Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Hydrogen Peroxide in Plants: A Versatile Molecule of Reactive Oxygen Species Network Li-Juan Quan1, Bo Zhang2 , Wei-Wei Shi2 and Hong-Yu Li* (1,2. MOE Key Laboratory of Arid and Grassland Ecology, School of Life sciences, Lanzhou University , Lanzhou,730000) *Author for correspondence. Tel: +86 (0)13519640428; Fax : +86(0)931 891 2561; E-mail: lihy @lzu.edu.cn Supported by the National Natural Science Foundation of China (30170238; 30670070) Abstract Plants often face the challenge of severe environmental conditions, which include various biotic and abiotic stresses, all of which exert adverse effects on plant growth and development. With the evolution of plants, Plants have evolved complex regulatory mechanisms in adapting to various environmental stressors, One of the consequences of much stress is an increase in the cellular concentration of reactive oxygen species(ROS), which is subsequently converted to hydrogen peroxide(H2O2). Even under normal conditions, higher plants produce ROS during the metabolic process. Excess concentrations of ROS results in oxidative damage to or the apoptotic death of cells, Development of an antioxidant defense system in plants protects them against oxidative stress damage. ROS and, more particularly, H2O2 plays versatile roles in plant normal physiological processes and resistance to stresses. Recently, H2O2 has been regarded as a signaling molecule and regulator of the expression of some genes in cells. This review describes various aspects of H2O2 function, generation and scavenging, genes regulation and the crosslink with other physiological functional molecules during plant growth, development and resistance responses. Key words: antioxidant system; gene regulation; hydrogen peroxide (H2O2); reactive oxygen species (ROS); signaling molecule Abbreviation: ABA, abscisic acid; APX, ascorbate peroxidase; CaM, calmodulin; CAT, catalase; CDPKs, cacium-dependent protein kinases; DHA, dehydroascorbate; DHAR, dehydroascorbate reductase; GPX, glutathione peroxidase; GR, glutathione reductase; GSH, glutathione; GSSG, glutathione reductase; H2O2, hydrogen peroxide; HR, hypersensitive reaction; iNOS, inducible nitric oxide synthase; .OH, hydroxyl radical; JA, Jasmonic acid; MAPKs, mitogen-activated protein kinases; MAPKKKs, mitogen-activated protein kanase kinase kinases; MDHA, mondehydroascorbate reductase; NO, nitric oxide; NOS, nitric oxide synthase; O2-, superoxide radical; ROS, reactive oxygen species; SA, salicylic acid; SAR, systemic acquired resistance; SOD, superoxide dismutase; UV, ultra-violet. As a kind of reactive oxygen species (ROS), hydrogen peroxide (H2O2) has been given much attention during the last decades. Ample evidence has proven that H2O2 plays an important role in plants under severe environmental conditions, which include various biotic and abiotic stresses (Dat et al. 2000). H2O2 participates in many resistance mechanisms, including reinforcement of the plant cell wall, phytoalexin production, and enhancement of resistance to various stresses (Dempsey and klessig 1995). Recently, H2O2 has also been shown to act as a key regulator in a broad range of physiological processes such as senescence (Peng et al. 2005), photorespiration and photosynthesis (Noctor and Foyer 1998a), stomatal movement (Bright et al. 2006), cell cycle (Mittler et al. 2004), and growth and development (Foreman et al. 2003). To some extent, excess H2O2 accumulation can lead to oxidative stress in plants, which then triggers cell death. The evolution of all aerobic organisms is dependent upon the development of efficient H2O2-scavenging mechanisms (Arora et al. 2002), Enzymes, including superoxide dismutase (SOD), catalase (CAT), peroxidase (POD), ascorbate peroxide (APX) and glutathione reductase (GR) (Zhang et al. 1995; Lee and Lee 2000), and nonenzymatic antioxidants such as tocopherols, ascorbic acid (AsA), and glutathione (GSH) (Wingsle and Hallgren 1993; Kocsy et al. 1996; Noctor et al. 1998) work in concert to detoxify H2O2. Sustaining the H2O2 concentration at an appropriate level can promote plant development and reinforce resistance to environment stressors. H2O2 modulates the expression of various genes (Neill et al. 2002). The H2O2 induced transcripts encoded proteins with functions such as metabolism, energy, protein destination and transport, cellular organization and biogenesis, cell rescue of defense, and transcription ( Desikan et al. 2001a).Among these genes, the genes encoding potential transcription factors should be emphasized due to their capacity for activating the expression of downstream target genes ( Desikan et al. 2001a). Using cDNA microarray technology, A large-scale analysis of gene transcription has been undertaken looking in Arabidopsis and tobacco during oxidative stress (Desikan et al. 2001a; Vandenabeele et al.2003;Vanderauwera et al. 2005).More studies have provided evidence that H2O2 itself is a key signal molecule mediating a series of responses (Desikan et al. 2003) and activating many other important signal molecules (Ca2+, SA, ABA, JA, ethylene, NO) of plants (Gundlach et al. 1992; Dempsey and Klessig 1995; Liu et al. 2004; Desikan et al.2004; Wendehenne et al. 2004). These signal molecules function together and play a complex role in signal transduction of resistance responses, and growth and development in plant. This article describes various aspects of H2O2 function, generation and scavenging, gene regulation and crosslinks with those physiological functional molecules during plant growth, development and resistance responses. Origin of H2O2 Since the oxygen molecule (O2) emerged in earth, it is usually said to be the final electron receptor during the biology respiration. Recently, studies have estimated that 1% of O2 consumed by plants is diverted to produce reactive oxygen species (ROS) in various sub-cellular loci (Bhattacharjee 2005). Reactive oxygen species (ROS), a collective term for radicals and other non-radical but reactive species derived from the oxygen molecule (O2), has been implicated in numerous developmental and adaptive responses in both animal and plant cells (Dypbukt et al. 1994; De Marco and Roubelasis-Angelakis 1996; Lamb and Dixon 1997). The earliest report about ROS production in plants is that challenged potato with incompatible P. infestant lead to reduction of cytochrome C that induces a hypersensitive reaction (HR) involving active defense reaction, and the reaction can be inhibited by SOD (Doke 1983a,b). The kinds of ROS have been investigated in plant including hydrogen peroxide (H2O2), superoxide anion (O2-), hydroxyl radicals (. OH), singlet oxygen (1O2) and nitric oxide (NO.) by far, H2O2, O2- , .OH can transform themselves into each other (figure 1). H+ 2e oxygen molecule (O2) superoxide anion (O2-) SOD Hydrogen peroxide (H2O2) Hydrogen peroxide (H2O2) (cell wall) (cytosol mitochondria chloroplast) PKC Hydrogen peroxide (H2O2) Fe2+ Hydroxyl radicals (Feton reaction) (.OH) Figure 1. Transition between the oxygen molecule (O2), superoxide anion (O2-), hydrogen peroxide (H2O2) and hydroxyl radicals (.OH). During oxidative burst, O2 is reduced to O2-, and then the O2- undergoes spontaneous dismutation at a higher rate and at acidic pH, which is also found in the cell wall (Sutherland 1991). O2- is also catalyzed by superoxide dismutase (SOD) enzymes, which occur in the cytosol, chloroplasts, and mitochondria (Scandalios 1993), O2 can also be reduced to H2O2 by protein kinase C (PKC) (Juan et al. 2004), PKC exists in all organelle of plants (Juan et al. 2004). H2O2 reacts with Fe2+ leading to the H2O2-dependent formation of .OH (Arora et al. 2002). It has been estimated that both resistance responses to stresses and normal physiological metabolism can lead to ROS production (Van Breusegem et al. 2001). By comparison, O2- and H2O2 are weaker oxidizing agents. Under normal condition, the half-life of H2O2 is probably 1ms, and other forms of ROS, including superoxide anion (O2-), hydroxyl radicals (.OH) and singlet oxygen (1O2), their half-life are very short, about 2-4 µs (Bhattacharjee 2005). Excess H2O2 leads to oxidative stress and is capable of injuring cells. During the course of evolution, plants were able to achieve a high degree of control over H2O2 accumulation (Droge 2002). Recent investigations revealed that ROS, especially H2O2 is a central component of the signal transduction cascade involved in plant adaptation to the changing environment (Neill et al. 2002). H2O2 participates in the physiological metabolism of plant and activate defense responses to various stresses. H2O2 is beginning to be accepted as a second messenger for signals generated by means of ROS because of its relatively long life and high permeability across membranes (Neill et al. 2002; Huang et al. 2002; Yang and Poovaiah 2002). Versatile roles of H2O2 Hydrogen peroxide (H2O2) plays a dual role in plants: at low concentrations, it acts as a signal molecule involved in acclimatory signaling triggering