaM-agarose matrix. After various washings with decreasing Ca²⁺ concentrations, the Ca²⁺-ATPase was eluted with 5 mm ethylenediaminetetraacetate (EDTA). The EDTA-eluted fraction contained about 25% of the loaded Ca²⁺-ATPase activity, with a specific activity 70-fold higher than that of the starting PM fraction. The EDTA-eluted fraction was highly enriched in a 133-kD polypeptide, which was identified as the PM Ca²⁺-ATPase by ¹²⁵I-CaM overlay and fluorescein-isothiocyanate labeling. The PM Ca²⁺-ATPase cross-reacted with an antiserum against a putative Ca²⁺-ATPase of the Arabidopsis thaliana chloroplast envelope.     

The Two Major Types of Plant Plasma Membrane H+-ATPases Show Different Enzymatic Properties and Confer Differential pH Sensitivity of Yeast Growth

The proton-pumping ATPase (H⁺-ATPase) of the plant plasma membrane is encoded by two major gene subfamilies. To characterize individual H⁺-ATPases, PMA2, an H⁺-ATPase isoform of tobacco (Nicotiana plumbaginifolia), was expressed in Saccharomyces cerevisiae and found to functionally replace the yeast H⁺-ATPase if the external pH was kept above 5.0 (A. de Kerchove d'Exaerde, P. Supply, J.P. Dufour, P. Bogaerts, D. Thinès, A. Goffeau, M. Boutry [1995] J Biol Chem 270: 23828–23837). In the present study we replaced the yeast H⁺-ATPase with PMA4, an H⁺-ATPase isoform from the second subfamily. Yeast expressing PMA4 grew at a pH as low as 4.0. This was correlated with a higher acidification of the external medium and an approximately 50% increase of ATPase activity compared with PMA2. Although both PMA2 and PMA4 had a similar pH optimum (6.6–6.8), the profile was different on the alkaline side. At pH 7.2 PMA2 kept more than 80% of the maximal activity, whereas that of PMA4 decreased to less than 40%. Both enzymes were stimulated up to 3-fold by 100 μg/mL lysophosphatidylcholine, but this stimulation vanished at a higher concentration in PMA4. These data demonstrate functional differences between two plant H⁺-ATPases expressed in the same heterologous host. Characterization of two PMA4 mutants selected to allow yeast growth at pH 3.0 revealed that mutations within the carboxy-terminal region of PMA4 could still improve the enzyme, resulting in better growth of yeast cells.     

A Phosphothreonine Residue at the C-Terminal End of the Plasma Membrane H+-ATPase Is Protected by Fusicoccin-Induced 14–3–3 Binding

We have isolated the plasma membrane H⁺−ATPase in a phosphorylated form from spinach (Spinacia oleracea L.) leaf tissue incubated with fusicoccin, a fungal toxin that induces irreversible binding of 14–3–3 protein to the C terminus of the H⁺-ATPase, thus activating H⁺ pumping. We have identified threonine-948, the second residue from the C-terminal end of the H⁺-ATPase, as the phosphorylated amino acid. Turnover of the phosphate group of phosphothreonine-948 was inhibited by 14–3–3 binding, suggesting that this residue may form part of a binding motif for 14–3–3. This is the first identification to our knowledge of an in vivo phosphorylation site in the plant plasma membrane H⁺-ATPase.     

CDPKs CPK6 and CPK3 Function in ABA Regulation of Guard Cell S-Type Anion- and Ca2+- Permeable Channels and Stomatal Closure

