Focus on Ethylene: Role of Ethylene and Its Cross Talk with Other Signaling Molecules in Plant Responses to Heavy Metal Stress

Excessive heavy metals (HMs) in agricultural lands cause toxicities to plants, resulting in declines in crop productivity. Recent advances in ethylene biology research have established that ethylene is not only responsible for many important physiological activities in plants but also plays a pivotal role in HM stress tolerance. The manipulation of ethylene in plants to cope with HM stress through various approaches targeting either ethylene biosynthesis or the ethylene signaling pathway has brought promising outcomes. This review covers ethylene production and signal transduction in plant responses to HM stress, cross talk between ethylene and other signaling molecules under adverse HM stress conditions, and approaches to modify ethylene action to improve HM tolerance. From our current understanding about ethylene and its regulatory activities, it is believed that the optimization of endogenous ethylene levels in plants under HM stress would pave the way for developing transgenic crops with improved HM tolerance.In addition to common abiotic stresses seen in agricultural production, such as drought, submerging, and extreme temperatures (Thao and Tran, 2012; Xia et al., 2015), heavy metal (HM) stress has arisen as a new pervasive threat (Srivastava et al., 2014; Ahmad et al., 2015). This is mainly due to the unrestricted industrialization and urbanization carried out during the past few decades, which have led to the increase of HMs in soils. Plants naturally require more than 15 different types of HM as nutrients serving for biological activities in cells (Sharma and Chakraverty, 2013). However, when the nutritional/nonnutritional HMs are present in excess, plants have to either suffer or take these up from the soil in an unwilling manner (Nies, 1999; Sharma and Chakraverty, 2013). Upon HM stress exposure, plants induce oxidative stress due to the excessive production of reactive oxygen species (ROS) and methylglyoxal (Sharma and Chakraverty, 2013). High levels of these compounds have been shown to negatively affect cellular structure maintenance (e.g. induction of lipid peroxidation in the membrane, biological macromolecule deterioration, ion leakage, and DNA strand cleavage; Gill and Tuteja, 2010; Nagajyoti et al., 2010) as well as many other biochemical and physiological processes (Dugardeyn and Van Der Straeten, 2008). As a result, plant growth is retarded and, ultimately, economic yield is decreased (Yadav, 2010; Anjum et al., 2012; Hossain et al., 2012; Asgher et al., 2015). Moreover, the accumulation of metal residues in the major food chain has been shown to cause serious ecological and health problems (Malik, 2004; Verstraeten et al., 2008).Plants employ different strategies to detoxify the unwanted HMs. Among the common responses of plants to HM stress are increases in ethylene production due to the enhanced expression of ethylene-related biosynthetic genes (Asgher et al., 2014; Khan and Khan, 2014; Khan et al., 2015b) and/or changes in the expression of ethylene-responsive genes (Maksymiec, 2007). Conventionally, this hormone has been established to modulate a number of important plant physiological activities, including seed germination, root hair and root nodule formation, and maturation (fruit ripening in particular; Dugardeyn and Van Der Straeten, 2008). On the other hand, although ethylene has also been suggested to be a stress-related hormone responding to a number of biotic and abiotic triggers, little is known about the exact role of elevated HM stress-related ethylene in plants (Zapata et al., 2003). Enhanced production of ethylene in plants subjected to toxic levels of cadmium (Cd), copper (Cu), iron (Fe), nickel (Ni), and zinc (Zn) has been shown (Maksymiec, 2007). As an example, Cd- and Cu-mediated stimulation of ethylene synthesis has been reported as a result of the increase of 1-aminocyclopropane-1-carboxylic acid (ACC) synthase (ACS) activity, one of the enzymes involved in