tolerance against various abiotic and biotic stresses (Laloi et al. 2004; Fukao and Bailey-Serres 2004; Mittler et al. 2004). And, at high concentrations, it orchestrates programmed cell death (Dat et al. 2000) H2O2 takes part in resistance mechanism, reinforcement of plant cell wall (lignification, cross-linking of cell wall structural proteins) phytoalexin production and resistance enhancement (Dempscy and Klessig 1995). In plant-microbe interaction, H2O2 production in plants can kill the pathogen directly or induces defense genes to limit infection by the microbe. H2O2 can be used as a marker in tobacco leaves for testing the occurrence of plant basal defense reactions (Bozso et al. 2005). Under other stress conditions, which include UV-radiation, salt stress, drought stresses, light stress, metal stress, high or low temperature and so on. H2O2 production in plants induces resistance to various stresses and protects itself from being hurt. Recently, it’s been suggested that H2O2 is not only a defensive signal molecule but it also functions as a signal molecule during plant growth and development. Evidence suggested that H2O2 production plays a key role in separating and culturing of protoplast during reproduction of tobacco protoplast (Papadakis and Roubelasis-Angelakis 2002). Using a luminescence probe one can check H2O2 accumulation in the germinating of radish seeds (Schopfer et al. 2001). H2O2 can also regulate the plant cell cycle. Treated tobacco with fungi elicitor produced H2O2 and activated MAPK protein (Suzuki et al. 1999). MAPK as a key signal protein regulates the cell cycle. The links between the H2O2 cell cycle are orthologous protein of MAPKKK, ANP1 and NPK1 (Suzuki et al. 1999) In addition, H2O2 is also a signal molecule related to senescence (Bhattacharjee 2005). It has been proven that there is more H2O2 accumulation in old leaf than young leaf. Hence, H2O2 also takes part in ABA-induced stomatal opening and closing (Pei et al. 2000; Neill et al. 2002). Distribution of H2O2 pH-dependent cell wall peroxidase is able to oxidize NADH and in the process catalyze the formation of superoxide anion (O2-); and cell wall oxidase catalyzes the oxidation of NADH to NAD+, which in turn reduces O2 to O2-, consequently is dismutated to produce O2 and H2O2 (Bhattacharjee 2005). In addition, germin-like oxalate oxidases and amine oxidases have been proposed to generate H2O2 at the apoplast (Bolwell and Wojtaszek 1997; Hu et al. 2003; Walters 2003). Cell membrane NADPH-dependent oxidase (NADPH oxidase) has recently received a lot of attention as a source of H2O2 for the oxidative burst; In addition, there are other enzymes at the surface of plasma membranes capable of generating H2O2 (cell wall polyamine oxidase) (Vianello and Macri 1991). It has been identified that respiratory burst oxidase homologues (rboh), plant homologues of the catalytic subunit of phagocyte NADPH oxidase (gp91phox), as a source of ROS during the apoplastic oxidative burst (Agrawal et al. 2003). ROPs (Rho-related Gtpases from plant) closely related to the mammalian Rac family, triggering H2O2 production and then the oxidative burst, most likely by activating the NADPH oxidase (Agrawal et al. 2003). Plant mitochondria as an“energy factory” is believed to be a major site of H2O2 production related to continuous physiological processes under aerobic conditions (Rasmusson et al. 1998). The mitochondria electron transport chain (ETC) is comprised of four complex NADH dehydrogenase(C Ⅰ ), succinate dehydrogenase(C Ⅱ ), ubiquinol-cytochrome bc1(C Ⅲ ), and cytochrome c oxidase (C Ⅳ) (Rasmusson et al. 1998). There are also five enzymes existing only in plants: they are one alternative oxidase (AOX), four NAD(P)H dehydrogenase assembled to flavoproteins, so they are a potential source of ROS production (Mller 2001). During respiration, O2 may undergo an univalent reduction at the sites of H2O2 generation in complexes Ⅰand Ⅲ of the respiratory chain (Figure 2). The ubiquinone site in complex Ⅲ appears as the major site of mitochondrial H2O2 production (Braidot et al. 1999), this site catalyzes the conversion of O2 into the O2- by a single electron. Of some substrates along respiratory chain. Flavoproteins, Quinols, especially semiquinols, its energy barrier of redox is very low, the electron before transporting to final oxidase reacts with O2 to form O2- (Elstner 1991). In aqueous solution, O2- is moderately reactive but can generate H2O2 by dismutation (Rasmusson et al. 1998). About 1-5% of mitochondria O2 consumption leads to H2O2 production (Mller 2001). The activity of CⅠ can be inhibited by rotenone and diphenyleneiodo (DPI) (Meloamp et al. 1996); and the activity of CⅢ can be inhibited by KCN, KCN interdicts the Q cycle, so inhibits the semi-quinone production (Rasmusson et al. 1998). O2- INTERMEMBRANE SPACE Cyc C O2 e INNER MITOCHONDRIA Ⅱ MATRIX e Ⅳ Ⅲ Ⅰ UQ MEMBRANE UQ O2 e superoxide anion (O2- ) O2 MnSOD hydrogen peroxide (H2O2) Figure 2. Sites of hydrogen peroxide formation in mitochondria electron transfer system. H2O2 production is at the two main sites, Complex I and III. The ubiquinone site (UQ) in complex Ⅲ catalyzes the conversion of O2 to O2- by a single electron transfer (Rasmusson et al. 1998). Since UQ is bound to two sites in complex III, one close to the inner surface of the inner mitochondria membrane, the other close to the out surface, ROS might be found on either side of the membranes (Rasmusson et al. 1998). O2- is converted into H2O2 by Mn-SOD (Mller 2001). CI NADH dehydrogenase; CII succinate dehydrogenase; CIII ubiquinol-cytochrome bc1; c Ⅳ cytochrome C oxidase Chloroplasts are also a major source for H2O2 production. Chloroplasts consist of pigment and protein, two photo reaction systems: photo-system Ⅰ(PSⅠ) and photo-system Ⅱ(PS Ⅱ) (Asada and Takahashi 1987). There is a photosynthesis electron transport, calling ‘Z’-scheme. Recently the electron transport chains (ETC) in photo-system Ⅰ(PSⅠ) have been considered to be the source of O2- in chloroplasts(figure 3). Normally, the electron flow from the excited PS centers is directed to NADP+, which is reduced to NADPH. It then enters the Calvin cycle and reduces the final electron acceptor, CO2. In situations of overloading of the ETC, a part of the electron flow is diverted from ferredoxin to O2, reducing it to superoxide anion via a Mehler reaction (Wise and Naylor 1987; Elstner 1991). Later studies have revealed that the acceptor side of ETC in PS Ⅱalso provides sides (QA, QB) with electron leakage to O2 producing O2(Takahashi and Asada 1988) (Figure 3).On the external, “stromal” membrane surface O2- is enzymatically by CuZn-SOD or spontaneously dismutated to H2O2(Takahashi and Asada 1988) P680 P680* PSⅡ P700* PSⅠ QA QB e O2 e O 2- CuZnSOD e e H2O2 FeS e PQ Fd acceptor side NADP+ P700 NADPH Calvin cycle Figure 3. Production of hydrogen peroxide in chloroplast at the site of PSI and PSII.. 680*, P700*:photo reaction center Ⅱ and Ⅰ,electron flows from PSⅡ to PSⅠ. QA: quinone A. QB: quinone B. PQ: proton quinone. FeS: ironsulfur protein. Fd:ferredoxin. At these sites of electron leakage provides electrons for O2 producing O2-, O2- is dismutated to H2O2 by CuZn-SOD(Takahashi and Asada 1988). Peroxisomes are subcellular organelles with an essentially oxidative type of metabolism. It is also called glyoxysome. peroxisomes produce superoxide radicals (O2-) as a consequence of their normal metabolism. At least, two sites of O2- generation are demonstrated (Figure 4) (refer to Del Río et al. 2002). One is in the organelle matrix, in which the generating system is identified as Xanthine oxidase (XOD), Xanthine oxidase (XOD) catalyzes the oxidation of Xanthine and hypoxanthine to uric acid and is a well-known producer of O2- (Corpas et al. 2001). Another site is in the peroxisome membranes dependent on NAD (P) H. Peroxisome membrane, a small electron transport chain, is composed of a flavoprotein NADH and cytochrome b, and O2- is produced by the peroxisome electron-transport chain. Monodehydroascorbate reductase (MDHAR) participating in O2- production by peroxisome membranes (Del Río et al. 1989). O2- radicals are rapidly converted into H2O2 and O2 by CuZn-SOD (Del Río et al. 2002). H2O2 Xanthine O2 MATRIX XOD CuZnSOD O2- Uric acid peroxisomal metabolism NAD+ NADH e MEMBRANE MDHAR Ctyb CYTOSOL O2 e e O2 O 2- O 2- H2O2 Figure 4. Production of hydrogen peroxide in peroxisomes. The model is based on results recently described (Jimenez et al. 1997) monodehydroascorbate reductase(MDHAR) is an NADH-dependent enzyme. Matrix and membrane are two sites of O2- generation. XOD oxidizes Xanthine to Uric acid, providing electrons for O2 to product O2-, cyt b also provides electrons for O2 to produce O2-; O2- then is converted into H2O2 by SOD, XOD (Xanthine oxidase) and cyt b (cytochrome b). Localization of H2O2 scavenging enzymes The accumulation of H2O2 increases the probability of hydroxyl radical formation via Teton-type reaction. This leads to the phenomenon known as oxidative stress (Bartosz 1997; Foyer and Noctor 2000). In plant cells, enzymes and redox metabolites act in synergy to carry out H2O2 scavenging (Table 1) TABLE 1. H2O2 scavenging enzymes Enzyme EC number Reaction catalyzed -+ O2- +2 H+ <=> 2 H2O + O2 Superoxide dismutase 1.15.1.1 O2 Catalase 1.11.1.6 2 H2O2 <=> 2 H2O +O2 Glutathione peroxidase 1.11.1.12 2GSH+PUFA-OOH<=>GSSG+PUFA+2 H2O Glutathine reductase 1.6.4.2 NADPH+GSSG <=> NADP +2GSH Ascorbate peroxidase 1.11.1.11 AA+ H2O2 <=> DHA+2 H2O Guaiacol type peroxidase 1.11.1.7 Donor + H2O2<=>Oxidized donor +2 H2O Major ROS-scavenging enzymes of plants include superoxide dismutase (SOD), ascorbate peroxidase (APX), catalase (CAT), and glutathione peroxidase (GPX) (Table1). These enzymes provide cells with highly efficient machinery for detoxifying O2- and H2O2. The balance between SOD and the different H2O2-scavenging enzymes in cells is considered to be crucial in determining the steady state level of O2- and H2O2 (Asada and Takahashi. 