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Abiotic Stress Generates ROS That Signal Expression of Anionic Glutamate Dehydrogenases to Form Glutamate for Proline Synthesis in Tobacco and Grapevine^[W]

^a Department of Biology, University of Crete, 71409 Heraklion, Greece
^b Department of Chemistry, University of Crete, 71409 Heraklion, Greece

¹ To whom correspondence should be addressed. E-mail poproube{at}biology.uoc.gr; fax 30-81-394459.

	ABSTRACT

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Glutamate dehydrogenase (GDH) may be a stress-responsive enzyme, as GDH exhibits considerable thermal stability, and de novo synthesis of the -GDH subunit is induced by exogenous ammonium and senescence. NaCl treatment induces reactive oxygen species (ROS), intracellular ammonia, expression of tobacco (Nicotiana tabacum cv Xanthi) gdh-NAD;A1 encoding the -subunit of GDH, increase in immunoreactive -polypeptide, assembly of the anionic isoenzymes, and in vitro GDH aminating activity in tissues from hypergeous plant organs. In vivo aminating GDH activity was confirmed by gas chromatorgraphy–mass spectrometry monitoring of ¹⁵N-Glu, ¹⁵N-Gln, and ¹⁵N-Pro in the presence of methionine sulfoximine and amino oxyacetic acid, inhibitors of Gln synthetase and transaminases, respectively. Along with upregulation of -GDH by NaCl, isocitrate dehydrogenase genes, which provide 2-oxoglutarate, are also induced. Treatment with menadione also elicits a severalfold increase in ROS and immunoreactive -polypeptide and GDH activity. This suggests that ROS participate in the signaling pathway for GDH expression and protease activation, which contribute to intracellular hyperammonia. Ammonium ions also mimic the effects of salinity in induction of gdh-NAD;A1 expression. These results, confirmed in tobacco and grape (Vitis vinifera cv Sultanina) tissues, support the hypothesis that the salinity-generated ROS signal induces -GDH subunit expression, and the anionic iso-GDHs assimilate ammonia, acting as antistress enzymes in ammonia detoxification and production of Glu for Pro synthesis.

	INTRODUCTION

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Most biotic and abiotic stresses signal the generation of reactive oxygen species (ROS), particularly O₂·^– and H₂O₂, both extra- and intracellularly, by deregulating electron transport in chloroplasts and mitochondria and by activation of the plasma membrane–bound NADPH oxidases, the cell wall–bound NAD(P)H oxidase-peroxidase, and possibly the amine oxidases (Apel and Hirt, 2004; Mittler et al., 2004; Papadakis and Roubelakis-Angelakis, 2005; Paschalidis and Roubelakis-Angelakis, 2005b). ROS have been viewed as toxic by-products of cellular metabolism; however, a growing body of evidence suggests that they function as signaling molecules in eukaryotes, leading to specific downstream responses (Mittler et al., 2004 and references therein). The activation of two of the Arabidopsis thaliana mitogen-activated protein kinases, MPK3 and MPK6, is essential for signal transduction in response to H₂O₂ (Kovtun et al., 2000). The OXI1 kinase acts as a ROS sensor in plants to activate MPK3 and MPK6 (Rentel and Knight, 2004), and OMTK1 plays a mitogen-activated protein kinase scaffolding role and activates H₂O₂-induced cell death in plants (Nakagami et al., 2004). Hydrogen peroxide produced directly or by superoxide dismutase (SOD) induces expression of antioxidant genes, such as ascorbate peroxidase and catalase (CAT), which act toward detoxification of ROS (Apel and Hirt, 2004 and references therein). Efficient scavenging of ROS plays a significant role in the osmotic stress tolerance of plants, although the exact contribution in the response to abiotic stresses remains unknown (Hasegawa et al., 2000). Furthermore, there is substantial evidence that the expression and functioning of many proteins depend on redox state (Foyer and Noctor, 2005).

Under stress conditions, such as salinity, increased proteolytic activity results in increased intracellular hyperammonia and toxicity if not efficiently removed (Lutts et al., 1999). Ammonium ions are incorporated into Gln and Glu by glutamine synthetase/glutamate synthase (GS/GOGAT; EC 6.3.1.2/EC 1.4.7.1, respectively; Lea and Miflin, 1974; Figure 1 ). In addition, glutamate dehydrogenase (GDH) (EC 1.4.1.2) catalyzes the reductive amination of 2-oxoglutarate (2OG) and the oxidative deamination of Glu in vitro and is abundant in plant tissues (Loulakakis and Roubelakis-Angelakis, 1990a, 1990b; Melo-Oliveira et al., 1996; Turano et al., 1997; Restivo, 2004; Figure 1). The GDH holoenzyme has a hexameric structure consisting of two subunit polypeptides, and ß, with small but distinct differences in their molecular mass and charge. The two subunits are associated in an ordered ratio so that isoenzymes 1 and 7 are homohexamers of the ß- and -subunits, respectively (Loulakakis and Roubelakis-Angelakis, 1991, 1992; Turano et al., 1997). The two GDH polypeptides are encoded by distinctive genes (for review, see Purnell et al., 2005). The exact physiological roles of GDH in plant carbon and nitrogen metabolism and remobilization in plants remain largely speculative (reviewed in Miflin and Habash, 2002; Stitt et al., 2002; Dubois et al., 2003). Intracellular hyperammonia due to either exogenous ammonium (Loulakakis and Roubelakis-Angelakis, 1992; Restivo, 2004; Tercé-Laforgue et al., 2004a), senescence-induced high proteolytic activities (Masclaux et al., 2000; Loulakakis et al., 2002; Tercé-Laforgue et al., 2004b), or abiotic stress (Lutts et al., 1999; Hoai et al., 2003) results in increased aminating GDH activity in vitro. Early in the season, in planta, fully developed and physiologically active leaves in the basal part of the shoot exhibit high GOGAT expression, protein accumulation, and activity, whereas GDH concentration and activity are low. Later during development, GS and GOGAT decrease in the senescing leaves, accompanied by expression of gdh-NAD;A1, GDH protein accumulation, and increased in vitro aminating activity in tissues from senescing leaves (Masclaux et al., 2000; Loulakakis et al., 2002; Tercé-Laforgue et al., 2004a, 2004b). In salt-tolerant rice (Oryza sativa) cultivars, aminating GDH activity increases with increasing salt stress, whereas it decreases in the salt-sensitive ones (Kumar et al., 2000), and in pea (Pisum sativum) plants, an ammonium-tolerant plant, the aminating GDH activity in roots is high (Lasa et al., 2002).

