Fluorescence recovery after photobleaching reveals high cycling dynamics of plasma membrane aquaporins in Arabidopsis roots under salt stress

The constitutive cycling of plant plasma membrane (PM) proteins is an essential component of their function and regulation under resting or stress conditions. Transgenic Arabidopsis plants that express GFP fusions with AtPIP1;2 and AtPIP2;1, two prototypic PM aquaporins, were used to develop a fluorescence recovery after photobleaching (FRAP) approach. This technique was used to discriminate between PM and endosomal pools of the aquaporin constructs, and to estimate their cycling between intracellular compartments and the cell surface. The membrane trafficking inhibitors tyrphostin A23, naphthalene-1-acetic acid and brefeldin A blocked the latter process. By contrast, a salt treatment (100 mm NaCl for 30 min) markedly enhanced the cycling of the aquaporin constructs and modified their pharmacological inhibition profile. Two distinct models for PM aquaporin cycling in resting or salt-stressed root cells are discussed.     

The response of Arabidopsis root water transport to a challenging environment implicates reactive oxygen species- and phosphorylation-dependent internalization of aquaporins

Aquaporins, which facilitate the diffusion of water across biological membranes, are key molecules for the regulation of water transport at the cell and organ levels. We recently reported that hydrogen peroxide (H₂O₂) acts as an intermediate in the regulation of Arabidopsis root water transport and aquaporins in response to NaCl and salicylic acid (SA).¹ Its action involves signaling pathways and an internalization of aquaporins from the cell surface. The present addendum connects these findings to another recent work which describes multiple phosphorylations in the C-terminus of aquaporins expressed in the Arabidopsis root plasma membrane.² A novel role for phosphorylation in the process of salt-induced relocalization of AtPIP2;1, one of the most abundant root aquaporins, was unraveled. Altogether, the data delineate reactive oxygen species (ROS)-dependent signaling mechanisms which, in response to a variety of abiotic and biotic stresses, can trigger phosphorylation-dependent PIP aquaporin intracellular trafficking and root water transport downregulation.Key words: reactive oxygen species, aquaporin, phosphorylation, cell signaling, stress, protein relocalization, root water transportPlants can regulate their water uptake capacity i.e. their root hydraulic conductivity (Lp_r) on a short term (minutes to hour) basis through regulation of plasma membrane (PM) aquaporins of the Plasma membrane Intrinsic Protein (PIP) subfamily.³ It has been known for a long time that salt stress (NaCl), as many other abiotic stresses such as cold, anoxia or nutrient deprivation, induces an inhibition of Lp_r in many plant species.³ In the recent study by Boursiac et al. (2008),¹ we identified SA as a new inhibitory increased the accumulation of ROS in roots, it was hypothesized that H₂O₂ or other ROS may have a central role in the regulation of root water transport in response to various biotic or abiotic stimuli. When Arabidopsis roots were treated with mM concentrations of exogenous H₂O₂, Lp_r was inhibited within minutes by up to 90%. These findings are consistent with previous reports showing that ROS can downregulate water transport in cucumber and maize roots or in the algae Chara corallina.^4–7 H₂O₂ and possibly other derived ROS may modulate the Lp_r through signaling mechanisms or by a direct oxidative gating of aquaporins. The latter hypothesis, which has been favored in previous studies by Steudle and colleagues,^6,7 was investigated by Boursiac et al., by functionally expressing aquaporins in Xenopus oocytes and by testing their sensitivity to external H₂O₂. The results show that Arabidopsis aquaporins are insensitive to direct oxidation by H₂O₂ or hydroxyl radicals. Thus, these and complementary pharmacological analyses on excised roots rather support a role for H₂O₂ as a second messenger that connects environmental stimulus perception to water transport regulation in plant roots. The additional finding that H₂O₂ can be transported by aquaporins^8,9 opens the possibility of intricate loop mechanisms whereby these proteins may interfere with their own regulation. For example, active PIP aquaporins could facilitate the diffusion within the cell of NADPH-oxidase derived apoplastic H₂O₂, which in turn would activate signaling pathways acting on PIP activity and/or subcellular localization.In a previous study, we monitored the subcellular localization of AtPIP1;2 and AtPIP2;1, two of the most abundant PIPs in roots, by expression in transgenic Arabidopsis of fusions with the green fluorescent protein (GFP).¹⁰ We observed that a 100 mM NaCl treatment induced in 2–4 hours an increased intracellular labeling which was interpreted as an intracellular relocalization of the two aquaporins.¹⁰ In our more recent study, both a 150 mM NaCl and a 0.5 mM SA treatments induced an intracellular labeling by GFP-PIP1;2 and PIP2;1-GFP fusions, with a “fuzzy” pattern or at the level of spherical bodies. Preventing the NaCl- or SA-dependent accumulation of ROS with exogenous catalase was able to almost completely counteract the effects of the two stimuli on the localization pattern of the PIP2;1-GFP fusion. In addition, the inhibition of Lp_r by SA was also counteracted at 33% by the catalase treatment. Altogether, the data stress the importance of an ROS-induced relocalization of aquaporins in the regulation of root water transport. Yet, we still miss quantitative data and complementary pharmacological evidence to determine the exact contribution of aquaporin relocalization with respect to other aquaporin regulatory mechanisms.Another recent work by our group has, however, provided deeper insights into the mechanisms of stress-induced relocalization of aquaporins in plants.² Our group identified by mass spectrometry multiple adjacent phosphorylation sites (up to 4 in the case of AtPIP2;4) in the C-terminus of aquaporins expressed at the root plasma membrane.