Regulation of stomatal opening by the guard cell expansin AtEXPA1

Stomatal movement is strictly regulated by various intracellular and extracellular factors in response environmental signals. In our recent study, we found that an Arabidopsis guard cell expressed expansin, AtEXPA1, regulates stomatal opening by altering the structure of the guard cell wall. This addendum proposes a mechanism by which guard cell expansins regulate stomatal movement.Key words: expansin, stomatal movement, AtEXPA1, guard cell, wall looseningStomatal movement is the most popular model system for cellular signaling transduction research. A complicated complex containing many proteins has been proposed to control stomatal responses to outside stimuli. The known regulation factors are primarily located in the nucleus, cytoplasm, plasma membrane and other intracellular organelles.^1,2 Although the cell wall structure of the stomata is different from that of other cells,^3,4 the presence of stomatal movement regulation factors in the cell wall has seldom been reported in reference ⁵. In our previous work, we found that extracellular calmodulin stimulates a cascade of intracellular signaling events to regulate stomatal movement.⁶ The involvement of this signaling pathway is the first evidence that cell wall proteins play an important role in regulation of stomatal opening. Cell wall-modifying factors constitute a major portion of cell wall proteins. However, the role of these factors in the regulation of stomatal movement is not yet known.Expansins are nonenzymatic proteins that participate in cell wall loosening.^7–9 Expansins were first identified as “acid-growth” factors because they have much higher activities at acidic pHs.^10,11 It has been reported that expansins play important roles in plant cell growth, fruit softening, root hair emergence and other developmental processes in which cell wall loosening is involved.^7–9,12,13 Wall loosening is an essential step in guard cell swelling and the role of stomatal expansins was investigated. AtEXPA1 is an Arabidopsis guard-cell-specific expansin.^13,14 Over-expressing AtEXPA1 increases the rate of light-induced stomatal opening,^14,15 while a potential inhibitor of expansin activity, AtEXPA1 antibody, reduces the sensitivity of stomata to stimuli.¹⁴ We showed that the transpiration rate and the photosynthesis rate in plant lines overexpressing AtEXPA1 were nearly two times the rates for wild-type plants (Fig. 1). These in plant data revealed that expansins accelerated stomatal opening under normal physiological conditions. In addition, the increases in the transpiration and photosynthesis rates strongly suggested the possibility of exploiting expansin-regulated stomatal sensitivity to modify plant drought tolerance. Compared with the effect of hydrolytic cell wall enzymes, the destruction of cell wall structures induced by expansins is minimal. In addition, it is very difficult to directly observe the changes in the guard cell wall structure caused by expansins during stomatal movement. Our recent work showed that, in AtEXPA1-overexpressing plants, the volumetric elastic modulus is lower than in wild-type plants,¹⁴ which indicates the wall structure was loosened and that the cell wall was easier to extend. Taken together, our data suggest that expansins participate in the regulation of stomatal movement by modifying the cell walls of guard cells.Open in a separate windowFigure 1Effects of AtEXPA1 overexpression on transpiration rates and photosynthesis rates. The transpiration rate (left) and photosynthesis rate (right) of wild-type and transgenic AtEXPA1 lines were measured at 10:00 AM in the greenhouse after being watered overnight. The illumination intensity was 180 µmol/m²·s. Bars represent the standard error of the mean of at least five plants per line.It is well known that the activation of proton-pumping ATPase (H⁺-ATPase) in the plasma membrane is an early and essential step in stomatal opening.¹⁶ The action of the pump results in an accumulation of H⁺ outside of the cell, increases the inside-negative electrical potential across the plasma membrane and drives potassium uptake through the voltage-gated, inward-rectifying K⁺ channels.^17–19 The main function of the H⁺ pump is well accepted to create an electrochemical gradient across the plasma membrane; however, the other result is the acidification of the guard cell wall, which may also contribute to stomatal opening. A possible mechanism responsible for this effect is as follows. Expansins are in an inactive state when the stomata are in the resting state. Stomatal opening signals induce wall acidification and activate expansins. Then, the expansins move along with cellulose microfibrils and transiently break down hydrogen bonding between hemicellulose and the surface of cellulose microfibrils,^20,21 facilitating the slippage of cell wall polymers under increasing guard cell turgor pressure. The guard cell then swells and the stomata open (Fig. 2).Open in a separate windowFigure 2Model of how guard cell wall expansins regulate stomatal opening. Environmental stimuli, e.g., light, activate guard cell plasma membrane H⁺-ATPases to pump H⁺ into the extracellular wall space. The accumulation H⁺ acidifies the cell wall and induces the activation of expansin. The active expansin disrupts non-covalent bonding between cellulose microfibrils and matrix glucans to enable the slippage of the cell wall. The wall is loosened coincident with guard cell swelling and without substantial breakdown of the structure.Although our results indicate that AtEXPA1 regulates stomatal movement, the biochemical and structural mechanism by which AtEXPA1 loosens the cell wall remains to be discovered. It remains to figure out the existing of other expansins or coordinators involving in this process. In addition, determining the roles of expansins and the guard cell wall in stomatal closing is another main goal of future research.     

