Phosphatidylinositol 3-Kinase Promotes Activation and Vacuolar Acidification and Delays Methyl Jasmonate-Induced Leaf Senescence.

Phosphatidylinositol 3-Kinase Promotes V-ATPase Activation and Vacuolar Acidification and Delays Methyl Jasmonate-Induced Leaf Senescence1 Jian Liu, Yingbin Ji, Jun Zhou, and Da Xing* MOE Key Laboratory of Laser Life Science, and Institute of Laser Life Science, College of Biophotonics, South China Normal University, Guangzhou 510631, China (J.L., Y.J., J.Z., D. X.).

PI3K and its product PI3P are both involved in plant development and stress responses. In this study, the down-regulation of PI3K activity accelerated leaf senescence induced by methyl jasmonate (MeJA) and suppressed the activation of vacuolar H+-ATPase (V-ATPase). Yeast two-hybrid analyses indicated that PI3K bound to the V-ATPase B subunit (VHA-B). Analysis of bimolecular fluorescence complementation in tobacco guard cells showed that PI3K interacted with VHA-B2 in the tonoplasts. Through the use of pharmacological and genetic tools, we found that PI3K and V-ATPase promoted vacuolar acidification and stomatal closure during leaf senescence. Vacuolar acidification was suppressed by the PIKfyve inhibitor in 35S:AtVPS34-YFP Arabidopsis during MeJA-induced leaf senescence, but the decrease was lower than that in YFP-labeled Arabidopsis. These results suggest that PI3K promotes V-ATPase activation and consequently induces vacuolar acidification and stomatal closure, thereby delaying MeJA-induced leaf senescence.

Leaf senescence is a complex, highly ordered process that occurs toward the end of leaf development (Lim et al., 2007). Although leaf senescence is an agedependent process, it is also induced by diverse biotic and abiotic stresses (Wingler et al., 2006). Leaf senescence is regulated by several plant hormones, such as jasmonic acid, ethylene, abscisic acid (ABA), and cytokinins (Lim et al., 2007). During leaf senescence, metabolism is significantly altered; for example, there is a switch to carbon assimilation to catabolize energy resources and enhance chlorophyll degradation (Yue et al., 2012). In addition, the water loss of senescing leaves is more rapid than that of nonsenescing leaves (Zhang et al., 2012). Water control is primarily dependent on stomatal movement, which can be regulated by vacuolar acidification (Bak et al., 2013). In plants, three distinct proton pumps can generate pH gradients (Gaxiola et al., 2007). Vacuolar H+-ATPase (V-ATPase) is a key proton pump that is localized in tonoplasts and 1

This research is supported by the Program for Changjiang Scholars and Innovative Research Team in University (no. IRT0829), the Key Program of NSFC-Guangdong Joint Funds of China (no. U0931005), and the National High Technology Research a n d De v e l o p m e n t Pr o g r am o f C h i n a ( 86 3 P r o g r a m ; n o . 2007AA10Z204). * Address correspondence to [email protected]. The author responsible for distribution of materials integral to the findings presented in this article in accordance with the policy described in the Instructions for Authors (www.plantphysiol.org) is: Da Xing ([email protected]). J.L. and D.X. designed the research; J.L. and Y.J. performed research; D.X. contributed analytic and computational tools; J.L., Y.J., J.Z., and D.X. analyzed data; and J.L., Y.J., J.Z., and D.X. wrote the paper. www.plantphysiol.org/cgi/doi/10.1104/pp.15.00744 1714

consists of 14 different subunits and two subcomplexes. The peripheral V1 domain is composed of eight distinct subunits (A3, B3, C1, D1, E2, F1, G2, and H1-2) and functions in ATP hydrolysis, whereas the integral V0 domain consists of six different subunits (a1, d1, en, c4-5, c91, and c991) and is responsible for proton translocation (Cipriano et al., 2008). V-ATPase is involved in various physiological events and stress responses, including embryonic development, lateral root development, membrane trafficking, nutrient storage, and environmental stress tolerance (Dettmer et al., 2005; Marshansky and Futai, 2008; Krebs et al., 2010). The major mechanism of V-ATPase regulation is the reversible assembly/disassembly of the V0 and V1 sectors. In renal epithelial cells induced with Glc, phosphoinositide 3-kinase type I (PI3K) promotes the assembly and translocation of V-ATPase (Sautin et al., 2005). PI3K activated by influenza A virus also interacts with the E subunit of the V1 domain of V-ATPase (Marjuki et al., 2011). In mammalian cells, there are three types of PI3K with distinct substrate specificities. The generation of phosphatidylinositol 3,4,5-trisphosphate (PtdIns (3,4,5)P3) by PI3K type I activates a highly complex downstream signaling network that regulates different cellular responses. The most recognized downstream target of PtdIns(3,4,5)P3 is protein kinase B, which is involved in the regulation of cell growth, proliferation, survival, and metabolism, as well as in protein transcription and synthesis (Foster et al., 2003). Other wellcharacterized proteins can also function as downstream targets of PtdIns(3,4,5)P3 production. These proteins include Tyr kinase Tec, phospholipase PLCg, most small GTPase activators, and V-ATPase (Hirsch et al., 2007; Sautin et al., 2005). PI3K type II uses phosphatidylinositol and phosphatidylinositol-4-phosphate as

Plant PhysiologyÒ, March 2016, Vol. 170, pp. 1714–1731, www.plantphysiol.org Ó 2016 American Society of Plant Biologists. All Rights Reserved.

PI3K Delays Leaf Senescence by Activating V-ATPase

substrates and suppresses apoptotic cell death, cytoskeletal organization, exocytosis, and insulin signaling (Lee et al., 2010). PI3K type III, which is the only type of PI3K identified in plants, phosphorylates the D-3 position of phosphoinositides; nevertheless, the function of PI3K type III appears to be more comprehensive and multifaceted than previously reported (Bunney et al., 2000). In Arabidopsis, PI3K type III promotes protein trafficking and endocytosis as well as intracellular ROS production, as reflected in the enhanced stomatal closing, F-actin reorganization, and pollen development observed upon PI3K type III activation (Park et al., 2003; Choi et al., 2008; Lee et al., 2008). PI3K type III is also involved in nuclear functions (Bunney et al., 2000). Although various studies have been conducted on PI3K, information on the role of PI3K in leaf senescence is lacking. Sugars accumulate in senescent Arabidopsis leaves (Wingler et al., 2012), and the accumulative signals of these compounds initiate the PI3K-V-ATPase pathway in senescent cells. The regulatory action of PI3K on V-ATPase has not been confirmed in plants, but recent reports have indicated a possible relationship between PI3K and V-ATPase (Aparicio-Fabre et al., 2006; daSilva et al., 2005; Ma et al., 2011; Schumacher and Krebs, 2010). V-ATPase is localized in various subcellular organelles in plants, such as the endoplasmic reticulum, Golgi apparatus, and vacuoles (Schumacher and Krebs, 2010). In each location, the targeting of V-ATPase to different membranes via vesicular trafficking is an important mechanism (Marshansky and Futai, 2008). PI3K type III plays a vital role in the trafficking of proteins to and from vacuoles. Treatment with PI3K inhibitors blocks the retrograde transport of vacuolar sorting receptors to the trans-Golgi (TGN), thereby resulting in vacuolation or swelling of the prevacuolar compartment (daSilva et al., 2005). PI3P is present in various compartments of plant cells, and it plays a role in the vacuolar trafficking of sporamin, which is normally localized in the large central vacuole (Kim et al., 2001). These studies have indicated that PI3K may regulate the transport of V-ATPase subunits from the TGN to the tonoplasts. V-ATPase activity is essential for endocytic and secretory trafficking in Arabidopsis (Dettmer et al., 2006), and V-ATPase may be regulated by PI3K in vacuolar trafficking. Structural biology studies have further demonstrated the possible relationship between V-ATPase and PI3K. The N-terminal domain of the V-ATPase subunit B in Arabidopsis contains a profilinlike motif (Ma et al., 2011). PI3K interacts with profilin in the poly-L-Pro-binding regions (Aparicio-Fabre et al., 2006) and with the V-ATPase subunit B. These interactions regulate the assembly of the V-ATPase complex and the activity of V-ATPase. Mammalian PI3K type I promotes the assembly and translocation of V-ATPase (Sautin et al., 2005). Plant V-ATPase down-regulation results in an enhanced stomatal aperture (Allen et al., 2000; Zhang et al., 2013), which leads to rapid water loss and premature leaf senescence (Zhang et al., 2012). Given these findings, we Plant Physiol. Vol. 170, 2016