² Phosphorylation of AtPIP2;1, which shows a simpler profile with only two sites at Ser280 and Ser283, was studied in closer detail by site-directed mutagenesis and expression in transgenic Arabidopsis of GFP-PIP2;1 fusions. A Ser283Ala mutation, which mimics a constitutively dephosphorylated Ser283, induced a marked intracellular accumulation of GFP-PIP2;1 in resting conditions. Because no phenotype was observed after a Ser280Ala mutation, the data suggest a specific role for Ser283 phosphorylation in the proper targeting of the protein. When plants were treated by 100 mM NaCl for 2 to 4 hours, the wild type (WT) and Ser280Ala mutant forms of GFP-PIP2;1 showed similar intracellular staining, in both “fuzzy” structures or spherical bodies. On the contrary, the Ser283Ala mutant did not label any spherical body. Interestingly, a Ser283Asp mutation that mimics a constitutively phosphorylated Ser283 resulted in a salt-induced labeling of spherical bodies similar to the one observed with WT GFP-PIP2;1 whereas no “fuzzy” staining was observed. Therefore, the phosphorylation status of Ser283 seems to determine the redistribution of AtPIP2;1 towards fuzzy structures (non-phosphorylated Ser283) or spherical bodies (phosphorylated Ser283). Although the nature of these intracellular structures remains to be identified, we now consider the possibility that the spherical bodies correspond to the late endosome/prevacuolar compartment that orientates aquaporins towards a degradation pathway whereas the fuzzy structures may act as a storage compartment for subsequent relocalization of PIP aquaporins to the PM, and rapid recovery of the PM water permeability. Although we favor the idea that the intracellular labeling shown by GFP-PIP2;1 in response to salt originates from aquaporins relocalized from the PM, newly synthesized proteins may also contribute to this pattern.Prak et al., also developed an absolute quantification method to show that the phosphorylation profile of AtPIP2;1 at the root plasma membrane was altered upon 100 mM NaCl and 2 mM H₂O₂ treatments. Whereas NaCl decreased the abundance of phosphorylated Ser283, H₂O₂ enhanced the overall phosphorylation of the AtPIP2;1 C-terminus. These observations add another level of complexity to the mechanisms of stimulus-induced and phosphorylation- dependent relocalisation of plant aquaporins uncovered in our group. Although one of the primary effects of NaCl is undoubtedly an accumulation of ROS, the difference in phosphorylation patterns observed in response to H₂O₂ and NaCl treatments may come from quantitative and kinetic differences in ROS patterns between the two treatments or from additional regulations activated by salt.We note that phosphorylation of PIP aquaporins had already been investigated in detail.^11–13 In particular, studies with spinach SoPIP2;1 has pointed to two phosphorylation sites, Ser115 in the first cytoplasmic loop (loop B) and Ser274 at the C-terminus, as important for modulating the water transport activity of this aquaporin after expression in Xenopus oocytes. A role for these two sites in aquaporin gating was also deduced from the atomic structure of SoPIP2;1.¹⁴ Whereas Ser280 in AtPIP2;1 corresponds to Ser274 in SoPIP2;1, the functional role of sites equivalent to Ser283 in AtPIP2;1 had not been considered previously in any other PIP. To our knowledge, the study by Prak et al., provides the first evidence in plants for a role of phosphorylation on the relocalization of aquaporins and highlights the importance of multiple phosphorylations sites in the C-terminus of aquaporins, as has been recently shown in human Aquaporin-2.^15,16Overall, the advance provided by our two recent studies delineates a working model (Fig. 1), whereby multiple abiotic and biotic stresses, which all induce an accumulation of ROS, activate common signaling pathways to downregulate root water transport. We have provided evidence that some of these pathways are calcium- and/ or protein kinase-dependent. One regulatory mechanism triggered by these pathways is the relocalization of aquaporins into intracellular “fuzzy” structures or bigger spherical bodies. For AtPIP2;1, the sorting between these structures is determined in part by the phosphorylation status of Ser283, which ultimately may control the cellular fate of the protein for degradation or remobilization to the PM. A coming challenge will be to determine how this and other cellular mechanisms quantitatively contribute to the integrated regulation of water transport at the cell and tissue (whole root) levels. Another avenue for future research will be to identify the molecular components involved in upstream ROS-dependent cell signaling and aquaporin phosphorylation. These studies will tell us how the regulation of root water uptake in parallel to the regulation of transpiration allows the plant to preserve its water status when it is continuously challenged by multiple stresses.Open in a separate windowFigure 1Tentative model of regulation of root hydraulic conductivity (Lp_r) through reactive oxygen species (ROS) signaling. Multiple biotic and abiotic stimuli such as NaCl or salicylic acid can induce an intra- and/or extracellular accumulation of ROS by acting on their production, degradation or transport. The stimulus-induced ROS in turn activate signaling pathways involving protein kinases and cytosolic calcium. These events result in changes in the phosphorylation and subcellular localization patterns of plasma membrane (PM) aquaporins (PIPs). In particular, endocytosis can direct PIPs towards various intracellular compartments for subsequent recycling at the PM or degradation. Phosphorylation can interfere with this routing process, but also determines the intrinsic water transport activity (gating) of PM localized PIPs. The possibility exists that signaling components directly act on PIP gating, recycling or degradation through phosphorylation- and endocytosis-independent pathways (not shown). In addition, transport of H₂O₂ by PIP aquaporins may provide retroactive effects of aquaporins on upstream signaling events. Aquaporin activity at the PM determines root cell water permeability, which contributes to most of Lp_r in Arabidopsis. The overall scheme shows how stress-induced ROS signaling results in an inhibition of PIP aquaporin activity and, as a consequence, in an overall downregulation of Lp_r.     