View larger version (20K): [in this window] [in a new window]   Figure 1. Potential Role of GDH under Stress Conditions. Abiotic stresses result in ROS generation, inducing protease activity, increases in intracellular ammonium ions, and expression of gdh-NAD;A1, which participates, along with the GS/GOGAT pathway, in NH4+ assimilation. The supply of 2OG for Glu synthesis is provided by isocitrate deamination catalyzed by I(C)DHs. Glu synthesis under stress conditions by GDH is shifted to Pro synthesis. The enzymes involved in this metabolic scheme include the following: GS1, cytosolic glutamine synthetase; GS2, chloroplastic glutamine synthetase; IDH, mitochondrial isocitrate dehydrogenase; and ICDH, cytosolic isocitrate dehydrogenase.

	RESULTS

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Addition of NaCl to Suspension Cells and Leaf Discs Resulted in Accumulation of ROS, DNA Fragmentation, and Induction of Programmed Cell Death
The intracellular and extracellular accumulation of O₂·^– and H₂O₂ was followed over a 96-h period with lucigenin- and luminol-dependent chemiluminescence assays, respectively, in grapevine suspension cells and leaf discs and tobacco Bright Yellow 2 (BY-2) cells and leaf discs supplemented with 100 mM NaCl. In grapevine cell suspensions, O₂·^– accumulated both intra- and extracellularly (Figure 2A ; P = 0.05). The intracellular O₂·^– increased during the entire culture period; at 96 h, the content was fourfold greater compared with zero time and 2.8-fold greater compared with the control. The extracellular O₂·^– reached a peak at 72 h, which was sevenfold higher than at zero time (P = 0.05). On the other hand, H₂O₂ accumulated only extracellularly at 24, 48, and 72 h (Figure 2A; P = 0.05); at 72 h, it was 14.6-fold greater compared with zero time and threefold greater compared with the control. The accumulation of ROS at 50 mM NaCl showed a similar profile, whereas 200 mM NaCl resulted in significant reduction of cell viability (see Supplemental Figure 1 online). Accumulation of ROS in BY-2 tobacco suspension cells cultured in the presence of NaCl followed similar trends (Figure 2B).

View larger version (18K): [in this window] [in a new window]   Figure 2. NaCl Induction and Accumulation of ROS in Grapevine and Tobacco. (A) Generation of ROS in V. vinifera cv Sultanina suspension cells. (B) Generation of ROS in N. tabacum BY-2 suspension cells. (C) Generation of ROS in V. vinifera cv Sultanina leaf discs. (D) Generation of ROS in N. tabacum leaf discs. The cells were treated with 100 mM NaCl and the leaf discs with 0, 50, 100, and 200 mm NaCl for 72 h. ROS were determined 24 h after treatment as described in Methods. Data are the means of three replicates out of three independent experiments, and bars represent ±SE.

For further confirmation, in situ ROS in tobacco BY-2 (Figure 3A ) and grapevine cells (Figure 3A) were detected after treatment with 200 mM NaCl using the highly sensitive, cell-permeable probe 2',7'-dichlorodihydrofluorescein diacetate (DCFH-DA) according to Schopher et al. (2001). Salt-treated BY-2 and grapevine cell cultures accumulated ROS as early as 2 h after treatment (Figures 3Ab and 3Af). Treatment of BY-2 cells with 200 mM NaCl resulted in DNA fragmentation, a symptom of programmed cell death (PCD), as assessed by the TdT-mediated dUTP nick-end labeling (TUNEL) method, which labels free 3'-OH groups of DNA; 24 h after treatment, 40% of the cells were stained positively in the TUNEL assay (Figures 3Bc and 3Bd).

View larger version (70K): [in this window] [in a new window]   Figure 3. Effect of NaCl, Menadione, NH4+, and MSX on ROS Accumulation and Induction of PCD in Tobacco BY-2 and Grapevine Suspension Cells. (A) In situ ROS detection in control grapevine cells (a), grapevine cells treated with 200 mM NaCl for 2 h (b), grapevine cells treated with 200 mM NaCl and 10 mM ascorbate for 2 h (c), grapevine cells treated with 100 µM menadione for 2 h (d), control tobacco BY-2 cells for 2 h (e), tobacco BY-2 cells treated with 200 mM NaCl for 2 h (f), tobacco BY-2 cells treated with 100 µM menadione for 2 h (g), grapevine cells treated with 10 mM NH4+ for 2 h (h), grapevine cells treated with 10 mM NH4+ for 24 h (i), grapevine cells treated with 200 mM NaCl for 24 h (j), and grapevine cells treated with MSX for 2 h (k). (B) Induction of the PCD syndrome: cells treated with 200 mM NaCl ([a] and [b]) and 50 µM menadione ([c] and [d]) after 24 h, propidium iodide ([a] and [c]), and the TUNEL assay ([b] and [d]). In situ ROS detection and TUNEL assay were performed as described in Methods.

