MEK1/2 and p38-like MAP kinase successively mediate H2O2 signaling in Vicia guard cell

As a second messenger, H₂O₂ generation and signal transduction is subtly controlled and involves various signal elements, among which are the members of MAP kinase family. The increasing evidences indicate that both MEK1/2 and p38-like MAP protein kinase mediate ABA-induced H₂O₂ signaling in plant cells. Here we analyze the mechanisms of similarity and difference between MEK1/2 and p38-like MAP protein kinase in mediating ABA-induced H₂O₂ generation, inhibition of inward K⁺ currents, and stomatal closure. These data suggest that activation of MEK1/2 is prior to p38-like protein kinase in Vicia guard cells.Key words: H₂O₂ signaling, ABA, p38-like MAP kinase, MEK1/2, guard cellAn increasing number of literatures elucidate that reactive oxygen species (ROS), especially H₂O₂, is essential to plant growth and development in response to stresses,^1–4 and involves activation of various signaling events, among which are the MAP kinase cascades.^1–3,5 Typically, activation of MEK1/2 mediates NADPH oxidase-dependent ROS generation in response to stresses,^4,6–8 and the facts that MEK1/2 inhibits the expression and activation of antioxidant enzymes reveal how PD98059, the specific inhibitor of MEK1/2, abolishes abscisic acid (ABA)-induced H₂O₂ generation.^6,8,9 It has been indicated that PD98059 does not to intervene on salicylic acid (SA)-stimulated H₂O₂ signaling regardless of SA mimicking ABA in regulating stomatal closure.^2,6,8,10 Generally, activation of MEK1/2 promotes ABA-induced stomatal closure by elevating H₂O₂ generation in conjunction with inactivating anti-oxidases.Moreover, activation of plant p38-like protein kinase, the putative counterpart of yeast or mammalian p38 MAP kinase, has been reported to participate in various stress responses and ROS signaling. It has been well documented that p38 MAP kinase is involved in stress-triggered ROS signaling in yeast or mammalian cells.^11–13 Similar to those of yeast and mammals, many studies showed the activation of p38-like protein kinase in response to stresses in various plants, including Arabidopsis thaliana,^14–16 Pisum sativum,¹⁷ Medicago sativa¹⁸ and tobacco.¹⁹ The specific p38 kinase inhibitor SB203580 was found to modulate physiological processes in plant tissues or cells, such as wheat root cells,²⁰ tobacco tissue²¹ and suspension-cultured Oryza sativa cells.²² Recently, we investigate how activation of p38-like MAP kinase is involved in ABA-induced H₂O₂ signaling in guard cells. Our results show that SB203580 blocks ABA-induced stomatal closure by inhibiting ABA-induced H₂O₂ generation and decreasing K⁺ influx across the plasma membrane of Vicia guard cells, contrasting greatly with its analog SB202474, which has no effect on these events.^23,24 This suggests that ABA integrate activation of p38-like MAP kinase and H₂O₂ signaling to regulate stomatal behavior. In conjunction with SB203580 mimicking PD98059 not to mediate SA-induced H₂O₂ signaling,^23,24 these results generally reveal that the activation of p38-like MAP kinase and MEK1/2 is similar in guard cells.On the other hand, activation of p38-like MAP kinase^23,24 is not always identical to that of MEK1/2^8,25 in ABA-induced H₂O₂ signaling of Vicia guard cells. For example, H₂O₂^- and ABA-induced stomatal closure was partially reversed by SB203580. The maximum inhibition of both regent-induced stomatal closure were observed at 2 h after treatment with SB203580, under which conditions the stomatal apertures were 89% and 70% of the control values, respectively. By contrast, when PD98059 was applied together with ABA or H₂O₂, the effects of both ABA- and H₂O₂-induced stomatal closure were completely abolished (Fig. 1). These data imply that the two members of MAP kinase family are efficient in H₂O₂-stimulated stomatal closure, but p38-like MAP kinase is less susceptive than MEK1/2 to ABA stimuli.Open in a separate windowFigure 1Effects of SB203580 and PD98059 on ABA- and H₂O₂-induced stomatal closure. The experimental procedure and data analysis are according to the previous publication.^8,23,24It has been reported that ABA or NaCl activate p38 MAP kinase in the chloronema cells of the moss Funaria hygrometrica in 2∼10 min.²⁶ Similar to this, SB203580 improves H₂O₂-inhibited inward K⁺ currents after 4 min and leads it to the control level (100%) during the following 8 min (Fig. 2). However, the activation of p38-like MAP kinase in response to ABA need more time, and only recovered to 75% of the control at 8 min of treatment (Fig. 2). These results suggest that control of H₂O₂ signaling is required for the various protein kinases including p38-like MAP kinase and MEK1/2 in guard cells,^1,2,8,23,24 and the ABA and H₂O₂ pathways diverge further downstream in their actions on the K⁺ channels and, thus, on stomatal control. Other differences in action between ABA and H₂O₂ are known. For example, Köhler et al. (2001) reported that H₂O₂ inhibited the K⁺ outward rectifier in guard cells shows that H₂O₂ does not mimic ABA action on guard cell ion channels as it acts on the K⁺ outward rectifier in a manner entirely contrary to that of ABA.²⁷Open in a separate windowFigure 2Effect of SB203580 on ABA- and H₂O₂-inhibited inward K⁺ currents. The experimental procedure and data analysis are according to the previous publication.²⁴ SB203580 directs ABA- and H₂O₂-inactivated inward K⁺ currents across plasma membrane of Vicia guard cells. Here the inward K⁺ currents value is stimulated by −190 mV voltage.Based on the similarity and difference between PD98059 and SB203580 in interceding ABA and H₂O₂ signaling, we speculate the possible mechanism is that the member of MAP kinase family specially regulate signal event in ABA-triggered ROS signaling network,^1–4 and the signaling model as follows (Fig. 3).Open in a separate windowFigure 3Schematic illustration of MAP kinase-mediated H₂O₂ signaling of guard cells. The arrows indicate activation. The line indicates enhancement and the bar denotes inhibition.     