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.     

Co-regulation of root hair tip growth by ROP GTPases and nitrogen source modulated pH fluctuations

Growth of plant cells involves tight regulation of the cytoskeleton and vesicle trafficking by processes including the action of the ROP small G proteins together with pH-modulated cell wall modifications. Yet, little is known on how these systems are coordinated. In a paper recently published in Plant Cell and Environment¹ we show that ROPs/RACs function synergistically with NH₄NO₃-modulated pH fluctuations to regulate root hair growth. Root hairs expand exclusively at their apical end in a strictly polarized manner by a process known as tip growth. The highly polarized secretion at the apex is maintained by a complex network of factors including the spatial organization of the actin cytoskeleton, tip-focused ion gradients and by small G proteins. Expression of constitutively active ROP mutants disrupts polar growth, inducing the formation of swollen root hairs. Root hairs are also known to elongate in an oscillating manner, which is correlated with oscillatory H⁺ fluxes at the tip. Our analysis shows that root hair elongation in wild type plants and swelling in transgenic plants expressing a constitutively active ROP11 (rop11^CA) is sensitive to the presence of NH₄⁺ at concentrations higher than 1 mM and on NO₃⁻. The NH₄⁺ and NO₃⁻ ions did not affect the localization of ROP in the membrane but modulated pH fluctuations at the root hair tip. Actin organization and reactive oxygen species distribution were abnormal in rop11^CA root hairs but were similar to wild-type root hairs when seedlings were grown on medium lacking NH₄⁺ and/or NO₃⁻. These observations suggest that the nitrogen source-modulated pH fluctuations may function synergistically with ROP regulated signaling during root hair tip growth. Interestingly, under certain growth conditions, expression of rop11^CA suppressed ammonium toxicity, similar to auxin resistant mutants. In this short review we discuss these findings and their implications.Key words: ROP, RAC, nitrogen, root hair, cell polarity, ammoniumIn Arabidopsis, root hairs grow out at the basal, rootward region (closer to root tip) of specialized root epidermal cells and expand exclusively at their apical end in a strictly polarized manner by a process known as tip growth. Tip growth is facilitated by Rho of Plants (ROP)-regulated processes such as maintenance of longitudinally-oriented actin cables in the shank of the root hair that are required for myosin-mediated organelle transport through the cytoplasm. ROPs also play a role in sustaining fine F-actin structures at the root hair tip, which promote the transport of secretory vesicles to sites of their fusion with the plasma membrane.^2,3 In addition, the polar growth of root hairs involves an oscillatory tip-focused Ca²⁺ gradient⁴ and tip-localized reactive oxygen species (ROS).⁵ Tip growth is also associated with oscillatory fluxes of H⁺ at the apex that correlate with the periodicity of growth.^6,7 These oscillations in extracellular pH and ROS have been shown to modulate tip growth and are predicted to act in a coordinated and complementary mode to regulate root hair elongation. Growth accelerates following reduction of apoplastic pH and slows upon apoplastic ROS increase and a coincident pH increase.⁷ROPs are small G proteins that localize to the plasma membrane at the apex of growing root hairs, where they activate a range of downstream pathways required for tip growth.^8,9 ROP activity is regulated by its cycling between a GTP-bound, active and GDP-bound, inactive state. Ectopic expression of constitutively active mutants of ROPs (dominant mutations in conserved residues that abolish the GTPase activity) depolarizes the growth of root hairs.^8–10 Downstream pathways activated by such ROP GTPases include the regulation of cytoskeletal dynamics and vesicular trafficking, production of ROS, maintenance of intracellular Ca²⁺ gradients and accumulation of signaling lipids, features all related to the regulation of apical growth.^11,12 For example, ectopic expression of constitutively active ROP11 (Atrop11^CA) depolarizes root hair growth, leading to the formation of swollen root hairs. This bulging root hair phenotype was associated with altered actin organization and inhibition of endocytosis.¹⁰It is well known that root hair development is highly plastic and regulated by environmental signals.^13,14 Yet, despite the known function of ROP GTPases and their regulatory proteins in root hair growth there is no data in the literature describing the relationship between ROP signaling and environmental factors in this process. Our results¹ show that induction of root hair swelling by rop11^CA occurs only under specific growth conditions, indicating that there is an interplay between ROP activity and the external environment, particularly nitrogen supply. We demonstrated that high external concentrations of ammonium are essential for the induction of depolarized root hair growth and activation of downstream pathways by rop11^CA. Depletion of ammonium did not affect the membrane localization and expression of GFP-rop11^CA, implying that NH₄⁺ was required in addition to ROP activity to cause root hair swelling. In