NaCl Resulted in Increased Intracellular Ammonium Ions, Expression of gdh-NAD;A1, Increased GDH Immunoreactive Protein and -Subunit Polypeptide, Assembly of the Anionic Iso-GDHs, and Increased GDH in Vitro Aminating Activity

View larger version (17K): [in this window] [in a new window]   Figure 4. Ammonium Ion Content and in Vitro Aminating and Deaminating Activities of GDH in Tobacco Plants Grown under Salinity Conditions. (A) and (B) Endogenous free NH4+ content in stems and leaves of tobacco plants, respectively. (C) and (D) In vitro aminating–specific activities of GDH (NADH-GDH) in stems and leaves, respectively. (E) and (F) In vitro deaminating–specific activities of GDH (NAD-GDH) in stem and leaves, respectively. (G) and (H) In vitro–specific activities of GOGAT and GS in leaves, respectively. The plants were treated with 0, 250, and 350 mM NaCl for 6 d as described in Methods. Data are the means of three replicates out of four independent experiments, and bars represent ±SE.

View larger version (57K): [in this window] [in a new window]   Figure 5. Salinity-Induced Expression of GDH in Tobacco Plants. (A) Abundance of Nt gdh-NAD;A1 transcript encoding for the -subunit of GDH in shoots, stems, and leaves of N. tabacum cv Xanthi. (B) Immunoreactive GDH protein and subunit polypeptides in tobacco shoots. (C) Isoenzymic profile of GDH; assembly of the anionic iso-GDHs in tobacco shoots. The plants were treated with 0, 250, and 350 mm NaCl for 6 d as described in Methods.

View larger version (58K): [in this window] [in a new window]   Figure 6. Salinity-Induced Expression of GDH in Grapevine Cells. (A) Abundance of Vv gdh-NAD;A1 transcript encoding for the -subunit of GDH in V. vinifera suspension cells. (B) Immunoreactive GDH protein. (C) Isoenzymic profile of GDH; assembly of the anionic iso-GDHs. (D) In vitro aminating GDH-specific activities. The cells were treated with 0, 50, and 100 mm NaCl for 96 h as described in Methods. Data are the means of three replicates out of four independent experiments, and bars represent ±SE.

View larger version (42K): [in this window] [in a new window]   Figure 7. Salinity-Induced Expression of GDH in Tobacco Leaf Discs. (A) Abundance of Nt gdh-NAD;A1 transcript encoding for the -subunit of GDH in leaf discs of N. tabacum cv Xanthi. (B) Immunoreactive GDH protein. (C) In vitro aminating GDH-specific activity. Leaf discs were treated with 0, 50, 100, and 200 mM NaCl for 72 h as described in Methods. Data are the means of three replicates out of three independent experiments, and bars represent ±SE.

View larger version (29K): [in this window] [in a new window]   Figure 8. Effect of Menadione on ROS Generation and on the Expression of Proteases and GDH in Grapevine Cells. (A) Intra- and extracellular generation and accumulation of O2·– and H2O2 in cells treated with 0 to 40 µM menadione. (B) Expression of proteases (left) and immunoreactive GDH protein (right) in cells treated with 0 (top), 10 (middle), and 20 µM menadione (bottom). (C) Aminating GDH-specific activity. Bars represent ±SE from four replicates.

The Increased in Vitro GDH Aminating Activity Induced by NaCl was Reflected in the Incorporation of ¹⁵N-Ammonium into ¹⁵N-Glu, ¹⁵N-Gln, and ¹⁵N-Pro in the Presence of MSX and AOA
To confirm the validity of in vitro measurements of aminating activity of GDH, tobacco plants were supplied with ¹⁵NH₄⁺, and GC-MS analyses of ¹⁵N-Glu, ¹⁵N-Gln, and ¹⁵N-Pro were performed at 12, 24, and 36 h (Figures 9A to 9C ). Because expression of gdh-NAD;A1 was evident 24 h following salt treatment (Figures 5 to 7), plants were treated with 250 mM NaCl for 24 h prior to the addition of ¹⁵NH₄⁺. ¹⁵N-Glu in the shoots of control and salt-treated plants in the presence of MSX at 36 h accounted for 45 and 250%, respectively, of ¹⁵N-Glu levels without MSX (Figure 9A). The corresponding nonlabeled Glu fractions accounted for 117 and 342%, respectively. Labeled and nonlabeled Gln were negligible in MSX-treated plants (Figure 4B), in agreement with the drastic reduction of GS (Figure 9D; P = 0.01). Treatment with 250 mM NaCl resulted in a time-dependent accumulation of ¹⁵N-Pro (Figure 9C, treatment C), reaching a fourfold increase after 36 h, compared with control plants (Figure 9C, treatment C). In the presence of MSX, ¹⁵N-Pro accumulation occurred at a lower rate, explaining the higher level of ¹⁵N-Glu (Figure 9C, treatment D; P = 0.01). Similar trends were observed for the nonlabeled Pro. Ammonium content in the shoots was consistent with the results obtained by the in vivo studies. Shoots from salt-treated plants contained higher NH₄⁺ content (P = 0.05), increasing by 38% at 24 h and 66% at 36 h compared with control plants (Figure 9E). Salt-treated plants with MSX contained lower NH₄⁺ content (P = 0.05), which corresponds to a 20 and 32% decrease at 24 and 36 h, respectively, compared with those treated with MSX (Figure 9E).