Prions: En route from structural models to structures

The prion hypothesis^1–3 states that the prion and non-prion form of a protein differ only in their 3D conformation and that different strains of a prion differ by their 3D structure.^4,5 Recent technical developments have enabled solid-state NMR to address the atomic-resolution structures of full-length prions, and a first comparative study of two of them, HET-s and Ure2p, in fibrillar form, has recently appeared as a pair of companion papers.^6,7 Interestingly, the two structures are rather different: HET-s features an exceedingly well-ordered prion domain and a partially disordered globular domain. Ure2p in contrast features a very well ordered globular domain with a conserved fold, and—most probably—a partially ordered prion domain.⁶ For HET-s, the structure of the prion domain is characterized at atomic-resolution. For Ure2p, structure determination is under way, but the highly resolved spectra clearly show that information at atomic resolution should be achievable.Key words: prion, NMR, solid-state NMR, MAS, structure, Ure2p, HET-sDespite the large interest in the basic mechanisms of fibril formation and prion propagation, little is known about the molecular structure of prions at atomic resolution and the mechanism of propagation. Prions with related properties to the ones responsible for mammalian diseases were also discovered in yeast and funghi^8,9 which provide convenient model system for their studies. Prion proteins described include the mammalian prion protein PrP, Ure2p,¹⁰ Rnq1p,¹¹ Sup35,¹² Swi1,¹³ and Cyc8,¹⁴ from bakers yeast (S. cervisiae) and HET-s from the filamentous fungus P. anserina. The soluble non-prion form of the proteins characterized in vitro is a globular protein with an unfolded, dynamically disordered N- or C-terminal tail.^15–18 In the prion form, the proteins form fibrillar aggregates, in which the tail adopts a different conformation and is thought to be the dominant structural element for fibril formation.Fibrills are difficult to structurally characterize at atomic resolution, as X-ray diffraction and liquid-state NMR cannot be applied because of the non-crystallinity and the mass of the fibrils. Solid-state NMR, in contrast, is nowadays well suited for this purpose. The size of the monomer, between 230 and 685 amino-acid residues for the prions of Figure 1, and therefore the number of resonances in the spectrum—that used to be large for structure determination—is now becoming tractable by this method.Open in a separate windowFigure 1Prions identified today and characterized as consisting of a prion domain (blue) and a globular domain (red).Prion proteins characterized so far were found to be usually constituted of two domains, namely the prion domain and the globular domain (see Fig. 1). This architecture suggests a divide-and-conquer approach to structure determination, in which the globular and prion domain are investigated separately. In isolation, the latter, or fragments thereof, were found to form β-sheet rich structures (e.g., Ure2p(1-89),^6,19 Rnq1p(153-405)²⁰ and HET-s(218-289)²¹). The same conclusion was reached by investigating Sup35(1-254).²² All these fragements have been characterized as amyloids, which we define in the sense that a significant part of the protein is involved in a cross-beta motif.²³ An atomic resolution structure however is available presently only for the HET-s prion domain, and was obtained from solid-state NMR²⁴ (vide infra). It contains mainly β-sheets, which form a triangular hydrophobic core. While this cross-beta structure can be classified as an amyloid, its triangular shape does deviate significantly from amyloid-like structures of smaller peptides.²³Regarding the globular domains, structures have been determined by x-ray crystallography (Ure2p^25,26 and HET-s²⁷), as well as NMR (mammal prions^15,28–30). All reveal a protein fold rich in α-helices, and dimeric structures for the Ure2 and HET-s proteins. The Ure2p fold resembles that of the β-class glutathione S-transferases (GST), but lacks GST activity.²⁵It is a central question for the structural biology of prions if the divide-and-conquer approach imposed by limitations in current structural approaches is valid. Or in other words: can the assembly of full-length prions simply be derived from the sum of the two folds observed for the isolated domains?     

Hydrogen sulfide effects on stomatal apertures

Hydrogen sulfide (H₂S) has recently been reported to be a signaling molecule in plants. It has been well established that is has such roles in animals and it has been suggested that it is included into the group of gasotransmitters. We have recently shown that hydrogen sulfide causes stomatal opening in the model plant Arabidopsis thaliana. H₂S can be supplied to the plant tissues from donors such as sodium hydrosulfide (NaSH) or more recently from slow release H₂S donor molecules such as GYY4137. Both give similar effects, that is, they cause stomatal opening. Furthermore both H₂S donors reduced the accumulation of nitric oxide (NO) induced by abscisic acid (ABA) treatment of leaf tissues. Here similar work has been repeated in a crop plant, Capsicum anuum, and similar data has been obtained, suggesting that such effects of hydrogen sulfide on plants is not confined to model species.Key words: abscisic acid, GYY4137, hydrogen sulfide, nitric oxide, stomatal apertureThe effects of hydrogen sulfide on plants have been studied for many years, but it is only recently that it has been suggested that this gas is acting as a signaling molecule. In animals this has been well established^1,2 and it has been suggested that H₂S be grouped together with other gasotransmitters.^2,3 This group will also contain nitric oxide (NO) which as well as having established roles in animals is also known to cause stomatal closure in plants.^4,5 With this in mind, we previously investigated whether H₂S may also have an effect on stomatal closure, using a model organism Arabidopsis thaliana.⁶ The study used two different H₂S donors, sodium hydrosulfide (NaSH) and morpholin-4-ium 4 methoxyphenyl(morpholino) phosphinodithionate (GYY4137). The former will release H₂S in an instant burst which soon dissipates, which questions the wisdom of its use. GYY4137 on the other hand will release H₂S much more slowly and in a manner which is more likely to reflect physiological generation of H₂S.