speculated that leaf senescence proceeds in the following order: Glc-PI3K-activation of V-ATPase-vacuolar acidification-stomatal closure-reduction of water lossalleviation of leaf senescence. Wortmannin and LY294002 are two pharmacological PI3K inhibitors used to elucidate the function of PI3Ks. Wortmannin, a fungal metabolite, dose-dependently targets PI3K and PI4K (Takác et al., 2012). At the subcellular level, wortmannin inhibits vacuolar trafficking and dilatation of the cell wall as well as the fusion, swelling, and vacuolization of the multivesicular body (Jaillais et al., 2008; Pimpl et al., 2006). LY294002, which is derived from the flavonoid quercetin, competes with ATP and binds to Lys residues in the ATP-binding pocket of PI3Ks (Walker et al., 2000). Generally, LY294002 suppresses PI3K-related kinases, such as DNA-dependent protein kinase and the target of rapamycin (Brunn et al., 1996). LY294002 is considered to be more selective than wortmannin (Leprince et al., 2014). In this work, we found that the stomatal aperture increased in methyl jasmonate (MeJA)-induced senescence, and that inhibition of vacuolar acidification promoted stomatal opening and accelerated senescence. The activity of V-ATPase and gene expression of its subunits was also increased in MeJA-induced leaf senescence. Treatment with PI3K inhibitors or down-regulation of AtVPS34 gene expression further suppressed V-ATPase activation in MeJA-induced leaf senescence. The results of yeast two-hybrid and bimolecular fluorescence complementation (BiFC) assays demonstrated that PI3K bound to the V-ATPase subunit B2 (VHA-B2) in vitro and in vivo. Vacuolar pH and the stomatal aperture also increased in the pi3k mutant and in treatments with PI3K inhibitors. Our findings demonstrate that PI3K binds to VHA-B2 and promotes the activation of V-ATPase, resulting in vacuolar acidification and stomatal closure, thereby delaying MeJAinduced leaf senescence. RESULTS Enhanced Stomatal Aperture during MeJA-Induced Leaf Senescence

Detached wild-type Arabidopsis leaves were treated with 50 mM MeJA for 3 d and observed using standard microscopy and scanning electron microscopy (SEM) to assess the stomatal aperture during leaf senescence. The stomatal aperture increased with increasing treatment time (Fig. 1, A and B). A similar increase in the stomatal aperture was also observed via SEM (Supplemental Fig. S1). Given that vacuolar acidification is important in regulating stomatal movement, we determined the pH of the stomata by using acridine orange (OH), a pH-sensitive fluorescent dye. The pH was lower in the closing stomata than in the opening stomata (Fig. 1B). These results indicated a relationship between increased stomatal aperture and vacuolar alkalization during MeJA-induced leaf senescence. 1715

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Figure 1. An increased stomatal aperture during leaf senescence. A, An increased stomatal aperture during leaf senescence. During the process of MeJA-induced senescence (1–3 d), the stomatal aperture was assayed by microscopy. Bars = 20 mm. Stomata are marked by arrowhead. Control means untreated with MeJA. B, Stomatal aperture were determined by microscopy and given as width to length ratio (n . 30). Asterisks (*) indicate significant difference by t test from the control treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test). C, The link between stomatal aperture and vacuolar acidification. Vacuolar acidification was observed using AO. After treatment with 50 mM MeJA for 3 d, the guard cells were stained with 50 mM AO for 100 min. A model no. LSM510 Meta microscope (Carl Zeiss) was used to detect the fluorescence ratio. The R/G ratio is displayed in pseudocolor. Regions with the lowest R/G ratio are in blue, while those with the highest R/G ratio (more acidic) are in red. The stomata in the square frame were enlarged in the right panel as shown in type 1 and type 2. Bars = 20 mm or 5 mm.

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V-ATPase Inhibitor Accelerates Vacuolar Alkalization and Stomatal Opening, Thereby Promoting MeJA-Induced Leaf Senescence

Bafilomycin A1 (BFA1), a V-ATPase-specific inhibitor, was used to elucidate the role of vacuolar alkalization in stomatal movement during leaf senescence. Treatment with 500 nM BFA1 accelerated vacuolar alkalization in leaf senescence induced by 50 mM MeJA in wild-type Arabidopsis (Fig. 2A). After 3 d of MeJA treatment, the stomatal aperture of leaves treated with 500 n M BFA1 increased by approximately 1.4-fold compared to leaves treated with only MeJA (Fig. 2, B and C). As concentrations of BFA1 increased (100 nM, 500 nM, and 1 mM), we observed more intense yellowing of leaves than that of controls treated with 50 mM MeJA for 3 d (Fig. 2D). The photochemical efficiency demonstrated a similar trend to that obtained in the photosystem II (PSII) assay (Fig. 2E). Conversely, leaf yellowing and photochemical efficiency were not significantly different in the series containing BFA1 without MeJA treatment (Fig. 2, D and E). Furthermore, treatment with BFA1 promoted gene expression of SAG12 in MeJA-induced leaf senescence (Fig. 2F). These results implied that vacuolar alkalization regulates stomatal opening and promotes MeJA-induced leaf senescence. Increased V-ATPase Activity and Gene Expression of V-ATPase Subunits during MeJA-Induced Leaf Senescence

V-ATPase activity and the gene expression patterns of the V-ATPase subunits were examined to explore the mechanisms of MeJA-induced leaf senescence. Detached wild-type Arabidopsis leaves were treated with 50 mM MeJA for 5 d. V-ATPase activity was measured with concanamycin A (Con A), which is a sensitive indicator of ATP hydrolysis. As shown in Figure 3A, the activity of V-ATPase in tonoplasts increased continuously during MeJA-induced leaf senescence in wild-type Arabidopsis. We also examined V-ATPase activity in microsomal membrane fractions. A similar increase in the activity of V-ATPase was observed in leaves treated with MeJA compared to control leaves (Supplemental Fig. S2). Gene expression of the V-ATPase subunits was also determined upon treatment with 50 mM MeJA. The results showed that gene expression of V-ATPase subunit A (VHA-A), subunit C (VHA-C), and VHA-B2 were up-regulated in senescent leaves, but their expression patterns differed. The gene expression of VHA-A and VHA-B2 peaked on the first day after treatment and then decreased with increasing treatment time, whereas the gene expression of VHA-C continuously increased (Fig. 3B). Hence, MeJA-induced senescence in Arabidopsis correlates with elevated V-ATPase activity and vha gene expression. Given that sugars also accumulate in senescent Arabidopsis leaves, we treated 3-week-old detached leaves with Glc or mannitol at two different concentrations (0.5% or 1.8%) to detect the effect of Glc Plant Physiol. Vol. 170, 2016

signaling on V-ATPase activation (Supplemental Fig. S3A). After 6 h, V-ATPase activity was up-regulated with an increasing concentration of Glc but was not significantly different from leaves treated with mannitol. Additionally, the activity of V-ATPase was measured at different times after 1.8% Glc or mannitol treatment (Supplemental Fig. S3B). The activity of V-ATPase increased with increasing treatment times. Down-Regulation of PI3K Activity Inhibits the Activity of V-ATPase in MeJA-Induced Leaf Senescence