the ethylene synthesis pathway (Schlagnhaufer and Arteca, 1997; Khan et al., 2015b).Plants tend to adjust or induce adaptation or tolerance mechanisms to overcome stress conditions. To develop stress tolerance, plants trigger a network of hormonal cross talk and signaling, among which ethylene production and signaling are prominently involved in stress-induced symptoms in acclimation processes (Gazzarrini and McCourt, 2003). Therefore, the necessity of controlling ethylene homeostasis and signal transduction using biochemical and molecular tools remains open to combat stress situations. Stress-induced ethylene acts to trigger stress-related effects on plants because of the autocatalytic ethylene synthesis. Autocatalytic stress-related ethylene production is controlled by mitogen-activated protein kinase (MAPK) phosphorylation cascades (Takahashi et al., 2007) and through stabilizing ACS2/6 (Li et al., 2012). Strong lines of evidence have shown the multiple facets of ethylene in plant responses to different abiotic stresses, including excessive HM, depending upon endogenous ethylene concentration and ethylene sensitivities that differ in developmental stage, plant species, and culture systems (Pierik et al., 2006; Kim et al., 2008; Khan and Khan, 2014). Under HM stress conditions, plants show a rapid increase in ethylene production and reduced plant growth and development, suggesting a negative regulatory role of ethylene in plant responses to HM stress (Schellingen et al., 2014; Khan et al., 2015b). On the other hand, a potential involvement of ETHYLENE INSENSITIVE2 (EIN2), a central component of the ethylene signaling pathway, as a positive regulator in lead (Pb) resistance in Arabidopsis (Arabidopsis thaliana) has also been demonstrated (Cao et al., 2009). More recently, Khan and Khan (2014) showed that ethylene-regulated antioxidant metabolism maintained a higher level of reduced glutathione (GSH) and alleviated photosynthetic inhibition in mustard (Brassica juncea) plants exposed to Ni, Zn, or Cd through the optimization of ethylene homeostasis (Masood et al., 2012). Taken together, the purpose of this review is to update the research community with our current understanding of the roles of ethylene and its signaling in plant responses to HM stress. Moreover, the cross talk of ethylene with other phytohormones and signaling molecules upon HM stress will also be discussed.     

Evolution of Conifer Diterpene Synthases: Diterpene Resin Acid Biosynthesis in Lodgepole Pine and Jack Pine Involves Monofunctional and Bifunctional Diterpene Synthases

Abscisic acid (ABA) induces stomatal closure and inhibits light-induced stomatal opening. The mechanisms in these two processes are not necessarily the same. It has been postulated that the ABA receptors involved in opening inhibition are different from those involved in closure induction. Here, we provide evidence that four recently identified ABA receptors (PYRABACTIN RESISTANCE1 [PYR1], PYRABACTIN RESISTANCE-LIKE1 [PYL1], PYL2, and PYL4) are not sufficient for opening inhibition in Arabidopsis (Arabidopsis thaliana). ABA-induced stomatal closure was impaired in the pyr1/pyl1/pyl2/pyl4 quadruple ABA receptor mutant. ABA inhibition of the opening of the mutant’s stomata remained intact. ABA did not induce either the production of reactive oxygen species and nitric oxide or the alkalization of the cytosol in the quadruple mutant, in accordance with the closure phenotype. Whole cell patch-clamp analysis of inward-rectifying K⁺ current in guard cells showed a partial inhibition by ABA, indicating that the ABA sensitivity of the mutant was not fully impaired. ABA substantially inhibited blue light-induced phosphorylation of H⁺-ATPase in guard cells in both the mutant and the wild type. On the other hand, in a knockout mutant of the SNF1-related protein kinase, srk2e, stomatal opening and closure, reactive oxygen species and nitric oxide production, cytosolic alkalization, inward-rectifying K⁺ current inactivation, and H⁺-ATPase phosphorylation were not sensitive to ABA.The phytohormone