agreement with this idea, normal actin organization and ROS localization were detected in rop11^CA root hairs when NH₄⁺ was depleted, suggesting that ammonium functions downstream of, or in parallel to ROP signaling (Fig. 1).Open in a separate windowFigure 1A model for regulation of root hair tip growth by ROP GTPases and pH oscillations dependent on nitrogen supply. GTP bound ROPs activate downstream effectors which directly affect actin organization, vesicular trafficking and localized ROS production as well as indirectly affecting the localization of membrane proteins involved in ion/proton fluxes. High concentrations of nitrogen ions in the growth medium increase pH oscillations at the apex of growing root hairs. In turn downstream ROP effectors sense the changes in pH and adjust their function accordingly. pH oscillations affect tip growth independent of ROPs via changes of wall pH and possibly through additional unknown factors. Dashed lines indicate that these effects were not confirmed experimentally.Plants can absorb and use various forms of nitrogen from soils, primarily the inorganic ions ammonium and nitrate. The concentrations of these ions are highly heterogeneous around the plant and can vary across several orders of magnitude among different soils and as a result of seasonal changes.¹⁵ Thus, plants would be expected to display highly plastic, N-regulated developmental responses and to employ a range of nitrogen uptake transport systems to optimize exploitation of local N resources. Transport systems that mediate NH₄ fluxes across the plasma membrane of root cells are divided into two categories: high affinity transport systems (HATS) that mediate uptake from relatively dilute solutions at relatively low rates and low affinity transport systems (LATS) that operate at high rates and higher external concentrations.¹⁶ The HATS are plasma membrane localized NH₄⁺-specific transporters (AMTs) that are most likely proton-coupled and their expression and function are repressed at external ammonium concentrations of 1 mM or higher.^17–19 In contrast, ammonium uptake by LATS is believed to take place through non-specific cation channels.^17,20 The NH₄⁺ concentration in the 0.5× Murashige Skoog (MS) medium is 10.3 mM, exceeding by an order of magnitude the concentration at which the high affinity NH₄⁺ uptake system is repressed. The root hair swelling in Atrop11_CA plants and inhibition of root hair elongation in wild type plants occurred primarily at external ammonium concentrations greater than 1 mM, and thus is most likely associated with uptake by the LATS.As noted above, root hair elongation is associated with oscillations of cytoplasmic and apoplastic pH that have been linked to growth control. Simultaneous fluorescence ratio imaging of internal and external pH revealed that application of 10 mM NH₄NO₃ enhanced the amplitude of these pH oscillations at the extreme apex of wild type root hairs1 and Figure 2. These oscillations are thought to modulate tip growth through altering the extensibility of the wall.⁴ Additional measurements (Fig. 2) show that similar to the effects of NH₄NO₃, addition of NH₄Cl induced increase in the apoplastic pH fluctuations and reduced the pH. However, the effects of NH₄Cl on cytoplasmic pH fluctuations seem subtler compared to the effects of NH₄NO₃. Thus, one possible explanation for the observed swelling of the root hair apex in rop11_CA expressing plants in media containing NH₄NO₃ is that rop11_CA root hairs are affected in their ability to re-establish the normal proton gradient across the plasma membrane in response to ammonium transport. The altered proton gradient would then prevent the normal localized oscillatory changes in pH-dependent wall properties required to restrict expansion to the very tip of the elongating root hair.Open in a separate windowFigure 2Changes in apoplastic and cytoplasmic pH fluctuations, following application of NH₄NO₃, NH₄Cl or KNO₃. (A) Apolplastic pH (pH_ex) following treatments with either NH₄NO₃, NH₄Cl or KNO₃. Note the increase pH fluctuations induced by either NH₄NO₃ and NH₄Cl but not by KNO₃. (B) Cytoplasmic pH (pH_cyt) following treatments as above. Note the changes in pH fluctuations induced by NH₄NO₃ and the subtler effects of NH₄Cl.Concurrent absorption of NH₄⁺ and NO₃⁻- maintains the cation-anion balance within both the rooting medium and the root, and thus potentially has an important function in maintaining intracellular and extracellular pH.^21,22 In agreement, application of these ions affected the amplitude of pH oscillations¹ and Figure 2. Interestingly, treatments of WT seedlings with 10 mM NH₄NO₃ causes increase in root hair pH oscillations and often tip bursting. Yet, prolonged exposure of WT root hairs to NH₄NO₃ is accompanied by adaptation (our unpublished data). This adaptation does not occur in rop11_CA mutants, suggesting that cycling of ROPs between active and inactive states maybe important in adaptation to changing environment. These data strongly suggest that NH₄⁺-dependent root hair swelling in the plants expressing activated ROP resulted from physiological changes in ion balance rather than a direct effect of ammonium on enzymatic activities required for root hair growth (Fig. 1). Application of NH₄⁺ and NO₃⁻, in the absence of