The role of PI3K type III in the regulation of V-ATPase activity was also determined in Arabidopsis. LY294002 (30 mM) was used in treatments with external 1.8% Glc. The results showed that LY294002 suppressed V-ATPase activation induced by Glc in Arabidopsis leaves (Supplemental Fig. S4). The gene expression of AtVPS34 encoding PI3K was also determined as senescence progressed. The gene expression of AtVPS34 increased in wild-type Arabidopsis after treatment with 50 mM MeJA for 1 d (Supplemental Fig. S5), which indicated that PI3K was expressed during MeJA-induced senescence in wild-type Arabidopsis. Two pi3k mutants (pi3k-1: SALK_007281 and pi3k-2: GABI_418H02) and the PI3K inhibitors LY294002 (30 mM) and wortmannin (10 mM) were used to downregulate the activity of PI3K type III in Arabidopsis. Gene expression of AtVPS34 was significantly downregulated in the pi3k mutants compared to wild-type plants (Supplemental Fig. S6A). Consistently with previous results, these findings showed that MeJA treatment promotes V-ATPase activity (Fig. 4, A and B; Supplemental Fig. S7). Treatment with both PI3K inhibitors (30 mM LY294002 or 10 mM wortmannin) and mutation of AtVPS34 suppressed V-ATPase activity in detached and attached leaves during MeJA-induced senescence. In treatments without MeJA, V-ATPase activity was not significantly different in pi3k mutants or among treatments with the PI3K inhibitors (30 mM LY294002 or 10 mM wortmannin) compared with the activity in wild-type plants and under control conditions, respectively (Fig. 4; Supplemental Fig. S7). These results show that the PI3K gene is required for full activation of V-ATPase during MeJA-induced senescence. PI3K and V-ATPase Subunit B Interact in Vitro and in Vivo

Two different methods were used to demonstrate an interaction between PI3K and the V-ATPase subunits and to investigate the mechanism of PI3K in the regulation of V-ATPase activity. The physical interaction between PI3K and members of the V-ATPase subunits was examined in vitro. Analyses using yeast two-hybrid with full-length PI3K and full-length V-ATPase subunit proteins indicated that PI3K interacted with the VHA-B family, but no significant interactions between PI3K and VHA-A or VHA-C were detected (Fig. 5). This finding suggested that PI3K binds to the VHA-B family in vitro. 1717

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Figure 2. Vacuolar alkalization induced by V-ATPase inhibitor promotes stomatal opening and accelerates MeJA-induced leaf senescence. A, Vacuolar acidification was suppressed by 500 nM Bafilomycins A1 (BFA1) during the process of 50 mM MeJAinduced leaf senescence. The vacuolar pH was determined by AO. B, C, Stomatal aperture were determined by microscopy (n . 30). The detached Arabidopsis leaves were treated with 50 mM MeJA supplemented with or without 500 nM BFA1. Asterisks (*) 1718



The V-ATPase subunit B2 was selected as the representative sample to examine the interaction between PI3K and V-ATPase subunits in vivo, through a BiFC assay. Strong fluorescence signals were observed in the tonoplasts of guard cells coexpressing PI3K-cYFP (C-terminal fragment of the yellow fluorescence protein) and VHA-B2-nYFP (N-terminal fragment of the yellow fluorescence protein) in tobacco leaf epidermis (Fig. 6).

stomatal aperture of YFP Arabidopsis was 0.47. Under both MeJA and PIKfyve inhibitor treatments, the stomatal aperture of 35S:AtVPS34-YFP Arabidopsis was 0.50, whereas the stomatal aperture of YFP Arabidopsis was 0.58. These findings were consistent with the results for vacuolar acidification.

Down-Regulation of PI3K Activity Accelerates MeJAInduced Leaf Senescence Down-Regulation of PI3K Activity Suppresses Vacuole Acidification and Stomatal Closing in MeJA-Induced Leaf Senescence

Given the key role of PI3K in V-ATPase activation and V-ATPase in vacuolar acidification, we examined the effect of PI3K on vacuolar acidification using AO. After incubation with 50 mM MeJA for 3 d, pi3k mutants and samples treated with PI3K inhibitors (30 mM LY294002 or 10 mM wortmannin) showed reduced vacuolar acidification, which differed from that under control conditions (Fig. 7, A and B). We also examined the stomatal aperture in detached leaves after MeJA treatment for 3 d pi3k mutants, and samples subjected to the PI3K inhibitor (30 mM LY294002 or 10 mM wortmannin) treatments showed increased stomatal apertures compared to wild-type Arabidopsis and samples under control conditions (Fig. 7; Supplemental Fig. S8). These data indicated that the down-regulation of PI3K activity inhibits vacuolar acidification and stomatal closing in MeJA-induced leaf senescence. The PIKfyve inhibitor YM201636 was used to exclude the effect of phosphatidylinositol 3,5-bisphosphate (PtdIns(3,5)P2) on vacuolar acidification and stomatal movement. We stably expressed YFP-fused PI3K protein in Arabidopsis by Agrobacterium tumefaciensmediated transformation, and named the resultant plants 35S:AtVPS34-YFP Arabidopsis. Increased protein levels of PI3K were found in 35S:AtVPS34-YFP Arabidopsis compared to YFP Arabidopsis (Supplemental Fig. S9). In Figure 8, vacuolar acidification was suppressed in leaves treated with the PIKfyve inhibitor in 35S:AtVPS34-YFP Arabidopsis during MeJA-induced senescence. Nevertheless, the decrease was lower than that in YFP Arabidopsis. Additionally, the stomatal aperture was examined. When leaves were treated with only MeJA, the stomatal aperture of 35S: AtVPS34-YFP Arabidopsis was 0.37, whereas the

The pi3k mutants and two PI3K inhibitors (30 mM LY294002 or 10 mM wortmannin) were used to further explore the effect of PI3K on leaf senescence. After detached and attached leaves were treated with 50 mM MeJA for 3 d, photochemical efficiency and chlorophyll content decreased, whereas SAG12 gene expression increased in pi3k mutants compared to wild-type Arabidopsis (Fig. 9; Supplemental Fig. S7). Similar results were also observed in leaves treated with PI3K inhibitors (30 mM LY294002 or 10 mM wortmannin; Fig. 9).

PI3K Is Involved in the Regulation of Dark-Induced Senescence but Does Not Function through the Regulation of V-ATPase Activity

The effect of PI3K on dark-induced senescence was also investigated. Mutation of the AtVPS34 gene (pi3k-1) resulted in more pronounced yellowing than in wild-type Arabidopsis in dark-induced senescence (Fig. 10A). Similar observations were made for chlorophyll content and the photochemical efficiency of PSII (Fig. 10, B and C). Interestingly, V-ATPase activity significantly increased in leaves in which senescence was induced with dark treatment compared to leaves under control conditions. However, V-ATPase activity minimally decreased in pi3k-1 mutants compared with wild-type plants (Fig. 10D). Additionally, vacuolar acidification was examined in detached leaves under dark treatment. Vacuolar acidification and stomatal closing were enhanced (Supplemental Fig. S10), but vacuolar acidification did not significantly differ between the pi3k-1 mutants and wild-type plants in dark-induced senescence (Fig. 10E). Similarly, the stomatal aperture did not differ between the pi3k-1 mutants and wild-type plants when senescence was induced with or without dark treatment (Fig. 10F; Supplemental Fig. S11).

Figure 2. (Continued.) indicate significant difference by t test from the MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test). Stomata are marked by arrowhead. D, Photographs showed leaves with different concentrations of BFA1 (100 nM; 500 nM; 1 mM) treatment in 50 mM MeJA-induced leaf senescence in wildtype Arabidopsis for 3 d. E, Photochemical efficiency of detached leaves was shown. Each bar represents three replications. F, Determination of gene expression of SAG12. The detached Arabidopsis leaves were treated with 50 mM MeJA supplemented with or without 500 nM BFA1. Gene expression of SAG12 was determined by qRT-PCR. UBQ10 was used as an internal control. Asterisks (*) indicate significant difference by t test from no MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test). Fv/Fm = maximum quantum yield of PSII electron transport (maximum variable fluorescence/maximum yield of fluorescence). Plant Physiol. Vol. 170, 2016

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acidification and stomatal closing, thereby delaying leaf senescence. PI3K Regulates the Activity of V-ATPase in MeJA-Induced Leaf Senescence but Not in Dark-Induced Leaf Senescence

Figure 3. The activity of V-ATPase and genes expression of V-ATPase subunits during MeJA-induced leaf senescence. A, The activity of V-ATPase in leaf senescence. After treatment with 50 mM MeJA, the activity of V-ATPase was calculated as the difference measured in the absence or presence of 100 nM Con A in the required time. Each bar represents three replications. Asterisks (*) indicate significant difference by t test from the control in the indicated times (*, P , 0.05). Control means untreated with MeJA. B, Genes expression of VHA-A, VHA-B1, VHA-B2, VHA-B3, and VHA-C in leaf senescence. The detached Arabidopsis leaves were treated with 50 mM MeJA, and genes expression was determined in the indicated time points. Arabidopsis UBQ10 was used as an internal control. Expression levels for each gene were normalized to control treatment (0 d) of the wild-type plant. Asterisks (*) indicate significant difference by t test from the control in the indicated days (*, P , 0.05). CK, untreated with MeJA.