View larger version (35K): [in this window] [in a new window]   Figure 9. GC-MS Analysis of the Fate of 15NH4 in Shoots of N. tabacum cv Xanthi Plants Grown in the Presence of NaCl. Fractions of labeled and nonlabeled Glu (A), Gln (B), Pro (C), GS activity (D), and ammonium ion (E) accumulation in plants grown in 250 mM NaCl at 12, 24, and 36 h after 15NH4 application. Amino acids were extracted and characterized by GC-MS as described in Methods. Data are the means of four replicates, and bars represent ±SE. FW, fresh weight.

View larger version (25K): [in this window] [in a new window]   Figure 10. Fate of 15NH4 in Stems and Leaves of N. tabacum cv Xanthi Plants Grown in the Presence of NaCl. Fractions of labeled (closed bars, 15N) and nonlabeled (open bars, 14N) Glu ([A] and [E]), Gln ([B] and [F]), Pro ([C] and [G]), and ammonium ion ([D] and [H]) accumulation in plants grown in 250 mM NaCl for 24 h with and without inhibitors (MSX and/or AOA). Note that in this experiment the plants were exposed for 24 h to salt treatment before supplying 15NH4. Amino acids were extracted and characterized by GC-MS as described in Methods. Data are the means of four replicates, and bars represent ±SE.

View larger version (53K): [in this window] [in a new window]   Figure 11. Effect of NaCl in the Presence/Absence of MSX on the Expression of gdh and icdh Genes in Tobacco Shoots. (A) Expression of NAD-dependent Nt idh;A, cytocolic NADP-dependent Nt cytICDH, Nt gdh-NAD;A1 encoding for the -subunit of GDH, and Nt gdh-NAD;B2 encoding for the ß-subunit of GDH. (B) Immunoreactive mtICDH, cytICDH, and GDH protein.

Exogenous Ammonium Ions Mirror the Effects of Salinity in Inducing the Expression of Vv gdh-NAD;A1, Increase in -GDH Immunoreactive Protein, Assembly of the Anionic Iso-GDHs, and Increase in in Vitro GDH Aminating Activity

View larger version (43K): [in this window] [in a new window]   Figure 12. Effect of Exogenous Ammonium, as a Sole Nitrogen Source, on GDH Expression in V. vinifera Suspension Cells. (A) Abundance of Nt gdh-NAD;A1 transcript encoding for the -subunit of GDH. (B) Immunoreactive -GDH protein. (C) Isoenzymic profile of GDH; assembly of the anionic iso-GDHs. (D) In vitro aminating–specific activity GDH. Suspension cells were treated with 10 mM NH4Cl or 20 mM KNO3 for 144 h as described in Methods. Bars represent ±SE of three replicates out of three independent experiments.

	DISCUSSION

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ROS generation is a central response of plant cells to stress. At low levels they are scavenged by enzymatic and nonenzymatic scavengers, such as CAT, SOD, ascorbate peroxidase, the Halliwell-Assada cycle enzymes, or numerous antioxidant molecules present in plant cells. Among them, Pro is a potent ROS scavenger associated with prevention of apoptotic-like PCD in Colletotrichum trifolii (Chen and Dickman, 2005). In addition, polyamines contribute to the homeostasis of ROS by inhibiting NAD(P)H-oxidase, preventing the induction of PCD (Papadakis and Roubelakis-Angelakis, 2005) and generating H₂O₂ via the catalytic action of polyamine oxidase (Paschalidis and Roubelakis-Angelakis, 2005b). ROS participate in the redox status of the cell, and redox signals are key regulators of responses to various stress conditions. For example, H₂O₂ induces the synthesis of heat shock proteins (Foyer et al., 1997; Foyer and Noctor, 2005). Moreover, ROS regulate the action of secondary messengers, such as Ca²⁺ (Foyer and Noctor, 2005). If not efficiently scavenged, ROS can have a detrimental effect(s) on metabolism and eventually on growth and development of cells through their ability to initiate reaction cascades, resulting in the production of toxic chemical species, such as hydroxyl radicals and lipid peroxides (Baier and Dietz, 2005; Rhoads et al., 2006). High levels of H₂O₂ trigger a distinct local sequence of events in gene expression that leads inevitably to PCD (Pastori and Foyer, 2002; Figure 3B).

ROS and the redox state of the cell participate in the signal network for the induction of expression of genes encoding effector proteins functioning toward increased stress tolerance (Mittler et al., 2004). Salt stress induces ROS generation in all in vitro model systems tested in this work, in agreement with other studies (Apel and Hirt, 2004 and references therein). Long-term treatment with ammonium ions in tobacco cells also elicited ROS generation, although to a lower extent compared with salt treatment (Figures 3Ai and 3Aj), and ammonium ions generated by Gln transamination induced the generation of O₂·^– in mammalian cells by upregulating the expression of the NADPH oxidase components (Pithon-Curi et al., 2002). Menadione, an elicitor of ROS, also increased proteases (Figure 8). Treatment of cells with H₂O₂ induced protease activity putatively responsible for the degradation of oxidatively damaged proteins and increased ammonia in the mitochondria (Sweetlove et al., 2001). Also, excessive intracellular accumulation of salt resulted in expression of proteases (Figure 8), leading to extensive proteolysis and deamination, which contributed to intracellular hyperammonia in rice (Lutts et al., 1999; Hoai et al., 2003) and Arabidopsis (Wong et al., 2004), as in stems and leaves of tobacco plants, grown under salt stress (Figures 4A and 4B).

