Role of Reactive Oxygen Species during Cell Expansion in Leaves

ROS IN THE APOPLAST: THE OXIDANT’S PLAYGROUND

Cell expansion is the result of a delicate balance between wall relaxation and wall stiffening (Wolf et al., 2012). The primary cell wall consists out of cellulose, hemicellulose, pectin, and structural proteins (Geisler et al., 2008). In primary cell walls, the cellulose matrix is cross-linked by hemicellulose and pectin molecules, in such a fashion that it provides mechanical strength but still allows for cell expansion. Loosening of the cell wall is in part regulated by two classes of proteins (expansins and xyloglucan endotransglucosylases/hydrolases) that act on the interaction between xyloglucans, the major hemicellulose polymer, and the cellulose network (Park and Cosgrove, 2012). Studies on leaf expansion in maize under saline conditions revealed a decreased O₂⁻-derived ˙OH production in the apoplast and a consequent reduction in leaf growth (Rodríguez et al., 2004). Interestingly, it was found that ˙OH promotes cell elongation by loosening the cell wall through oxidative cleavage of polymers like xyloglucan and pectin (Fry, 1998; Müller et al., 2009). In the presence of transition metals, the Haber-Weiss reaction can convert H₂O₂ and O₂⁻ anions to ˙OH, a reaction that can be performed both nonenzymatically as well as enzymatically (Chen and Schopfer, 1999). Although, H₂O₂ is a prerequisite for the formation of ˙OH and thereby for oxidative cell wall loosening, a buildup of H₂O₂ causes cross-linking of the cell wall and restricts elongation growth (Schopfer, 1996). Indeed, during salt, drought, or osmotic stress, an increase in the level of apoplastic H₂O₂ has been noticed and was linked to the inhibition of leaf growth (Lin and Kao, 2001; Kravchik and Bernstein, 2013; Avramova et al., 2015). These observations argue that the apoplastic balance between ˙OH and H₂O₂ regulates cell expansion during leaf growth, but how is ROS homeostasis regulated in the apoplast?

This fundamental question is complex to answer, as large apoplastic and membrane protein families contribute to ROS production (Fig. 1). Among the enzymes that contribute to apoplastic ROS homeostasis are peroxidases (POXs), amine oxidases, oxalate oxidases, and NADPH oxidases (Kärkönen and Kuchitsu, 2015). NADPH oxidases are plasma membrane-located enzymes that, in a Ca²⁺-dependent manner, produce O₂⁻ in the apoplast (Fig. 1). The O₂⁻ dismutates into H₂O₂, which can cause cross-linking of the cell wall or is converted into the cell wall loosening ˙OH (Richards et al., 2015). During biotic stress, NADPH oxidases produce an oxidative burst to eliminate invading pathogens and send stress signals (Suzuki et al., 2011); during abiotic stress, they appear to mainly act as stress signal amplifiers to promote adaptive responses. If NADPH oxidase-derived O₂⁻ is required for cell wall stiffening by H₂O₂, then loss-of-function mutants would be expected to develop more elongated cells. In contrast, mutations in NADPH oxidases have been shown to impair the elongation of root hairs and pollen tubes (Foreman et al., 2003; Takeda et al., 2008; Kaya et al., 2014) and the growth of leaves (Chaouch et al., 2012). Thus, NADPH oxidases are positive regulators of cell growth. So, how can plants control the transition of the NADPH oxidase-derived O₂⁻ into ˙OH to promote cell expansion? A recent report suggests that NADPH oxidase-derived ROS is channeled to apoplastic peroxidases during lignification in roots, by a protein scaffold that brings both proteins in close proximity (Fig. 1; Lee et al., 2013). NADPH oxidase/peroxidase scaffolds have evolved in animals as single proteins, the DUOX class of NADPH oxidases. Still, DUOX proteins are absent in plants, indicating a necessity for a flexible protein scaffold. The identified scaffold proteins belong to the CASPARIAN STRIP MEMBRANE DOMAIN PROTEIN (CASP) family, which, in Arabidopsis, has 20 members (Roppolo et al., 2014). Therefore, it would be interesting to determine which CASP-LIKE proteins might regulate ROS channeling from NADPH oxidases during leaf growth.