Abscisic acid (ABA) signal transduction has been proposed to utilize cytosolic Ca²⁺ in guard cell ion channel regulation. However, genetic mutants in Ca²⁺ sensors that impair guard cell or plant ion channel signaling responses have not been identified, and whether Ca²⁺-independent ABA signaling mechanisms suffice for a full response remains unclear. Calcium-dependent protein kinases (CDPKs) have been proposed to contribute to central signal transduction responses in plants. However, no Arabidopsis CDPK gene disruption mutant phenotype has been reported to date, likely due to overlapping redundancies in CDPKs. Two Arabidopsis guard cell–expressed CDPK genes, CPK3 and CPK6, showed gene disruption phenotypes. ABA and Ca²⁺ activation of slow-type anion channels and, interestingly, ABA activation of plasma membrane Ca²⁺-permeable channels were impaired in independent alleles of single and double cpk3cpk6 mutant guard cells. Furthermore, ABA- and Ca²⁺-induced stomatal closing were partially impaired in these cpk3cpk6 mutant alleles. However, rapid-type anion channel current activity was not affected, consistent with the partial stomatal closing response in double mutants via a proposed branched signaling network. Imposed Ca²⁺ oscillation experiments revealed that Ca²⁺-reactive stomatal closure was reduced in CDPK double mutant plants. However, long-lasting Ca²⁺-programmed stomatal closure was not impaired, providing genetic evidence for a functional separation of these two modes of Ca²⁺-induced stomatal closing. Our findings show important functions of the CPK6 and CPK3 CDPKs in guard cell ion channel regulation and provide genetic evidence for calcium sensors that transduce stomatal ABA signaling.     

Adaptation of Active Proton Pumping and Plasmalemma ATPase Activity of Corn Roots to Low Root Medium pH

Corn (Zea mays L.) root adaptation to pH 3.5 in comparison with pH 6.0 (control) was investigated in long-term nutrient solution experiments. When pH was gradually reduced, comparable root growth was observed irrespective of whether the pH was 3.5 or 6.0. After low-pH adaptation, H⁺ release of corn roots in vivo at pH 5.6 was about 3 times higher than that of control. Plasmalemma of corn roots was isolated for investigation in vitro. At optimum assay pH, in comparison with control, the following increases of the various parameters were caused by low-pH treatment: (a) hydrolytic ATPase activity, (b) maximum initial velocity and Michaelis constant (c) activation energy of H⁺-ATPase, (d) H⁺-pumping activity, (e) H⁺ permeability of plasmalemma, and (f) pH gradient across the membranes of plasmalemma vesicles. In addition, vanadate sensitivity remained unchanged. It is concluded that plasmalemma H⁺-ATPase contributes significantly to the adaptation of corn roots to low pH. A restricted net H⁺ release at low pH in vivo may be attributed to the steeper pH gradient and enhanced H⁺ permeability of plasmalemma but not to deactivation of H⁺-ATPase. Possible mechanisms responsible for adaptation of plasmalemma H⁺-ATPase to low solution pH during plant cultivation are discussed.     

Hsp30, the integral plasma membrane heat shock protein of Saccharmyces cerevisiae, is a stress-inducible regulator of plasma membrane H+-ATPase

Saccharomyces cerevisiae has a single integral plasma membrane heat shock protein (Hsp). This Hsp30 is induced by several stresses, including heat shock, ethanol exposure, severe osmostress, weak organic acid exposure and glucose limitation, Plasma membrane H⁺-ATPase activities of heat shocked and weak acid-adapted, hsp30 mutant and wild-type cells, revealted that Hsp30 induction leads to a downregulation of the stress-stimulation of this H⁺-ATPase. Plasma membrane H⁺-ATPase activity consumes a substantial fraction of the ATP generated by the cell, a usage that will be increased by the H⁺-ATPase stimulation occurring with several Hsp30-inducing stresses. Hsp30 might therefore provide an energy conservation role, limiting excessive ATP consumption by plasma membrance H⁺-ATPase during prolonged stress exposure or glucose limitation, Consistent with the role of Hsp30 being energy conservation, Hsp30 null cultures give lower final biomass yields. They also have lower ATP levels, consistent with higher H⁺-ATPase activity, at the glucose exhaustion stage of batch fermentations (diauxic lag), when Hsp30 is normally induced. Loss of Hsp30 does not affect several strees tolerances but it extends the time needed for cells to adapt to growth under several stressful conditions where the maintenance of homeostasis will demand an unusually high usage of energy. hsp30 is the first yeast gene identified as both weak organic acid-inducible and assisting the adaptation to growth in the presence of these acids.     

atp Mutants of Escherichia coli Fail To Grow on Succinate Due to a Transport Deficiency

Escherichia coli atp mutants, which lack a functional H⁺-ATPase complex, are capable of growth on glucose but not on succinate or other C₄-dicarboxylates (Suc⁻ phenotype). Suc⁺ revertants of an atp deletion strain were isolated which were capable of growth on succinate even though they lack the entire H⁺-ATPase complex. Complementation in trans with the yhiF gene suppressed the growth of the Suc⁺ mutants on succinate, which implicates the yhiF gene product in the regulation of C₄-dicarboxylate metabolism. Indeed, when the E. coli C₄-dicarboxylate transporter (encoded by the dctA gene) was expressed in trans, the Suc⁻ phenotype of the atp deletion strain reverted to Suc⁺, which shows that the reason why the E. coli atp mutant is unable to grow aerobically on C₄-dicarboxylates is insufficient transport capacity for these substrates.     