Overall, in the in vitro plant models that were treated with either salt, ammonium ions, or menadione, ROS accumulation was accompanied by increased gdh-NAD;A1 transcript, immunoreactive GDH protein, anionic GDH isoenzymes, and in vitro GDH aminating activity, thus establishing a role for GDH in ROS sensing/responses. Cells treated with either ammonium or MSX exhibited lower ROS accumulation compared with salt-treated cells. In MSX-treated control plants, although ammonium accumulated, gdh-NAD;A1 was not induced (Figure 11), in contrast with the effect of exogenous ammonium in tobacco cell cultures (Figure 12). In salt-treated plants, gdh-NAD;A1 was induced with a 36-h lag phase, which was the duration of MSX monitoring, since a longer time resulted in damaged plant tissues. Therefore, in the MSX-treated plants, ammonium accumulation during the 36-h follow-up period was probably not sufficient to induce the threshold of ROS necessary for induction of gdh-NAD;A1. In addition, lower intracellular ammonia titers, intracellular ammonia compartmentation or translocation, and the source of ammonia (exogenous or photorespiratory) might differentiate the response of gdh-NAD;A1 in MSX-treated plants. Photorespiratory-produced ammonia in mitochondria is effectively reassimilated in the chloroplast by the action of the chloroplastic GS2, since in gs2 mutants of barley (Hordeum vulgare) (Lea and Forde, 1994), the cytosolic GS1 could not compensate for the loss of chloroplastic GS2. Furthermore, mitochondria possess an efficient defense antioxidant system that may prevent ROS accumulation and/or diffusion in the cytosol and, therefore, gdh-NAD;A1 expression (Rhoads et al., 2006). Recently, it was suggested that GDH in phloem companion cells may play a dual role in the cytosol when ammonium concentration increases above a certain threshold or in the mitochondria when mineral nitrogen availability is low (Tercé-Laforgue et al., 2004a). It can be inferred therefore that exogenous ammonium and its accumulation in the cytosol results in higher levels of ROS generation effective in the induction of gdh-NAD;A1. If ammonium were the principal signal and not ROS for gdh-NAD;A1 gene induction, then the response in salt-treated cells/calluses/leaf discs/plants would follow the timing of ammonium rather than that of ROS, which was not the case. For ammonium to induce gdh-NAD;A1, it has to reach an intracellular threshold before being able to generate sufficient levels of ROS to act as a signal. These results allow the proposition that ROS participate in the signaling pathway, and either alternatively or additively, they result in proteolysis contributing to intracellular hyperammonia.

Although GS/GOGAT are the main enzymes mediating the assimilation of ammonium in plant cells (Lea and Miflin, 1974; Figure 1), their activities in salt-treated tobacco shoots (stems and leaves) remained largely unchanged in contrast with the aminating activity of GDH, which increased. When photorespiratory ammonium accumulates as a result of impaired GOGAT activity (Ferrario-Mery et al., 2002) or when GS becomes limiting (Harrison et al., 2003), alternative metabolic pathways may be activated to avoid ammonium accumulation or that may be important in controlling the flux of nitrogen.

Because the in vitro aminating activities do not always reflect the in vivo function of the enzyme (Dubois et al., 2003; Maslaux-Daubresse et al., 2006; our unpublished data), GC-MS analyses were performed for monitoring the fate of ¹⁵NH₄⁺. The aminating role of the anionic GDH isoenzymes acting toward ammonia detoxification was supported by the incorporation of ¹⁵NH₄⁺ into ¹⁵N-Glu in salt-treated tobacco plants in the presence of MSX or AOA. In the presence of salt, ¹⁵N-Glu synthesis was significantly enhanced, and the sum of ¹⁵N-Glu plus ¹⁵N-Pro in the presence of MSX firmly supports the idea that the anionic isoenzymes of GDH, which consist mostly of the stress-induced -subunit, do function in ammonia assimilation. Although the use of inhibitors may lead to conflicting findings, the relatively low in vivo amination of ¹⁵NH₄⁺ found in MSX control plants eliminates the possibility of an artificial diversion of carbon and nitrogen to GDH. The reaction catalyzed by GDH could be one of the alternative pathways that may be induced when the ammonium concentration reaches a certain threshold (Dubois et al., 2003), and our results support this view.

The fact that the ¹⁵N-Glu produced in salt-treated plants was shifted toward ¹⁵N-Pro synthesis further supports the idea that these molecular responses are induced as a reaction to stress. The biosynthetic pathway of Pro from Glu is mediated by the enzymes P5CS and P5CR (Yoshiba et al., 1997). Pro accumulation in stressed plants has been associated with enhanced tolerance to conditions of abiotic stress (Nanjo et al., 1999a, 1999b). It also plays an important role in the protection of complex II in the mitochondria of roots of salt-treated plants (Hamilton and Heckathorn, 2001). Recent findings reveal that Pro functions as an antioxidant and inhibitor of PCD (Chen and Dickman, 2005). In addition to Pro synthesis, the ammonia detoxification effect of GDH links the entrance of Glu into the Krebs-Henseleit (urea) cycle and to polyamine biosynthesis (Paschalidis et al., 2001). Under hyperammonia, Glu is shifted to synthesize Orn, which is recycled via arginase as part of the urea cycle (Paschalidis and Roubelakis-Angelakis, 2005a) and may be the substrate for Pro synthesis. Both Orn and Arg are used for the biosynthesis of polyamines (Paschalidis and Roubelakis-Angelakis, 2005a, 2005b), which may also play a role in the protection of plants against abiotic stress (Capell et al., 2004).