abscisic acid (ABA), which is synthesized in response to abiotic stresses, plays a key role in the drought hardiness of plants. Reducing transpirational water loss through stomatal pores is a major ABA response (Schroeder et al., 2001). ABA promotes the closure of open stomata and inhibits the opening of closed stomata. These effects are not simply the reverse of one another (Allen et al., 1999; Wang et al., 2001; Mishra et al., 2006).A class of receptors of ABA was identified (Ma et al., 2009; Park et al., 2009; Santiago et al., 2009; Nishimura et al., 2010). The sensitivity of stomata to ABA was strongly decreased in quadruple and sextuple mutants of the ABA receptor genes PYRABACTIN RESISTANCE/PYRABACTIN RESISTANCE-LIKE/REGULATORY COMPONENT OF ABSCISIC ACID RECEPTOR (PYR/PYL/RCAR; Nishimura et al., 2010; Gonzalez-Guzman et al., 2012). The PYR/PYL/RCAR receptors are involved in the early ABA signaling events, in which a sequence of interactions of the receptors with PROTEIN PHOSPHATASE 2Cs (PP2Cs) and subfamily 2 SNF1-RELATED PROTEIN KINASES (SnRK2s) leads to the activation of downstream ABA signaling targets in guard cells (Cutler et al., 2010; Kim et al., 2010; Weiner et al., 2010). Studies of Commelina communis and Vicia faba suggested that the ABA receptors involved in stomatal opening are not the same as the ABA receptors involved in stomatal closure (Allan et al., 1994; Anderson et al., 1994; Assmann, 1994; Schwartz et al., 1994). The roles of PYR/PYL/RCAR in either stomatal opening or closure remained to be elucidated.Blue light induces stomatal opening through the activation of plasma membrane H⁺-ATPase in guard cells that generates an inside-negative electrochemical gradient across the plasma membrane and drives K⁺ uptake through voltage-dependent inward-rectifying K⁺ channels (Assmann et al., 1985; Shimazaki et al., 1986; Blatt, 1987; Schroeder et al., 1987; Thiel et al., 1992). Phosphorylation of the penultimate Thr of the plasma membrane H⁺-ATPase is a prerequisite for blue light-induced activation of the H⁺-ATPase (Kinoshita and Shimazaki, 1999, 2002). ABA inhibits H⁺-ATPase activity through dephosphorylation of the penultimate Thr in the C terminus of the H⁺-ATPase in guard cells, resulting in prevention of the opening (Goh et al., 1996; Zhang et al., 2004; Hayashi et al., 2011). Inward-rectifying K⁺ currents (I_Kin) of guard cells are negatively regulated by ABA in addition to through the decline of the H⁺ pump-driven membrane potential difference (Schroeder and Hagiwara, 1989; Blatt, 1990; McAinsh et al., 1990; Schwartz et al., 1994; Grabov and Blatt, 1999; Saito et al., 2008). This down-regulation of ion transporters by ABA is essential for the inhibition of stomatal opening.A series of second messengers has been shown to mediate ABA-induced stomatal closure. Reactive oxygen species (ROS) produced by NADPH oxidases play a crucial role in ABA signaling in guard cells (Pei et al., 2000; Zhang et al., 2001; Kwak et al., 2003; Sirichandra et al., 2009; Jannat et al., 2011). Nitric oxide (NO) is an essential signaling component in ABA-induced stomatal closure (Desikan et al., 2002; Guo et al., 2003; Garcia-Mata and Lamattina, 2007; Neill et al., 2008). Alkalization of cytosolic pH in guard cells is postulated to mediate ABA-induced stomatal closure in Arabidopsis (Arabidopsis thaliana) and Pisum sativum and Paphiopedilum species (Irving et al., 1992; Gehring et al., 1997; Grabov and Blatt, 1997; Suhita et al., 2004; Gonugunta et al., 2008). These second messengers transduce environmental signals to ion channels and ion transporters that create the driving force for stomatal movements (Ward et al., 1995; MacRobbie, 1998; Garcia-Mata et al., 2003).In this study, we examined the mobilization of second messengers, the inactivation of I_Kin, and the suppression of H⁺-ATPase phosphorylation evoked by ABA in Arabidopsis mutants to clarify the downstream signaling events of ABA signaling in guard cells. The mutants included a quadruple mutant of PYR/PYL/RCARs, pyr1/pyl1/pyl2/pyl4, and a mutant of a SnRK2 kinase, srk2e.     