DISCUSSION

In this study, we investigated the molecular mechanism underlying the function of PI3K in the delay of MeJA-induced leaf senescence. The down-regulation of AtVPS34 gene expression or treatment with PI3K inhibitors suppressed the activation of V-ATPase in MeJA-induced leaf senescence. In vitro and in vivo interaction analyses revealed that PI3K bound to VHAB2. Treatment with PI3K or V-ATPase inhibitors also suppressed vacuolar acidification and stomatal closing. These results indicated that PI3K promotes vacuolar 1720

PI3K type III, a hetero-oligomeric complex, consists of the catalytic subunit VPS34, putative protein kinase VPS15, and several accessory subunits, including Beclin 1 (Backer, 2008). As a catalytic subunit, VPS34 produces PI3P by phosphorylating the D-3 position of phosphoinositides. The localization and activity of VPS34 are regulated by other subunits. Although the principal function of PI3K type III is the production of PI3P on restricted membrane domains, its subunits may exhibit additional functions. In Phaseolus vulgaris, PI3K type III interacts with profilin; however, this interaction depends on the Tyr phosphorylation status within the Pro-rich binding domains (Aparicio-Fabre et al., 2006). The structural analysis of V-ATPase subunits indicated that the subunits B and C exhibited similar structural features to profilin (Ma et al., 2011). In renal epithelial cells, PI3K type I regulates V-ATPase assembly and translocation (Sautin et al., 2005). PI3K type III, which is the only type of PI3K identified in plants, phosphorylates the D-3 position of phosphoinositides; nevertheless, the function of PI3K type III appears to be more comprehensive and multifaceted than previously reported (Bunney et al., 2000). For instance, PI3K type I mediates the activation of MAPK via trimeric G protein-coupled receptors in animals (Lopez-Ilasaca et al., 1997). PI3K type III activity is also required for Cd2+-induced MAPK activation in rice roots (Yeh et al., 2007). Nevertheless, the relationship between PI3K type III and V-ATPase subunits in plants requires additional study. The activity of V-ATPase was lower in the pi3k mutants and in samples treated with PI3K inhibitors in the presence of 50 mM MeJA than under control conditions. This finding indicated that PI3K regulates the activity of V-ATPase in senescing Arabidopsis leaves. Wortmannin suppressed the activation of V-ATPase and stomatal closing severely; this effect may have been due to the diverse inhibition on PIK activity (Fig. 4A). Moreover, no significant difference was detected between wildtype Arabidopsis and the pi3k mutants without MeJA treatment (Fig. 4B; Supplemental Fig. S7E). In renal epithelial cells, Glc stimulation initiates PI3K type I-dependent signaling and consequently promotes V-ATPase-dependent acidification of endosomes as well as V-ATPase assembly and trafficking (Sautin et al., 2005). In addition, leaf senescence is induced by high light intensity, phytohormones, and long-day treatment duration, and these factors are associated with hexose accumulation (Diaz et al., 2005; Wingler et al., 2006; Rolland et al., 2006). A previous study has revealed that the V-ATPase subunit B is involved in Glc signaling in Arabidopsis (Cho et al., 2006). Considering these findings, we speculated that the accumulated sugar signaling might initiate PI3K signaling and Plant Physiol. Vol. 170, 2016


promote the activation of V-ATPase during leaf senescence. To test this hypothesis, we used a PI3K inhibitor in V-ATPase activation stimulated by Glc in Arabidopsis leaves. The results showed that LY294002 treatment suppressed Glc-activated V-ATPase (Supplemental Fig. S4). Dark-induced leaf senescence was also achieved as indicated by the low levels of hexoses and disaccharides in the isolated Arabidopsis leaves stored under dark conditions (Quirino et al., 2000; van Doorn, 2008). Although vacuolar acidification is necessary for stomatal closing in dark-induced senescence (Supplemental Fig. S10), vacuolar acidification and stomatal aperture did not significantly differ between the pi3k-1 mutants and wildtype Arabidopsis (Fig. 10). A similar observation was made for the determination of V-ATPase activity in darkinduced senescence (Fig. 10). The blockage of sugar signaling might possibly have abolished initiation of the PI3K-V-ATPase pathway in leaf senescence. However, the upstream signaling mechanism linking Glc to PI3K remains unclear. Because Glc and Glc-6-phosphate are well-known physiologically relevant allosteric regulators of a variety of enzymes (Bollen et al., 1998), they may be required for allosteric activation of the Vps34-VHA-B2 complex. Although PI3K is involved in the regulation of dark-induced senescence, Arabidopsis Vps34 may exist in different complexes and participate in different cellular functions. An autophagy-related function of PI3K class III may exist in dark-induced senescence. AMPK (homologous to Arabidopsis SnRK) is a key cellular energy sensor that maintains energy homeostasis upon Glc starvation (Hardie, 2007). In Glc-starved cells, AMPK inhibits the nonautophagy Vps34 complex by phosphorylating T163/S165 in Vps34, thereby inhibiting overall PI3P production and protecting cells from starvation. In addition, AMPK activates the proautophagy Vps34 complex by phosphorylating S91/S94 in Beclin1 to induce autophagy (Kim et al., 2013). The increased V-ATPase activity in pi3k-1 mutants during dark-induced senescence indicated that other regulators promote V-ATPase activation during leaf senescence. A previous study has revealed that dark treatment results in increased stability of V-ATPase (Schnitzer et al., 2011). Vacuolar acidification is accompanied by cytosolic alkalization of guard cells during ABA-induced stomatal closure (Bak et al., 2013). Ma et al. (2013) has revealed that cytosolic alkalizationmediated H2O2 and NO production are involved in darkness-induced stomatal closure in Vicia faba. However, the underlying mechanism that induces the alteration in vacuolar pH and the activation of V-ATPase in darkness remains unknown. Regulator of H+-ATPase of vacuolar and endosomal membranes (RAVE) is a V-ATPase exclusive assembly factor, but the formation of the RAVE-C and RAVE-V1 subcomplexes in the cytosol is not Glc-dependent (Parra et al., 2014). Interestingly, a recent study revealed that, unlike the change in assembly of the mammalian V-ATPase in response to other stimuli, the amino acid-dependent change in assembly does not appear to involve PI3K (Stransky and Plant Physiol. Vol. 170, 2016

Figure 4. Down-regulation of PI3K activity suppresses the activity of V-ATPase in MeJA-induced leaf senescence. Determination of V-ATPase activity in treatment with PI3K inhibitors (A) or pi3k mutants (B) with or without 50 mM MeJA treatment. After treatment with 50 mM MeJA for 3 d or not, the activity of V-ATPase was assayed. Each bar represents three replications. Asterisks (*) indicate significant difference by t test from no MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test).

Forgac, 2015). Therefore, PI3K can be a significant regulator of V-ATPase activity but not an exclusive regulator of leaf senescence. PI3K Binds to the V-ATPase Subunit B

Nakamura et al. (1997) has revealed that V-ATPase colocalizes in osteoclasts with p85 regulated by PI3K. Furthermore, Vps34p of the human pathogenic yeast Candida albicans interacts with the putative vacuolar H+-ATPase subunit Vma7p (Eck et al., 2005). The V1 subunit E protein of V-ATPase has recently been reported to be immunoprecipitated by an antibody specific for P-PI3K (p85a) during endosomal acidification induced by influenza A virus (Marjuki et al., 2011). Hence, we speculated that PI3K might interact with the 1721

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Figure 5. The interaction of PI3K and V-ATPase subunit B examined by yeast two-hybrid analysis. The recombined bait plasmids, prey plasmids constructs, were cotransformed into the yeast strain EGY48 using LiAc-mediated yeast transformation. Assay of b-galactosidase activity on induction or no-induction plates was carried out 3 d after transformation. Quantification of b-galactosidase activity was measured by using ONPG as a substrate. The results shown represented the mean values of 10 independent b-galactosidase assays, and the error bars represent SE. Asterisks (*) indicate significant difference by t test from negative control (*, P , 0.05).