1987;Bowler et al. 1991) In plants, the main enzymatic H2O2 scavenger of photosynthetic cells is CAT, which convert H2O2 into H2O and O2 (Scandalios 1987). CAT scavenges H2O2 generated during mitochondrial electron transport, β-oxidation of the fatty acids, and most importantly in photorespiratory oxidation (Scandalios et al. 1997). In perxoxisomes/ glyoxysomes, CAT predominates. CAT isoforms are distinguished on the basis of organ specificity and responses to environmental stress (Willekens et al 1994a). A CAT isoform has been reported to be present in maize mitochondria (Scandalios et al 1980), but no mitochondrial form has been reported in C3 species (Foyer and Noctor 2000). Peroxisomes contain a large amount of CAT, but its properties suggest that the enzyme is inefficient in removing low concentrations of H2O2 (Willekens et al. 1994a) Peroxidase (POD) is a heme-containing glycoprotein encoded by a large mutigene family in plants and involved in various physiological processes. Studies have suggested that POD plays a role in lignification, cross-linking of cell wall structure proteins and defense against pathogen (Kawano 2003). POD exists as isoenzymes in individual plant species (Hiraga et al. 2001). Ascorbate peroxidase(APX) is the main enzyme responsible for H2O2 removal in the chloroplast, peroxisomes and mitochondria. APX utilizes ascorbate as its specific electron donor to reduce H2O2 to water (Asada 1992). Glutathione peroxidase (GPX) is a family of isoenzymes that uses glutathione to reduce H2O2 and organic and lipid hydro-peroxides, thereby protecting cells against oxidative damage. GPX is an important H2O2 scavenging enzyme in mammals. In plants, GPX exists in the cytosol to reduce H2O2 to water. But the ability of plant GPX to scavenge H2O2 decreases largely due to its Cys residue without selenium. Hence, the major functions of GPX in plants are lignin biosynthesis, degradation of indole-3-acetic acid and resistance to pathogens (Asada 1992). However, except for the donor specific peroxidase mentioned above, there is a group of non-donor specific peroxidase in plant cells, for which guaiacol is a common donor, named guaiacol peroxidase (Mika and Luthje 2003). Recently, two distinct guaiacol peroxidases (pm POD1 and pm POD2) have been separated from the plasma membrane. However more functions of guaiacol peroxidase are still unclear (Mika and Luthje 2003). Balance between H2O2 and cell redox An appropriate intracellular balance between H2O2 generation and scavenging exists in all cells (figure 5) (refer to Mittler et al 2004). This “redox homeostasis” requires the efficient coordination of reactions in different cell compartments and is governed by a complex network of prooxidant and antioxidant systems. The latter include nonenzymatic scavengers such as ascorbate, glutathione, hydrophobic molecules, tocopherols and detoxifying enzymes (Noctor and Foyer 1998a). INNER MEMBRANE Ascorbate MATRIX DHA H 2O FD MDA O2- Ascorbate MDA H2O2 O 2- CuZnSOD H2O2 H 2O H2O2 PSⅠ PSⅡ e O2- e APX CuZnSOD e Complexes ubiquinone CuZnSOD Chloroplast Mitochondria Catalase GSSG H2O2 H 2O Ascorbate O 2DHAR MDAR APX H2O2 Ascorbate APX H2O MDA H2O CuZnSOD GPX GR DHA 2GSH H 2O Cytosol MDA Peroxisome Figure 5. Localization of hydrogen peroxide (H2O2) scavenging pathways in plant cells(chloroplast, peroxisome, cytosol and mitochondria). The enzymatic pathways responsible for H2O2 detoxification are shown. The water-water cycle detoxifies O2- and H2O2. H2O2 distributes in peroxisomes, mitochondria, chloroplast and cytosol. Catalase (CAT), ascorbate peroxidase(APX). SOD and other components of the Ascorbate-glutathione cycle are also present in mitochondria and peroxisomal. Glutathione peroxidase(GPX) is involved in H2O2 removal in the cytosol. H2O2 can easily diffuse through membranes and antioxidants such as glutathione and ascorbic acid (reduced or oxidized) can be transported between the different compartments. Abbreviations: DHA, dehydroascrobate; DHAR,DHA reductase; FD, ferredoxin; GLR, glutaredoxin; GR, glutathione reductase; GSH, reduced glutathione; GSSG, Oxidized glutathione; IM, inner membrane; MDA, monodehydroascorbate; MDAR, MDA reductase; PSⅠ,photosystemⅠ; PSⅡ, photosystemⅡ. Ascorbate is present in chloroplasts, cytol, and vacuole and apoplastic spaces of leaf cells in high concentration (Foyer et al. 1991). It is perhaps the most important antioxidant in plants, with a fundamental role in the removal of H2O2 (Polle et al. 1990). The ascorbate/glutathione cycle is the most important H2O2 – detoxifying system in the chloroplasts. But it also has been an identifying system in the cytosol (Nakano and Asada 1981), peroxisomes, and mitochondria (Jimenez et al. 1997). Two enzymes are involved in the regeneration of reduced ascorbate, namely mono-dehydro-ascorbate reductase (MDHR) which uses NAD (P) H directly to recycle ascorbate and dehydro-ascorbate reductase (DHR). Mono-dehydro-ascorbate is reduced directly to ascorbate by using electrons derived from the photosynthetic electrons transport chain as follows (Arora et al. 2002): 4 Mono-dehydro- ascorbate(MDHR) + 2 H2O→ 4 Ascorbate + O2 H 2O 2 AsA GSSG H 2O GR DHAR APX MDHA DHR NADPH NADP+ GSH Figure 6. Ascorbate-glutathione cycle (Halliwell-Asada pathway) of H2O2 scavenging. AsA, ascorbate; APX, ascorbate-peroxidase; MDHAR, mondehydroascorbate reductase; DHA, dehydroascorbate; DHAR, dehydroascorbate reductase; GR, glutathione reductase; GSH, Glutathione. Regulation of genes expression related to H2O2 Hydrogen peroxide (H2O2) has been regarded as the second messenger for gene activation in mammalian systems as well as in plant. In plants, increased H2O2 level induces the expressing not only of defense genes, but also other resistance genes (Mitter et al. 2004). Temperature-independent induction of smHSPs has been observed in response to high light (HL) (Pnueli et al. 2003; Yamamoto et al. 2004) and to various other abiotic stress conditions (Zimmermann et al. 2004). A subset of genes within the heat shock response might be triggered by increased levels of H2O2 (Larkindale and Knight 2002). H2O2 is clearly able to induce the smHSPs 17.6 class. In the different assessed abiotic stresses, these smHSPs are coexpressed with AtHsf 2A; recently, this class of cytoplasmic smHSPs has been shown not to be under transcriptional control of HsfA1a/HsfA1b during heat shock (Busch et al. 2005). And recently a role of AtHsfA4a in the early sensing of H2O2 stress has been demonstrated in Arabidopsis (Davletova et al. 2005) Recent studies of knockout and antisense lines for Cat2, Apx1, chlAOX, mitAOX, CSD2, 2-cysteine PrxR and various NADPH oxidases have revealed a strong link between H2O2 and processes such as growth, development, stomatal responses and biotic and abiotic stress responses (Mittler 2004). Based on the analysis of the different mutants. Cat2, Apx1, ChlAOX, CSD2 and 2-cysteine PrxR are essential for the protection of chloroplasts against oxidative damage. Suppression of CSD2, for example, results in the induction of a High-light (HL) stress response in Arabidopsis plants grown under a low light intensity (Rizhksy et al. 2003). Catalase deficiency triggers growth retardation and high sensitivity to ozone and high light stress (Vandenabeele et al. 2004).the absence of Apx1 results in reduced photosynthetic activity, augmented induction of heat shock proteins during light stress and altered stomatal responses (Pnueli et al. 2003). Catalase deficiency triggers growth retardation and high sensitivity to Ozone and high light stress (Vandenabeele et al. 2004). By contrast, the absence of the NADPH oxidase genes AtrbohD and AtrbohF suppresses H2O2 production and the defense responses of Arabidopsis against pathogen attack (Torres et al. 2002). And knockout of atrbohC has an altered root phenotype (Foreman et al. 2003). AtrbohD and AtrbohF are also essential for abscisic acid signaling in guard cells (Kwak et al. 2003). Figure 7 (refer to Vanderauwera et al. 2005) presents the overlap of the H2O2-induced genes with each of the