other ions, induced formation of additional growth tips, in which the membrane localized GFP-rop11^CA was concentrated. This observation suggests that interplay between the regulation of ROP localization and activity and the regulation of nitrogen fluxes may have an important function in the maintenance of unidirectional growth. As root hair elongation is coupled to spatially distinct regulation of extracellular pH oscillations and ROS production,⁷ it seems likely that there is a mechanism that can adjust the fluxes of nitrogen ions relative to these pH fluxes. This system would then maintain the oscillations in pH such that polarized growth is continued. One possible mechanism for this coordination is through the highly localized ROP cycling between active and inactive states that has an important role in the spatial activation of cell polarization machinery.^23–27 Due to the function of ROP GTPases in vesicle trafficking, actin organization and maintenance of ROS and Ca²⁺ gradients,^{2,8,9,23,24,28–33} expression of activated ROP11 may indirectly influence cell wall properties by altering the localization and/or recycling of cation and anion transporters/channels or plasma membrane H⁺-ATPases delivered to the growing tip of the hair and in this way affect the maintenance of the proton gradients. In agreement with a possible effect of activated ROPs on localization and/or recycling of membrane transporters we discovered that rop11^CA plants were resistant to ammonium toxicity when grown in the presence of NH₄NO₃ and several micronutrients.¹We propose a model (Fig. 1) in which spatial regulation of ROP activity creates a positive feedback loop with pH oscillations around the growing apex of root hairs. According to this model ROP cycling between active and inactive states spatially and temporally activates the downstream signaling cascades essential for the tip-growth of root hairs. At the same time, localization of membrane proteins involved in maintenance of normal nitrogen fluxes across the plasma membrane is indirectly affected by ROP signaling. Alternatively, ROP signaling is modulated to adapt to altered nitrogen fluxes. NH₄⁺ fluxes increase the amplitude of pH oscillations at the root hair apex and in turn affect cell-wall properties. Thus, when the ROP activity is upregulated by dominant mutations, the synergistic effects of pH changes and constant activation of ROP downstream effectors result in the uncontrolled cell expansion seen as root hair bulging. Previous studies have suggested that feedback between oscillatory pH change and ROS distribution is required to support tip growth.⁷ However, the factors that may integrate these processes are unknown. Our results suggest that spatial regulation of ROP activity in response to changing environments is one of the key elements that may coordinate the pH and ROS oscillations during the root hair tip growth.It will be interesting to examine whether ROP function is coordinated with apoplastic pH fluctuation in other cell types. Recently, it has been suggested that the effects of auxin on pavement cell structure in leaf epidermis require Auxin Binding Protein 1 (ABP1) dependent ROP activation.³⁴ It is well known that auxin induces changes in apoplastic pH. Possibly, like nitrogen source in root hairs, auxin dependent apolplastic pH fluctuations in the leaf epidermis may function coordinately with ROP in the regulation of cell growth. Consistent with this idea, it has been shown that auxin inhibits clathrin-dependent endocytosis through ABP1 reinforcing a possible role in modulating membrane flux/membrane properties.³⁵ Some auxin resistant mutants also display resistance to ammonium toxicity³⁶ further suggesting a link between auxin and membrane transport. Hence, auxin and ROPs may indeed function synergistically to modulate plasma membrane properties, in turn affecting ion balance in the apoplast and so modulating cell wall properties and growth.     

Loss of LORELEI function in the pistil delays initiation but does not affect embryo development in Arabidopsis thaliana

Double fertilization, uniquely observed in plants, requires successful sperm cell delivery by the pollen tube to the female gametophyte, followed by migration, recognition and fusion of the two sperm cells with two female gametic cells. The female gametophyte not only regulates these steps but also controls the subsequent initiation of seed development. Previously, we reported that loss of LORELEI, which encodes a putative glycosylphosphatidylinositol (GPI)-anchored protein, in the female reproductive tissues causes a delay in initiation of seed development. From these studies, however, it was unclear if embryos derived from fertilization of lre-5 gametophytes continued to lag behind wild-type during seed development. Additionally, it was not determined if the delay in initiation of seed development had any lingering effects during seed germination. Finally, it was not known if loss of LORELEI function affects seedling development given that LORELEI is expressed in eight-day-old seedlings. Here, we showed that despite a delay in initiation, lre-5/lre-5 embryos recover, becoming equivalent to the developing wild-type embryos beginning at 72 hours after pollination. Additionally, lre-5/lre-5 seed germination, and seedling and root development are indistinguishable from wild-type indicating that loss of LORELEI is tolerated, at least under standard growth conditions, in vegetative tissues.Key words: LORELEI, glycosylphosphatidylinositol (GPI)-anchored protein, embryogenesis, DD45, seed germination, primary and lateral root growth, seedling developmentDouble fertilization is unique to flowering plants. Upon female gametophyte reception of a pollen tube, the egg and central cells of the female gametophyte fuse with the two released sperm cells to form zygote and endosperm, respectively and initiate seed development.