^7,8 Both donors caused stomatal that had previously been exposed to light to open even further. If leaf tissues were not light treated H₂S compounds once again caused stomata to open. Furthermore, H₂S treatment prevented stomatal closure caused by dark treatment. To investigate the possible mechanism of this effect, tissues were treated with the plant hormone abscisic acid (ABA) to initiate NO generation and then NO accumulation was measured in the absence and presence of H₂S donors using fluorescent probes and confocal microscopy.⁹ Both NaSH and GYY4137 caused a reduction in the accumulation of NO. This suggests that H₂S may be acting by a disruption of NO signaling, which results in the alteration of guard cell physiology.Others have reported different effects of H₂S on stomatal movements. Garcia-Mata and Lamattina¹⁰ found that both H₂S donors NaSH and GY4137 caused stomatal closure in different plant species including Vicia faba, Arabidopsis thaliana and Impatiens walleriana. Use of glibenclamide, which is an ABC transport inhibitor, reduced the effect. Cystathione γ lyase and L-Cys desulfhydrase are enzymes which may be responsible for H₂S synthesis and stomatal movements were also reduced by propargylglycine, an inhibitor of these enzymes. It was suggested therefore that H₂S helps to mediate ABA signaling pathway in guard cells. This paper was further discussed following its publication by Desikan.¹¹ However, this seems to be in conflict with the work we reported. This would not be the first time that there has been contradictory data when it comes to reporting stomatal movements, as ethylene has been shown to mediate auxin-induced opening¹² and to cause stomatal closure.¹³More recently it has been reported that stomatal conductance was increased by carbonyl sulfide (COS).¹⁴ The authors went on to suggest that this effect was mediated by H₂S which was produced from COS hydrolysis. This seems to support our original data. Therefore, here we report on the effects of both NaSH and GYY4137 on a different plant species and one which has relevance as an important crop, that is Capsicum anuum. GYY4137 was supplied as in our previous paper in reference ⁶ and ⁷. As can be seen in Figure 1A NaSH caused stomata to open further, even though the leaf tissue had been exposed to the light. Stomata were able to close, as ABA treatment demonstrated, therefore showing that the stomata were not defective. When the experiments were repeated with GYY4137 (Fig. 1B) and smaller but similar effect of the addition of the H₂S donor was seen. This would be expected as the release of H₂S from GYY4137 would be slower and more prolonged than from NaSH.^7,8 To investigate if NO accumulation is also effected in Capsicum when treated with H₂S donors, leaf tissue was treated with ABA to initiate NO generation and NO measured by the use of DAF2-DA as previously reported in references ⁶ and ⁹. Once again the presence of H₂S donors dramatically reduced the amount of NO that was measured following ABA treatment (Fig. 2). This once again suggests that H₂S is having an effect on NO metabolism which may account for the stomata aperture measurements. It has been suggested in animal systems that H₂S and NO react, resulting in the formation of nitrosothiols/nitrothiol-like species¹⁵ which could have signaling effects in their own right. NO in plants has been reported to lead to increased cGMP and/or increased nitrosylation of proteins,⁵ but if H₂S was removing the bioavailability of NO both mechanisms are likely to be reduced.Open in a separate windowFigure 1H₂S donors cause stomatal opening in Capsicum anuum. The leaves of analyzed from Capsicum anuum plants which were between 6 and 7 weeks old. Stomatal bioassays were performed as described previously by Desikan et al.⁹ Epidermal peels were incubated in MES-KCl buffer [10 mM 2-morpholino ethane sulfonic acid (MES), 5 mM KCl, 50 µM CaCl₂, pH 6.15] for 2.5 h exposed to the direct lightning (in 60–100 IE m⁻² s⁻¹) before the addition of various compounds. (A) Samples were sheltered from direct lighting and treated with ABA or NaHS for 2.5 h and left under the day light conditions before stomata apertures were analyzed. (B) Samples were sheltered from direct lighting and treated with ABA or GYY 4137 for next 2 h and left under the day light conditions before stomata apertures were analyzed. Apertures were measured using a light microscope and imaging camera with LEICA QWIN image processing and analysis software (Leica Microsystems and Imaging Solutions, Cambridge, UK). n = 40 stomatal apertures, ±SE. GYY4137 was synthesis as previously described in reference ⁷.Open in a separate windowFigure 2H₂S donors reduce NO accumulation in Capsicum anuum. Nitric oxide accumulation was estimated using the specific NO dye DAF2-DA (Calbiochem, Nottingham, UK), using the method described previously by Desikan et al.⁹ Epidermal fragments in MES-KCl buffer (10 mM MES, 5 mM KCl, 50 µM CaCl₂, pH 6.15) were exposed to the direct lightning for 2 h. After 2 h samples were loaded with 30 µM DAF2-DA for 15 min before washing with MES-KCl buffer; three times for 10 min. Fragments were subsequently incubated for a further 30 min in the presence of various compounds (as indicated below) before images were visualized using CLSM (excitation 488 nm, emission 515 nm; Nikon PCM2000, Kingston-upon-Thames, UK). Images acquired were analyzed using SCION IMAGE software (Scion, Frederick, MD, USA). (A) Control with no treatment; (B) ABA (50) treatment; (C) NaHS (100 µm) treatment alone; (D) ABA treatment in the presence of NaHS; (E) GYY4137 (100 µm) treatment alone; (F) ABA treatment in the presence of NaHS.NO metabolism is involved in a wide range of plant functions, including seed germination,¹⁶ floral development,¹⁷ root gravitropism¹⁸ and gene expression¹⁹ as well as controlling stomatal function.⁴ H₂S on the other hand may be present in or around plants for a variety to reasons. H₂S can be produced endogenously by for example by plastid located cysteine desulfhydrases,²⁰ or H₂S may come from the environment,²¹ including the soil and waters.²² This is further discussed in a recent review in reference ²³. Therefore future work should be focused on the interplay between H₂S from a variety of sources on the NO metabolism of a range of plant tissues. Not all affects of H₂S will be mediated by NO, with alterations of glutathione on H₂S treatment being reported for example.²⁴ But the full extent of the modulation of NO accumulation and signal by both exogenous and endogenous H₂S needs to be explored so the role of these gasotransmitters^2,3 in mediating hormone and stress responses in plants can be fully understood.     