environmental stresses. Twenty genes were induced in response to H2O2 and under at least two stress conditions. Within these 20 commonly induced genes, two transcription factors, DREB2A and ZAT12, could be identified, which have already been linked to H2O2 responses (Rizhksy et al. 2004). DREB2A is known to be a key regulator of drought response (Shinozaki and Yamaguchi-Shinozaki 2000), whereas ZAT12 participates in regulation of cold-responsive genes and contributes to an increase in freezing tolerance (Rizhsky et al. 2004). The up-regulation of other H2O2-responsive transcription factors was restricted to one specific environmental stress. AtWRKY48 was also induced by cold, whereas two NAC family proteins were responsive to drought. These NAC proteins belong to the ATAF suvfamily and have been shown to respond upon abscisic acid, dehydration, and salt treatments (Fujita et al. 2004) At4g12400 Stress-induced protein sti1 At1g62510 Lipid transfer protein At2g24100 Unknown At5g10695 HSP70 At5g11090 Unknown At5g05410 DREB2A At1g66500 Zn finger protein At1g68440 Unknown At3g12580 Hsp70 Cold Heat 6 At5g49520AtWRKY48 16(1) 59(3) 3(1) 0 At2g26150 At Hsf 2A At3g51910 At HsfA7a At4g11660 At HsfB2b 11(1) 8(2) At5g59820 ZAT12 At1g19020 Unknown At2g32210 Unknown Drought At5g63790 NAC-family protein At1g77450 NAC-family protein At5g65300 Unknown At3g02840 Unknown At1g66160 Unknown At5g57220 Cytochrome P450 At4g20830 reticuline oxidase At5g64310 Arabinogalactan-protein At1g66290 Disease resistance protein At1g02400 Dioxygenase Figure 7. H2O2-up-regulated genes within three principal environmental stresses. The different stress conditions (cold, heat, and drought) are indicated together with the number of genes within the overlap with the H2O2-responsive genes and the total number of gene input of each of the stresses as well. In the Venn diagram, numbers of genes are given that are unique to that gene set or in the common sections between sets, with the amount of transcription factors present within a specific gene set in parentheses. Transcription factors are indicated in blue. In Arabidopsis, a network of at least 152 genes is involved in managing the level of H2O2 (Mittler et al 2004). Expression profiles were compared between control and catalase-deficient Arabidopsis plants (CAT2HP1) by high light (HL) exposure. In the CAT2HP1 plants, HL irradiation results in elevated level of H2O2 positively regulate genes involved in the defense response, hypersensitive response, protease, transcription and translation, and mitochondrial metabolism (Vandenabeele et al. 2003, 2004). In total 349 transcripts were significantly up-regulated by H2O2 in catalase-deficient plants and 88 were down-regulated (Vanderauwera et al. 2005). Transgenic Catalase-deficient tobacco plant (CAT1AS) were exposing to high light (HL). Because the CAT1AS plants only maintain 10% of their residual catalase activity, H2O2 cannot be scavenged efficiently. During HL exposure, H2O2 accumulated early and sustained over time. The expression kinetics of >14,000 genes were monitored by using transcript profiling technology based on cDNA-amplified fragment length polymorphism. Clustering and sequence analysis of 713differentially expressed transcript fragments revealed a transcriptional response that mimicked that reported during both biotic and abiotic stresses (Vandenabeele et al. 2003). Including the up-regulation of genes involved in hypersensitive response, vesicular transport, posttranscriptional processes, biosynthesis of ethylene and jasmonic acid, mitochondrial metabolism, and cell death (Figure 8)(refer to Vandenabeele et al. 2003). Nox DAGK PLC Px oxidative burst HL AmOx ROS C 2 H2 SA SAMs UGSG JA Lox ACCs Photorespiration H2O2 ACCo ARRM MYB ARC1 PLK Shaggy AP-2 Grp WAK-1 Pti 12-OPDR signal interplay WRKY WIPK PAS DES ARF Kinase SCRC PP2C HBF-1 vesicular transport ADL2b defense response protein degradation Ub E2 E3 BAG mitochondria CYT-C PHB 26s cell death AOX BCS1 Peptidase Figure 8. Model for the role of H2O2 in the induction of defense and cell death and the relation of the genes identified in this expression analysis. HL intensities provoke an increase in photorespiratory H2O2 in CAT1AS plants. Signal transduction components in close interaction with hormone signals, vesicular transport, protein degradation, and mitochondrial responses regulate the induction of the defense response and cell death. 12-OPDR, 12-oxophytodienoatereductase; 26S, 26S proteasome non-ATPase regulatory subunit; DYN, dynamin; ACCo, 1-aminocyclopropane-1-carboxylic acid oxidase;ACCs,1-aminocyclopropane-1-carboxylic acid synthase; ADL2b, ADL2b dynamin; AmOx,amine oxidase; AOX, alternative oxidase; AP2, APETALA2 domain-containingprotein; ARF, ADP-ribosylation factor; ARRM, two-component cytokinine response regulator; BAG, BAG-domain-containing protein; BCS1, ubiquinolcytochromereductase synthase; CYT-C, cytochrome C; DAGK, diaglycerolkinase; DES, divinyl ether synthase; E2, ubiquitin-conjugating enzyme; E3,ubiquitin-protein ligase; Grp, glycine-rich protein; HBF1, bZIP DNA-bindingprotein, HBF1; HL; LOX, lipoxygenase; MYB, MYB transcription factor; Nox,NADPH oxidase; PAS, PAS-domain containing protein; PHB, prohibitin; PLC,phospholipase C; PP2C, protein phosphatase 2C; Pti, Pto-interacting protein; Px, peroxidase; RLK, receptor-like kinase; ROS; SAMs, S-adenosyl-Lmethioninesynthetase; SCRC, SCARECROW transcription factor; Shaggy, SHAGGY-like kinase; Ub, ubiquitin; UGSG, UDP-glucose:SA:glucosyltransferase;WAK1; WIPK, wound-induced kinase. H2O2:Part of signaling network Hydrogen peroxide (H2O2) acts as a signaling molecule, the second messenger, mediating the acquisition of tolerance to both biotic and abiotic stresses (Desikan et al. 2003). H2O2 plays a signaling role in various adaptive processes. Plant can sense, transport and induce cellular responses. These responses include defense reactions against pathogens, ABA-mediated stomatal closure (Neill 2002a), and regulation of cell expansion (Suzuki et al., 1999), plant senescence (Bhattacharjee 2005) and programmed cell death (Mittler 2002). H2O2 can modulate the activities of many components in signaling, such as protein phosphatases, protein kinases and transcription factors (TFs) (Cheng and Song 2006). H2O2 is also found to communicate with other signal molecules and the pathway forming part of the signaling network that controls response downstream of H2O2 (Neill 2002a). H2O2 and Ca2+、K+ Calcuim as a ubiquitous internal- second messenger can regulate diverse cellular processes in plant. The earlier reactions of plant cells to stresses are changes in plasma membrane permeability leading to calcium and proton influx appears to be necessary and sufficient for induction of the hydrogen peroxide (H2O2) (Pei et al. 2000). More lines of evidence concerning the relationship between H2O2 and Ca2+ signals were provided by the study of H2O2 homeostasis in Arabidopsis (Yang and Poovaiah. 2002). H2O2 production requires a continuous Ca2+ influx, which activates the plasma membrane-localized NADPH oxidase (Lamb and Dixon 1997), subsequently calcium-dependent cellular responses referred to anion and K+ efflux (Blein 1991). Challenge Abrabidopsis with H2O2 triggered a biphasic Ca2+ elevation (Rentel and Knignt 2004). A recent study demonstrated that aequorin-expressing tobacco cell cultures also displayed a biphasic [Ca2+] 2+ inhibitors, preventing cyt signature in response to H2O2 challenge (Lecourieux 2002). Ca increases of cytosolic Ca2+ concentration, also delayed the accumulation of endogenous H2O2. Further evidence indicated that H2O2 and Ca2+ were both involved in a signaling cascade leading to the closure of stomata in Arabidopsis (Pei et al., 2000). In this study, H2O2-activated Ca2+ channels Mediated both the influx of Ca2+ in protoplasts and increases in [Ca2+]cyt in intact guard cells (Pei et al. 2000) Calmodulin(CaM), ubiquitous calcium-binding protein, bound and activated some plant catalases in the presence of calcium. Ca2+/CaM has been supposed to increase H2O2.generation through Ca2+/CaM dependent NAD kinase that affects the concentration of available NADPH during activation of NADPH oxidase (Harding et al. 1997). Ca2+/CaM can down-regulate H2O2 levels in plants by stimulating the catalytic activity of plant catalase (Yang and Poovaiah 2002), controlling H2O2 homeostasis in plants. Cacium-dependent protein kinases (CDPKs) are implicated as major primary Ca2+ sensors in plants. CDPKs activation, like activation of mitogen-activated protein kinases (MAPKs), is triggered by biotic and abiotic stresses. N-terminal CDPK 2 signaling triggered enhanced levels of the phytohormones jasmonic acid and ethylene but not salicylic acid. Elevated CDPK signaling compromises stress-induced mitogen-activatied protein kinases (MAPKs) activation and this inhibition requires ethylene synthesis and perception (Andrea et al. 2005). Potassium (K+) is essential to plants and required in large quantities by plant (Shin and Schachtman 2004). Changes in the kinetics of