¹ The female gametophyte controls seed development by (1) repressing premature central cell or egg cell proliferation until double fertilization is completed,^1–3 (2) supplying factors that mediate early stages of embryo and endosperm development^1,4,5 and (3) regulating imprinting of genes required for seed development.^1,6The molecular mechanisms underlying female gametophyte control of early seed development are poorly understood. Although much progress has been made in identifying genes and mechanisms by which the female gametophyte represses premature central cell or egg cell proliferation until double fertilization is completed and regulates imprinting of genes required for seed development,^1,6 only a handful of female gametophyte-expressed genes that affect early embryo^7,8 and endosperm⁹ development after fertilization have been characterized. This is particularly important given that a large number of female gametophyte-expressed genes likely regulate early seed development.⁵We recently reported on a mutant screen for plants with reduced fertility and identification of a mutant that contained a large number of undeveloped ovules and very few viable seeds.¹⁰ TAIL-PCR revealed that this mutant is a new allele of LORELEI(LRE) [At4g26466].^10,11 Four lre alleles have been reported;¹¹ so, this mutant was designated lre-5.¹⁰ The Arabidopsis LORELEI protein contains 165 amino acids and possesses sequence features indicative of a glycosylphosphatidylinositol (GPI)-anchor containing cell surface protein. GPI-anchors serve as an alternative to transmembrane domains for anchoring proteins in cell membranes and GPI-anchored proteins participate in many functions including cell-cell signaling.¹²     

Reactive oxygen species (ROS) as early signals in root hair cells responding to rhizobial nodulation factors

Reactive oxygen species (ROS) are involved in supporting polar growth in pollen tubes, fucoid cells and root hair cells. However, there is limited evidence showing ROS changes during the earliest stages of the interaction between legume roots and rhizobia. We recently reported using Phaseolus vulgaris as a model system, the occurrence of a transient increase of ROS, within seconds, at the tip of actively growing root hair cells after treatment with Nod factors (NFs).¹ This transient response is NFs-specific, and clearly distinct from the ROS changes induced by a fungal elicitor, with which sustained increases in ROS signal, is observed. Since ROS levels are transiently elevated after NFs perception, we propose that this ROS response is specific of the symbiotic interaction. Furthermore, the observed ROS changes correlate spatially and temporarily with the reported transient increases in calcium levels suggesting key roles for calcium and ROS during the early NF perception.Key words: reactive oxygen species, root hair, nodulation, NADP(H) oxidase, nod factorsThe symbiotic interaction between rhizobia and plant legumes entails a molecular dialogue. Legume roots exude flavonoids that induce the expression of bacterial nodulation genes, which encode proteins involved in the synthesis and secretion of Nod factors (NFs) (reviewed in ref. ²). NFs are perceived by the plant root, which in turn exhibit several responses such as ion fluxes (K⁺, Cl⁻, Ca²⁺, H⁺), cytoplasmic alkalinization, cytoplasmic calcium oscillations ([Ca²⁺] c), and gene expression,³ leading to bacterial invasion and nodule formation.In the last decade, convincing evidences have appeared indicating that in plants as well as in animals, an elevated production and accumulation of reactive oxygen species (ROS) accompanies various processes, such as: development, hypersensitive response, hormone action, gravitropism and stress responses.⁴ In support of these findings, Ca²⁺-permeable channel modulation by ROS was demonstrated in Vicia faba guard cells and recently in Arabidopsis, where ROS regulated calcium channels are also active in sustaining plant cell growth.^5,6It has been widely reported that in plants, the ROS production accumulate in the apical region of tip growing cells such as pollen tubes and root hair cells, as well as Fucus and fungal hyphae.^6–9 Furthermore, patch-clamp studies showed that ROS can regulate calcium channels.⁶ Arabidopsis mutants in NADPH oxidase are characterized by stunted or absence of root hairs,¹⁰ and fail to exhibit the tip-localized ROS gradient. Since NADPH oxidase contains calcium ion-binding EF hand domains, it is plausible that its regulation is calcium dependent. However, the role of calcium ions in NADPH oxidase activation in root hair cells remains unknown.In legumes, ROS levels are elevated during the rhizobial infection, specifically in the developed nodules,¹¹ as well as during the preceding stages, such as the infection thread formation,^12,13 a process that is usually initiated after 72 h after Rhizobium inoculation. Furthermore, it has been proposed that the failure to produce and maintain proper ROS concentrations results in infection thread abortion.