V-ATPase subunits in plants, thereby promoting the activation of V-ATPase. In P. vulgaris, vesicular trafficking mediated by PI3K may rely on dynamic changes in the actin cytoskeleton because profilin, a regulator of actin dynamics, binds to PI3K in a phosphorylationdependent manner (Aparicio-Fabre et al., 2006). Recent studies have additionally indicated that V-ATPase directly interacts with the actin cytoskeleton through actin-binding sites located in the N-terminal domain of subunit B. In this subunit, the N-terminal domains of plants contain a profilin-like motif (Ma et al., 2011). Thus, the V-ATPase subunit B may interact with PI3K type III in plants. Because results of the yeast two-hybrid assay showed that PI3K bound to the three types of VHA-B (Fig. 5), we

used the V-ATPase subunit B2 as the representative subunit B for the BiFC assay. PI3K interacted with the V-ATPase subunit B2 on the tonoplast of tobacco guard cells (Fig. 6). The interaction between VHA-B2 and PI3K may have promoted the assembly of V-ATPase on the tonoplast, but this finding should be confirmed in future studies. V-ATPase assembly in the presence of a full complement of subunits occurred via a concerted assembly pathway in which early associations between the V1 and V0 subunits preceded the full assembly of either complex rather than associations occurring with preassembled V1 and V0 sectors (Kane, 2006). Thus, the effect of PI3K on the colocalization efficiency of the V1 and V0 domains should be investigated in more detail. Additionally, the indirect role of PI3K on V-ATPase

Figure 6. PI3K interacts with VHA-B2 in vivo. BiFC analysis of PI3K and VHA-B2 interacted in tobacco. Vectors containing the indicated constructs were cotransformed into Nicotiana benthamiana leaves. Both YFP fluorescence images merged with light view images (lower panel), and YFP-alone fluorescence images (upper panel) were shown. Bar = 5 mm. Pictures represent typical examples.

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Figure 7. Down-regulation of PI3K activity suppressed the vacuolar acidification and stomatal closing during MeJA-induced leaf senescence. A disturbance of pH value decrease in pi3k mutants (A) or PI3K inhibitor treatment (B) under leaf senescence, as determined by AO. Representative R/G ratio images of Arabidopsis guard cells were shown after treatment with 50 mM MeJA in pi3k mutants and wild type. Bar = 50 mm. C, D, The stomatal aperture was assayed in pi3k mutants or supplemented with PI3K inhibitors in 50 mM MeJA treatment for 3 d by microscopy. Bars = 20 mm. Stomata are marked by arrowhead. E, F, The stomatal aperture was assayed (n . 30). Asterisks (*) indicates significant difference by t test from no MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test).

activation cannot be ruled out, especially a general trafficking role for PI3K in the translocation of VHA-B2 to the vacuoles. Additional experiments are necessary to confirm these possibilities; in particular, the effect of PI3K on the transport of VHA-B2 to the tonoplast should be examined. However, the domain of VHA-B that binds to PI3K is unknown. The profilin-like motif of VHA-B may be the domain that binds to PI3K, and Plant Physiol. Vol. 170, 2016

this motif has also been demonstrated to bind to F-actin (Aparicio-Fabre et al., 2006). The alteration in subunit composition may also be attributed to changes in enzymatic properties (Ratajczak et al., 1998). The vacuoles isolated from the vps34Δ and vps15Δ have been reported to reduce the V-ATPase activity and decrease the levels of several V-ATPase subunits (Sambade et al., 2005). Given that PI3K is involved in nuclear function (Bunney 1723

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Figure 8. The effect of PIKfyve inhibitor on vacuolar acidification and stomatal movement in 35S:AtVPS34-YFP Arabidopsis during MeJA-induced senescence. A, The detached Arabidopsis leaves from 35S:AtVPS34-YFP and YFP Arabidopsis leaves were treated with 1 mM PIKfyve inhibitor for 1 d supplemented with 50 mM MeJA. Vacuolar acidification was observed using AO. B, The extent of vacuolar acidification was quantified as the means of the R/G ratios. Each bar represents three replications (n $ 30). C, The stomatal aperture was assayed in YFP transgenic and 35S:AtVPS34-YFP transgenic Arabidopsis after 50 mM MeJA treatment for 3 d supplemented with 1 mM PIKfyve inhibitor or not by microscopy. Bars = 20 mm. Stomata are marked by arrowhead. D, The stomatal aperture was assayed (n . 30). Asterisks (*) indicate significant difference by t test from only MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test).

et al., 2000), the PI3K-induced change in the abundance of the V-ATPase subunits may be another regulatory mechanism of V-ATPase activity. Downstream of the PI3K-V-ATPase Pathway in MeJA-Induced Leaf Senescence

Water loss is accelerated in senescent leaves compared to young leaves (Jordan et al., 1975), and stomatal activity plays an important role in this process (Zhang et al., 2012). To control water transpiration, guard cells generally live longer than mesophyll cells in senescing leaves and remain functional until the late stages of senescence (Zeiger and Schwartz, 1982; Peñarrubia and Moreno, 2001). Zhang et al. (2012) have found that SAG113, which encodes a protein phosphatase that 1724

belongs to the PP2C family, antagonizes ABA signal transduction and accelerates water loss during leaf senescence. Nevertheless, the factors and mechanisms involved in the regulation of stomatal movement in senescent leaves remain unknown. In this study, stomatal opening was enhanced with prolonged MeJA treatment (Fig. 1A and Fig. 2C) and an alkalized vacuolar lumen. Enhanced stomatal aperture was also found in the low-acidified vacuolar lumen in MeJA-induced leaf senescence (Fig. 1B). Bak et al. (2013) have further reported that vacuolar acidification is accompanied by ABA-induced stomatal closure. The alteration in vacuolar pH may be related to the stomatal opening in MeJA-induced leaf senescence. To further elucidate the possible relationships between vacuolar pH and stomatal activity, we treated senescent leaves Plant Physiol. Vol. 170, 2016


Figure 9. PI3K promotes the MeJA-induced leaf senescence. Photographs show leaves after incubation with 50 mM MeJA in pi3k mutants (A) or treatment with PI3K inhibitors (B) for 3 d. Photochemical efficiency (C, F), chlorophyll content (D, G), and SAG12 gene expression (E, H) of detached leaves were shown. UBQ10 was used as internal control. Each bar represents three replications. Asterisks (*) indicates significant difference by t test from no MeJA treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test). Fv/Fm = maximum quantum yield of PSII electron transport (maximum variable fluorescence/maximum yield of fluorescence).

induced by MeJA with the V-ATPase inhibitor BFA1 or the PIKfyve inhibitor to accelerate vacuolar alkalization (Figs. 2A and 8A). Stomatal openings were enhanced compared with those under control conditions (Figs. 2B and 8C), suggesting that the alteration of vacuolar pH is necessary for stomatal opening in MeJA-induced leaf senescence. In plants, the pH homeostasis of the vacuole is regulated by antiporters and proton pumps (V-ATPase and V-PPase). V-ATPase, an important regulator of vacuolar acidification (Ferjani et al., 2011), is highly conserved. V-ATPase is a multisubunit complex containing 14 different subunits and two subcomplexes. Plant Physiol. Vol. 170, 2016

Our data indicated that the gene expression of VHA-A, VHA-B2, and VHA-C was up-regulated and the activity of V-ATPase promoted in MeJA-induced leaf senescence (Fig. 3). A previous study has revealed that the vacuolar membrane probably plays an important role in the early stages of leaf senescence. Suzuki and Kasamo (1993) have found that ATPase activity and the rate of ATP-dependent proton-pumping increase until day 14, whereas they observed a rapid decrease in the rate of pumping on day 26, as indicated by the apparent loss of fresh weight in the cotyledons. We also found that the gene expression of VHA-A, VHA-B2, and VHA-C exhibited different expression patterns, which 1725