pH signature for the responses of arbuscular mycorrhizal fungi to external stimuli

Environmental and developmental signals can elicit differential activation of membrane proton (H⁺) fluxes as one of the primary responses of plant and fungal cells. In recent work,¹ we could determine that during the presymbiotic growth of arbuscular mycorrhizal (AM) fungi specific domains of H⁺ flux are activated by clover root factors, namely host root exudates or whole root system. Consequently, activation on hyphal growth and branching were observed and the role of plasma membrane H⁺-ATPase was investigated. The specific inhibitors differentially abolished most of hyphal H⁺ effluxes and fungal growth. As this enzyme can act in signal transduction pathways, we believe that spatial and temporal oscillations of the hyphal H⁺ fluxes could represent a pH signature for both early events of the AM symbiosis and fungal ontogeny.Key words: H⁺-specific vibrating probe, pH signatures, arbuscular mycorrhiza, pH signalling, Gigaspora margaritaThe 450-million-year-old symbiosis between the majority of land plants and arbuscular mycorrhizal (AM) fungi is one of the most ancient, abundant and ecologically important symbiosis on Earth.^2,3The development of AM interaction starts before the physical contact between the host plant roots and the AM fungus. The hyphal growth and branching are induced by the root factors exudated by host plants, followed by the formation of appressorium leading to the hyphal penetration in the root system. These root factors seems to be specifically synthesized by host plants, since exudates from non-host plants are not able to promote neither hyphal differentiation nor appressorium formation.^4,5 Most root exudates contain several host signals or better, active compounds including flavonoids^6,19 and strigolactones,^7,8 however many of them are not yet known.Protons (H⁺) may have an important role on the fungal growth and host signal perception.¹ In plant and fungal cells, H⁺ can be pumped out through two different mechanisms: (1) the activity of the P-type plasma membrane (PM) H⁺-ATPase⁹ and (2) PM redox reactions.¹⁰ The proportional contribution from both mechanisms is not known, but in most plant cells the PM H⁺-ATPase seems to be the major responsible by the H⁺ efflux across plasma membrane. AM Fungal cells also energize their PM using P-type H⁺-pumps quite similar to the plant ones. Indeed, some genes codifying isoforms of P-type H⁺-ATPase have been isolated of AM fungi,^11–13 and AM fungal ATP hydrolysis activity was shown by cytochemistry, localized mainly in the first 70 µm from the germ tube tip.¹⁴ This structural evidence correlates with data obtained by H⁺-specific vibrating probe (Fig. 1A and B), which indicates that the H⁺ efflux in Gigaspora margarita is more intense in the subapical region of the lateral hyphae¹ (Fig. 1A). Furthermore, the correlation between the cytosolic pH profile previously obtained by Jolicoeur et al.,¹⁵ with the H⁺ efflux pattern (erythrosine-dependent), seems to clearly indicate that an active PM H⁺-ATPase takes place at the subapical hyphal region. Using orthovanadate, we could show that those H⁺ effluxes are susceptible mainly in the subapical region, but no effect in the apical was found.¹ Recently, a method to use fluorescent marker expression in an AM fungus driven by arbuscular mycorrhizal promoters was published.³¹ It could be adjusted as an alternative to measure “in vivo” PM H⁺-ATPase expression in AM fungal hyphae and their responses to root factors.³¹Open in a separate windowFigure 1(A) H⁺ flux profile along growing secondary hyphae of G. margarita in the presence (open squares) or absence (closed squares) of erythrosin B and its correlation with cytosolic pH (pHc) data described by Jolicoeur et al.,¹⁵ (dotted line). Dotted area depicts the region with higher susceptibility to erythrosin B. (B) ion-selective electrode near to AM fungal hyphae. (C) Stimulation on hyphal H⁺ efflux after incubation with root factors or whole root system. R, roots; RE, root exudates; CO₂, carbon dioxide; CWP, cell wall proteins; GR24, synthetic strigolactone. The medium pH in all treatment was monitored and remained about 5.7, including with prior CO₂ incubation. Means followed by the same letter are statistically equal by Duncan''s test at p < 5%.The H⁺ electrochemical gradient generated by PM H⁺-ATPases provides not only driving force for nutrient uptake,^9,16 but also can act as an intermediate in signal transduction pathways.¹⁸ The participation of these H⁺ pumps in cell polarity and tip growth of plant cells was recently reported,²⁷ addressing their crucial role on apical growth.²⁸ Naturally, in the absence of root factors the AM fungi have basal metabolic^8,21–23 and respiratory activity.²⁴ However when root signals are recognized and processed by AM fungal cells they might become activated.²² We thus searched for pH signatures that could reflect the alterations on fungal metabolism in response to external stimuli. In fact, preliminary analyses from our group demonstrate that AM fungal hyphae increase their H⁺ efflux in response not only to root exudates recognition, but also to other root factors (Fig. 1C). The incubation for 30 min of AM fungal hyphae with several root factors induces hyphal H⁺ efflux similar to the response to intact root system (5 days of incubation). The major increases were found with 1% CO₂ (750%) followed by root cell wall proteins (221%), root exudates (130%) and synthetic strigolactone (5%) (Fig. 1C). Those stimulations could define the transition from the state without root signals to the presymbiotic developmental stage (Fig. 1C). In the case of CO₂, the incorporation of additional carbon could represent a new source of energy, since CO₂ dark fixation takes place in Glomus intraradices germ tubes.^22,25Interestingly, after the treatment with synthetic strigolactone (10⁻⁵ M GR24), no significant stimulation was found compared to the remaining factors (Fig. 1C). It opens the question if the real effect of strigolactone is restrict to hyphal branching and does not intervene in very fast response pathways. Likewise, strigolactones need additional time to exhibit an effect, as recently discussed by Steinkellner et al.,²⁶ However, at the moment, no comprehensive electrophysiological analyses are presently available separating the effects of strigolactone and some flavonoids in AM fungal hyphae.The next target of our work is the study of ionic responses of single germ tubes or primary hyphae to root factors (Fig. 2). As reported by Ramos et al.,¹ we have been observing that the pattern of ion fluxes at the apical zone of primary hyphae is differentiated from secondary or lateral hyphae. In the primary, two interesting responses were detected in the absence of root factors: (1) a “dormant Ca²⁺ flux” and (2) Cl⁻ or anion fluxes at the same direction of H⁺ ions, suggesting a possible presence of H⁺/Cl⁻ symporters at the apex, similarly to what occurs in root hairs (Fig. 2).³⁰ In the presence of root factors such as root exudates the stimulated influxes of Cl⁻ (anion), H⁺, Na⁺ and effluxes of K⁺ and Ca²⁺ are activated. It can explain why the AM fungi hyphal tips are depolarized^20,29 during the period without root signals—“asymbiosis”—as long as K⁺ efflux and H⁺ influx occur simultaneously. Indeed, H⁺ as well as Ca²⁺ ions may act as second messengers, where extra and intracellular transient pH changes are preconditions for a number of processes, including gravity responses and possibly in plant-microbe interactions.^17,30Open in a separate windowFigure 2Ion dynamics in the apex of primary hyphae of arbuscular mycorrhizal fungi. It represents the Stage 1 described in Ramos et al.¹ After treatment with root factors, an activation of Ca²⁺ efflux is observed at the hyphal apex.Clearly, further data on the mechanism of action of signaling molecules such as strigolactones over the signal transduction and ion dynamics in AM fungi will be very important to improve our understanding of the molecular bases of the mycorrhization process. Future studies are necessary in order to provide basic knowledge of the ion signaling mechanisms and their role on the response of very important molecules playing at the early events of AM symbiosis.     