¹⁴ Conversely, other studies reported a decrease in intracellular ROS levels in root hair cells treated with NFs.^15,16 However, these studies were done at different time scales and the processes observed were different; while Shaw et al., (2003) and Lohar et al., (2007) made the observations on ROS levels in root hair cells several minutes after exposure to NFs during the swelling response, Santos et al., (2001) and Ramu et al., (2002) looked at the root hairs forming infection threads induced by Rhizobium inoculation. Using Phaseolus vulgaris, we recently demonstrated that living root hair cells show changes in ROS levels within few seconds after NFs addition.¹ This work was carried out by using a ROS sensitive dye (CM-H2DCFDA, Invitrogen). This fluorescent dye has been widely used as a ROS indicator dye; nevertheless, limitations are encountered when it is used as a single wavelength dye. This is due to the accessible volume in root hair cells, which usually present an increased cytoplasmic accumulation at the tip region. However, we have circumvented this problem by using the ROS sensitive CM-H2DCFDA dye in combination with a reference dye (Cell Tracker Red, Invitrogen) to establish a pseudo-ratiometric analysis. This allowed us to visualize the subcellular distribution of the ROS signal in living root hair cells, which now can be described as a tip-localized gradient.In summary, the production and distribution of intracellular ROS levels were analyzed in P. vulgaris growing root hair cells as well as their responses to NFs. We found that ROS levels were dramatically and transiently increased within a few seconds after NFs treatment. This response is specific for NFs, and clearly distinct from those observed after the addition of chitin oligomers (pentamers).¹ It is possible that the modulation of ROS production in epidermal cells enables rhizobia to enter the host plant without triggering a hypersensitive response. A failure to control ROS elevation might provoke an infection thread abortion (Vasse et al., 1993). Root hair cells responded to the presence of NFs with a transient ROS signature signal, in a different way than observed after chitosan treatment. These results suggest that within seconds these cells are able to perceive differentially, symbiotic signals from pathogenic fungal elicitors. Therefore, this transient ROS signature specifically triggered by NFs could play a key role in modulating the rhizobia-legume interaction.In root hairs, the NF-induced transient increase in the ROS levels, which is initiated 15 sec after NFs treatment clearly precedes the onset of the observed [Ca²⁺]c oscillations in the perinuclear region that occur 10–15 min later. Therefore, the transient ROS response can be considered as one of the earliest responses to NFs. However, these ROS changes correlate spatially and temporally with the described calcium influx at the tip region of root hair cells responding to NFs (Fig. 1), suggesting a connection for both the players during the NFs signal perception. So far we do not know if the ROS response is earlier or subsequent to the [Ca²⁺]c increases (fluxes) observed at the tip region of legume root hair cells treated with NFs. However, it is possible that a feed back response is established as suggested in Arabidopsis root hair cells.¹⁷ In this scenario, the transiently induced ROS changes observed after NFs treatment could stimulate the calcium channels located at the tip region (Fig. 1, inset). This would result in the transiently increased [Ca²⁺]c levels observed at the tip region after NFs treatment, which in turn could activate the NAD(P)H oxidase leading to the generation of more ROS. The generated ROS could then stimulate the calcium channels at the tip region triggering signalling cascade.Open in a separate windowFigure 1Model on the earliest responses observed at the tip of root hair cells after NFs treatment. Note that [Ca²⁺]c and ROS at the tip region respond with a transient changes in their levels within a few seconds after NFs treatment, while [Ca²⁺]c oscillations in the perinuclear region follow after 10–15 min. Inset depicts a model where the generated ROS could activate the calcium channels located at the tip region and this in turn could generate an increase in [Ca²⁺]c. Increased [Ca²⁺]c then activates the NAD(P)H oxidase maintaining increased ROS levels.     

ARF-GTPase as a Molecular Switch for Polar Auxin Transport Mediated by Vesicle Trafficking in Root Development