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Figure 10. PI3K is involved in dark-induced leaf senescence but not through the regulation of V-ATPase activity. A, The detached Arabidopsis leaves of pi3k-1 mutant and wild-type Arabidopsis were put into dark for 3 d, and the phenotype of leaves was taken. Photochemical efficiency (B) and chlorophyll content (C) of the detached leaves were shown. D, Determination of V-ATPase activity in pi3k-1 mutant and wild-type Arabidopsis after dark treatment for 3 d. E, Vacuolar acidification was observed using AO in pi3k-1 mutant and wild-type Arabidopsis leaves for 3 d after dark treatment. F, The alteration of stomatal aperture was examined by microscopy. Each bar represents three replications. Asterisks (*) indicate significant difference by t test from no dark treatment (*, P , 0.05). Hash marks (#) indicate statistically significant differences between indicated samples (P , 0.05; Student’s t test). Fv/Fm = maximum quantum yield of PSII electron transport (maximum variable fluorescence/maximum yield of fluorescence).

may have been due to the different roles of each subunit in V-ATPase activation and responses to environmental stress. The catalytic hexamer A3B3 is linked with the 1726

proton pathways by stalks (Marshansky and Futai, 2008). VHA-C has been reported to link VHA-E to the membrane-integral sector V0 and to act as a flexible Plant Physiol. Vol. 170, 2016


stator subunit in regulating the coupling between ATP hydrolysis and proton transport (Li and Zhang, 2004; Schnitzer et al., 2011). ATP binding to VHA-C has also been demonstrated by Armbrüster et al. (2005). To further elucidate the role of V-ATPase in leaf senescence, we used the V-ATPase inhibitor BFA1. Treatment with the V-ATPase inhibitor significantly accelerated vacuolar alkalization (Fig. 2A), resulting in an enhanced stomatal aperture in MeJA-induced leaf senescence (Fig. 2C). Additional analysis of senescent characteristics revealed that BFA1 treatment hastened MeJA-induced senescence (Fig. 2, D, E, and F). Considering these findings, we speculated that V-ATPase activity might be enhanced in anti-MeJAinduced leaf senescence. This enhanced activity delayed vacuolar alkalization and suppressed stomatal opening, thereby maintaining water homeostasis in leaves and delaying leaf senescence. V-ATPase may play another role in the regulation of leaf senescence. In the senescing petals of Japanese morning glory, treatment with Con A, a V-ATPase-specific inhibitor, accelerates petal senescence (Shibuya et al., 2009). The effect of Con A primarily results from the high pH conditions in the vacuole; under these conditions, vacuolar hydrolase is inactivated, and the accumulation of autophagic bodies is induced (Yoshimoto et al., 2004). These studies suggest that autophagy is associated with plant senescence and functions as the primary mechanism of degradation and remobilization of macromolecules. Autophagy also acts as an aid to cell survival rather than as a cause of cell death (Yamada et al., 2009). A recent report has revealed that chlorophyll breakdown is a detoxification process rather than a remobilization process (Schelbert et al., 2009). Thus, the duration of vacuolar acidification may minimize the risk of the accumulation of chlorophyll intermediates and potential phototoxicity, resulting in delayed leaf senescence. PI3P is the product of PI3K and the precursor to another phosphoinositide, PtdIns(3,5)P2, which is produced by PI3P 5-kinase and is known as Fab1p in yeast and PIKfyve in mammals. PtdIns(3,5)P2 is a lowabundance phosphoinositide located in the endosomal, lysosomal, and vacuolar membranes of fungi and higher eukaryotes (Ho et al., 2012; Bak et al., 2013). Depending on the organism and cell type, PtdIns(3,5)P2 governs a diverse array of cellular functions, such as complete inhibition of PIKfyve, which induces vacuole formation from early endosomes. The vacuoles in fab1Δ yeast are less acidified than those in wild type (McCartney et al., 2014). PIKfyve is also required for the trafficking of protein from endosomes to the TGN (Zhang et al., 2007). Additionally, recent reports have revealed that polyphosphoinositides (including PtdIns (3,5)P2) are crucial for the trafficking, morphology, and functions of vacuoles in Arabidopsis (Nováková et al., 2014; Whitley et al., 2009; Vermeer et al., 2006). PI3P and PtdIns(3,5)P2 have similar roles in plant development and vacuolar functions. Thus, to exclude the effect of PtdIns(3,5)P2 on stomatal movement, a PIKfyve inhibitor was used in 35S:AtVPS34-YFP Arabidopsis during MeJA-induced senescence. This Plant Physiol. Vol. 170, 2016

approach distinguishes between both macromolecules because the upstream product of PtdIns(3,5)P2 is PI3P, which is the phosphorylated product of PI3K. Although vacuolar acidification was suppressed with treatment of the PIKfyve inhibitor in 35S:AtVPS34-YFP Arabidopsis during MeJA-induced senescence, the decrease was lower than that in YFP-labeled Arabidopsis (Fig. 8). PI3K may regulate vacuolar acidification in MeJAinduced senescence through the downstream product PtdIns(3,5)P2 as well as through other signaling pathways. These findings can be interpreted using the direct effect of PI3K on the activity of V-ATPase. PI3K Is Widely Involved in Leaf Senescence

The inhibitory effects of PI3K activity on stomatal movement in Arabidopsis (Jung et al., 2002) and dayflower (Choi et al., 2008) have been established, and recent reports have revealed that PI3K may be involved in the regulation of leaf senescence. During petal senescence, the gene expression of AtVPS34 is up-regulated in the Japanese morning glory (Shibuya et al., 2009). In ethylene-accelerated petal senescence, treatment with the PI3K inhibitor 3-MA reduces the time to petal senescence (Yamada et al., 2009). In this study, PI3K inhibitors or down-regulation of AtVPS34 gene expression accelerated MeJA-induced leaf senescence (Fig. 9). Our data revealed that the down-regulation of PI3K activity suppresses vacuolar acidification and stomatal closing in MeJAinduced senescence (Fig. 7). The down-regulation of PI3K activity also accelerated dark-induced leaf senescence (Fig. 10), but V-ATPase activity did not significantly differ between the pi3k mutants and wild-type Arabidopsis during this process (Fig. 10). This finding suggested that PI3K also regulates dark-induced senescence but does not do so through the PI3K-V-ATPase pathway. In plant development and stress responses, PI3K exhibits diverse functions, such as actin filament reorganization, plasma membrane endocytosis, and NADPH oxidase activation (Choi et al., 2008; Leshem et al., 2007; Liu et al., 2012). Thus, PI3K may be involved in the regulation of leaf senescence. CONCLUSION

This work provides a comprehensive perspective of the PI3K-V-ATPase pathway in MeJA-induced leaf senescence. The binding of PI3K to the VHA-B subunits improved the assembly of V-ATPase and enhanced V-ATPase activity and vacuolar acidification, thereby suppressing stomatal opening and MeJA-induced leaf senescence. MATERIALS AND METHODS Chemicals PI3K inhibitors LY294002 and wortmannin were obtained from Biyuntian (Shanghai, China). Bafilomycins A1 (BFA1), concanamycin A (Con A), 9-amino6chloro-2-methoxyacridine (ACMA), and methyl jasmonate (MeJA) were 1727

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purchased from Sigma-Aldrich (St. Louis, MO). Acridine orange (AO) was purchased from Invitrogen (Carlsbad, CA). And the PIKfyve inhibitor (YM201636) was offered by Calbiochem (Merck Millipore, Darmstadt, Germany).