Why have chloroplasts developed a unique motility system?

Organelle movement in plants is dependent on actin filaments with most of the organelles being transported along the actin cables by class XI myosins. Although chloroplast movement is also actin filament-dependent, a potential role of myosin motors in this process is poorly understood. Interestingly, chloroplasts can move in any direction and change the direction within short time periods, suggesting that chloroplasts use the newly formed actin filaments rather than preexisting actin cables. Furthermore, the data on myosin gene knockouts and knockdowns in Arabidopsis and tobacco do not support myosins'' XI role in chloroplast movement. Our recent studies revealed that chloroplast movement and positioning are mediated by the short actin filaments localized at chloroplast periphery (cp-actin filaments) rather than cytoplasmic actin cables. The accumulation of cp-actin filaments depends on kinesin-like proteins, KAC1 and KAC2, as well as on a chloroplast outer membrane protein CHUP1. We propose that plants evolved a myosin XI-independent mechanism of the actin-based chloroplast movement that is distinct from the mechanism used by other organelles.Key words: actin, Arabidopsis, blue light, kinesin, myosin, organelle movement, phototropinOrganelle movement and positioning are pivotal aspects of the intracellular dynamics in most eukaryotes. Although plants are sessile organisms, their organelles are quickly repositioned in response to fluctuating environmental conditions and certain endogenous signals. By and large, plant organelle movements and positioning are dependent on actin filaments, although microtubules play certain accessory roles in organelle dynamics.^1,2 Actin inhibitors effectively retard the movements of mitochondria,^3–6 peroxisomes,^5,7–11 Golgi stacks,^12,13 endoplasmic reticulum (ER),^14,15 and nuclei.^16–18 These organelles are co-aligned and associated with actin filaments.^{5,7,8,10–12,15,18} Recent progress in this field started to reveal the molecular motility system responsible for the organelle transport in plants.¹⁹Chloroplast movement is among the most fascinating models of organelle movement in plants because it is precisely controlled by ambient light conditions.^20,21 Weak light induces chloroplast accumulation response so that chloroplasts can capture photosynthetic light efficiently (Fig. 1A). Strong light induces chloroplast avoidance response to escape from photodamage (Fig. 1B).²² The blue light-induced chloroplast movement is mediated by the blue light receptor phototropin (phot). In some cryptogam plants, the red light-induced chloroplast movement is regulated by a chimeric phytochrome/phototropin photoreceptor neochrome.^23–25 In a model plant Arabidopsis, phot1 and phot2 function redundantly to regulate the accumulation response,²⁶ whereas phot2 alone is essential for the avoidance response.^27,28 Several additional factors regulating chloroplast movement were identified by analyses of Arabidopsis mutants deficient in chloroplast photorelocation.^29–32 In particular, identification of CHUP1 (chloroplast unusual positioning 1) revealed the connection between chloroplasts and actin filaments at the molecular level.²⁹ CHUP1 is a chloroplast outer membrane protein capable of interacting with F-actin, G-actin and profilin in vitro.^29,33,34 The chup1 mutant plants are defective in both the chloroplast movement and chloroplast anchorage to the plasma membrane,^22,29,33 suggesting that CHUP1 plays an important role in linking chloroplasts to the plasma membrane through the actin filaments. However, how chloroplasts move using the actin filaments and whether chloroplast movement utilizes the actin-based motility system similar to other organelle movements remained to be determined.Open in a separate windowFigure 1Schematic distribution patterns of chloroplasts in a palisade cell under different light conditions, weak (A) and strong (B) lights. Shown as a side view of mid-part of the cell and a top view with three different levels (i.e., top, middle and bottom of the cell). The cell was irradiated from the leaf surface shown as arrows. Weak light induces chloroplast accumulation response (A) and strong light induces the avoidance response (B).Here, we review the recent findings pointing to existence of a novel actin-based mechanisms for chloroplast movement and discuss the differences between the mechanism responsible for movement of chloroplasts and other organelles.     