MyD88 Intrinsically Regulates CD4 T-Cell Responses

Myeloid differentiation factor 88 (MyD88) is an essential adaptor protein in the Toll-like receptor-mediated innate signaling pathway, as well as in interleukin-1 receptor (IL-1R) and IL-18R signaling. The importance of MyD88 in the regulation of innate immunity to microbial pathogens has been well demonstrated. However, its role in regulating acquired immunity to viral pathogens and neuropathogenesis is not entirely clear. In the present study, we examine the role of MyD88 in the CD4⁺ T-cell response following lymphocytic choriomeningitis virus (LCMV) infection. We demonstrate that wild-type (WT) mice developed a CD4⁺ T-cell-mediated wasting disease after intracranial infection with LCMV. In contrast, MyD88 knockout (KO) mice did not develop wasting disease in response to the same infection. This effect was not the result of MyD88 regulation of IL-1 or IL-18 responses since IL-1R1 KO and IL-18R KO mice were not protected from weight loss. In the absence of MyD88, naïve CD4⁺ T cells failed to differentiate to LCMV-specific CD4 T cells. We demonstrated that MyD88 KO antigen-presenting cells are capable of activating WT CD4⁺ T cells. Importantly, when MyD88 KO CD4⁺ T cells were reconstituted with an MyD88-expressing lentivirus, the rescued CD4⁺ T cells were able to respond to LCMV infection and support IgG2a antibody production. Overall, these studies reveal a previously unknown role of MyD88-dependent signaling in CD4⁺ T cells in the regulation of the virus-specific CD4⁺ T-cell response and in viral infection-induced immunopathology in the central nervous system.     

Innate immunity signaling: cytosolic Ca2+ elevation is linked to downstream nitric oxide generation through the action of calmodulin or a calmodulin-like protein

Ca²⁺ rise and nitric oxide (NO) generation are essential early steps in plant innate immunity and initiate the hypersensitive response (HR) to avirulent pathogens. Previous work from this laboratory has demonstrated that a loss-of-function mutation of an Arabidopsis (Arabidopsis thaliana) plasma membrane Ca²⁺-permeable inwardly conducting ion channel impairs HR and that this phenotype could be rescued by the application of a NO donor. At present, the mechanism linking cytosolic Ca²⁺ rise to NO generation during pathogen response signaling in plants is still unclear. Animal nitric oxide synthase (NOS) activation is Ca²⁺/calmodulin (CaM) dependent. Here, we present biochemical and genetic evidence consistent with a similar regulatory mechanism in plants: a pathogen-induced Ca²⁺ signal leads to CaM and/or a CaM-like protein (CML) activation of NOS. In wild-type Arabidopsis plants, the use of a CaM antagonist prevents NO generation and the HR. Application of a CaM antagonist does not prevent pathogen-induced cytosolic Ca²⁺ elevation, excluding the possibility of CaM acting upstream from Ca²⁺. The CaM antagonist and Ca²⁺ chelation abolish NO generation in wild-type Arabidopsis leaf protein extracts as well, suggesting that plant NOS activity is Ca²⁺/CaM dependent in vitro. The CaM-like protein CML24 has been previously associated with NO-related phenotypes in Arabidopsis. Here, we find that innate immune response phenotypes (HR and [avirulent] pathogen-induced NO elevation in leaves) are inhibited in loss-of-function cml24-4 mutant plants. Pathogen-associated molecular pattern-mediated NO generation in cells of cml24-4 mutants is impaired as well. Our work suggests that the initial pathogen recognition signal of Ca²⁺ influx into the cytosol activates CaM and/or a CML, which then acts to induce downstream NO synthesis as intermediary steps in a pathogen perception signaling cascade, leading to innate immune responses, including the HR.     