Rb+ uptake in Arabidopsis roots occur within 6h after K+ deprivation. H2O2 increases when the plants are deprived of K+. H2O2 accumulates in a discrete region of roots that has been shown to be active in K+ uptake and translocation (Shin and Schachtman 2004). It might play a role in cellular signaling of K+ deprivation (Shin and Schachtman 2004). During stomatal closure, in addition to regulating calcium channels, H2O2 also inhibits K+ channel activity and induces cytosolic alkalinzation in guard cells (Zhang et al. 2001a, b) H2O2 and salicylic acid H2O2 has also been supposed to play a critical role in the activation of hypersensitive reaction (HR) (Bestwick et al. 1997). Following activation of localized resistance associated with HR, plants display systemic acquired resistance (SAR). Salicylic acid (SA) has emerged as a key signal in the establishment of SAR (Dempser and Klessig 1995). Benzoic acid is immediated-prescursor of SA. H2O2 is further implicated in SA synthesis as the conversion of benzoic acid into SA is catalyzed by the H2O2 – mediated activating of benzoic-acid-2 hydroxylase (Dempser and Klessig 1995). Nah G gene encoded salicylate hydroxylase converts SA into catechol. That appears to have little effect on plant response-to infection (Bi et al. 1995; Friedrich et al.1995; Mur et a l.1997). PR-1 gene induction by H2O2 is suppressed in NahG plants, suggesting that SA acts downstream of H2O2 induction. Van camp suggested a H2O2 –SA interaction pattern: H2O2 and SA constitute a self-amplifying system; H2O2 induces SA accumulation and SA enhances H2O2 level (Van camp et al. 1998). Challenge transgenic tobacco Samsun NN expressing salicylate hydroxylase (35S-SH-L) with avirulent strains of pseudomonas syringae delays H2O2 accumulation by 2-3h. That indicates an early transient rise in SA potentate the oxidative burst with resultant effects on accumulation of H2O2 (Del Río et al. 2002). Soybean CaM (ScaM)-4 and ScaM-5 genes specifically depend on the increase of intracellular Ca2+ level. Expression of ScaM-4 and ScaM-5 in transgenic tobacco-plants triggered spontaneous induces an array of systemic acquired resistance (SAR)-associated genes. But have normal level of endogenous salicylic acid (SA). Indicating that SA is not involved in the SAR gene induction mediated by SCaM-4or SCaM-5 (Wayne et al. 2001). Transgenic tobacco expressing an antisense copy of SABP (salicylic acid-binding protein) catalase exhibits not only a reduction in catalase activity and but also constitutive expression of PR –1 genes (Sanchez-Casas and Klessig.1994; Chen et al. 1995) H2O2 and nitric oxide In mammals, the generator of NO by inducible Nitric oxide synthetase (iNOS) plays an important role in inflammation and host defense responses (Nathan and Shiloh 2000). Anmounting body of evidence suggests that NO is a novel effecter of plant growth, development and defense. For example, NO was shown to be involved in photo-morphogenesis, leaf expansion, root growth, senescence, and phytoalexin production ( Noritake et al. 1996;Beligni and Lamattina 2000). An increasing number of reports suggest that H2O2 emerges following synthesis of Nitric Oxide (NO) and that NO collaborates with H2O2 in plant disease resistance (Delledonne et al. 2001; Hancock et al. 2002; Wendehenne et al. 2004). NO is indispensable to salicylic acid (SA) function as a SAR inducer (Durner and Wendehenne 1998; Song and Goodman 2001). Nitric Oxide as a bioactive molecule displays pro-oxidant and anti-oxidant properties in plant as well. The role of NO may be explained by its relative timing and intensity, NO and H2O2 released in plants cells may be different in different plant-pathogen systems (Urszula and Rozalska 2005). Two main potential roles for NO produced during plant-pathogen interactions have been postulated in relation with H2O2: NO can act as an antioxidant, scavenging excess H2O2, ending radical-mediated lipid peroxidation and inhibiting H2O2 signaling pathways, which leads to cell death; NO can act synergistically with H2O2 to induce SAR (Urszula and Rozalska 2005). Recent demonstrations of nitric oxide synthase (NOS) in plants peroxisomes also has a function in plant cells as a source of signal molecules like nitric oxide (NO.) and hydrogen peroxide (H2O2) (Barroso et al. 1999). H2O2 and abscisic acid Abscisic acid (ABA) is an endogenous anti-transpirant that reduces water loss through stomatal pores on the leaf surface (Tardieu et al. 1992). The regulation of stomatal closure involves various controls that help the plant adapt to a variety of environmental changes (Hetherington and Woodward 2003). H2O2 is an essential signal in mediating stomatal closure induced by abscisic acid (ABA) via the activation of calcium-permeable channels in the plasma membrane (Pei et al. 2000; Neill 2002a). The phenotype of the open stomatal 1(ost1) protein kinase mutant, which is disrupted in ABA-induced ROS production but able to close stomatal in response to H2O2. The following discovered that H2O2 is also an essential signal mediating ABA-induced stomatal closure (Neill et al. 2002a). H2O2 and ethylene The plant hormone ethylene is involved in regulation of a wide variety of development, and physiological events, such as seed germination, pathogen and stress responses, fruit ripening, senescence and regulation of Legumes (Abeles et al. 1992; O’Donnell et al. 1996; Penninckx et al. 1996).The role of ethylene as a signal of defense response is supported by various studies (Liu et al. 2004). Treatment of plants with ethylene was shown to induce the synthesis of basic chitinases(PR-3) and β -1-3-glucanases(PR-2)(BoIIer et al. 1983; Mauch et al. 1984). Exogenous H2O2 challenge CAT lose mutant pine needle induces ethylene production. And the production peak emerged before endogenous H2O2 accumulation in plant. H2O2 may be an up-stream signal molecular (Ievinsh and Tiberg 1995). Ozone challenged tobacco, 1h later induced H2O2 production in apoplast and ethylene accumulation (Schraudner et al. 1998). As for ozone-sensitive mutant Arabidopis challenged by ozone, studies suggested it is necessary for ethylene biosynthesis and signal transduction to O2- accumulation (Overmyer et al. 2000). MAPKs have also been shown to regulate ethylene signal transduction in Medicago and Arabidopsis, implying the involvement of a MAPKKK pathway (Fatma et al. 2003) H2O2 and jasmonate The rapid accumulation of jasmonate (JA) has been observed in many cultured plant cells in response to various elicitor treatments (Gundlach et al. 1992). In suspension-cultured rice cells, an N-acetylchitoheptaose elicitor led to synthesis of the phytoalexin, momilactone A, which is preceded by the accumulation of jasmonate (Nojiri et al. 1996). Methyl jasmonate (MeJA), a methyl ester of jasmonic acid (JA), is a well-established signal molecule in plant defense responses and an effective inducer of secondary metabolite accumulation in plant cell cultures such as hydrogen peroxide (Wang and Wu 2005). SA has been supposed to antagonize jasmonic acid (JA) biosynthesis and signaling. SA levels were reduced in salicylate hydroxylase-expressing of tobacco plants, while JA levels were not elevated when challenged by Pseudomonas syringae pv. Phaseolicola (Takahashi et al. 2004). Contreatment with various concentrations of SA and JA was assessed in tobacco and Arabidopsis. There was a transient synergistic enhancement in the expression of genes associated with either JA (PDF 1.2 and Thi 1.2) or SA (PR1) signaling when both signals were applied at low concentrations. Antagonism was observed at prolonged treatment times or at higher concentrations (Takahashi et al. 2004). Transduction of the SA signal requires the function of NPR1, a regulatory protein that was identified in Arabidopsis through genetic screens for SAR- compromised mutants (Cao et al. 1997). SA and JA are modulated through a novel function of NPR1. NPR1 is essential for SA-mediated defense gene expression, and is not required for the suppression of JA signaling (Steven et al. 2003). Concluding remarks In plant metabolism, reductive activation of molecule oxygen produces an array of reactive oxygen species (ROS), such as singlet oxygen (1O2), superoxide anion (O2-), hydrogen peroxide (H2O2) and hydroxyl radicals (.OH). For many years, research has focused on the detrimental effects of ROS, which were considered as undesirable, harmful byproducts in an oxygenic atmosphere. In the last decade, increasing evidences have suggested that ROS, especially H2O2 play an important role as signaling molecules, and is produced both accidentally and deliberately by plant controls and fine tuned metabolic networks. It is safe to say that ROS is “two-faced”, being “harmful” when produced in excess and “beneficial” at lower concentrations. ROS at these “beneficial” levels plays a part in sensing the environment and regulating development, growth, and environmental accumulation. H2O2 is a byproduct of cellular metabolism, and in plants it is produced by relatively large amounts in