The Arabidopsis Abiotic Stress-Induced TSPO-Related Protein Reduces Cell-Surface Expression of the Aquaporin PIP2;7 through Protein-Protein Interactions and Autophagic Degradation

The Arabidopsis thaliana multi-stress regulator TSPO is transiently induced by abiotic stresses. The final destination of this polytopic membrane protein is the Golgi apparatus, where its accumulation is strictly regulated, and TSPO is downregulated through a selective autophagic pathway. TSPO-related proteins regulate the physiology of the cell by generating functional protein complexes. A split-ubiquitin screen for potential TSPO interacting partners uncovered a plasma membrane aquaporin, PIP2;7. Pull-down assays and fluorescence imaging approaches revealed that TSPO physically interacts with PIP2;7 at the endoplasmic reticulum and Golgi membranes in planta. Intriguingly, constitutive expression of fluorescently tagged PIP2;7 in TSPO-overexpressing transgenic lines resulted in patchy distribution of the fluorescence, reminiscent of the pattern of constitutively expressed yellow fluorescent protein-TSPO in Arabidopsis. Mutational stabilization of TSPO or pharmacological inhibition of the autophagic pathway affected concomitantly the detected levels of PIP2;7, suggesting that the complex containing both proteins is degraded through the autophagic pathway. Coexpression of TSPO and PIP2;7 resulted in decreased levels of PIP2;7 in the plasma membrane and abolished the membrane water permeability mediated by transgenic PIP2;7. Taken together, these data support a physiological role for TSPO in regulating the cell-surface expression of PIP2;7 during abiotic stress conditions through protein-protein interaction and demonstrate an aquaporin regulatory mechanism involving TSPO.     