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Figure 1.

Cell wall remodeling and apoplastic ROS homeostasis. ROS have a dual role in regulating cell expansion. NADPH oxidase-derived ROS can both promote as well as restrict cell wall extensibility. H₂O₂ derived from the dismutation of O₂⁻ or produced through the action of cell wall-located POXs, polyamine oxidases (POA), or copper-containing amine oxidase (COA) results in dehydration and cross-linking of cell wall polymers. On the other hand, H₂O₂ and O₂⁻ can act as substrates for the Haber-Weiss reaction or pH-dependent POXs, leading to the production of highly reactive ˙OH. The ˙OH results in cleavage of cell wall polymers and thereby promotes cell wall loosening. The pH-dependent formation of ˙OH by POXs can operate in parallel to the pH-dependent activation of EXPANSINs (EXPs) to stimulate cell growth. ROS channeling from NADPH oxidases to POXs is mediated by CASP-LIKE proteins [CASP(L)s], allowing for control over the balance between H₂O₂ and ˙OH production. In addition, apoplastic ˙OH provokes activation of the Ca²⁺ transporter ANN1. The influx of Ca²⁺ might act as a feed-forward signal, since it can activate NADPH oxidases.

The secreted class III POXs in Arabidopsis (Arabidopsis thaliana) consists of 73 members with largely unexplored biochemical properties (Passardi et al., 2004). Early reports on cell growth revealed an inverse correlation between cell growth and POX activity (Fry, 1986; Goldberg et al., 1987). Also, during abiotic stress, POX activity increases and can cause lignification and rigidification of the cell wall, limiting leaf growth (Heggie et al., 2005; Lee et al., 2007). In Arabidopsis, several POX genes have been linked to the regulation of cell expansion during leaf development. Plants overexpressing POX57 or POX71 show a reduced leaf size due to the accumulation of H₂O₂ (Lu et al., 2014; Raggi et al., 2015). Interestingly, both POXs only affect cell expansion, but not proliferation, indicating that POXs might be specifically employed during the regulation of cell growth. However, not all apoplastic POXs generate H₂O₂, some do the opposite while others convert H₂O₂ and O₂⁻ into ˙OH (Chen and Schopfer, 1999; Liszkay et al., 2003). The enzymatic generation of ˙OH in the apoplast by POXs requires a low pH, which can be achieved through the action of auxin (Schopfer et al., 2002). Still, it is not known which of the 73 class III POX proteins contribute to ˙OH formation.

The accumulation of ˙OH in the apoplast activates the atypical Ca²⁺-permeable ANNEXIN1 (ANN1) channel (Laohavisit et al., 2012). Studies on ANN1 in Arabidopsis indicate that loss-of-function mutants have reduced vegetative growth (Konopka-Postupolska et al., 2009). The influx of Ca²⁺ might act as an amplification mechanism for the production of ˙OH, as it activates NADPH oxidases (Renew et al., 2005). Intriguingly, ANN1 is a multifunctional protein that also exhibits peroxidase activity (Gorecka et al., 2005). As stated above, a low pH can promote ˙OH production by several apoplastic POXs, suggesting that ANN1 might also contribute to the production of apoplastic ROS. This assumption would be worth to test as it would place the action of ANN1 into a different perspective, allowing for a feed-forward model in which NADPH oxidase-dependent ˙OH production is amplified by the activation of ANN1.

Next to NADPH oxidases and POXs, other enzymes also contribute to ROS homeostasis in the apoplast. Both amine and oxalate oxidases have a major impact on apoplastic H₂O₂ production (Kärkönen and Kuchitsu, 2015). Two types of amine oxidases, copper-containing oxidases and polyamine oxidases, catalyze the oxidative deamination of di- and polyamines, resulting in the formation of H₂O₂ (Ghuge et al., 2015). To what extent these enzymes contribute to growth regulation during development still needs to be further explored.