As the induction of gdh-NAD;A1 by salt is accompanied by increased aminating GDH activity, it is expected that the genes encoding the enzymes that mediate 2OG synthesis should be upregulated as well. Two types of I(C)DH have been identified in plants that use different cofactors (Hodges, 2002). The first is IDH, a tricarboxylic acid cycle enzyme localized in the mitochondria of eukaryotic cells that use NAD. The second is ICDH, consisting of several isoenzymes, localized in the cytosol (Gálvez et al., 1996), the chloroplasts (Gálvez et al., 1994), the mitochondria (Gálvez et al., 1998), and the peroxisomes (Corpas et al., 1999). Both enzymes are potential candidates for supplying 2OG for the amination reactions of GOGAT and GDH. In rice plants treated with ammonium ions, IDH increased concomitantly with GOGAT, suggesting that it could serve to provide 2OG (Abiko et al., 2005). The increase in the Nt gdh-NAD;A1 transcript in the shoots of salt-treated plants was accompanied by a concomitant increase in the transcripts of Nt idh;A and Nt _cyticdh and in the levels of _mtICDH and _cytICDH immunoreactive proteins. These results suggest that, in the presence of salt, both enzymes could supply 2OG for Glu synthesis by GDH.

Quantitative genetic approaches strongly suggest that the reaction catalyzed by NAD(H)-GDH is of major importance in the control of plant growth and productivity (Dubois et al., 2003). Compared with wild-type plants, transgenic tobacco overexpressing bacterial gdh (-subunit of GDH) showed increased tolerance to herbicides and to toxic levels of ammonia as well as higher biomass (Ameziane et al., 2000). Plants transformed with the - and ß-subunits of GDH from Chlorella sorokiniana showed increased growth rates and improved stress tolerance (Schmidt and Miller, 1999), whereas a maize (Zea mays) GDH null mutant was cold temperature sensitive (Pryor, 1990). Fruits from transgenic tomato (Solanum lycopersicum) plants carrying a gene for NADP-GDH from Aspergillus nidulans contained twofold to threefold more free amino acids and twofold more Glu (Kisaka and Kida, 2003), which has been proposed as a signaling molecule in plant growth and environmental response (Glevarec et al., 2004). This idea is strongly supported by the fact that plants possess functional homologues of animal Glu receptors (Lam et al., 1998; Galili et al., 2001). Thus, consistent with its stress-related and signaling role, Glu content might be highly regulated and maintained at a constant level in plants (Glevarec et al., 2004).

Finally, the large amount of GDH activity in phloem companion cells and in the soluble fraction (Paczek et al., 2002; Dubois et al., 2003; Tercé-Laforgue et al., 2004a) opens new perspectives for elucidating the role of GDH in stress response. For instance, under abiotic stress conditions, such as salinity, the sorting of the protein to the mitochondria might be inhibited to allow its accumulation in the cytosol (Ficarelli et al., 1999).

Our results strongly support the hypothesis that plant cells cope with stress conditions by generating ROS, which signal the expression of the -subunit of GDH, the assembly of the anionic iso-GDHs, and an increase in GDH aminating activity. As a result, GDH detoxifies the high intracellular ammonia that is generated by the proteolytic and deaminating activities. These data further reinforce the stress-related function of the anionic isoenzymes of GDH, suggest different physiological roles for the seven GDH isoenzymes, and present a new strategy that plant cells could employ to cope with abiotic stress. Studies of transgenic plants overexpressing gdh-NAD;A1 and gdh-NAD;B2 (Purnell et al., 2005) could contribute further to our understanding of the molecular mechanisms and signaling pathways of stress response in plants.

	METHODS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION METHODS REFERENCES

 
Plant Material and Treatments
Nicotiana tabacum cv Xanthi seeds were surface-sterilized by immersion in 10% (v/v) NaClO for 10 min with gentle shaking. After washing thoroughly with sterile water, the seeds were placed in sterile half-strength Murashige and Skoog (MS) liquid medium (Murashige and Skoog, 1962). Plants were grown in a growth chamber at a 16/8-h photoperiod, 25°C, and 75% RH. Two weeks after emergence, seedlings were transferred in half-strength MS medium without sucrose and allowed to grow for another 2 weeks before the salt treatments (0, 250, and 350 mM NaCl).

Leaf discs (1 disc of 0.1 g mL^–1) from glasshouse-grown Vitis vinifera cv Sultanina or tobacco plants were prepared according to Papadakis and Roubelakis-Angelakis (2005). Leaf discs were immersed in NaCl (0 to 200 mM) under continuous light (100 µmol photons m^–2 s^–1) for up to 72 h. Calluses derived from shoot explants of in vitro–grown grapevine plants were used for the establishment of a suspension cell culture as previously described (Primikirios and Roubelakis-Angelakis, 1999). Calluses were grown for three generations on MS medium containing 20 mM nitrate as the sole nitrogen source. TBY-2 cells (derived from N. tabacum cv BY-2) were cultured as previously described (de Pinto et al., 2000). Calluses, cell suspension cultures of grapevine, or BY-2 cells were treated with NaCl (0 to 200 mM) to monitor the NaCl effect or with 10 mM NH₃Cl to study the effect of ammonium ions. Furthermore, cell suspension cultures were treated with 0, 10, 20, and 40 µM menadione for up to 48 h to monitor the effect of ROS.

Protein Extraction, Enzyme Assays, and Electrophoresis
Total proteins were extracted from cells, calluses, and leaf discs as previously described (Primikirios and Roubelakis-Angelakis, 1999; Papadakis et al. 2005). In brief, 0.2 M Tris-HCl, pH 8.0, 5 mM DTT, 0.5 mM PMSF, 10 µM leupeptin, 10% (w/v) glycerol, and 0.25% (w/v) Triton X-100 was used in the presence of 20% (w/v) polyvinylpolypyrrolidone. The samples were homogenized using a Polytron (Ultra Turrax T25, probe S15 N 10G; LabX) at a speed of 20,000 rpm. The ratio of sample:extraction buffer was 1:3 for cells and 1:4 for other tissues. The homogenates were centrifuged at 12,000 rpm for 30 min, and the supernatants were divided into aliquots and frozen at –80°C. All work was done at 4°C.