Single-molecule analysis of PIP2;1 dynamics and partitioning reveals multiple modes of Arabidopsis plasma membrane aquaporin regulation

PIP2;1 is an integral membrane protein that facilitates water transport across plasma membranes. To address the dynamics of Arabidopsis thaliana PIP2;1 at the single-molecule level as well as their role in PIP2;1 regulation, we tracked green fluorescent protein-PIP2;1 molecules by variable-angle evanescent wave microscopy and fluorescence correlation spectroscopy (FCS). Single-particle tracking analysis revealed that PIP2;1 presented four diffusion modes with large dispersion of diffusion coefficients, suggesting that partitioning and dynamics of PIP2;1 are heterogeneous and, more importantly, that PIP2;1 can move into or out of membrane microdomains. In response to salt stress, the diffusion coefficients and percentage of restricted diffusion increased, implying that PIP2;1 internalization was enhanced. This was further supported by the decrease in PIP2;1 density on plasma membranes by FCS. We additionally demonstrated that PIP2;1 internalization involves a combination of two pathways: a tyrphostin A23-sensitive clathrin-dependent pathway and a methyl-β-cyclodextrin-sensitive, membrane raft-associated pathway. The latter was efficiently stimulated under NaCl conditions. Taken together, our findings demonstrate that PIP2;1 molecules are heterogeneously distributed on the plasma membrane and that clathrin and membrane raft pathways cooperate to mediate the subcellular trafficking of PIP2;1, suggesting that the dynamic partitioning and recycling pathways might be involved in the multiple modes of regulating water permeability.     

Changes in plasma membrane aquaporin gene expression under osmotic stress and blue light in tomato

Divergent abiotic stresses induce osmotic stress on plant cells resulting in an imbalance in water homeostasis which is preserved by aquaporins. Since the plasma membrane aquaporins (PIPs) were shown to be involved in seed development and responses to abiotic stresses, we focused on determining the contribution of mannitol-induced osmotic stress, blue light (BL), and 7B-1 mutation to their gene expression in tomato (Solanum lycopersicum L.) seeds. To assess that, we used a quantitative RT-PCR to determine the expression profiles of genes encoding PIPs. Subsequently, a multiple linear regression analysis was used to evaluate the impact of studied stressors (mannitol and BL) and 7B-1 mutation on PIP gene expressions. We found that mannitol-induced osmotic stress and 7B-1 mutation (conferring the lower responsiveness to osmotic stress- and BL-induced inhibition of seed germination) decreased expression of PIP1;3, PIP2;3 and PIP1;2, PIP2;1 genes, respectively. This might be a way to retain water for radicle elongation and seed germination under the stress conditions. Interestingly, the expression of PIP1;3 gene was downregulated not only by osmotic stress, but also by BL. Altogether, our data indicate the existence of a link between osmotic stress and BL signalling and the involvement of the 7B-1 mutation in this crosstalk.     

A map of the subcellular distribution of phosphoinositides in the erythrocytic cycle of the malaria parasite Plasmodium falciparum

Despite representing a small percentage of the cellular lipids of eukaryotic cells, phosphoinositides (PIPs) are critical in various processes such as intracellular trafficking and signal transduction. Central to their various functions is the differential distribution of PIP species to specific membrane compartments through the actions of kinases, phosphatases and lipases. Despite their importance in the malaria parasite lifecycle, the subcellular distribution of most PIP species in this organism is still unknown. We here localise several species of PIPs throughout the erythrocytic cycle of Plasmodium falciparum. We show that PI3P is mostly found at the apicoplast and the membrane of the food vacuole, that PI4P associates with the Golgi apparatus and the plasma membrane and that PI(4,5)P2, in addition to being detected at the plasma membrane, labels some cavity-like spherical structures. Finally, we show that the elusive PI5P localises to the plasma membrane, the nucleus and potentially to the transitional endoplasmic reticulum (ER). Our map of the subcellular distribution of PIP species in P. falciparum will be a useful tool to shed light on the dynamics of these lipids in this deadly parasite.     