Among the large number of proteins that control ROS homeostasis at the cell wall, several have now been demonstrated to have a role in regulating cell expansion during leaf growth. Still, additional research efforts are needed to understand how a cell manages to produce ROS in a specific and timely manner to control cell growth. The recent discovery of potential protein scaffolds that modulate ROS channeling at the apoplast represent attractive new avenues for future research efforts.

WATER UPTAKE AND TRANSPORT OF H₂O₂

Leaf growth relies on active water uptake through controlled transport across membranes (Steudle and Frensch, 1996). Water uptake by cells from the apoplast is facilitated by aquaporins (AQPs). Interestingly, AQPs contribute to the permeability of lipid membranes for a variety of neutral molecules, which are, next to water itself, carbon dioxide and H₂O₂ (Bienert and Chaumont, 2014). Thus, movement of apoplastic H₂O₂ relies on an active transport system, which might serve several functions (Fig. 2). For several AQPs, roles in leaf growth have been demonstrated (Chaumont et al., 1998; Lee et al., 2012). Overexpression of PIP1;2 from Arabidopsis in tobacco (Nicotiana tabacum) speeds up whole-plant growth and increases leaf dry matter accumulation under nonstress conditions. Thus, water transport via AQPs represents a rate-limiting step for growth (Aharon et al., 2003).

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Figure 2.

H₂O₂ modulates water uptake by aquaporins. Turgor pressure-driven cell expansion is controlled by AQPs, which facilitate the transport of H₂O across the plasma membrane. Uptake of extracellular H₂O₂, derived from either NADPH oxidases or apoplastic POXs, across the membrane is regulated by AQPs. In the apoplast, a buildup of H₂O₂ limits cell growth by cross-linking the cell wall. In addition, the influx of H₂O₂ might also limit the water uptake as it appears to activate the endocytosis of AQPs, regulating their abundance at the plasma membrane. Thus, apoplastic H₂O₂ could cause both cell wall stiffening and the inhibition of water uptake.

The transport of H₂O₂ across membranes via plant AQPs was first demonstrated using yeast (Bienert et al., 2007; Dynowski et al., 2008). Expression of Arabidopsis PIP2;1, PIP2;4, TIP1;1, or TIP1;2 increased intracellular accumulation of H₂O₂ (Bienert et al., 2007). The comparable dipole moment and molecular diameter of H₂O₂ and H₂O allow these molecules to undergo hydrogen bonds with residues at the inner surface of the AQP pore (Bienert and Chaumont, 2014). Consistently, mutation of a cytosolic His residue within AtPIP2;1 impairs both water transport and H₂O₂ uptake (Dynowski et al., 2008).

Considering the negative role of H₂O₂ on cell wall extensibility, it was assumed that H₂O₂ might also interfere with AQP activity. Indeed, H₂O₂ treatment of the alga Chara corallina significantly reduced the water permeability of the plasma membrane (Henzler et al., 2004). Interestingly, AQPs contain redox-sensitive Cys residues that form disulphide bonds between PIP monomers, which could be potential targets of H₂O₂ to deactivate the channel (Bienert et al., 2012). However, mutation of these conserved Cys residues into redox-insensitive residues did not affect the channeling activity of maize PIPs under oxidizing or reducing conditions in oocytes (Bienert et al., 2012). Still, to determine whether this is also the case in plant cells, one should complement specific aqp mutants with their corresponding redox-insensitive forms.

PIPs move into or out of membrane microdomains, allowing a dynamic distribution between the plasma membrane and intracellular compartments to control water permeability of the cell (Boursiac et al., 2008; Wudick et al., 2015). Abiotic stress conditions, which result in increased H₂O₂ levels, promote PIP endocytosis. Moreover, intracellular accumulation of PIPs in Arabidopsis upon salt stress was prevented in the presence of catalase (Boursiac et al., 2008). Furthermore, a phosphoproteomics study points to oxidative stress-induced posttranslational modifications of PIPs that initiate endocytosis (Prak et al., 2008). Differential phosphorylation of two Ser residues within the C terminus of AtPIP2;1 upon H₂O₂ treatment correlated with redistribution of AQPs from the plasma membrane to intracellular vesicles (Prak et al., 2008). A lower PIP abundance at the plasma membrane ultimately results in diminished water transport through the membrane (Wudick et al., 2015). Thus, H₂O₂ not only restricts cell expansion by cross-linking the cell wall, but potentially also reduces water transport across the membrane, by promoting the endocytosis of PIPs (Fig. 2).