Voltage,reactive oxygen species and the influx of calcium

The apical plasma membrane of young Arabidopsis root hairs has recently been found to contain a depolarisation-activated Ca²⁺ channel, in addition to one activated by hyperpolarisation. The depolarisation-activated Ca²⁺ channel may function in signalling but the possibility that the root hair apical plasma membrane voltage may oscillate between a hyperpolarized and depolarized state suggests a role in growth control. Plant NADPH oxidase activity has yet to be considered in models of oscillatory voltage or ionic flux despite its predicted electrogenicity and voltage dependence. Activity of root NADPH oxidase was found to be stimulated by restricting Ca²⁺ influx, suggesting that these enzymes are involved in sensing Ca²⁺ entry into cells.Key words: calcium, channel, NADPH oxidase, oscillation, root hairElevation of cytosolic free Ca²⁺ ([Ca²⁺]_cyt) encodes plant cell signals.¹ Reactive oxygen species (ROS) are potent regulators of the PM Ca²⁺ channels implicated in signalling and developmental increases in [Ca²⁺]_cyt.^1,2 Plasma membrane (PM) voltage (V_m) also plays a significant part in generating specific [Ca²⁺]_cyt elevations through the opening of voltage-gated Ca²⁺-permeable channels, allowing Ca²⁺ influx.^1,3 Patch clamp electrophysiological studies on the root hair apical PM of Arabidopsis have revealed co-localisation of hyperpolarisation-activated Ca²⁺ channels (HACCs),⁴ ROS-activated HACCs⁵ and depolarisation-activated Ca²⁺ channels (DACCs).⁶ The DACC characterisation pointed to the presence of a Cl⁻-permeable conductance that was activated by moderate hyperpolarisation (−160 mV) but rapidly inactivated when the voltage was maintained at such negative values.⁶ This may be the R-type anion efflux conductance previously described in Arabidopsis root hair and root epidermal PM.⁷ Previous studies have shown that root hair PM also harbors K⁺ channels (mediating inward or outward flux)^8–10 and a H⁺-ATPase.¹¹ A key problem to address now is how these transporters interact to generate and be influenced by PM V_m, thus gating and in turn being regulated by their companion Ca²⁺ channels to encode developmental and environmental signals at the hair apex.A seminal study on the relationship between V_m and ionic fluxes in wheat root protoplasts not only confirmed oscillatory events but also determined that the PM can exist in three distinct states.¹² In the “pump state” the H⁺-ATPase predominates, there is net H⁺ efflux and the hyperpolarized V_m is negative of the equilibrium potential for K⁺ (E_K). In the “K state”, K⁺ permeability predominates but there is still net H⁺ efflux and V_m = E_K. In the third state, there is net H⁺ influx and V_m > E_K. In this depolarized H⁺-influx state, the H⁺-ATPase is thought to be inactive. Oscillations in PM V_m and H⁺ flux may be more profound in growing cells^13,14 and oscillations between these states may explain the temporal changes in H⁺ flux recently observed at the apex of growing Arabidopsis root hairs.¹⁵ Peaks of H⁺ influx may reflect a depolarized V_m that could activate DACC, suggesting that DACC would play a significant role in growth regulation. The view has arisen that the HACC would be the main driver of growth, primarily because in patch clamp assays its current is greater than DACC^4–6 and because resting V_m is usually found to be hyperpolarized. In a growing cell, with a V_m oscillating between a hyperpolarized and depolarized state, a DACC could just as well be a driver of growth given that the Ca²⁺ influx it permits could be amplified through intracellular release.The PM H⁺-ATPase traditionally lies at the core of models of voltage and ionic flux^14,16 but in terms of [Ca²⁺]_cyt regulation, the activity of PM NADPH oxidases must also now be considered. The Arabidopsis root hair apical PM also contains an NADPH oxidase (AtrbohC) that catalyses extracellular superoxide production.⁵ AtrbohC is implicated in the transition to polar growth at normal extracellular pH⁵ and also osmoregulation.¹⁷ NADPH oxidases catalyse the transport of electrons out of the cell and thus, in common with PM redox e⁻ efflux systems,¹⁸ their activity would depolarize the membrane voltage unless countered by cation efflux or anion influx.¹⁹ Two H⁺ would also be released into the cytosol for every NADPH used. The voltage-dependence of plant NADPH oxidases is unknown but e⁻ efflux by animal NADPH oxidases is fairly constant over negative V_m and decreases at very depolarized V_m.²⁰ AtrbohC is implicated in generating oscillatory ROS at the root hair apex and loss of function affects magnitude and duration of apical H⁺ flux oscillations.¹⁵ The latter suggests that AtrbohC function does in some way affect V_m, a situation extending to other root cell types (such as the epidermis) expressing NADPH oxidases.²¹NADPH oxidase activity in roots is under developmental control but also responds to anoxia and nutrient deficiency^22,23 to signal stress conditions. Blockade of PM Ca²⁺ channels by lanthanides increases superoxide production in tobacco suspension cells.²⁴ This suggests that NADPH oxidases are involved in sensing the cell''s Ca²⁺ status and the prediction would be that extracellular Ca²⁺ chelation would increase their activity. To test this, superoxide anion production by excised Arabidopsis roots was measured using reduction of the tetrazolium dye XTT (Sodium, 3′-[1-[phenylamino-carbonyl]-3,4-tetrazolium]-bis(4-methoxy-6-nitro) benzene-sulphonic acid).^25,26 Lowering extracellular Ca²⁺ from 0.5 mM to 1.4 µM by addition of 10 mM EGTA caused a mean 95% increase in diphenyliodinium-sensitive superoxide production (Fig. 1; n = 9), implicating NADPH oxidases as the source of this ROS. Stimulation of NADPH oxidase activity by decreasing Ca²⁺ influx at first appears contradictory as NADPH oxidases are stimulated by increased [Ca²⁺]_cyt²⁷ (Fig. 1). However, reduction of Ca²⁺ influx should promote voltage hyperpolarisation (just as block of K⁺ influx causes hyperpolarisation in root hairs²⁸) and this could feasibly cause increased NADPH oxidase activity. Production of superoxide could then result in ROS-activated HACC activity⁵ to increase Ca²⁺ influx.Open in a separate windowFigure 1Superoxide anion production by Arabidopsis roots. Assay medium comprised 10 mM phosphate buffer with 0.5 mM CaCl₂, 500 µM XTT, pH 6.0. Production was linear over the 30 min incubation period. Control, mean ± standard error, n = 9. Test additions were: 20 µM of the NADPH oxidase inhibitor diphenylene iodonium (DPI; n = 6); 100 µM of the Ca²⁺ ionophore {"type":"entrez-nucleotide","attrs":{"text":"A23187","term_id":"833253","term_text":"A23187"}}A23187,³⁰ to increase [Ca²⁺]_cyt (n = 9); 10 mM of the chelator EGTA (n = 9). Dimethyl sulphoxide [DMSO; 1% (v/v)] was used as a carrier for XTT and DPI and a separate control for this is shown (n = 9).In addition to V_m, activities of PM transporters in vivo will be subject to other levels of regulation such as phosphorylation, nitrosylation and the action of [Ca²⁺]_cyt itself. Distinct spatial separation of transporters will undoubtedly play a significant role in governing V_m and [Ca²⁺]_cyt dynamics, particularly in growing cells. An NADPH oxidase has already been found sequestered in a potential PM microdomain in Medicago.²⁹ While there is still much to do on the “inventory” of PM transporters involved in Ca²⁺ signalling in any given cell, placing them in context not only requires knowledge of their genetic identity but also modelling of their concerted action.     