Polar auxin transport (PAT), which is controlled precisely by both auxin efflux and influx facilitators and mediated by the cell trafficking system, modulates organogenesis, development and root gravitropism. ADP-ribosylation factor (ARF)-GTPase protein is catalyzed to switch to the GTP-bound type by a guanine nucleotide exchange factor (GEF) and promoted for hybridization to the GDP-bound type by a GTPase-activating protein (GAP). Previous studies showed that auxin efflux facilitators such as PIN1 are regulated by GNOM, an ARF-GEF, in Arabidopsis. In the November issue of The Plant Journal, we reported that the auxin influx facilitator AUX1 was regulated by ARF-GAP via the vesicle trafficking system.¹ In this addendum, we report that overexpression of OsAGAP leads to enhanced root gravitropism and propose a new model of PAT regulation: a loop mechanism between ARF-GAP and GEF mediated by vesicle trafficking to regulate PAT at influx and efflux facilitators, thus controlling root development in plants.Key Words: ADP-ribosylation factor (ARF), ARF-GAP, ARF-GEF, auxin, GNOM, polar transport of auxinPolar auxin transport (PAT) is a unique process in plants. It results in alteration of auxin level, which controls organogenesis and development and a series of physiological processes, such as vascular differentiation, apical dominance, and tropic growth.² Genetic and physiological studies identified that PAT depends on efflux facilitators such as PIN family proteins and influx facilitators such as AUX1 in Arabidopsis.Eight PIN family proteins, AtPIN1 to AtPIN8, exist in Arabidopsis. AtPIN1 is located at the basal side of the plasma membrane in vascular tissues but is weak in cortical tissues, which supports the hypothesis of chemical pervasion.³ AtPIN2 is localized at the apical side of epidermal cells and basally in cortical cells.^1,4 GNOM, an ARF GEF, modulates the localization of PIN1 and vesicle trafficking and affects root development.^5,6 The PIN auxin-efflux facilitator network controls root growth and patterning in Arabidopsis.⁴ As well, asymmetric localization of AUX1 occurs in the root cells of Arabidopsis plants,⁷ and overexpression of OsAGAP interferes with localization of AUX1.¹ Our data support that ARF-GAP mediates auxin influx and auxin-dependent root growth and patterning, which involves vesicle trafficking.¹ Here we show that OsAGAP overexpression leads to enhanced gravitropic response in transgenic rice plants. We propose a model whereby ARF GTPase is a molecular switch to control PAT and root growth and development.Overexpression of OsAGAP led to reduced growth in primary or adventitious roots of rice as compared with wild-type rice.¹ Gravitropism assay revealed transgenic rice overxpressing OsAGAP with a faster response to gravity than the wild type during 24-h treatment. However, 1-naphthyl acetic acid (NAA) treatment promoted the gravitropic response of the wild type, with no difference in response between the OsAGAP transgenic plants and the wild type plants (Fig. 1). The phenotype of enhanced gravitropic response in the transgenic plants was similar to that in the mutants atmdr1-100 and atmdr1-100/atpgp1-100 related to Arabidopsis ABC (ATP-binding cassette) transporter and defective in PAT.⁸ The physiological data, as well as data on localization of auxin transport facilitators, support ARF-GAP modulating PAT via regulating the location of the auxin influx facilitator AUX1.¹ So the alteration in gravitropic response in the OsAGAP transgenic plants was explained by a defect in PAT.Open in a separate windowFigure 1Gravitropism of OsAGAP overexpressing transgenic rice roots and response to 1-naphthyl acetic acid (NAA). (A) Gravitropism phenotype of wild type (WT) and OsAGAP overexpressing roots at 6 hr gravi-stimulation (top panel) and 0 hr as a treatment control (bottom panel). (B) Time course of gravitropic response in transgenic roots. (C and D) results correspond to those in (A and B), except for treatment with NAA (5 × 10⁻⁷ M).The polarity of auxin transport is controlled by the asymmetric distribution of auxin transport proteins, efflux facilitators and influx carriers. ARF GTPase is a key member in vesicle trafficking system and modulates cell polarity and PAT in plants. Thus, ARF-GDP or GTP bound with GEF or GAP determines the ARF function on auxin efflux facilitators (such as PIN1) or influx ones (such as AUX1).ARF1, targeting ROP2 and PIN2, affects epidermal cell polarity.⁹ GNOM is involved in the regulation of PIN1 asymmetric localization in cells and its related function in organogenesis and development.⁶ Although VAN3, an ARF-GAP in Arabidopsis, is located in a subpopulation of the trans-Golgi transport network (TGN), which is involved in leaf vascular network formation, it does not affect PAT.¹⁰ OsAGAP possesses an ARF GTPase-activating function in rice.¹¹ Specifically, our evidence supports that ARF-GAP bound with ARF-GTP modulates PAT and gravitropism via AUX1, mediated by vesicle trafficking, including the Golgi stack.¹Therefore, we propose a loop mechanism between ARF-GAP and GEF mediated by the vascular trafficking system in regulating PAT at influx and efflux facilitators, which controls root development and gravitropism in plants (Fig. 2). Here we emphasize that ARF-GEF catalyzes a conversion of ARF-bound GDP to GTP, which is necessary for the efficient delivery of the vesicle to the target membrane.¹² An opposite process of ARF-bound GDP to GTP is promoted by ARF-GTPase-activating protein via binding. A loop status of ARF-GTP and ARF-GDP bound with their appurtenances controls different auxin facilitators and regulates root development and gravitropism.Open in a separate windowFigure 2Model for ARF GTPase as a molecular switch for the polar auxin transport mediated by the vesicle traffic system.     