ROS AND THE REGULATION OF THE CYTOSKELETON AND VESICLE TRANSPORT DURING EXPANSION

Cell size and shape is controlled by the extension of the cell wall (Smith and Oppenheimer, 2005). The building blocks for cell growth are delivered by Golgi-derived vesicles that are transported to the cell surface through the action of the cytoskeleton. The cytoskeleton allows for controlling the growth direction of cells by guiding the delivery of Golgi-derived vesicles and the cellulose synthase machinery (Geisler et al., 2008). Uniform cell enlargement in all directions is called isotropic expansion (Fig. 3A), while cell growth along a preferred axis, or in a preferred direction, is known as anisotropic expansion (Crowell et al., 2010). During leaf growth, mesophyll cells mainly show isotropic expansion while epidermal cells show mainly anisotropic expansion (Fu et al., 2002). Still, in single cells, both isotropic and anisotropic growth can occur at the same time (Crowell et al., 2010).

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Figure 3.

Interplay between ROS, the cytoskeleton, and vesicle transport during expansion growth. A, Isotropic growth implies an equal rate of cell expansion in all direction, whereas anisotropic growth modulates cell shape through differential cell expansion rates. B, Schematic overview of the integration points between ROS and cell growth processes that involve the cytoskeleton and transport of Golgi-derived vesicles. ROP-mediated activation of NADPH oxidases results in an increased level of H₂O₂. The H₂O₂ can enter the cell through the action of AQPs and there directly cause depolymerization of either F-actin or MTs. In addition, ROP promotes the exocytosis of trans-Golgi-derived SVCs that contain novel cell wall material. Formation of SVCs relies on the action of ECH, YIP, and the ATPase VHAa1. Accumulation of H₂O₂ causes oxidation of VHAa1 and subsequent inhibition of vesicle transport. Next to the promotive effect of ROP2/4 on F-actin formation in the outgrowing region of a cell, ROP6 mainly acts through KTN1 on the MT bundling to restrict cellular outgrowth. In addition, MT orientation is controlled by MAP65 proteins, which act downstream of the H₂O₂-activated MAPK cascade, consisting of ANP, MKK6, MAPK3, MAPK4, and MAPK6.

The importance of microtubules (MTs) and actin filaments in the regulation of cell expansion has been widely demonstrated. For leaf development, ACTIN2 and ACTIN7 also are required for optimal growth (Gilliland et al., 2002) together with numerous tubulin genes (Ishida et al., 2007; Komis et al., 2011). In contrast to its name, the cytoskeleton consists of a highly dynamic and mobile network of protein polymers. MTs and actin filaments exhibit a treadmilling movement caused by a fast rate of net polymerization at the plus end and a slower rate of depolymerization at the minus end (Blanchoin et al., 2010). Interestingly, microtubules and actin filaments are known to be very sensitive to ROS, and emerging evidence suggests that redox cues impact on cytoskeleton dynamics (Livanos et al., 2012). Chemical interference with ROS homeostasis results in the reorientation and replacement of MTs in plants. For instance, NADPH oxidase activity has been shown to modulate MT and actin polymerization upon abiotic stress or treatment with cytoskeletal toxins (Yao et al., 2011; Liu et al., 2012). Interestingly, tolerance of plants toward cold stress is associated with the stability of microtubules (Wang and Nick, 2001). Plants that maintain microtubule stability show cold-resistant leaf expansion (Ahad et al., 2003). Oxidative stress as part of abiotic stress can result in oxidative modifications of tubulin and actin proteins (Fig. 3B; Wang et al., 2012) and reorientation of the cytoskeleton.