Plant Materials and Growth Conditions The plant materials containing the wild-type Arabidopsis (Col-0), pi3k-1 mutant Arabidopsis (SALK_007281), pi3k-2 mutant Arabidopsis (GABI_418H02), YFP Arabidopsis, and 35S:AtVPS34-YFP were grown in an environmentally controlled growth room with a 16-h light/8-h dark cycle at 22°C for 3 weeks. SALK_007281 contained T-DNA at position +2388 relative to the ATG of VPS34. Sequence-indexed T-DNA insertion line was generated by vacuum infiltration of Columbia (Col) plants with Agrobacterium tumefaciens vector pROK2; kanamycin was employed for selection of plants carrying a T-DNA. GABI_418H02 contained a T-DNA into the fifth exon at position +664; ampicillin was employed for selection of plants carrying a T-DNA. The pi3k mutant was germinated on MS agar medium containing kanamycin or ampicillin (50 mg L21) to obtain Kan or Amp resistance heterozygous Arabidopsis seedlings since the homozygous seedlings are lethal. PCR-based genotyping analysis of these pi3k mutants were taken by the previous study (Lee et al., 2008). The Arabidopsis leaves at the approximate middle of the petioles were cut as the leaf sample. The determination of pi3k mutant, vha-B2 mutant, and 35S:AtVPS34-YFP was performed by quantitative reverse transcription (qRT)-PCR (Supplemental Fig. S6). One week after germination, the seedlings on MS agar medium (including wild type) were transplanted to soil.

Hormone Treatment and Dark-Induced Senescence For in planta treatment, one week after seed germination, the seedlings were transplanted on fresh MS containing 50 mM MeJA for 1 week under a 16-h light/ 8-h dark cycle (He et al., 2002). For senescence assay in detached leaves upon MeJA treatment, leaves numbers 4 and 5 were detached from rosettes from 3-week-old plants after sowing, and were immediately floated on 3 mM MES buffer (pH 5.8) solution with or without 50 mM MeJA under continuous lighting to incubate leaves for different times (Woo et al., 2001). Before the experiments, leaves were washed three times with distilled water. All the experiments were carried out at 22°C and repeated at least three times (Yue et al., 2012). For senescence assay in detached leaves under dark treatment, leaves were cut from 21 d plants grown in soil and placed onto 3 mM MES buffer (pH 5.8) in the dark for 3 d (Shan et al., 2011).

Measurement of Chlorophyll Content and Photochemical Efficiency Chlorophyll was extracted from two leaf discs by boiling the leaves in 95% ethanol at 80°C. And the chlorophyll content per fresh weight of leaf was calculated according to the methods described previously by Lichtenthaler (1987). The chlorophyll content was expressed as the percentage of the initial value of rosettes. The photochemical efficiency of photosystem II (PSII) was examined by using a PAM fluorometer (Walz, Eichenring, Germany) according to the protocol as described previously (Müller et al., 2001). The ratio of maximum variable fluorescence to maximum yield of fluorescence was represented as the photochemical efficiency of PSII (Oh et al., 1996).

RNA was determined by measuring OD at 260 nm. First-strand cDNA was synthesized with the SuperScript II First-Strand Synthesis System for quantitative reverse transcript-PCR (qRT-PCR; Invitrogen). The transgenic Arabidopsis was examined by qRT-PCR. qPCR amplification was carried out using UBQ10 as endogenous control. SYBR Green probes for each gene were used. The primers were listed in Supplemental Table S1. The primers in determination of pi3k mutant were as follows: 59-GCTGTTCCCGCAAATGGTT-39 and 59-CCGCAGATGTCGCAGATGTA-39. qPCR was carried out using 50 ng of cDNA and SYBR PCR master mix (TaKaRa, Clontech, Mountain View, CA), following the manufacturer’s protocol. Relative expression levels were calculated using the 2-DDCT analysis method. Expression levels for each gene were normalized to control treatment of the wild-type plant (Livak and Schmittgen, 2001; Sun et al., 2012).

Plasmid Construction DNA manipulations were carried out by using standard procedures (Zhang et al., 2013). The cDNA sequences of AtVPS34, AtVHA-A, AtVHA-B1, AtVHAB2, AtVHA-B3, and AtVHA-C were amplified by reverse transcript-PCR for constructing different vectors as follows: For a yeast two-hybrid construct, AtVPS34 was cloned into the bait plasmid pEG202, and the AtVHA-A, AtVHAB1, AtVHA-B2, AtVHA-B3, and AtVHA-C were cloned into the prey plasmid pGADT7 (Clontech; kindly provided by Dr. Yongsheng Liu, Hefei University of Technology, Hefei, China); for the bimolecular fluorescence complementation construct (BiFC), AtVPS34 and AtVHA-B2 were cloned into the pBiFC vectors, which contained either N-terminal 155 amino acids or C-terminal 84 amino acids of EYFP (Walter et al., 2004) to generate 35S-AtVPS34-cYFP and 35S-AtVHA-B2-nYFP, respectively. For 35S:AtVPS34-YFP vector construction, AtVPS34 was cloned into the pHB-YFP vector. The primers, GenBank accession number and restriction sites of them were listed in Supplemental Table S1.

Yeast Two-Hybrid Assays Yeast two-hybrid assays were performed according to the Lex A two-hybrid system. Full-length open reading frame cDNA sequences of Arabidopsis PI3K, VHA-A, VHA-B1, VHA-B2, VHA-B3, and VHA-C were PCR-amplified using the primers in Supplemental Table S1. The PCR fragments were cloned into the prey plasmid pJG4-5 and the bait plasmid pEG202, respectively, and fused with DNA-binding protein (Lex A) and activation domain (B42) sequences of the yeast Lex A system. The recombined bait plasmids and prey plasmids constructs were cotransformed into the yeast strain EGY48 using LiAc-mediated yeast transformation. Photographs of resulting yeast colonies were taken 3 d after transfer and b-galactosidase assay (Invitrogen) was carried out according to the supplier’s protocol (Wang et al., 2008; Gao et al., 2013).

Bimolecular Fluorescence Complementation Assay The 35S:AtVPS34-cYFP fusion protein construct together with 35S:AtVHAB2-nYFP or 35S-nYFP, and the 35S:AtVHA-B2-nYFP fusion protein construct together with 35S:AtVPS34-cYFP or 35S-cYFP, were transiently transformed to Nicotiana benthamiana mediated by Agrobacterium tumefaciens GV3101. Cells with YFP fluorescence were monitored under a laser scanning confocal microscopy (YFP: excitation 514 nm, emission 525–550 nm), and the detailed protocol follows Walter et al. (2004) and Huang et al. (2009a).

Vacuolar Lumenal Acidification Determination The vacuolar acidification in Arabidopsis guard cell was observed using the pH-dependent fluorescent dye AO (Bak et al., 2013). For vacuolar pH determination, Arabidopsis leaf epidermis with guard cells was stained with 50 mM AO for 100 min. AO fluorescence was captured by an LSM 510 META system (Carl Zeiss, Jena, Germany) following excitation at 488 nm and two band-pass (BP) filters (BP 615–660 nm and BP 530–540 nm) were used for the red and green channels, respectively. The quantitative analysis of fluorescence images was analyzed with an AxioVision 4.8.2 analysis program (Carl Zeiss) and ImageJ software (National Institutes of Health, Bethesda, MD).

Total RNA Extraction and Quantitative Reverse Transcript-PCR Total RNA was extracted from Arabidopsis leaves according to manufacturer’s instruction using the TRIZOL reagent (Invitrogen). Concentration of 1728

Generation of Transgenic Plants Transgenic Arabidopsis were generated by Agrobacterium tumefaciens-mediated transformation according to the described procedure previously (Clough and Bent, 1998). The resulting transgenic T1 seeds were selected by plating on 0.53 MS (pH 5.8) containing hygromycin (50 mg L21) and confirmed by PCR using hpt (accession no. E00777.1)-specific primers (59-TAGGAGGGCGTGGATATGTC-39 and 59-TACACAGCCATC GGTCCAGA-39; Yue et al., 2012; Zhang et al., 2013). The overexpression of AtVPS34 gene in 35S:AtVPS34-YFP transgenic Arabidopsis was determined by qRT-PCR (Supplemental Fig. S6B).

Tonoplast Membrane Protein Extraction Microsomal membrane fractions were extracted from leaves according to protocol described previously (Liu et al., 2012). The crude microsomal membrane protein was used to the extraction of tonoplast vesicles. The microsomal membrane Plant Physiol. Vol. 170, 2016


pellet was resuspended in a buffer containing 2 mM BTP/MES, pH 7.0, 250 mM Suc, 1 mM DTT, 10% glycerol (v/v), 0.2% BSA (w/v) and covered with a 25/38% (w/w) discontinuous Suc density gradient, then centrifuged with 100,000g for 2 h. The fraction from the interface was the tonoplast protein. The concentrations of tonoplast membrane protein were determined by Lowry method (Zhang et al., 2013).