Transgenic <Emphasis Type="Italic">Arabidopsis</Emphasis> and tobacco plants overexpressing an aquaporin respond differently to various abiotic stresses

Despite the high isoform multiplicity of aquaporins in plants, with 35 homologues including 13 plasma membrane intrinsic proteins (PIPs) in Arabidosis thaliana, the individual and integrated functions of aquaporins under various physiological conditions remain unclear. To better understand aquaporin functions in plants under various stress conditions, we examined transgenic Arabidopsis and tobacco plants that constitutively overexpress Arabidopsis PIP1;4 or PIP2;5 under various abiotic stress conditions. No significant differences in growth rates and water transport were found between the transgenic and wild-type plants when grown under favorable growth conditions. The transgenic plants overexpressing PIP1;4 or PIP2;5 displayed a rapid water loss under dehydration stress, which resulted in retarded germination and seedling growth under drought stress. In contrast, the transgenic plants overexpressing PIP1;4 or PIP2;5 showed enhanced water flow and facilitated germination under cold stress. The expression of several PIPs was noticeably affected by the overexpression of PIP1;4 or PIP2;5 in Arabidopsis under dehydration stress, suggesting that the expression of one aquaporin isoform influences the expression levels of other aquaporins under stress conditions. Taken together, our results demonstrate that overexpression of an aquaporin affects the expression of endogenous aquaporin genes and thereby impacts on seed germination, seedling growth, and stress responses of the plants under various stress conditions. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Nonvesicular sterol movement from plasma membrane to ER requires oxysterol-binding protein-related proteins and phosphoinositides

Sterols are moved between cellular membranes by nonvesicular pathways whose functions are poorly understood. In yeast, one such pathway transfers sterols from the plasma membrane (PM) to the endoplasmic reticulum (ER). We show that this transport requires oxysterol-binding protein (OSBP)-related proteins (ORPs), which are a large family of conserved lipid-binding proteins. We demonstrate that a representative member of this family, Osh4p/Kes1p, specifically facilitates the nonvesicular transfer of cholesterol and ergosterol between membranes in vitro. In addition, Osh4p transfers sterols more rapidly between membranes containing phosphoinositides (PIPs), suggesting that PIPs regulate sterol transport by ORPs. We confirmed this by showing that PM to ER sterol transport slows dramatically in mutants with conditional defects in PIP biosynthesis. Our findings argue that ORPs move sterols among cellular compartments and that sterol transport and intracellular distribution are regulated by PIPs.     

Temperature-induced lipocalin (TIL) is translocated under salt stress and protects chloroplasts from ion toxicity

Temperature-induced lipocalins (TIL) have been invoked in the defense from heat, cold and oxidative stress. Here we document a function of TIL for basal protection from salinity stress. Heterologous expression of TIL from the salt resistant poplar Populus euphratica did not rescue growth but prevented chlorophyll b destruction in salt-exposed Arabidopsis thaliana. The protein was localized to the plasma membrane but was re-translocated to the symplast under salt stress. The A. thaliana knock out and knock down lines Attil1-1 and Attil1-2 showed stronger stress symptoms and stronger chlorophyll b degradation than the wildtype (WT) under excess salinity. They accumulated more chloride and sodium in chloroplasts than the WT. Chloroplast chloride accumulation was found even in the absence of salt stress. Since lipocalins are known to bind regulatory fatty acids of channel proteins as well as iron, we suggest that the salt-induced trafficking of TIL may be required for protection of chloroplasts by affecting ion homeostasis.     

Arabidopsis dynamin-related protein 1A polymers bind, but do not tubulate, liposomes

The Arabidopsis dynamin-related protein 1A (AtDRP1A) is involved in endocytosis and cell plate maturation in Arabidopsis. Unlike dynamin, AtDRP1A does not have any recognized membrane binding or protein-protein interaction domains. We report that GTPase active AtDRP1A purified from Escherichia coli as a fusion to maltose binding protein forms homopolymers visible by negative staining electron microscopy. These polymers interact with protein-free liposomes whose lipid composition mimics that of the inner leaflet of the Arabidopsis plasma membrane, suggesting that lipid-binding may play a role in AtDRP1A function. However, AtDRP1A polymers do not appear to assemble and disassemble in a dynamic fashion and do not have the ability to tubulate liposomes in vitro, suggesting that additional factors or modifications are necessary for AtDRP1A’s in vivo function.     