Is membrane occupation and recognition nexus domain functional in plant phosphatidylinositol phosphate kinases?

Phosphatidylinositol phosphate kinase (PIPK) catalyzes a key step controlling cellular contents of phosphatidylinositol-4,5-bisphosphate [PtdIns(4,5)P₂], a critical intracellular messenger involved in vesicle trafficking and modulation of actin cytoskeleton and also a substrate of phospholipase C to produce the two intracellular messengers, diacylglycerol and inositol-1,4,5-trisphosphate. In addition to the conserved C-terminal PIPK catalytic domain, plant PIPKs contain a unique structural feature consisting of a repeat of membrane occupation and recognition nexus (MORN) motifs, called the MORN domain, in the N-terminal half. The MORN domain has previously been proposed to regulate plasma membrane localization and phosphatidic acid (PA)-inducible activation. Recently, the importance of the catalytic domain, but not the MORN domain, in these aspects was demonstrated. These conflicting data raise the question about the function of the MORN domain in plant PIPKs. We therefore performed analyses of PpPIPK1 from the moss Physcomitrella patens to elucidate the importance of the MORN domain in the control of enzymatic activity; however, we found no effect on either enzymatic activity or activation by PA. Taken together with our previous findings of lack of function in plasma membrane localization, there is no positive evidence indicating roles of the MORN domain in enzymatic and functional regulations of PpPIPK1. Therefore, further biochemical and reverse genetic analyses are necessary to understand the biological significance of the MORN domain in plant PIPKs.Key words: membrane occupation and recognition nexus (MORN) domain, phosphatidylinositol phosphate kinase, phosphatidic acid, Physcomitrella patensPhosphoinositides (PIs) are minor membrane phospholipds that play pivotal roles in various signal transduction cascades involved in development and stress response via the regulation of cytoskeletal organization, ion channel activation and vesicle trafficking.^1,2 These are derivatives of phosphatidylinositol (PtdIns) produced by phosphorylation of the 3-, 4- and 5- positions of the inositol ring.² To address the roles of PIs, enzymes involved in their production have been extensively studied using biochemical and molecular biological approaches. Of these enzymes, phosphatidylinositol monophosphate kinases (PIPKs) catalyze the reaction producing phosphatidylinositol-4,5-bisphosphate [PtdIns(4,5)P₂] that is a substrate of phospholipase C and phosphatidylinositol 3-kinase, and also acts as an intracellular messenger involved in the regulation of F-actin organization and activity of ion channels.^1–3 Although PtdIns(4,5)P₂ is produced by sequential phosphorylation by phosphatidylinositol 4-kinase, producing phosphatidylinositol-4-phosphate [PtdIns(4)P], and then by PIPK,^1,2 the cellular levels of PtdIns(4)P are much higher compared to PtdIns(4,5)P₂.^4–6 Thus, a restriction step controlling cellular PtdIns(4,5)P₂ contents is mediated by PIPKs, indicating the importance of PIPK regulation in various kinds of physiological processes.The roles of plant PIPKs have been established in growth regulation, such as polarized tip growth of root hairs and pollen tubes, via their localization at plasma membranes.^7–12 It is worth to note that plant PIPKs contain a unique structure consisting of a repeat of a membrane occupation recognition nexus (MORN) motifs, called MORN domain, at the N-terminal region and a C-terminal PIPK catalytic domain, except for AtPIP5K10 and AtPIP5K11 from Arabidopsis thaliana, which lack the N-terminal MORN domain.¹³ The MORN domain was first identified as plasma membrane-binding module in junctophilin¹⁴ and the involvement of the MORN domain in plasma membrane localization was proposed for A. thaliana AtPIP5K1 and AtPIP5K3.^9,15,16Another remarkable feature of eukaryotic PIPKs is dependency of the enzymatic activity on phosphatidic acid (PA).^17,18 Indeed, PA-dependent activation of PIPKs has been observed in A. thaliana and in the moss Physcomitrella patens,^6,19,20 as with animal type I PIPKs.²¹ Although much less is known about how PA activates PIPKs in plants, biochemical analyses suggested the involvement of the MORN domain in PA-dependent activation of AtPIP5K1.¹⁵Based on above findings, it was proposed that plasma membrane-localization and PA-dependent activation of plant PIPKs might be regulated by the MORN domain.^9,15,16 In contrast, we recently demonstrated the critical involvement of the C-terminal half containing the catalytic domain of plant PIPKs in both plasma membrane-localization and PA-dependent activation.²² Thus, the function of the MORN domain remains elusive in plant PIPKs.As shown earlier, the N-terminal half of P. patens PpPIPK1 containing the MORN domain enhances its catalytic activity.