SAUR proteins and PP2C.D phosphatases regulate H+-ATPases and K+ channels to control stomatal movements

Activation of plasma membrane (PM) H⁺-ATPase activity is crucial in guard cells to promote light-stimulated stomatal opening, and in growing organs to promote cell expansion. In growing organs, SMALL AUXIN UP RNA (SAUR) proteins inhibit the PP2C.D2, PP2C.D5, and PP2C.D6 (PP2C.D2/5/6) phosphatases, thereby preventing dephosphorylation of the penultimate phosphothreonine of PM H⁺-ATPases and trapping them in the activated state to promote cell expansion. To elucidate whether SAUR–PP2C.D regulatory modules also affect reversible cell expansion, we examined stomatal apertures and conductances of Arabidopsis thaliana plants with altered SAUR or PP2C.D activity. Here, we report that the pp2c.d2/5/6 triple knockout mutant plants and plant lines overexpressing SAUR fusion proteins exhibit enhanced stomatal apertures and conductances. Reciprocally, saur56 saur60 double mutants, lacking two SAUR genes normally expressed in guard cells, displayed reduced apertures and conductances, as did plants overexpressing PP2C.D5. Although altered PM H⁺-ATPase activity contributes to these stomatal phenotypes, voltage clamp analysis showed significant changes also in K⁺ channel gating in lines with altered SAUR and PP2C.D function. Together, our findings demonstrate that SAUR and PP2C.D proteins act antagonistically to facilitate stomatal movements through a concerted targeting of both ATP-dependent H⁺ pumping and channel-mediated K⁺ transport.

SMALL AUXIN UP RNA (SAUR) proteins and PP2C.D phosphatases antagonistically regulate stomatal aperture in Arabidopsis by modulating the activities of plasma membrane H⁺-ATPases and K⁺ channels.     

Reversibility of H+-ATPase and H+-Pyrophosphatase in Tonoplast Vesicles from Maize Coleoptiles and Seeds

Tonoplast-enriched vesicles isolated from maize (Zea mays L.) coleoptiles and seeds synthesize ATP from ADP and inorganic phosphate (Pi) and inorganic pyrophosphate from Pi. The synthesis is consistent with reversal of the catalytic cycle of the H⁺-ATPase and H⁺-pyrophosphatase (PPase) vacuolar membrane-bound enzymes. This was monitored by measuring the exchange reaction that leads to ³²Pi incorporation into ATP or inorganic pyrophosphate. The reversal reactions of these enzymes were dependent on the proton gradient formed across the vesicle membrane and were susceptible to the uncoupler carbonyl cyanide p(trifluoromethoxy)-phenylhydrazone and the detergent Triton X-100. Comparison of the two H⁺ pumps showed that the H⁺-ATPase was more active than H⁺-PPase in coleoptile tonoplast vesicles, whereas in seed vesicles H⁺-PPase activity was clearly dominant. These findings may reflect the physiological significance of these enzymes in different tissues at different stages of development and/or differentiation.     

Role of a mitogen-activated protein kinase cascade in ion flux-mediated turgor regulation in fungi

Fungi normally maintain a high internal hydrostatic pressure (turgor) of about 500 kPa. In response to hyperosmotic shock, there are immediate electrical changes: a transient depolarization (1 to 2 min) followed by a sustained hyperpolarization (5 to 10 min) prior to turgor recovery (10 to 60 min). Using ion-selective vibrating probes, we established that the transient depolarization is due to Ca²⁺ influx and the sustained hyperpolarization is due to H⁺ efflux by activation of the plasma membrane H⁺-ATPase. Protein synthesis is not required for H⁺-ATPase activation. Net K⁺ and Cl⁻ uptake occurs at the same time as turgor recovery. The magnitude of the ion uptake is more than sufficient to account for the osmotic gradients required for turgor to return to its original level. Two osmotic mutants, os-1 and os-2, homologs of a two-component histidine kinase sensor and the yeast high osmotic glycerol mitogen-activated protein (MAP) kinase, respectively, have lower turgor than the wild type and do not exhibit the sustained hyperpolarization after hyperosmotic treatment. The os-1 mutant does not exhibit all of the wild-type turgor-adaptive ion fluxes (Cl⁻ uptake increases, but net K⁺ flux barely changes and net H⁺ efflux declines) (os-2 was not examined). Both os mutants are able to regulate turgor but at a lower level than the wild type. Our results demonstrate that a MAP kinase cascade regulates ion transport, activation of the H⁺-ATPase, and net K⁺ and Cl⁻ uptake during turgor regulation. Other pathways regulating turgor must also exist.     