mitochondria, chloroplasts, peroxisomes/glyoxysomes, and at the plasma membrane and cell wall. Growing evidence suggests that H2O2 plays a versatile role in plant defense and physiological reaction. There is also H2O2 accumulation during the normal plant metabolism condition. It functions as an important signal molecular during plant growth and development. H2O2 accumulation is maintained at the very low level because of the existence of an antioxidant system in plant, for eliminating excess H2O2 production, and maintaining the level of H2O2 at a normal dynamic balance. For the continuous production of H2O2, an unavoidable consequence of aerobic metabolic processes such as respiration and photosynthesis sensing changes of H2O2 concentrations that result from metabolic disturbances is used by plants to activate stress responses that help the plant cope with environmental changes. H2O2 is the reactive oxygen species (ROS) whose physiological functions are the most extensively and long-term. And H2O2 is a less oxidant among other kinds of ROS. It can also act as a balance point in plant between oxidative and oxidative stress. The effect of H2O2 in plants varies according to different conditions. In a word, the merit of H2O2 outweighs its demerit to plants. Genetically, some of the H2O2 –sensitive genes could also be involved in plant resistance and hormone signaling. In addition, H2O2 is apparently used as an intracellular signal that often works together with other molecules to controls a variety of processes of plant. In a word, H2O2 plays a key role in regulating plant growth, development, resistance responses and signal transduction (Figure 9). H2O2 metabolism in plants physiological stress perception metabolism pathogen recognition photosythesis respiration H2O 2 low accumulation high normal oxidative stress ion flux SA signal NO transduction genes regulation redox balance JA antioxidant system ethylene ABA regulating plant growth and development Figure 9. Plant endogenic H2O2 accumulation during normal metabolism (photosynthesis, respiration, growth, senescence, stomatal close) and various abiotic and biotic stress conditions, which include UV-C radiation, low and high temperature, salt stress and pathogenic stress). Excess H2O2 can induce oxidative stress, injuring plant cells. When the amount of H2O2 accumulation is maintained at normal level by a series of antioxidant molecular and enzyme, H2O2 acts as a second messenger and functions with other important signal molecules. They work together to protect plants from stresses and in regulating plant growth and development. H2O2 production is indispensable during plant growth, development and resistance responses. As a stable ROS, H2O2 has higher stability and longer half-life, which allows H2O2 to have great capability to buffer other ROS molecules. In another view, the balance between H2O2 and cell redox under oxygen scavenging enzymes plays a versatile role in changing oxygen relative impact on cells and altering cell resistance mechanism. Thus we can get better understanding of the roles of H2O2 in plants using physiological and genetic analysis in the future research. Acknowledgement: The author thank professor Hong-Yu Li (College of Life Sciences at Lanzhou University) for reviewing and improving early drafts of the manuscript and Bo Zhang (College of Life Sciences at Lanzhou University) for helping to develop many of the ideas. References Abeles FB, Morgan PW, Saltveit ME (1992). Ethylene in Plant Biology. 2nd ed. Scan Dieg, CA Academic Press. Agrawal GK, Iwahashi H, Rackwal R (2003). Small GTPase (ROP) molecular switch for plant defense. FEBS Lett. 546, 173-180. Andrea A, Saitoh H, Felix G, Freymark G, Miersch O, Wasternack C et al. (2005). Ethylene-mediated cross-talk between calcium-dependent protein kinase and MAPK signaling controls stress response in plants. Proc Natl Acad Sci USA. 102(30), 10736-10741. Arora A, Sairam RK, Srivastava GC (2002). Oxidative stress and antioxidative system in plants. Current Science 82 (10), 1227-1234. Asada K (1992). Ascorbate peroxidase: A hydrogen peroxide-scavenging enzyme in plants. Physiol Plant 85, 235-241. Asada K, Takahashi M (1987). Production and scavenging active oxygen in photosynthesis. In: Kyle DJ, Osmond CB, Amtzen CJ, eds. Photoinhibition. Amsterdam: Elsevier. pp. 227-287. Bartosz G (1997). Oxidative stress in plants. Acta Physiol Plant. 19, 47-64. Barroso JB, Corpas FJ, Carrerase A, Sandalio LM, Valderrama R, Palma JM et al. (1999). Localization of Nitric oxide synthase in plant peroxisomes. J.Biol Chem. 274, 36729-36733. Beligni MV, Lamattina L (2000). Nitric oxide stimulates seed germination and de-etiolation, and inhibits hypocotyls elongation, three light-inducible responses in plant. Planta 210, 215-221. Bestwich CS, Brown IR, Bennett MH, Mansfield JW (1997). Localization of hydrogen peroxide accumulation during the hypersensitive reaction of Lettuce cells to Pseudomonas syringae pv phaseolicola. Plant Cell 9, 209-221. Bhattachrjee S (2005). Reactive oxygen species and oxidative burst: Roles in stress, senescence and signal transduction in plant. Current Science 89, 1113-1121. Bi YM, Kenton P, Mur L, Darby R, Draper J (1995). Hydrogen peroxide does not function down stream of salicylic acid in the induction of PR protein expression. Plant J. 8, 235-245. Blein JP, Milat ML, Ricci P (1991). Response of tobacco is associated with the attenuation of a salicylic acid-potentiated oxidative burst. The plant Journal 23(5), 609-621. Boller T, Gehri A, Mauch F, Vogeli U (1983). Chitinase in bean leaves: induction by ethylene, purification, properties, and possible function. Planta 157, 22-31. Bolwell GP , Wojtaszek P (1997). Mechanisms for the generation of reactive oxygen species in plant defense broad perspective. Physiol. Mol. Plant Pathol. 51, 347-366 Bowler C, Slooten L, Vandenbranden S, de Rycke R, Botterman J, Sybesma C et al. (1991). Manganese Superoxide dismutase can reduce cellular damage mediated by oxygen radicals in transgenic plants. EMBO J. 10, 1723-1732. Bozsó Z., Ott PG, Szamári Á, Zelleng ÁC, Varga G, Besenyei E et al (2005). Early detection of Bacterium–induced basal resistance in Tobacco leaves with diaminobenzidine and dichlorofluorescein diacetate. J Phytopathology. 153, 596-607. Braidot E, Petrussa E, Vianello A, Macri F (1999). Hydrogen peroxide generation by higher plant mitochondria oxidizing complexⅠor complex Ⅲ substrates. GEBS Lett. 451, 347-350. Bright J, Desikan R, Hancock JT, Weir IS, Neill SJ (2006). ABA-induced NO generation and stomatal closure in Arabidopsis are dependent on H2O2 synthesis. The Plant Journal 45, 113-122. Busch W, Wunderlich M, Schöffl F (2005). Identification of novel heat shock factor-dependent genes and biochemical pathways in Arabidopsis thaliana. Plant J. 41, 1-4. Cao H, Glazebrook J, Clarke JD, Volko S, Dong X (1997). The Arabidopsis NPR1 gene that controls systemic acquired resistance encodes a novel protein containing ankyrin respects. Cell 88, 57-63. Cheng Y, Song C (2006). Hydrogen peroxide homeostasis and signaling in plant cells. Sci China C Life Sci. 49, 1-11. Chen Z, Malamy J, Henning J, Conrath U, Sanchez-Casas P, Silva H et al. (1995). Induction, modification, and transduction of the salicylic acid signal in plant defense responses. Proc Natl Acad Sci USA. 92, 4134-4137. Corpas FJ, Barroso JB, Del Rio LA (2001). Peroxisomes as a source of reactive oxygen species and nitric oxide signal molecules in plant cells. Trends in plant Science 6, 145-150. Dat J, Vandenabeele S, Vranova E, van Montagu M, Inze D, van Breusegem F (2000). Dual action of the active oxygen species during plant stress responses. Cell. Mol. Life Sci. 57, 779-795. Davletova S, Rizhsky L, Liang H, Coutu J, David J, Zhang SQ et al. (2005). Cytosolic ascorbate peroxidase 1 is a central component of the reactive oxygen gene network of Arabidopsis. Plant Cell 17, 268-281. Del Rio LA, Fernandez VM, Ruperez FL, Sandalio LM, Palma JM (1989). NADH induces the generation of superoxide radicals in leaf peroxisomes. Plant Physiology 89, 728-731. DeMarco A, Roubelasis-Angelakis KA (1996). The complexity of enzymatic control of hydrogen peroxide concentration may affect the regeneration potential of plant protoplasts. Plant Physiol. 110, 137-145. Delledone M, Zejer A, Marocco, Lamb C (2001). Signal interactions between Nitric oxide and reactive oxygen intermediates in the plant hypersensitive disease resistance response. Proc. Nat L. Acad. Sci. USA.98, 13454-13459. Dempsey DA , klessig DF (1995). Signals in plant disease resistance. Bull. Inst. Pasteur. 93, 167-186. Desikan RS, Mackerness AH, Hancock JT, Neill SJ (2001a). Regulation of the Arabidopsis transcriptome by oxidative stress. Plant Physiol. 