²² Thus, to identify the region required for the activation of PpPIPK1, we further dissected the N-terminal half into 3 regions; the N-terminal region (amino acid nos. 1–154), the MORN repeat (amino acid nos. 155–316) and the linker region (amino acid nos. 338–452), and made deletion mutants of PpPIPK1 as shown in Figure 1A. Using Pfu Turbo DNA polymerase (Stratagene, La Jolla, USA), DNA fragments corresponding to deletion mutants lacking the N-terminal and N-terminal plus the MORN repeat, designated PpPIPK1ΔN and PpPIPK1ΔN-MORN, respectively, were amplified with primer sets; one is M_PIPK1_fb (5′-GGC AAG CAC GTG TAT AAT GTC TGA AGG GCT T-3′) and XhoIPIPK1 (5′-TAA ACT CGA GTT AGC TGG GTA GGA GGA AA-3′) and the other is M_PIPK1_f7 (5′-AGA GAA CAC GTG TAT AAT GTC TGA CTT CTA CGT CGG T-3′) and XhoIPIPK1. For building an expression plasmid for a deletion mutant lacking the MORN repeat, designated PpPIPK1ΔMORN, the N-terminal region and PpPIPK1ΔN-MORN were amplified with primer sets, M_PIPK1_fb and M_PIPK1_r3 (5′-TTG TAA GTC TCG GGT GCC ATT TGA GAG CTC-3′) M_PIPK1_f6 (5′-GAG CTC TCA AAT GGC ACC CGA GAC TTA CAA-3′) and XhoIPIPK1, respectively, using Pfu Turbo DNA polymerase and resultant DNA fragments were fused by PCR with a primer set, M_PIPK1_fb and XhoIPIPK1 using the same enzyme. These PCR products were digested with Pml1 and XhoI and inserted into Pml1-XhoI digested pPICZB (Invitrogen) to construct expression plasmids, pPICZB-PpPIPK1ΔN, pPICZB-PpPIPK1ΔN-MORN and pPICZB-PpPIPK1ΔMORN. Transformation of P. pastoris X-33 cells with the above expression plasmids, colony PCR of transformants and following expression, purification and western blot analysis of His-tagged recombinant proteins were performed as described previously.⁶ The PIPK activity assay using purified His-tagged proteins was carried out as described previously²³ with the modifications.⁶Open in a separate windowFigure 1Functional dissection of the N-terminal region of PpPIPK1 identifies positive regulatory regions. (A) His-tagged recombinant PpPIPK1 proteins. A repetition of eight MORN motifs (grey boxes) and the conserved catalytic domain (black box) are indicated in wild type and mutant PpPIPK1s. The MORN repeat and junction of internal deletion are indicated by amino acid position numbers. (B) In vitro lipid kinase activity of His-tagged recombinant proteins. The activities of recombinant proteins bound to Ni-NTA agarose beads were assayed with PtdIns4P. (C) In vitro PA-dependent lipid kinase activity of His-tagged proteins. The activities of recombinant proteins bound to Ni-NTA agarose beads were assayed with PtdIns4P with 143 µM PA. Top and bottom arrowheads represent reaction products PtdIns(4,5)P₂ and lysoPtdIns(4,5)P₂, respectively.Biochemical analyses of these enzymes after expression in yeast P. pastoris X-33 cells followed by purification showed that deletion of the N-terminal region (PpPIPK1ΔN) reduced PpPIPK1 activity ca 40% compared to the full length enzyme, whereas loss of the MORN repeat (PpPIPK1ΔMORN) had no significant effect (Fig. 1B). In agreement, a mutant lacking four MORN repeats of the total eight repeats showed no difference in the activity compared the full length enzyme (data not shown). These results indicate a positive role of the N-terminal region, but not the MORN repeats, on PpPIPK1 activity. However, these findings differ from those obtained with AtPIP5K1, where the MORN domain represses enzymatic activity.¹⁵ Interestingly, PpPIPK1ΔN-MORN containing the linker and catalytic regions showed higher enzymatic activity of ca 23 % compared to the full length PpPIPK1 (Fig. 1B). The C-terminal half only containing the catalytic domain of PpPIPK1 and thus lacking the linker region showed a reduced activity.²² It is therefore proposed that the linker region carries a positive regulatory element. Although details are unknown, negligible effects of the N-terminal and MORN domains for the enzymatic activity has been indicated in AtPIP5K3 from A. thaliana.¹¹ Moreover, it is noteworthy that PA-dependent activation was not affected by any deletion as shown in Figure 1C, confirming that the N-terminal half is not involved in PA dependency of the PpPIPK1 activity.²²Our results indicated that the MORN domain is not involved in the regulation of the catalytic activity in PpPIPK1. Similarly, the function of the MORN domain found in the accumulation and replication of chloroplasts 3 (ARC3) was not resolved. ARC3 is an FtsZ homologue involved in chloroplast division²⁴ and the only protein containing the MORN repeats other than PIPKs in A. thaliana. It was shown that the ARC3 MORN domain did not interact with any stromal plastid division components.²⁵ Moreover, there are reports representing functions of the MORN domain other than plasma membrane binding. Human amyotrophic lateral sclerosis 2 (ALS2), a guanine nucleotide exchange factor (GEF) specific to the small GTPase Rab5, contains the MORN domain at the central region that is essential for the GEF activity but not for interaction with Rab5.²⁶ In contrast, specific interaction of the MORN domain with Rab-E GTPases and resultant enzymatic activation was recently demonstrated for AtPIP5K2.¹² It is interesting that these results are inconsistent with each other in terms of interaction of the MORN domain with small GTPases.Taken together, with no function of the MORN domain in plasma membrane localization of PpPIPK1 and AtPIP5K1,²² the function of the MORN domain is still unknown, despite its high conservation plants PIPKs. Alternatively, based on the findings of ARC3, ALS2 and AtPIP5K2,^12,25,26 the function of the MORN domain possibly varies among PIPK isoforms and may thus have multifunctional roles. Therefore, it is necessary to identify interaction partners for the MORN domain of each plant PIPKs and to analyze phenotypes of transgenic plants carrying MORN domain-lacking PIPKs during developmental process and environmental stress responses.