Determination of the Purity of the Tonoplast Fraction To characterize the purity of the isolated tonoplast vesicles, hydrolytic and proton pumping activities of the vacuolar H+-ATPase (V-ATPase) were assayed in the presence and absence of appropriate inhibitors (Queirós et al., 2009; Snowden et al., 2015). Quantities of 50 mM KNO3, 0.1 mM Na3VO4, and 0.5 mM NaN3 were used to inhibit tonoplast V-ATPase, plasma membrane P-ATPase, and F-ATPase, respectively. In addition, the effect of the specific inhibitor of the tonoplast ATPase, Con A, on ATP-dependent proton pumping into tonoplast vesicles was also determined. ATP-dependent proton pumping was measured by the quenching of ACMA fluorescence (Shabala et al., 2011). The proton pump activity of V-ATPase was assayed in a reaction buffer containing 250 mM sorbitol, 50 mM KCl, 3 mM ATP, 50 mM NaVO4, 1 mM NaN3, 2 mM ACMA, and 10 mM MES-Tris (pH 7.5). A quantity of 3 mM MgSO4 was used to initiate the reaction. The fluorescence quenching was measured with an excitation wavelength 410 nm and an emission wavelength of 480 nm by an auto-microplate reader. The determination of purity of tonoplast fraction was shown in Supplemental Fig. S12.

V-ATPase Activity Assays Ten micrograms of tonoplast membrane protein was applied to analyze the V-ATPase activity with 10 mg BSA as a negative control. The V-ATPase activity, which was calculated as the difference measured with or without 100 nM Con A, was examined in a reaction medium as described previously (Zhang et al., 2013).

Stomatal Aperture Measurements Stomatal aperture was monitored by microscopy and scanning electron microscopy, respectively. After treatment, stomata were observed by microscopy and given as width to length ratio. At least 30 stomata were assayed (Zhou et al., 2013). To determine the stomatal aperture by scanning electron microscopy, leaves were fixed by 2.5% glutaraldehyde in 0.1 M phosphate buffer (pH 7.2) at 4°C for 24 h, washed twice with 0.1 M phosphate buffer for 10 min, then immersed in 50, 60, 70, 80, 90, and 100% ethanol sequentially for 10 min each. After drying at vacuum dryer, the samples were coated with gold for scanning electron microscopy analysis (Huang et al., 2009b).

NM_001036222 (VHA-A), NM_106251 (VHA-B1), NM_001036730 (VHA-B2), NM_101877 (VHA-B3); AY059872 (VHA-C), AF370131 (SAG12).

Supplemental Data The following supplemental materials are available. Supplemental Table S1. The primers used for plasmid construction and functional analysis. Supplemental Figure S1. Scanning electron microscopy analysis of stomatal aperture in leaf senescence. Supplemental Figure S2. The V-ATPase activity of microsomal membrane fractions in MeJA-induced Arabidopsis leaf senescence. Supplemental Figure S3. The V-ATPase activity under Glc treatment. Supplemental Figure S4. The V-ATPase activity under Glc and LY294002 treatment. Supplemental Figure S5. Genes expression of AtVPS34 and SAG12 in MeJA-induced senescence. Supplemental Figure S6. Characterization of pi3k Arabidopsis mutants and 35S:AtVPS34-YFP transgenic Arabidopsis. Supplemental Figure S7. The effect of PI3K on MeJA-induced senescence in attached Arabidopsis leaves. Supplemental Figure S8. Scanning electron microscopy analysis of stomatal aperture during leaf senescence in pi3k mutant or supplemented with PI3K inhibitors. Supplemental Figure S9. Determination of 35S:AtVPS34-YFP Arabidopsis seedling. Supplemental Figure S10. The vacuolar acidification in dark-induced leaf senescence. Supplemental Figure S11. Scanning electron microscopy analysis of stomatal aperture in dark-induced leaf senescence in pi3k-1 mutant. Supplemental Figure S12. Assessment of purity of tonoplast membrane fractions.

Western Blot

ACKNOWLEDGMENTS

Protein extracts were extracted from 35S:AtVPS34-YFP and YFP Arabidopsis leaf samples after washing with sterile water. Protein extracts were separated on a 10% (w/v) sodium dodecyl sulfate-polyacrylamide gel electrophoresis minigel and then a western blot was taken. To obtain the optimal antibody, amino acid sequences of VPS34 in different species was compared using DNAman (Supplemental Fig. S9). The VPS34 polyclonal antibody (Cat. no. AP1851b; Abgent, San Diego, CA) is generated from rabbits immunized with a KLH conjugated synthetic peptide between 770 and 801 amino acids from the C-terminal region of hVPS34. The antibody is purified through a protein G column, then eluted with high and low pH buffers and neutralized immediately, followed by dialysis against PBS. For detection of VPS34 protein, blots were probed with a 1:1000 dilution of VPS34 antibody. Subsequently, blots were washed and incubated with an HRP-labeled goat anti-rabbit secondary antibody (Wuhan Boster Biological Technology, Wuhan, China). Proteins were detected by using a Gbox Chemi XT4 system (Syngene, Cambridge, UK).

We thank Prof. Yongsheng Liu for providing the yeast plasmids for a yeast two-hybrid assay and appreciate the conversation with the members of our group in developing some of the ideas presented in this study.

Statistical Analysis All assays were repeated independently for a minimum of three times. Data are represented as mean 6 SD. Statistical analysis was performed with the Student’s paired t test.

Accession Numbers Sequence data from this article can be found in the GenBank/EMBL data libraries under accession numbers AY139999 (UBQ10), NM_104735 (VPS34), Plant Physiol. Vol. 170, 2016

Received May 22, 2015; accepted January 5, 2016; published January 6, 2016.

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1731

A pivotal role of phosphatidylinositol 3-kinase in delaying of methyl jasmonate-induced leaf senescence.

ABA receptor PYL9 promotes drought resistance and leaf senescence.

Mutation of SPOTTED LEAF3 (SPL3) impairs abscisic acid-responsive signalling and delays leaf senescence in rice.

Silencing of the CaCP gene delays salt- and osmotic-induced leaf senescence in Capsicum annuum L.

Vacuolar acidification and chloroquine sensitivity in Plasmodium falciparum.

Autophagy extends lifespan via vacuolar acidification.

S6K1.

SNF2-Like Chromatin-Remodeling Proteins, DRD1 and DDM1, Delays Leaf Senescence in Arabidopsis thaliana.

An S-domain receptor-like kinase, OsSIK2, confers abiotic stress tolerance and delays dark-induced leaf senescence in rice.

Lifespan extension by methionine restriction requires autophagy-dependent vacuolar acidification.

Expression of IPT in Asakura-sanshoo (Zanthoxylum piperitum (L.) DC. f. inerme Makino) Alters Tree Architecture, Delays Leaf Senescence, and Changes Leaf Essential Oil Composition.

Transcriptional networks in leaf senescence.

Force engages vinculin and promotes tumor progression by enhancing PI3K activation of phosphatidylinositol (3,4,5)-triphosphate.

A Rice NAC Transcription Factor Promotes Leaf Senescence via ABA Biosynthesis.

Phosphatidylinositol membrane anchors and T-cell activation.

Role of TFP1 in vacuolar acidification, oxidative stress and filamentous development in Candida albicans.

[Changes of glyco- and phospholipid contents during leaf senescence].

Towards understanding abscisic acid-mediated leaf senescence.

Mitochondria change dynamics and morphology during grapevine leaf senescence.

Modelling transcriptional networks in leaf senescence.

Combined effects of girdling and leaf removal on fluorescence characteristic of Alhagi sparsifolia leaf senescence.

Senescence-associated Long Non-coding RNA (SALNR) Delays Oncogene-induced Senescence through NF90 Regulation.

DISP3 promotes proliferation and delays differentiation of neural progenitor cells.

Vitamin E Supplementation Delays Cellular Senescence In Vitro.