127, 159-172. Desikan R, Hancock JT, Neill SJ (2003). Oxidative stress signaling. In H. Hirt and Shinozaki K (eds.), Plant responses to abiotic stress: topic in current genetics. Springer-Berlag, Berlin, Heidelberg, Nes York. pp. 121-148. Desikan R, Cheng MK, Clarke A, Golding S, Sagi M, Fluhr R et al. (2004). Hydrogen peroxide is a common signal for darkness- and ABA-induced stomatal closure in Pisum sativum. Funct. Plant Biol. 31, 913-920. Doke N (1983a). Involvement of superoxide anion generation in hypersensitive response of potato tuber tissues to infection with an incompatible race of Phytophthora infestans. Physiol. Plant Pathol. 23, 345-357. Doke N (1983b). Generation of superoxide anion by potato tuber protoplasts upon the hypersensitive response to hyphal wall components of Phytophthora infestans and specific inhibition of the reaction by suppressor of hypersensitivity. Physiol. Plant Pathol. 27, 311-322. Droge W (2002). Free radicals in the physiological control of cell function. Physiol Rev. 82, 47-95. Dypbukt JM, Ankarcrona M, Burkitt M, Sjöholm A, Ström K, Orrenius S et al. (1994). Different peroxidant levels stimulate growth, trigger apoptosis or produce necrosis of insulin secreting RINm 5F cells. J Biol Chem. 369, 30553-30560. Durner J, Wendehenne D, Klessig DF (1998). Defense gene induction in tobacco by nitric oxide, cyclic GMP. And cyclic ADP-ribose. Proc. Natl. Acad. Sci. USA. 95, 10328-10333. Elstner EF (1991). Mechanism of oxygen activation in different compartment of plant cells. In E.J. Pell and K.L. Steffen(eds.), Active oxygen/Oxidative stress and plant metabolism. American Society of Plant Physiologists, Rockville 13-25. Fatma O, Rozhon W, Lecourieux D, Hirt H (2003). A MAPK pathway mediates signaling in plants. EMBO J. 22, 1282-1288. Foreman J, Bothwell JH, Demidchik V, Mylona P, Miedema H, Torres MA et al. (2003). Reactive oxygen species produced by NADPH oxidase regulate plant cell growth. Nature 422, 442-446. Foyer CH, Lelandais M, Edwards EA, Mullineaux PM (1991). The role of ascorbate in plants interactions with photosynthesis, and regulatory significance. In active oxygen/oxidative stress and plant metabolism. Current Topics in plant physiology (eds Pell E. and Steffen K.), Am. Soc. Plant Physiologists 6,131-144. Foyer CH, Noctor G (2000). Transley Review NO .112. Oxygen processing in photosynthesis: Regulation and signaling. New Phytol. 146, 359-389. Friedrich L, Vernooij B, Gaffney T, Morse A, Ryals J (1995). Characterization of tobacco plants expressing a bacterial hydroxylase gene. Plant Mol Biol. 29, 959-968. Fukao T, Bailey-Serres J (2004). Plant responses to hypoxia-is survival a balancing act. Trends in Plant Science 9, 449-456. Fujita M, Fujita Y, Maruyama K, Seki M, Hiratsu K, Ohme-Takagi M et al. (2004). A dehydration-induced NAC protein, RD26, is involved in a novel ABA-dependent stress-signaling pathway. Plant J. 39, 863-876. Gundlach H, Muller MJ, Kutchan TM, Zenk MH (1992). Jasmonic acid is a signal transducer in elicitor-induced plant cell cultures. Proc Natl Acad Sci USA. 89, 2389-2393. Harding SA, Oh SH, Roberts DM (1997). Transgenic tobacco expressing foreign calmodulin genes. Show an enhanced production of active oxygen species. EMBO J. 16, 1137-1144. Hancock JT, Desikan R, Clarke RD, Hurst SI, Neill S (2002). Cell signaling following plant/pathogen interactions involves the generation of reactive oxygen and reactive nitrogen species. Plant Physiol Biochem. 40, 611-617. Hetherington AM, Woodward H (2003). The role of stomata in sensing and driving environmental change. Nature 424, 901-908. Hiraga S, Sasaki K, Ito H, Ohashi Y, Matsui H (2001). A large Family of Class Ⅲ Plant Peroxidases. Plant Cell Physiol 42, 462-468. Huang X, Kiefer E, Rad UN, Ernst D, Foissner I, Durner J (2002). Nireic oxide burst and nitric oxide-dependent gene induction in plants. Plant Physiol Biochem. 40, 625-631. Hu X, Bidney DL, Yalpani N, Duvick JP, Crasta O, Folkerts O et al. (2003). Overexpression of a gene encoding hydrogen peroxide-generating oxalate oxidase evokes defense responses in sunflower. Plant Physiol. 133, 170-181. Ievinsh G, Tiberg E (1995). Stress-induced ethylene biosynthesis in pine needles: A search for the putative 1-aminocy-clopropane-1-carboxylic-independent pathway. J Plant Physiol. 145, 308-314. Jimenez A, Hernandez JA, Del Rio LA, Sevilla F (1997). Evidence for the presence of the ascorbate-glutathione cycle in mitochondria and peroxisomes of pea leaves. Plant Physiol. 114, 275-284. Juan A, Pedro C, Stewawart O et al. (2004). Hydrogen peroxide generation induces PP600 src activation in Human P; atelets. 279(3), 1665-1675. Kawano T (2003). Roles of the reactive oxygen species generating peroxidase reactions in plant defense and growth induction. Plant Cell Rep. 21, 829-937. Koscy G, Brunner M, Ruegsegger A, Stamp P, Brunold C (1996). Glutathione synthesis in maize genotypes with different sensitivities to chilling. Planta 198, 365-370. Kwak JM, Mori IC, Pei ZM, Leonhardt N, Torres MA, Dangl JL et al. (2003). NADPH oxidase AtrbohD and AtrbohF genes function in ROS-dependent ABA signaling in Arabidopsis. EMBO J. 22, 2623-2633. LaIoi C, Apel K, Danon A (2004). Reactive oxygen signaling: the latest news. Current opinion in plant Biology 7, 323-328. Larkindale J, Knight MR (2002). Protection against heat stress-induced oxidative damage in Arabidopsis involves calcium, abscisic acid, ethylene, and salicylic acid. Plant Physiol. 128, 682-695. Lamb C, Dixon RA (1997). The oxidative burst in plant disease resistance. Annu Rev Plant Physiol Plant Mol Biol. 48, 251-275. Lecourieux D, Marzars C, Pauly N, Ranjeva R, Pugin A (2002). Analysis and effects of cytosolic free calcium increase in response to elictous Nicotiana plumbaginigolia cells. Plant Cell 14, 2627-2641. Lee DH, Lee CB (2000). Chilling stress-induced changes of antioxidant enzymes in the leaves of cucumber: in gel enzymes activity assays. Plant Sci. 159, 75-85. Liu Q, Yu ZG, Kuang WC (2004). Ethylene signal transduction in Arabidopsis. Journal of plant Physiology and Molecular Biology 30(3), 241-250. del Río LA, Corpas FJ, Sandalio LM, Palma JM, GÓmez M, Barroso JB et al. (2002). Reactive oxygen species, antioxidant systems and nitric oxide in peroxisomes. Journal of Experimental Botany 53 (372), 1255-1272. Mauch F, Hadwiger LA, Boller T (1984). Ethylene: symptom, not signal for the induction of chitinase andβ –1,3-glucanase in pea pods by pathogens and elicitors. Plant Physiol. 76, 607-611. Melo AMP, Roberts TH, Mller IM (1996). Evidence for the presence of two rotenone-insensitive NAD (P) H dehydrogenases on the inner surface of the inner membrane of potato tuber mitochondria [J]. Biochim. Biophys Acta. 1276, 133-139. Mittler R (2002). Oxidative stress, antioxidants and stress tolerance. Trends Plant Sci. 7, 405-410. Mittler R, Vanderauwera S, Gollery M, Van Breusegem F (2004). Reactive oxygen gene network of plant. TRENDS Plant Science 9(10), 490-498. Mika A, Luthje S (2003). Properties of guaiaiol peroxidase activities isolated from corn root plasma membrane. Plant Physiol. 132, 1489-1498. Mller IM (2001). Plant mitochondria and oxidative stress electron transport, NADPH turnover, and metabolism of reactive oxygen species [J]. Annu. Rev. Plant Physiol Plant Mol Biol. 52, 561-591. Mur LAJ, Bi YB, Darbu RM, Firek S, Draper J (1997). Compromising early SA accumulation delays the hypersensitive response and increases viral dispersal during lesion establishment in TMV-infected tobacco. Plant J .12, 1113-1126. Murata Y, Pei ZM, Mori IC, Schroeder J (2001). Abscisic acid activation of plasma membrane Ca2+ channels in guard cells requires cytosolic NAD(P)H and is differentially disrupted upstream and downstream of reactive oxygen species production in abi1-1 and abi2-1 protein phosphatase 2C mutants. Plant Cell 13, 2513-2523 Mustilli AC, Merlot S, Vavasseur A, Fenzi F, Giraudat J (2002). Arabidopsis OST1 Protein kinase mediates the regulation of stomatal aperture by abscisic acid and acts upstream of reactive oxygen species production. Plant Cell 14, 3089-3099 Nakano Y, Asada K (1981). Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts (1981). Plant Cell Physiol. 22, 869-880. Nathan C, Shiloh MU (2000). Reactive oxygen and nitrogen intermediates in the relationship between mammalian hosts and microbial pathogens. Proc. Natl. Acad. Sci. USA. 97, 8841-8848. Neill SJ, Desikan R, Clarke A, Hancock JT (2002a). Nitric oxide is a novel component of abscisic acid signaling in stomatal guard cells (2002a). Plant Physiology 128, 13-16. Neill SJ, Desikan R, Hancock J (2002). Hydrogen peroxide signaling. Curr Opin plant Biol. 5,388-395. Nojiri H, Sugimori M, Yamane H,Nishimura Y, Yamada A, Shibuya N et al. (1996). Involvement of jasmonic acid in elicitor-induced phytoalexin production in suspension-cultured rice cells. Plant Physiol. 110, 387-392. Noctor G, Foyer CH (1998a). Ascorbate and glutathione: keeping active oxygen under control. Annu. Rev. Plant Physiol. Plant Mol Biol. 49, 249-279. Noctor G, Arisi AM, Jouanin L, Kunert KJ, Rennenberg H, Foyer CH (1998). Glutathione: biosynthesis, metabolism and relationship to stress tolerance explored in transformed plants. J. Exp. Bot. 49, 623-647. Noritake T, Kawakita K, Doke N (1996). Nitric oxide induces phytoalixin accumulation in potato tuber tissue. Plant Cell Physiol. 