Turnip mosaic virus Moves Systemically through Both Phloem and Xylem as Membrane-Associated Complexes

Plant viruses move systemically in plants through the phloem. They move as virions or as ribonucleic protein complexes, although it is not clear what these complexes are made of. The approximately 10-kb RNA genome of Turnip mosaic virus (TuMV) encodes a membrane protein, known as 6K₂, that induces endomembrane rearrangements for the formation of viral replication factories. These factories take the form of vesicles that contain viral RNA (vRNA) and viral replication proteins. In this study, we report the presence of 6K₂-tagged vesicles containing vRNA and the vRNA-dependent RNA polymerase in phloem sieve elements and in xylem vessels. Transmission electron microscopy observations showed the presence in the xylem vessels of vRNA-containing vesicles that were associated with viral particles. Stem-girdling experiments, which leave xylem vessels intact but destroy the surrounding tissues, confirmed that TuMV could establish a systemic infection of the plant by going through xylem vessels. Phloem sieve elements and xylem vessels from Potato virus X-infected plants also contained lipid-associated nonencapsidated vRNA, indicating that the presence of membrane-associated ribonucleic protein complexes in the phloem and xylem may not be limited to TuMV. Collectively, these studies indicate that viral replication factories could end up in the phloem and the xylem.Plant viruses use the host preexisting transport routes to propagate infection to the whole plant. After replication in the initially infected cells, viruses move cell to cell through plasmodesmata (PD) and start a new round of replication in the newly infected cells. This cycle is repeated until viruses reach vascular tissues, where they enter into the conducting tubes for systemic movement. Several studies have indicated that plant viruses are passively transported along the source-to-sink flow of photoassimilates and thus are believed to move systemically through the phloem (for review, see Hipper et al., 2013).The conducting tube of the phloem is the sieve element. The mature sieve element is enucleated and relies on the associated companion cells for the maintenance of its physiological function (Fisher et al., 1992). The specialized PD connecting one sieve element with one companion cell is called the pore plasmodesmal unit (PPU). Different from the other PDs, PPUs are always branched on the companion cell side but have only one channel on the sieve element side (Oparka and Turgeon, 1999). It is believed that the loading and uploading of viral material during phloem transport are through PPUs. Even though the size exclusion limit of PPUs (Kempers and Bel, 1997) is larger than that of the other PDs (Wolf et al., 1989; Derrick et al., 1990), PPUs should not allow, in their native state, virions or viral ribonucleoprotein (vRNP) complexes to pass through. It is thus believed that specific interactions between virus and host factors are required to allow the viral entity to go through. For instance, the movement protein of Cucumber mosaic virus (CMV) is targeted to PPUs (Blackman et al., 1998), suggesting that this viral protein modifies the size exclusion limit of PPUs and helps viral entry into sieve elements.Most plant viruses are assumed to move systemically through the phloem as virions. This assumption is based on the observation that Coat Protein (CP) deletions debilitating virus assembly prevent systemic infection (Brault et al., 2003; Zhang et al., 2013; Hipper et al., 2014). Some investigations showed the actual presence of virions in sieve elements. This is the case for the icosahedral Tobacco ringspot virus (Halk and McGuire, 1973), Carrot red leaf virus (Murant and Roberts, 1979), Potato leaf roll virus (Shepardson et al., 1980), and Beet western yellows virus (Hoefert, 1984). In addition, virions also were observed in phloem sap, such as the icosahedral CMV (Requena et al., 2006) and the rigid rod-shaped Cucumber green mottle mosaic virus (Simón-Buela and García-Arenal, 1999). Some viruses also are believed to move as ribonucleic protein (RNP) complexes, since systemic movement was observed in CP mutants where virion assembly was hindered. For instance, Tobacco rattle virus, Potato mop-top virus, Brome mosaic virus, and Tomato bushy stunt virus can still move systemically when the CP gene has been deleted from the viral genome (Swanson et al., 2002; Savenkov et al., 2003; Gopinath and Kao, 2007; Manabayeva et al., 2013). For potyviruses, it is still not clear if long-distance transport involves exclusively viral particles or if vRNP complexes also are implicated (Dolja et al., 1994, 1995; Cronin et al., 1995; Schaad et al., 1997; Kasschau and Carrington, 2001; Rajamaki and Valkonen, 2002). But whether virions or vRNP