Phosphoinositides regulate clathrin-dependent endocytosis at the tip of pollen tubes in Arabidopsis and tobacco

Using the tip-growing pollen tube of Arabidopsis thaliana and Nicotiana tabacum as a model to investigate endocytosis mechanisms, we show that phosphatidylinositol-4-phosphate 5-kinase 6 (PIP5K6) regulates clathrin-dependent endocytosis in pollen tubes. Green fluorescent protein-tagged PIP5K6 was preferentially localized to the subapical plasma membrane (PM) in pollen tubes where it apparently converts phosphatidylinositol 4-phosphate (PI4P) to phosphatidylinositol 4,5-bisphosphate [PI(4,5)P(2)]. RNA interference-induced suppression of PIP5K6 expression impaired tip growth and inhibited clathrin-dependent endocytosis in pollen tubes. By contrast, PIP5K6 overexpression induced massive aggregation of the PM in pollen tube tips. This PM abnormality was apparently due to excessive clathrin-dependent membrane invagination because this defect was suppressed by the expression of a dominant-negative mutant of clathrin heavy chain. These results support a role for PI(4,5)P(2) in promoting early stages of clathrin-dependent endocytosis (i.e., membrane invagination). Interestingly, the PIP5K6 overexpression-induced PM abnormality was partially suppressed not only by the overexpression of PLC2, which breaks down PI(4,5)P(2), but also by that of PI4Kβ1, which increases the pool of PI4P. Based on these observations, we propose that a proper balance between PI4P and PI(4,5)P(2) is required for clathrin-dependent endocytosis in the tip of pollen tubes.     

Mechanisms and effects of retention of over-expressed aquaporin AtPIP2;1 in the endoplasmic reticulum

Plasma membrane intrinsic proteins (PIPs) are aquaporins that mediate water transport across the plant plasma membrane (PM). The present work addresses, using Arabidopsis AtPIP2;1 as a model, the mechanisms and significance of trafficking of newly synthesized PIPs from the endoplasmic reticulum (ER) to the Golgi apparatus. A functional diacidic export motif (Asp4-Val5-Glu6) was identified in the N-terminal tail of AtPIP2;1, using expression in transgenic Arabidopsis of site-directed mutants tagged with the green fluorescent protein (GFP). Confocal fluorescence imaging and a novel fluorescence recovery after photobleaching application based on the distinct diffusion of PM and intracellular AtPIP2;1-GFP forms revealed a retention in the ER of diacidic mutated forms, but with quantitative differences. Thus, the individual role of the two acidic Asp4 and Glu6 residues was established. In addition, expression in transgenic Arabidopsis of ER-retained AtPIP2;1-GFP constructs reduced the root hydraulic conductivity. Co-expression of AtPIP2;1-GFP and AtPIP1;4-mCherry constructs suggested that ER-retained AtPIP2;1-GFP may interact with other PIPs to hamper their trafficking to the PM, thereby contributing to inhibition of root cell hydraulic conductivity.     

Clathrin and Membrane Microdomains Cooperatively Regulate RbohD Dynamics and Activity in Arabidopsis

Arabidopsis thaliana respiratory burst oxidase homolog D (RbohD) functions as an essential regulator of reactive oxygen species (ROS). However, our understanding of the regulation of RbohD remains limited. By variable-angle total internal reflection fluorescence microscopy, we demonstrate that green fluorescent protein (GFP)-RbohD organizes into dynamic spots at the plasma membrane. These RbohD spots have heterogeneous diffusion coefficients and oligomerization states, as measured by photobleaching techniques. Stimulation with ionomycin and calyculin A, which activate the ROS-producing enzymatic activity of RbohD, increases the diffusion and oligomerization of RbohD. Abscisic acid and flg22 treatments also increase the diffusion coefficient and clustering of GFP-RbohD. Single-particle analysis in clathrin heavy chain2 mutants and a Flotillin1 artificial microRNA line demonstrated that clathrin- and microdomain-dependent endocytic pathways cooperatively regulate RbohD dynamics. Under salt stress, GFP-RbohD assembles into clusters and then internalizes into the cytoplasm. Dual-color fluorescence cross-correlation spectroscopy analysis further showed that salt stress stimulates RbohD endocytosis via membrane microdomains. We demonstrate that microdomain-associated RbohD spots diffuse at the membrane with high heterogeneity, and these dynamics closely relate to RbohD activity. Our results provide insight into the regulation of RbohD activity by clustering and endocytosis, which facilitate the activation of redox signaling pathways.     