Next to a direct effect of H₂O₂ on cytoskeleton polymers, it also modulates the activity of microtubule/actin-associated proteins (MAPs; Fig. 3B). MAPs are direct targets of MAPK cascades (Komis et al., 2011), of which some have a role in ROS signaling (Schmidt and Schippers, 2015). ARABIDOPSIS NUCLEUS- AND PHRAGMOPLAST-LOCALIZED KINASE1-RELATED PROTEIN KINASE1 (ANP1), ANP2, and ANP3 encode MAP3Ks that are activated by H₂O₂ and initiate a signaling cascade involving MKK6 and the MAPKs MAPK3, MAPK4, and MAPK6 (Kovtun et al., 2000; Beck et al., 2010). ANPs are required during cytokinesis, but also regulate pavement cell expansion, since anp2anp3 mutants show aberrant epidermal cell morphology (Beck et al., 2010). Notably, downstream the MAPK cascade act two conserved key regulators of cortical MT array organization, the microtubule-associated proteins MAP65-1 and MAP65-2, which both have been implicated in ROS responses (Lucas et al., 2011; Zhu et al., 2013; Livanos et al., 2012). Potentially, H₂O₂ sensed by the ANP cascade modulates cytoskeleton dynamics during cell proliferation and expansion (Fig. 3B). Additional research efforts are needed to understand the importance of the ANP cascade in ROS signaling during cell growth.

The Golgi is a highly diverse organelle with roles in many different physiological and molecular processes within the plant, including cell growth (Fu et al., 2002). Still, a potential role of the Golgi in oxidative stress responses in plants was presented only recently (Lee et al., 2015). The trans-Golgi network regulates cell expansion by directing vesicle trafficking and targeting (Gendre et al., 2011). Secretion of pectin and hemicellulose, the two major cell wall polysaccharides, is controlled by a trans-Golgi network-localized complex formed by YPT/RAB GTPase Interacting Protein 4a (YIP4a), YIP4b, and ECHIDNA (ECH; Gendre et al., 2013). In addition, the vacuolar H⁺-ATPase subunit a1 (VHAa1) colocalizes with the ECH/YIP4 complex. As chemical inhibition of VHAa1 activity mimics ech/yip4 mutants, the proteins appear to act in the same pathway (Gendre et al., 2011). Since VHAa1 activity is redox regulated (Tavakoli et al., 2001), it might represent an integration site for ROS within the trafficking network. Treatment of Arabidopsis with H₂O₂ results in Cys oxidation of VHA subunits (Waszczak et al., 2014), which inactivates their H⁺-pumping activity (Tavakoli et al., 2001). Thus, oxidative stress might act as a brake on vesicle trafficking, which could hamper cell expansion. The mobile secretory vesicle compartments (SVCs) move toward the cell surface to interact with the exocyst complex (Hála et al., 2008) and deliver cell wall material during growth. Rho of plant (ROP) GTPases, together with their effector proteins, have been shown to interact with exocyst subunits to mediate directed cell growth (Lavy et al., 2007; Uhrig and Hülskamp, 2014). Next to a role for ROP proteins in vesicle trafficking, they have also been implemented in the regulation of actin and MTs during leaf pavement cell morphogenesis (Fu et al., 2002; Oda and Fukuda, 2012). On the one hand, activated ROP2/4 promotes the formation of F-actin networks required for the lateral outgrowth of a lobe (Fu et al., 2005); on the other hand, activation of ROP6 promotes the MT-severing activity of KATANIN1 (KTN1), which results in the reassembly and alignment of MTs to restrict cell growth in the neck regions of the developing pavement cell (Fig. 3, B and C). Furthermore, NADPH oxidases are activated by a direct interaction with ROP proteins, indicating an intimate relation between the regulation of ROS homeostasis and the diverse functions of ROP during cell elongation (Wong et al., 2007). How H₂O₂ and NADPH oxidase activity regulate cytoskeleton dynamics and vesicle trafficking is poorly understood and requires extensive research efforts in the future.