complexes are involved in viral movement, the full nature of the viral entity being implicated has not been defined.Xylem also is used for systemic infection of viruses, but its importance in viral transport generally has been overlooked. Vessel elements are the building blocks of xylem vessels, which constitute the major part of the water-upward-transporting system in a plant. The side walls of mature vessel elements contain pits, which are areas lacking a secondary cell wall; the end walls of the mature vessel elements are removed, and the openings are called perforation plates (Roberts and McCann, 2000). CP or virions of some plant viruses of all different shapes have been detected in the xylem vessels and/or guttation fluid, suggesting that these viruses may move systemically through xylem vessels. For example, the CP of the icosahedral Tomato bushy stunt virus (Manabayeva et al., 2013) and Rice yellow mottle virus (Opalka et al., 1998), the CP of the rigid rod-shaped Soilborne wheat mosaic virus (Verchot et al., 2001) and Cucumber green mottle mosaic virus (Moreno et al., 2004), and the flexuous rod-shaped Potato virus X (PVX; Betti et al., 2012) were detected in xylem vessels. Colocalization of anti-Rice yellow mottle virus antibodies and a cell wall marker for cellulosic β-(1-4)-d-glucans over vessel pit membranes suggests that the pit membranes might be a pathway for virus migration between vessels (Opalka et al., 1998). Moreover, flexuous rod-shaped virions of Zucchini yellow mosaic virus were found in both xylem vessels of root tissue and the guttation fluid (French and Elder, 1999). Finally, icosahedral Brome mosaic virus (Ding et al., 2001) and rigid rod-shaped Tomato mosaic virus and Pepper mild mottle virus (French et al., 1993) virions were found in guttation fluid. Guttation fluid originates from xylem exudate, indicating that these plant viruses can move through xylem within the infected plant. The above studies, however, mainly relied on electron microscopy and infection assays and may have missed the presence of other viral components that might be involved in transport.Turnip mosaic virus (TuMV) is a positive-strand RNA virus belonging to the family Potyviridae, genus Potyvirus, which contains around 30% of the currently known plant viruses and causes serious diseases in numerous crops (Shukla et al., 1994). Potyviruses are nonenveloped, flexuous rod-shaped particles of 680 to 900 nm in length and 11 to 13 nm in diameter. The genomic approximately 10-kb RNA encodes a polyprotein, which is processed into at least 11 mature proteins. TuMV remodels cellular membranes into viral factories, which are intracellular compartments involved in viral replication and movement. These compartments take the form of vesicles of approximately 100 nm in diameter originating from the endoplasmic reticulum (Grangeon et al., 2012). These vesicles contain viral RNA (vRNA) and viral and host proteins involved in vRNA replication (Beauchemin et al., 2007; Beauchemin and Laliberté, 2007; Dufresne et al., 2008; Huang et al., 2010; Grangeon et al., 2012). The viral membrane 6K₂ protein is involved in the membrane alterations and vesicle production (Beauchemin et al., 2007). The membrane-bound replication complexes can move intracellularly and cell to cell (Grangeon et al., 2013) at a rate of one cell being infected every 3 h (Agbeci et al., 2013). Intercellular trafficking of the replication complex is likely mediated by the PD-localized potyviral proteins Cytoplasmic Inclusion (CI) and P3N-PIPO (for N-terminal Half of P3 fused to the Pretty Interesting Potyviridae ORF; Carrington et al., 1998; Wei et al., 2010; Vijayapalani et al., 2012) as well as CP (Dolja et al., 1994, 1995), Viral Protein genome-linked (VPg; Nicolas et al., 1997; Rajamaki and Valkonen, 1999, 2002), and Helper Component-Proteinase (HC-Pro; Cronin et al., 1995; Kasschau et al., 1997; Rojas et al., 1997; Kasschau and Carrington, 2001), which are involved in both cell-to-cell and vascular movement.It is expected that, ultimately, TuMV reaches the vascular tissues of the plant, but how and under what form it is released into the conducting tubes are not known. To further understand viral spread and systemic movement, we investigated the distribution of 6K₂-tagged TuMV factories in all of the leaf and stem tissues other than the epidermal cells. We found TuMV factories in all tissues. Interestingly, we observed 6K₂-tagged vesicles, containing vRNA and viral replication proteins, in both phloem sieve elements and xylem vessels. We confirmed that TuMV could move systemically through xylem by a so-called stem-girdling assay, which induces cell death of the phloem without affecting xylem integrity. Hence, our study indicates that membrane-associated TuMV replication complexes are involved in the systemic movement of the virus.     