In vitro enzyme activity of GDH was determined as described previously (Loulakakis and Roubelakis-Angelakis, 1990a), and values are presented as units ± SE. One unit of GDH is defined as the reduction of 1 µmol NADH per min at 30°C. Analytical and preparative SDS-PAGE of protein extracts was performed as described by Loulakakis and Roubelakis-Angelakis (1992). Transfer of electrophoretically resolved proteins onto nitrocellulose filters (0.2-µm pore size; Schleicher and Schuell) was performed according to Loulakakis and Roubelakis-Angelakis (1990b). GDH isoenzymes were localized in nondenaturating polyacrylamide gels using the in situ staining technique as analytically described by Loulakakis and Roubelakis-Angelakis (1991).

In vitro activity of NADH-GOGAT was assayed using NADH as the electron donor by determining the formation of Glu in the reaction as described by Matoh and Takahashi (1982). One unit of enzyme activity was defined as the amount catalyzing the formation of 1.0 µmol of Glu per minute at 30°C. GS activity was determined as described by Loulakakis and Roubelakis-Angelakis (1996). One unit of enzyme was defined as the amount that catalyzed the formation of 1.0 µmol of -glutamyl hydroxamate per minute at 30°C.

For I(C)DH detection, 100 µg of crude extract protein was analyzed in 10% SDS-PAGE. _cytICDH and _mtICDH primary antibodies were used according to Gálvez et al. (1994).

RNA Gel Blot Analysis
Extraction of RNA from plant tissues was as described by Loulakakis et al. (1996). Total RNA (15 µg) was fractionated in 1% agarose-formaldehyde gel, blotted onto Hybond-N⁺ membrane (Amersham Pharmacia Biotech), and then hybridized with radiolabeled probes, under high-stringency conditions. Prehybridization, hybridization, and washing conditions were performed as described by Church and Gilbert (1984). Probes were labeled using a random hexamer oligonucleotide system (RadPrime DNA Labeling System; Invitrogen). The full-length cDNAs of Vv gdh-NAD;A1 (Syntichaki et al., 1996) and Nt gdh-NAD;B2 (accession number AY366370) from grapevine were used as probes. Moreover, the catalytic NAD-dependent Nt idh (accession number X96727) and the cytocolic NADP-dependent Nt _cyticdh (accession number X77944) isocitrate dehydrogenase clones from N. tabacum were used (Gálvez et al., 1996). Hybridization and washing conditions were stringent to avoid cross-reaction with other subunits.

Protease Activity Assay
For protease activity assays, 20 µg of total protein were separated in 10% acrylamide gel containing 1 mg mL^–1 gelatin (Lockwood et al., 1987). Electrophoresis was performed at 10 mA constant current for 2 h at 4°C. After electrophoresis, the resolving gel was incubated overnight at 37°C in 40 mM Tris-HCl, pH 8.6, and 0.2% Triton X-100. The gel was stained in Coomassie Brilliant Blue R 250 and destained, and the protease activity appeared as white bands.

Ammonia Extraction and Determination
Tissues were ground in liquid nitrogen and extracted in 10 volumes of 10 mM ice-cold formic acid. Free ammonium was determined fluorometrically according to Husted et al. (2000) following derivatization at 63°C with 3 mM O-phthalaldehyde and 10 mM 2-mercaptoethanol (in 0.2 M Tris-HCl, pH 6.8) and quantification in an HPLC system (HP 1100; Hewlett-Packard). Ammoniun concentration was also determined as the amount of NADH oxidized via the aminating reaction of GDH at 340 nm at room temperature in a total reaction volume of 0.5 mL consisting of 100 mM Tris, pH 8.0, 15 mM 2OG, 1 mM CaCl₂, 1 mM NADH, and 2 units of GDH (1 mg protein equals 46 units; Sigma-Aldrich). Control assays were conducted by omitting either 2OG or GDH. The ammonium was quantified by preparing a standard curve with ammonium nitrate.

Chemiluminescence Assay for H₂O₂ and O₂^.–
The production of O₂^.– and H₂O₂ from V. vinifera cv Sultanina cell cultures was determined by the chemiluminescence assay of luminol and lucigenin, respectively, in cells and in the culture medium as already described (Papadakis and Roubelakis-Angelakis, 1999). Three independent experiments, with three replicates each, were performed. One-way analysis of variance was used for statistical analysis.

Incorporation of ¹⁵NH₄⁺ into Nitrogenous Compounds in Tobacco Plants Grown in the Presence of NaCl
N. tabacum cv Xanthi plants (30 d after emergence) were used for the in vivo ¹⁵N assimilation analysis. Two sets of experiments were performed to confirm whether GDH is involved in the amination of 2OG to Glu.

In the first experiment, tobacco plants were transferred in distilled water and 250 mM NaCl (without nutrients) for 24 h before the addition of ¹⁵NH₄⁺. Then the plants were transferred to half-strength MS solution with 20 mM ¹⁵NH₃Cl, as a sole nitrogen source, and the incorporation of ¹⁵NH₄⁺ into Glu, Gln, and Pro was assessed at 12, 24, and 36 h. For GS inhibition, plants were sprayed with 1.5 mM MSX solution of the potential GS inhibitor, and roots were immersed in the same solution for 10 min.