NaCl-Induced Alternations of Cellular and Tissue Ion Fluxes in Roots of Salt-Resistant and Salt-Sensitive Poplar Species

Using the scanning ion-selective electrode technique, fluxes of H⁺, Na⁺, and Cl⁻ were investigated in roots and derived protoplasts of salt-tolerant Populus euphratica and salt-sensitive Populus popularis 35-44 (P. popularis). Compared to P. popularis, P. euphratica roots exhibited a higher capacity to extrude Na⁺ after a short-term exposure to 50 mm NaCl (24 h) and a long term in a saline environment of 100 mm NaCl (15 d). Root protoplasts, isolated from the long-term-stressed P. euphratica roots, had an enhanced Na⁺ efflux and a correspondingly increased H⁺ influx, especially at an acidic pH of 5.5. However, the NaCl-induced Na⁺/H⁺ exchange in root tissues and cells was inhibited by amiloride (a Na⁺/H⁺ antiporter inhibitor) or sodium orthovanadate (a plasma membrane H⁺-ATPase inhibitor). These results indicate that the Na⁺ extrusion in stressed P. euphratica roots is the result of an active Na⁺/H⁺ antiport across the plasma membrane. In comparison, the Na⁺/H⁺ antiport system in salt-stressed P. popularis roots was insufficient to exclude Na⁺ at both the tissue and cellular levels. Moreover, salt-treated P. euphratica roots retained a higher capacity for Cl⁻ exclusion than P. popularis, especially during a long term in high salinity. The pattern of NaCl-induced fluxes of H⁺, Na⁺, and Cl⁻ differs from that caused by isomotic mannitol in P. euphratica roots, suggesting that NaCl-induced alternations of root ion fluxes are mainly the result of ion-specific effects.Soil salinity causes increasingly agricultural and environmental problems on a worldwide scale, especially in arid areas. When plant roots are subjected to saline environments with high NaCl content, external Na⁺ and Cl⁻ establish a large electrochemical gradient favoring the passive entry of salt ions through a variety of cation and anion channels and/or transporters in the plasma membrane (PM; Blumwald et al., 2000; Hasegawa et al., 2000; White and Broadley, 2001; Roberts, 2006; Demidchik and Maathuis, 2007). The entry and accumulation of toxic ions lead to disruption of ion homeostasis and finally cause secondary stress, e.g. oxidative bursts (Zhu, 2001, 2003). Accordingly, the maintenance of low salt concentration in the cytosol is of great importance for salt adaptation of plants (Greenway and Munns, 1980; Munns and Tester, 2008).Active Na⁺ extrusion to the apoplast or external environment is essential for sustaining Na⁺ homeostasis in the cytosol (Blumwald et al., 2000; Tester and Davenport, 2003; Zhu, 2003; Apse and Blumwald, 2007). PM Na⁺/H⁺ antiporters have been widely considered to play a crucial role in active Na⁺ extrusion under saline conditions (Shi et al., 2000, 2002; Qiu et al., 2002; Martínez-Atienza et al., 2007). NaCl-induced activity of PM Na⁺/H⁺ antiporter has been reported in crop species, tomato (Solanum lycopersicum; Wilson and Shannon, 1995), Arabidopsis (Arabidopsis thaliana; Qiu et al., 2002, 2003), and rice (Oryza sativa; Martínez-Atienza et al., 2007). Furthermore, overexpression of the Na⁺/H⁺ antiporter gene AtSOS1 decreases the accumulation of Na⁺ in transgenic Arabidopsis under NaCl stress (Shi et al., 2003). These PM Na⁺/H⁺ antiporters depend on electrochemical H⁺ gradients, which are generated by PM H⁺-ATPase (Blumwald et al., 2000; Zhu, 2003). Using an ion-selective microelectrode, Shabala and a colleague suggested the involvement of PM H⁺-ATPase in the Na⁺/H⁺ antiport according to H⁺ kinetics on salt shock (Shabala, 2000; Shabala and Newman, 2000). Therefore, the NaCl-induced H⁺ pumping is fundamental to Na⁺/H⁺ exchange and salinity tolerance (Ayala et al., 1996; Vitart et al., 2001; Chen et