Focus on Ethylene: Ethylene Biosynthesis Is Promoted by Very-Long-Chain Fatty Acids during Lysigenous Aerenchyma Formation in Rice Roots

In rice (Oryza sativa) roots, lysigenous aerenchyma, which is created by programmed cell death and lysis of cortical cells, is constitutively formed under aerobic conditions, and its formation is further induced under oxygen-deficient conditions. Ethylene is involved in the induction of aerenchyma formation. reduced culm number1 (rcn1) is a rice mutant in which the gene encoding the ATP-binding cassette transporter RCN1/OsABCG5 is defective. Here, we report that the induction of aerenchyma formation was reduced in roots of rcn1 grown in stagnant deoxygenated nutrient solution (i.e. under stagnant conditions, which mimic oxygen-deficient conditions in waterlogged soils). 1-Aminocyclopropane-1-carboxylic acid synthase (ACS) is a key enzyme in ethylene biosynthesis. Stagnant conditions hardly induced the expression of ACS1 in rcn1 roots, resulting in low ethylene production in the roots. Accumulation of saturated very-long-chain fatty acids (VLCFAs) of 24, 26, and 28 carbons was reduced in rcn1 roots. Exogenously supplied VLCFA (26 carbons) increased the expression level of ACS1 and induced aerenchyma formation in rcn1 roots. Moreover, in rice lines in which the gene encoding a fatty acid elongase, CUT1-LIKE (CUT1L; a homolog of the gene encoding Arabidopsis CUT1, which is required for cuticular wax production), was silenced, both ACS1 expression and aerenchyma formation were reduced. Interestingly, the expression of ACS1, CUT1L, and RCN1/OsABCG5 was induced predominantly in the outer part of roots under stagnant conditions. These results suggest that, in rice under oxygen-deficient conditions, VLCFAs increase ethylene production by promoting 1-aminocyclopropane-1-carboxylic acid biosynthesis in the outer part of roots, which, in turn, induces aerenchyma formation in the root cortex.Aerenchyma formation is a morphological adaptation of plants to complete submergence and waterlogging of the soil, and facilitates internal gas diffusion (Armstrong, 1979; Jackson and Armstrong, 1999; Colmer, 2003; Voesenek et al., 2006; Bailey-Serres and Voesenek, 2008; Licausi and Perata, 2009; Sauter, 2013; Voesenek and Bailey-Serres, 2015). To adapt to waterlogging in soil, rice (Oryza sativa) develops lysigenous aerenchyma in shoots (Matsukura et al., 2000; Colmer and Pedersen, 2008; Steffens et al., 2011) and roots (Jackson et al., 1985b; Justin and Armstrong, 1991; Kawai et al., 1998), which is formed by programmed cell death and subsequent lysis of some cortical cells (Jackson and Armstrong, 1999; Evans, 2004; Yamauchi et al., 2013). In rice roots, lysigenous aerenchyma is constitutively formed under aerobic conditions (Jackson et al., 1985b), and its formation is further induced under oxygen-deficient conditions (Colmer et al., 2006; Shiono et al., 2011). The former and latter are designated constitutive and inducible lysigenous aerenchyma formation, respectively (Colmer and Voesenek, 2009). The gaseous plant hormone ethylene regulates adaptive growth responses of plants to submergence (Voesenek and Blom, 1989; Voesenek et al., 1993; Visser et al., 1996a,b; Lorbiecke and Sauter, 1999; Hattori et al., 2009; Steffens and Sauter, 2009; van Veen et al., 2013). Ethylene also induces lysigenous aerenchyma formation in roots of some gramineous plants (Drew et al., 2000; Shiono et al., 2008). The treatment of roots with ethylene or its precursor (1-aminocyclopropane-1-carboxylic acid [ACC]) stimulates aerenchyma formation in rice (Justin and Armstrong, 1991; Colmer et al., 2006; Yukiyoshi and Karahara, 2014), maize (Zea mays; Drew et al., 1981; Jackson et al., 1985a; Takahashi et al., 2015), and wheat (Triticum aestivum; Yamauchi et al., 2014a,b). Moreover, treatment of roots with inhibitors of ethylene action or ethylene biosynthesis effectively blocks aerenchyma formation under hypoxic conditions in maize (Drew et al., 1981; Konings, 1982; Jackson et al., 1985a; Rajhi et al., 2011).Ethylene biosynthesis is accomplished by two main successive enzymatic reactions: conversion of S-adenosyl-Met to ACC by 1-aminocyclopropane-1-carboxylic acid synthase (ACS), and conversion of ACC to ethylene by 1-aminocyclopropane-1-carboxylic acid oxidase (ACO; Yang and Hoffman, 1984). The activities of both enzymes are enhanced during aerenchyma formation under hypoxic conditions in maize root (He et al., 1996). Since the ACC content in roots of maize is increased by oxygen deficiency and is strongly correlated with ethylene production (Atwell et al., 1988), ACC biosynthesis is essential for ethylene production during aerenchyma formation in roots. In fact, exogenously supplied ACC induced ethylene production in roots of maize (Drew et al., 1979; Konings, 1982; Atwell et al., 1988) and wheat (Yamauchi et al., 2014b), even under aerobic conditions. Ethylene production in plants is inversely related to oxygen concentration (Yang and Hoffman, 1984). Under anoxic conditions, the oxidation of ACC to ethylene by ACO, which requires oxygen, is almost completely repressed (Yip et al., 1988; Tonutti and Ramina, 1991). Indeed, anoxic conditions stimulate neither ethylene production nor aerenchyma formation in maize adventitious roots (Drew et al., 1979). Therefore, it is unlikely that the root tissues forming inducible aerenchyma are anoxic, and that the ACO-mediated step is repressed. Moreover, aerenchyma is constitutively formed in rice roots even under aerobic conditions (Jackson et al., 1985b), and thus, after the onset of waterlogging, oxygen can be immediately supplied to the apical regions of roots through the constitutively formed aerenchyma.Very-long-chain fatty acids (VLCFAs; ≥20 carbons) are major constituents of sphingolipids, cuticular waxes, and suberin in plants (Franke and Schreiber, 2007; Kunst and Samuels, 2009). In addition to their structural functions, VLCFAs directly or indirectly participate in several physiological processes (Zheng et al., 2005; Reina-Pinto et al., 2009; Roudier et al., 2010; Ito et al., 2011; Nobusawa et al., 2013; Tsuda et al., 2013), including the regulation of ethylene biosynthesis (Qin et al., 2007). During fiber cell elongation in cotton ovules, ethylene biosynthesis is enhanced by treatment with saturated VLCFAs, especially 24-carbon fatty acids, and is suppressed by an inhibitor of VLCFA biosynthesis (Qin et al., 2007). The first rate-limiting step in VLCFA biosynthesis is condensation of acyl-CoA with malonyl-CoA by β-ketoacyl-CoA synthase (KCS; Joubès et al., 2008). KCS enzymes are thought to determine the substrate and tissue specificities of fatty acid elongation (Joubès et al., 2008). The Arabidopsis (Arabidopsis thaliana) genome has 21 KCS genes (Joubès et al., 2008). In the Arabidopsis cut1 mutant, which has a defect in the gene encoding CUT1 that is required for cuticular wax production (i.e. one of the KCS genes), the expression of AtACO genes and growth of root cells were reduced