A second set of experiments was performed with a similar design to that described previously to study the response of different organs. Twenty-four hours following the addition of ¹⁵NH₄⁺, the tobacco plants were separated into stems and leaves, and the enrichment of Glu, Gln, and Pro in isotopic nitrogen was determined by GC-MS. In addition to MSX, 1 µM AOA, an inhibitor of transaminases, was added to ensure that transaminations of Glu did not occur.

In all experiments, the plants were harvested and kept at –80°C. Tissue was extracted with 0.01 N HCl and 100 µL of the extraction solution and dried at 90°C under gas nitrogen. Subsequently, 100 µL of acetonitrile and 100 µL of N-methyl-N-(tert-butyldimethylsilyl)-trifluoroacetamide were added to the residue. The mixture was sonicated for 30 s, heated at 70°C for 30 min, and filtered. One-chlorohexadecane was added as internal standard, and 1 µL of the resulting solution was administered to GC-MS for amino acid determination (Sobolevsky et al., 2003). GC-MS analyses were performed using a Hewlett-Packard 5971A mass-selective detector with the appropriate data system. A Hewlett-Packard model 5890 gas chromatograph, equipped with a Grob-type split-splitless injector, was directly coupled with the fused-silica capillary column (HP-5 MS with 0.25-mm film, 30 m x 0.25 mm i.d.) to the ion source. Helium was used as the carrier gas with a back pressure of 0.8 Atm. The injector temperature was 280°C, and the oven temperature program started at 70°C, staying there 2 min, and then increased until 290°C with 5°C/min rate. At 290°C, it stayed for 10 min. Two independent experiments, with two replicates each, were performed. One-way analysis of variance was used for statistical analysis.

Epifluorescence Cytochemical Localization of H₂O₂
In situ localization of H₂O₂ was performed using the highly sensitive, cell-permeable probe DCFH-DA (Molecular Probes) according to Schopher et al. (2001). Cells were harvested, after centrifugation at 3000 rpm, and were incubated in 1 mL buffer (20 mM K-phosphate, pH 6.0, containing 50 µM DCHF-diacetate and 3 µg mL^–1 horseradish peroxidase; Sigma-Aldrich) for 10 min at 25°C in darkness. An aliquot of cells (0.1 mL) was removed, washed in the same buffer, and visualized immediately. Pictures were taken with an epifluorescence microscope (Nikon Eclipse E800) with excitation filter EX 450-490 and emission filter BA 520 using a Sony DXC-950P camera.

Detection of DNA Fragmentation
Cell suspensions, cultured for 18 h in 200 mM NaCl or 40 µM menadione, were analyzed for nuclear DNA fragmentation as previously described (Papadakis and Roubelakis-Angelakis, 2005). Total cellular DNA was stained with propidium iodide (1 µg mL^–1), and the free 3'-OH groups in DNA were labeled by the TUNEL method using an in situ cell death detection kit (Boehringer Mannheim) as instructed by the manufacturer. DNA was visualized with a Nikon Eclipse 800 fluorescence microscope.

Preparation of Figures
The Coomassie blue–stained polyacrylamide gels were photographed using a Kodak DC120 digital camera, and the densitometry was performed with Kodak Digital Science 1D image analysis software. Protein and RNA gel blots were scanned with an HP ScanJet 6100 scanner (Hewlett Packard).

Accession Numbers
Sequence data from this article can be found in the GenBank/EMBL data libraries under accession numbers AY366369 (Nt gdh-NAD;A1), X86924 (Vv gdh-NAD;A1), AY366370 (Nt gdh-NAD;B2), X77944 (Nt _cytICDH), and X96727 (Nt idh;A).

Supplemental Data
The following materials are available in the online version of this article.

Supplemental Figure 1. Viability of Grapevine Cells Grown in 0, 50, 100, and 200 mM NaCl for 24 h.

Supplemental Figure 2. Salinity Induced the Expression of Catalase in Grapevine Leaf Discs Exposed to Salt Stress.

Supplemental Figure 3. Ammonium Content and in Vitro Aminating and Deaminating Activities of GDH and in Vitro–Specific Activities of GS and GOGAT in Tobacco Plants Grown under Salinity Conditions.

Supplemental Figure 4. Salinity Induced the Expression of GDH in BY-2 Cells Grown under Salinity Conditions.

Supplemental Figure 5. Salinity Induced the Expression of GDH in Grapevine Leaf Discs.

Supplemental Figure 6. Addition of Ascorbate (10 µM) Prevents Increase in in Vitro Aminating–Specific Activity of GDH in Grapevine Cells Exposed to Salinity Treatment (200 mM NaCl) for 24 h.

Supplemental Figure 7. In Vitro–Specific Activities of GS in Stems and Leaves of Tobacco Plants Grown in the Presence of MSX ± AOA for 24 h.

	Acknowledgments

 
We thank L. Panagis and A. Dermon (University of Crete) for their advice and assistance in performing the TUNEL assay and the in situ staining of ROS. We also thank M. Hodges (University of Paris) for kindly offering I(C)DH clones and antibodies, M.C. de Pinto (Universita degli Studi di Bari, Italy) for kindly providing the BY-2 cells, and G. Iamine (USDA, Beltsville, MD) for providing the antibody against catalase. The project is cofunded by the European Social Fund and National resources, projects Herakleitos and Pythagoras, and was implemented in the frame of COST858.

	Footnotes

 
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.plantcell.org) is: Kalliopi A. Roubelakis-Angelakis (poproube{at}biology.uoc.gr).

^[W] Online version contains Web-only data.

www.plantcell.org/cgi/doi/10.1105/tpc.105.038323

Received September 30, 2005; Revision received August 2, 2006. accepted September 19, 2006.

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