TRANSCRIPTIONAL REGULATION OF ROS HOMEOSTASIS DURING LEAF EXPANSION

Under nonstress conditions, the final size of plant leaves is predictable due to the strict genetic control of cell proliferation and expansion. Although many transcription factors regulating cell proliferation have been identified (Polyn et al., 2015), those controlling leaf expansion growth are largely lacking (Powell and Lenhard, 2012).

Thus far, only two transcription factors specifically regulating leaf cell expansion were reported: KUODA1 (KUA1) and ZHD5 (Lu et al., 2014; Hong et al., 2011). ZHD5 belongs to the group of zinc finger homeodomain (ZHD) transcription factors and its activity is regulated by a mini zinc finger protein (MIF1). Scanning electron microscopy of epidermal cells of ZHD5 overexpression lines revealed bigger cell sizes compared to the wild type (Hong et al., 2011). Overexpression of the non-DNA binding MIF1 causes a great decrease in leaf area due to the inhibition of ZHD5 (Hong et al., 2011; Hu et al., 2008). Still, the factors causing cell enlargement and the direct targets of ZHD5 are not known (Hong et al., 2011).

KUA1 is a MYB-like transcription factor that is upregulated during expansion growth of the leaf (Lu et al., 2014). Overexpression of KUA1 results in an increase in leaf cell size compared to the wild type, while kua1 mutants show a decrease in cell size. Detailed analysis revealed that KUA1 negatively regulates POX activity by direct repression of seven POX genes during leaf growth (Lu et al., 2014). As mentioned above, class III POXs can promote cell wall loosening or cross-linking depending on the apoplastic conditions. KUA1-regulated POXs increase apoplastic H₂O₂ levels, which restricts expansion (Fig. 4). Therefore, KUA1 positively regulates leaf growth by lowering the levels of apoplastic H₂O₂ and promoting cell wall relaxation (Lu et al., 2014). Still, as H₂O₂ acts as a precursor for the production of ˙OH, it is likely that the regulation of POX activity within the cell wall is more complex.

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Figure 4.

Transcriptional regulation of ROS homeostasis during leaf expansion. Cell expansion is restricted by cell wall stiffening due to the action of H₂O₂. During cell expansion in Arabidopsis, the levels of apoplastic H₂O₂ are maintained low through the action of the transcription factor KUA1. KUA1 represses the expression of seven POX genes (POX7, POX8, POX10, POX30, POX35, POX44, and POX57), which produce H₂O₂ in the apoplast. The repression of the POX genes is crucial for cell wall relaxation and expansion.

Interestingly, in roots, a transcription factor of the bHLH family similarly acts on POX gene expression. UPBEAT (UPB1) is mainly expressed in the root elongation zone and its overexpression causes a decrease in root cell size, but increased cell proliferation, resulting in longer roots compared to the wild type (Tsukagoshi et al., 2010). Among the direct target genes of UPB1, 21 encode POXs, including POX57, which is also targeted by KUA1 in leaves (Tsukagoshi et al., 2010; Lu et al., 2014). While KUA1-regulated POXs promote cell wall stiffening in leaves, the POXs controlled by UPB1 in roots mainly cause cell wall relaxation by either scavenging H₂O₂ or promoting the formation of ˙OH. In both cases, loss of the transcriptional regulators results in increased H₂O₂ levels and decreased cell size, indicating that the biochemical action of H₂O₂ in roots and leaves on cell enlargement is conserved. Notably, UPB1 was shown to act independently from plant hormones, while overexpression of KUA1 is accompanied by an increase in auxin (Kwon et al., 2013). As KUA1 and UPB1 show no homology, it indicates that plants evolved diverse transcriptional regulators to control POXs.

So far, to our knowledge, KUA1 is the first described transcription factor with a clearly defined role in modulating leaf cell expansion through the regulation of ROS homeostasis. In accordance with the successful identification of transcription factors controlling cell proliferation (Polyn et al., 2015), it is expected that future research will reveal additional transcriptional regulators of leaf cell expansion.