37, 393-398. Overmyer K, Tuominen H, Kettunen R, Betz C, Langebartels C, kangasjärvi J et al (2000). Ozone-sensitive Arabidopsis rcd1 mutant reveals opposite roles for ethylene and jasmonate signaling pathways in regulation superoxide-dependent cell death. Plant Cell 12, 1849-1862. O’Dnonell P, Calvert C, Atzorn R, Wasternack C, Leyser H (1996). Ethylene as a signal mediating the wound response of tomato plants. Science 274, 1914-1917. Papadakis AK, Roubelakis-Angelakis KA (2002). Oxidative stress could be responsible for the recalcitrance of plant protoplasts. Plant Physiol Biochem. 40, 549-559. Park KY, Jung JY, Park J, Hwang JU, Kim YW, Hwang I et al. (2003). A role for phosphatidylinositol 3-phosphate in abscisic acid-induced reactive oxygen species generation in guard cells. Plant Physiol. 132, 92-98 Pei ZM, Murata Y, Bnning G, Thomine S, Klusener B, Allen GJ et al. (2000). Calcium channels activated by hydrogen peroxide mediate abscisic acid signaling in guard cell. Nature 406, 731-734. Peng LT, Jiang YM, Yang SZ, Pan SY (2005). Accelerated senescence of Fresh-cut Chinese water chestnut Tissues in relation to Hydrogen peroxide accumulation. Plant PHYSLMOLBI 31(5), 527-532. Penninckx IA, Eggermont K, Terras FR, Thomma BP, De Samblanx GW, Buchala A et al. (1996). Pathogen-induced systemic activation of a plant defense gene in Arabidopsis follows a salicylic acid-independent pathway. Plant Cell 8, 2309-2323. Pnueli L, Liang H, Rozenberg M, Mittler R (2003). Growth suppression, altered stomatal responses, and augmented induction of heat shock proteins in cytosolic ascorbate peroxidase (Apx1)-deficient Arabidopsis plants. Plant J. 34, 187-203. Polle A, Chakrabariti K, Schurmann W, Rnnenberg H (1990). Composition and properties of Hydrogen peroxide Decomposing systems in extra-cellular and Total Extracts from needles of Norway spruce. Plant Physiol. 94, 312-319. Rasmusson AG, Heiser V, Zabaleta E, Brennicke A, Grohmann L (1998). Physiological, biochemical and molecular aspects of Mitochondria complex in plants [J]. Biochmi Biophys. Acta. 1364, 101-111 Rentel MC, Knight MR (2004). Oxidative stress-induced calcium signaling in Arabidopsis . Plant Physiology 135, 1471-1479. Rizhsky L, Liang HJ, Mittler R (2003). The water-water cycle is essential for chloroplasts protection in the absence of stress. J.Biol. Chem. 278, 38921-38925. Sanchez-Casas P, Klessig DF (1994). A salicylic acid-binding activity and a salicylic acid-inhibitible catalase activity are present in a variety of plant species. Plant Physiol. 106, 1657-1679. Scandalios JG, Guan LM, Polidoros A (1997). Oxidative stress and the Molecular biology of antioxidant defenses. Cold spring Harbor Lab. Press Planvies NY. 343-406. Scandalios JG (1987). The antioxidant enzyme genes Cat and Sod of maize: regulation, functional significance, and molecular biology. Isozyme.in Current Topics in Biological and Medical research 14, 19-44. Scandalios JG (1993). Oxygen stress and superoxide dismutases. Plant Physiol. 101, 7-12. Scandalios JG, Tong WF, Roupakisa DG (1980). Cat3, A third gene locus coding for a tissue-specific catalase in maize:Genetics intracellular location, and some biochemical properties. Mol. Gen Genet. 179, 33-41. Schopfer P, Plachy C, Frahry G (2001). Release of reactive oxygen intermediates (superoxide radicals, hydrogen peroxide, and hydroxyl radicals) and peroxidase in germination radish seeds controlled by light, gibberellin, and abscisec acid. Plant Physiol. 125, 1591-1602. Schraudner M, Moeder W, Wiese C, Camp WV, Inzé D, Langebartels C et al. (1998). Ozone-induced oxidative burst in the ozone biomonitor plant tobacco Belw 3. Plant J. 16,235-245. Shin R, Schachtman DP (2004). Hydrogen peroxide mediated plant root cell response to nutrient deprivation. plant biology101(23), 8829-8832. Shinozaki K, Yamaguchi-Shinozaki K (2000). Molecular responses to dehydration and low temperature: differences and cross-talk between two stress signaling pathways. Curr Opin Plant Biol. 3, 217-223. Song F, Goodman RM (2001). Activity of nitric oxide is dependent on, but is particularly required for function of salicylic acid in the signaling pathway in tobacco systemic acquired resistance. Mol. Plant-Microbe Int. 14, 1458-1462. Steven H, Spoela B, Koomneefa A (2003). NPR1 Modulates Cross-Talk between Salicylate and jasmonate dependent defense pathways through a Novel Function in the cytosol. The Plant Cell 15, 760-770. Sutherland MW (1991). The generation of oxygen radicals during host plant responses to infection. Physiol Mol Plant Pathol. 39, 79-93. Suzuki K, Yano A, Shinshi H (1999). Slow and prolonged activation of the p47 protein kinase during hypersensitive cell death in cultured tobacco cells. Plant Physiol. 119, 1465-1472. Takahashi M, Shiraishi T, Asada K (1988). Superoxide production in aprotic interior of chloroplast thylakoids. Archives of Biochemistry and Biophysics 267, 714-722. Takahashi H, Kanayama Y, Zheng MS, Kusano T, Hase S, Ikeqami M et al. (2004). Antagonistic interactions between the SA and JA signaling Pathways in Arabidopsis Modulate Expression of Defense genes and Gene-for Gene resistance to Cucumber Mosaic Virus. Plant and cell physiology 45(6),803-809 Tardieu F, Davies WJ, Ruiz L (1992). Stomatal response to ABA is a function of current plant water status. Plant Physiology 102, 497. Torres MA, Dangl JL, Jones JD (2002). Arabidopsis gp91phox homologues AtrbohD and AtrbohF are required for accumulation of reactive oxygen intermediates in the plant defense response. Proc. Natl. Acad. Sci. USA. 99, 517-522 Urszula M, Rozalska S (2005). Nitric Oxide and hydrogen peroxide in tomato resistance: Nitric oxide modulates hydrogen peroxide level in O-hydroxyethylorutin-induced resistance to Botrytis cinerea in tomato. Plant Physiology and Biochemistry43, 623-635 Van Breusegem F, Vranova E, Dat JF, Inze D (2001). The role of active oxygen species in plant signal transtrction. Plant Sci. 161,405-414. Van Camp W, Van Montagu M, Inze D (1998). H2O2 and NO: redox signals in disease resistance. Trends Plant Sci 3, 330-334. Vandenabeele S, Van Der Kelen K, Dat J, Gadjev I, Boonefaes T, Morsa S et al. (2003). Acomprehensive anlysis of hydrogen peroxide-induced gene expression in tobacco. PNAS. 100(26), 16113-16118. Vandenabeele S, Vanderauwera S, Vuylsteke M, Rombauts S, Langebartels C, Seidlitz HK et al. (2004). Catalase deficiency drastically affects high light-induced gene expression in Arabidopsis thaliana. Plant J. 39, 45-58 Vanderauwera S, Zimmermann P, Rombauts S, Vandenabeele S, Langebartels C, Gruissem W et al. (2005). Genome-Wide Analysis of Hydrogen peroxide-Regulated Gene Expression in Arabidopsis Reveals a High Light-induced Transcriptional Cluster Involved in Anthocyanin Biosynthesis. Plant Physiology 139, 806-821 Vianello A, Macri FG (1991). Generation of superoxide anion and hydrogen peroxide at the surface of plant cell. J Bioenerg Biomembr. 23(3), 409-423. Walters DR (2003). Polyamines and plant disease. Phytochemistry 64, 97-107. Wang JW, Wu JY (2005). Nitric oxide is involved in methyl jasmonate-induced defense responses and secondary metabolism activities of Taxus cells. Plant cell Physiol. 46(6), 923-930. Wayne A, Snedden, Fromm H (2001). Caluoduliu as a versatile calcium Signal Transducer in plants. New Phytologist 151(1), 36-66. Wendehenne D, Dumer J, Klessing DF (2004). Nitric oxide: a new player in plant signaling and defense responses. Curr. Opin. Plant Biol. 7, 449-455. Willekens H, Langebartels C, Tire C, Van Montagu M, Inze D, Van Camp W (1994a). Differential expression of catalase genes in Nicotiana plumbaginifolia (L.). Proc. Natl. Acad.Sci. USA. 91, 10450-10454. Wingsle G, Hallgren JE (1993). Influence of SO2 and NO2 exposure on glutathione, superoxide dismutase and glutathione reductase activities in Scots pine needles. Journal of Experimental Botany 44, 463-470. Wise RR, Naylor AW (1987). Chilling-enhanced peroxidative destruction of Lipids during chilling injury to photosynthesis and ultrastructure. Plant Physiol. 83, 272-277. Yang T, Poovaiah BW (2002). Hydrogen peroxide homeostasis activation of plant catalase by calcium/calmodulin. Plant Biology 99(6), 4097-4102. Yamamoto YY, Shimada Y, Kimura M, Manabe K, Sekine Y, Matsui M et al. (2004). Global classification of transcriptional response to light stress in Arabidopsis thaliana. Endocytobiosis Cell Res.15, 438-452. Zhang X, Dong FC, Cao JF, Song CP (2001a). Hydrogen peroxide-induced changes in intracellular pH of guard cells precede stomatal closure. Cell Research 11, 37-43. Zhang X, Miao YC, An GY, Zhou Y, Shangguan ZP, Gao JF et al (2001b). K+ Channels-inhibited by hydrogen peroxide mediate abscisic acid signaling in Vicia guard cells. Cell Research 11, 195-202. Zhang JS, Li CJ, Wei J, Kirkham MB (1995). Protoplasmic factors, antioxidants responses, and chilling resistance in maize. Plant Physiol. Biol Chem. 382, 1123-1131. Zimmermann P, Hirsch-Hoffmann M, Hennig L, Gruissem W (2004). GENEVESTIGATOR: Arabidopsis microarray database and analysis toolbox. Plant Physiol 136, 2621-2632.