Strigolactones' ability to regulate root development may be executed by induction of the ethylene pathway

The newly defined phytohormones strigolactones (SLs) were recently shown to act as regulators of root development. Their positive effect on root-hair (RH) elongation enabled examination of their cross talk with auxin and ethylene. Analysis of wild-type plants and hormone-signaling mutants combined with hormonal treatments suggested that SLs and ethylene regulate RH elongation via a common regulatory pathway, in which ethylene is epistatic to SLs. The SL and auxin hormonal pathways were suggested to converge for regulation of RH elongation; this convergence was suggested to be mediated via the ethylene pathway, and to include regulation of auxin transport.Key words: strigolactone, auxin, ethylene, root, root hair, lateral rootStrigolactones (SLs) are newly identified phytohormones that act as long-distance shoot-branching inhibitors (reviewed in ref. ¹). In Arabidopsis, SLs have been shown to be regulators of root development and architecture, by modulating primary root elongation and lateral root formation.^2,3 In addition, they were shown to have a positive effect on root-hair (RH) elongation.² All of these effects are mediated via the MAX2 F-box.^2,3In addition to SLs, two other plant hormones, auxin and ethylene, have been shown to affect root development, including lateral root formation and RH elongation.^4–6 Since all three phytohormones (SLs, auxin and ethylene) were shown to have a positive effect on RH elongation, we examined the epistatic relations between them by examining RH length.⁷ Our results led to the conclusion that SLs and ethylene are in the same pathway regulating RH elongation, where ethylene may be epistatic to SLs.⁷ Moreover, auxin signaling was shown to be needed to some extent for the RH response to SLs: the auxin-insensitive mutant tir1-1,⁸ was less sensitive to SLs than the wild type under low SL concentrations.⁷On the one hand, ethylene has been shown to induce the auxin response,^9–12 auxin synthesis in the root apex,^11,12 and acropetal and basipetal auxin transport in the root.^4,13 On the other, ethylene has been shown to be epistatic to SLs in the SL-induced RH-elongation response.⁷ Therefore, it might be that at least for RH elongation, SLs are in direct cross talk with ethylene, whereas the cross talk between SL and auxin pathways may converge through that of ethylene.⁷ The reduced response to SLs in tir1-1 may be derived from its reduced ethylene sensitivity;^7,14 this is in line with the notion of the ethylene pathway being a mediator in the cross talk between the SL and auxin pathways.The suggested ethylene-mediated convergence of auxin and SLs may be extended also to lateral root formation, and may involve regulation of auxin transport. In the root, SLs have been suggested to affect auxin efflux,^3,15 whereas ethylene has been shown to have a positive effect on auxin transport.^4,13 Hence, it might be that in the root, the SLs'' effect on auxin flux is mediated, at least in part, via the ethylene pathway. Ethylene''s ability to increase auxin transport in roots was associated with its negative effect on lateral root formation: ethylene was suggested to enhance polar IAA transport, leading to alterations in the quantity of auxin that unloads into the tissues to drive lateral root formation.⁴ Under conditions of sufficient phosphate, SL''s effect was similar to that of ethylene: SLs reduced the appearance of lateral roots; this was explained by their ability to change auxin flux.³ Taken together, one possibility is that the SLs'' ability to affect auxin flux and thereby lateral root formation in the roots is mediated by induction of ethylene synthesis.To conclude, root development may be regulated by a network of auxin, SL and ethylene cross talk.⁷ The possibility that similar networks exist elsewhere in the SLs'' regulation of plant development, including shoot architecture, cannot be excluded.     

Responses of root hair development to elevated CO2

This review highlights a potential signaling pathway of CO₂-dependent stimulation in root hair development. Elevated CO₂ firstly increases the carbohydrates production, which triggers the auxin or ethylene responsive signal transduction pathways and subsequently stimulates the generation of intracellular nitric oxide (NO). The NO acts on target Ca²⁺ and ion channels and induces activation of MAPK. Meanwhile, reactive oxygen species (ROS) activates cytoplasmic Ca²⁺ channels at the plasma membrane in the apex of the root tip. This complex pathway involves transduction cascades of multiple signals that lead to the fine tuning of epidermal cell initiation and elongation. The results suggest that elevated CO₂ plays an important role in cell differentiation processes at the root epidermis.Key words: elevated CO₂, root hairs, carbohydrate, auxin, ethylene, NO, ROS, Ca²⁺, genetic elementsIncreasing concentration of atmospheric CO₂ in the 21st century will impact many aspects of the human and natural world. Elevated CO₂ has some beneficial physiological effects on plants but nutrient limitation has generally been found to suppress these beneficial effects.¹ Therefore, under conditions of suboptimal supply of nutrients and elevated CO₂, the plants need to develop adaptive mechanisms to enhance nutrient acquisition, among which the plasticity of root development is of crucial importance.Root hairs make a significant contribution to increasing root surface area and facilitating physical anchorage to a substrate and providing a large interface for nutrient uptake.² Root-hair cells are highly polarized cellular structures resulting from tip growth of specific epidermal cells, which are controlled by multiple cellular factors and genetic processes.^3,4 Previous studies have shown that root hair development can influenced by various environmental factors, such as nutritional status,⁵ mycorrhizal infection and water stress,⁶ salinity⁷ and light intensity.⁸ Our current research has demonstrated a profound effect of elevated CO₂ on development of root hairs in Arabidopsis, which works through the well-characterized auxin signal transduction pathway.⁹ Since root hairs are an efficient strategy to alleviate the limitation of nutrients, one promising area of future research will be to discover the pathway that control root hair differentiation in crops under elevated CO₂. In this paper, we discussed a layer pathway in the interaction between CO₂ and some classical signals on regulating gene regulatory network to control development of root hairs.