PIP Water Transport and Its pH Dependence Are Regulated by Tetramer Stoichiometry

Many plasma membrane channels form oligomeric assemblies, and heterooligomerization has been described as a distinctive feature of some protein families. In the particular case of plant plasma membrane aquaporins (PIPs), PIP1 and PIP2 monomers interact to form heterotetramers. However, the biological properties of the different heterotetrameric configurations formed by PIP1 and PIP2 subunits have not been addressed yet. Upon coexpression of tandem PIP2-PIP1 dimers in Xenopus oocytes, we can address, for the first time to our knowledge, the functional properties of single heterotetrameric species having 2:2 stoichiometry. We have also coexpressed PIP2-PIP1 dimers with PIP1 and PIP2 monomers to experimentally investigate the localization and biological activity of each tetrameric assembly. Our results show that PIP2-PIP1 heterotetramers can assemble with 3:1, 1:3, or 2:2 stoichiometry, depending on PIP1 and PIP2 relative expression in the cell. All PIP2-PIP1 heterotetrameric species localize at the plasma membrane and present the same water transport capacity. Furthermore, the contribution of any heterotetrameric assembly to the total water transport through the plasma membrane doubles the contribution of PIP2 homotetramers. Our results also indicate that plasma membrane water transport can be modulated by the coexistence of different tetrameric species and by intracellular pH. Moreover, all the tetrameric species present similar cooperativity behavior for proton sensing. These findings throw light on the functional properties of PIP tetramers, showing that they have flexible stoichiometry dependent on the quantity of PIP1 and PIP2 molecules available. This represents, to our knowledge, a novel regulatory mechanism to adjust water transport across the plasma membrane.     

An aquaporin gene from halophyte <Emphasis Type="Italic">Sesuvium portulacastrum</Emphasis>, <Emphasis Type="Italic">SpAQP1</Emphasis>, increases salt tolerance in transgenic tobacco

Key message

SpAQP1 was strongly induced by salt in an ABA-independent way, promoted seed germination and root growth in transgenic tobaccos and increased salt tolerance by increasing the activities of antioxidative enzymes.

Abstract

Aquaporin (AQP) plays crucial roles in the responses of plant to abiotic stresses such as drought, salt and cold. Compared to glycophytes, halophytes often have excellent salt and drought tolerances. To uncover the molecular mechanism of halophyte Sesuvium portulacastrum tolerance to salt, in this study, an AQP gene, SpAQP1, from S. portulacastrum was isolated and characterized. The amino acid sequence of SpAQP1 shared high homology with that of plant plasma membrane intrinsic proteins (PIPs) and contained the distinct molecular features of PIPs. In the phylogenic tree, SpAQP1 was evidently classified as the PIP2 subfamily. SpAQP1 is expressed in roots, stems and leaves, and was significantly induced by NaCl treatment and inhibited by abscisic acid (ABA) treatment. When heterologously expressed in yeast and tobacco, SpAQP1 enhanced the salt tolerance of yeast strains and tobacco plants and promoted seed germination and root growth under salt stress in transgenic plants. The activity of antioxidative enzymes including superoxide dismutase, peroxidase and catalase was increased in transgenic plants overexpressing SpAQP1. Taken together, our studies suggested that SpAQP1 functioned in the responses of S. portulacastrum to salt stress and could increase salt tolerance by enhancing the antioxidative activity of plants.

     

A conserved cysteine residue is involved in disulfide bond formation between plant plasma membrane aquaporin monomers

AQPs (aquaporins) are conserved in all kingdoms of life and facilitate the rapid diffusion of water and/or other small solutes across cell membranes. Among the different plant AQPs, PIPs (plasma membrane intrinsic proteins), which fall into two phylogenetic groups, PIP1 and PIP2, play key roles in plant water transport processes. PIPs form tetramers in which each monomer acts as a functional channel. The intermolecular interactions that stabilize PIP oligomer complexes and are responsible for the resistance of PIP dimers to denaturating conditions are not well characterized. In the present study, we identified a highly conserved cysteine residue in loop A of PIP1 and PIP2 proteins and demonstrated by mutagenesis that it is involved in the formation of a disulfide bond between two monomers. Although this cysteine seems not to be involved in regulation of trafficking to the plasma membrane, activity, substrate selectivity or oxidative gating of ZmPIP1s (Zm is Zea mays), ZmPIP2s and hetero-oligomers, it increases oligomer stability under denaturating conditions. In addition, when PIP1 and PIP2 are co-expressed, the loop A cysteine of ZmPIP1;2, but not that of ZmPIP2;5, is involved in the mercury sensitivity of the channels.