al., 2007; Gévaudant et al., 2007). However, the active Na⁺/H⁺ antiport across PM and the contribution to salt exclusion have been rarely investigated in tree species.Munns and Tester (2008) claimed that Cl⁻ toxicity is more important than Na⁺ toxicity in some woody species, e.g. citrus. Similarly, we have noticed that the inability to restrict Cl⁻ uptake contributes to the NaCl-induced salt damage in salt-sensitive poplar (Populus spp.) species, in addition to toxicity of excess Na⁺ (Chen et al., 2001, 2002, 2003). The differences in Cl⁻ tolerance exhibited by plants are usually related to the ability to restrict Cl⁻ transport to the aerial part (Greenway and Munns, 1980; White and Broadley, 2001). Excluding Cl⁻ from the xylem seems to be an effective mechanism for lotus to cope with the interactive effect of salt and water logging (Teakle et al., 2007). An influx of Cl⁻, immediately after addition of NaCl, was observed in bean (Vicia faba) mesophyll tissue (Shabala, 2000). The Cl⁻ flux response to salt shock is helpful to reveal the rapid adjustments of plants to salinity. However, Cl⁻ fluxes in salt-adapted roots, which are necessary to clarify plant adaptations to long durations of salinity, have not been examined.Populus euphratica has been widely considered as a model plant to elucidate physiological and molecular mechanisms of salt tolerance in woody species (Chen et al., 2001, 2002, 2003; Gu et al., 2004; Ottow et al., 2005a, 2005b; Junghans et al., 2006; Wang et al., 2007, 2008; Wu et al., 2007; Zhang et al., 2007). Comparative studies have shown that salt-stressed P. euphratica seedlings accumulate less Na⁺ and Cl⁻ in root and shoot tissues than salt-sensitive poplar species (Chen et al., 2001, 2002). It is suggested that the greater capacity to exclude NaCl in P. euphratica is likely the result of salt uptake and transport restriction in roots (Chen et al., 2002, 2003). However, this needs further investigations, e.g. by electrophysiology, to clarify.In this study, we used a noninvasive ion flux technique to measure the tissue and cellular fluxes of H⁺, Na⁺, and Cl⁻ in roots of the salt-tolerant P. euphratica and salt-sensitive P. popularis 35-44. The aim was to compare the NaCl-induced alternations of ion fluxes in poplar species differing in salt tolerance. Furthermore, we examined the effects of pH, salt shock, and PM transport inhibitors on Na⁺ and H⁺ fluxes in root-derived protoplasts of the salt-tolerant species, P. euphratica, which exhibited an evident Na⁺ exclusion under saline conditions.     

Summary

The plasma membrane H⁺-ATPase in higher plants has been implicated in nutrient uptake, phloem loading, elongation growth and establishment of turgor. Although a C-terminal regulatory domain has been identified, little is known about the physiological factors involved in controlling the activity of the enzyme. To identify components which play a role in the regulation of the plant H⁺-ATPase, a fusicoccin responsive yeast expressing Arabidopsis plasma membrane H⁺-ATPase AHA2 was employed. By testing the fusicoccin binding activity of yeast membranes, the C-terminal regulatory domain of AHA2 was found to be part of a functional fusicoccin receptor, a component of which was the 14–3-3 protein. ATP hydrolytic activity of AHA2 expressed in yeast internal membranes was activated by all tested isoforms of the 14–3-3 protein of yeast and Arabidopsis, but only in the presence of fusicoccin, and activation was prevented by a phosphoserine peptide representing a known 14–3-3 protein binding motif in Raf-1. The results demonstrate that the 14–3-3 protein is an activator molecule of the H⁺-ATPase and provides the first evidence of a protein involved in activation of plant plasma membrane H⁺-ATPase.