when compared with the wild type (Qin et al., 2007). Furthermore, expression of the AtACO genes was rescued by exogenously supplied saturated VLCFAs (Qin et al., 2007). These observations imply that VLCFAs or their derivatives work as regulatory factors for gene expression during some physiological processes in plants.reduced culm number1 (rcn1) was first identified as a rice mutant with a low tillering rate in a paddy field (Takamure and Kinoshita, 1985; Yasuno et al., 2007). The rcn1 (rcn1-2) mutant has a single nucleotide substitution in the gene encoding a member of the ATP-binding cassette (ABC) transporter subfamily G, RCN1/OsABCG5, causing an Ala-684Pro substitution (Yasuno et al., 2009). The mutation results in several mutant phenotypes, although the substrates of RCN1/OsABCG5 have not been determined (Ureshi et al., 2012; Funabiki et al., 2013; Matsuda et al., 2014). We previously found that the rcn1 mutant has abnormal root morphology, such as shorter root length and brownish appearance of roots, under stagnant (deoxygenated) conditions (which mimics oxygen-deficient conditions in waterlogged soils). We also found that the rcn1 mutant accumulates less of the major suberin monomers originating from VLCFAs in the outer part of adventitious roots, and this results in a reduction of a functional apoplastic barrier in the root hypodermis (Shiono et al., 2014a).The objective of this study was to elucidate the molecular basis of inducible aerenchyma formation. To this end, we examined lysigenous aerenchyma formation and ACC, ethylene, and VLCFA accumulation and their biosyntheses in rcn1 roots. Based on the results of these studies, we propose that VLCFAs are involved in inducible aerenchyma formation through the enhancement of ethylene biosynthesis in rice roots.     

Involvement of the Sieve Element Cytoskeleton in Electrical Responses to Cold Shocks

This study dealt with the visualization of the sieve element (SE) cytoskeleton and its involvement in electrical responses to local cold shocks, exemplifying the role of the cytoskeleton in Ca²⁺-triggered signal cascades in SEs. High-affinity fluorescent phalloidin as well as immunocytochemistry using anti-actin antibodies demonstrated a fully developed parietal actin meshwork in SEs. The involvement of the cytoskeleton in electrical responses and forisome conformation changes as indicators of Ca²⁺ influx was investigated by the application of cold shocks in the presence of diverse actin disruptors (latrunculin A and cytochalasin D). Under control conditions, cold shocks elicited a graded initial voltage transient, ΔV₁, reduced by external La³⁺ in keeping with the involvement of Ca²⁺ channels, and a second voltage transient, ΔV₂. Cytochalasin D had no effect on ΔV₁, while ΔV₁ was significantly reduced with 500 nm latrunculin A. Forisome dispersion was triggered by cold shocks of 4°C or greater, which was indicative of an all-or-none behavior. Forisome dispersion was suppressed by incubation with latrunculin A. In conclusion, the cytoskeleton controls cold shock-induced Ca²⁺ influx into SEs, leading to forisome dispersion and sieve plate occlusion in fava bean (Vicia faba).It has been argued for a long time that sieve elements (SEs) are devoid of a cytoskeleton (Parthasarathy and Pesacreta, 1980; Thorsch and Esau, 1981; Evert, 1990), but more recent biochemical and cytological studies favor the opposite view. Actin as well as profilin were detected in phloem exudates of various monocot and dicot species (Schobert et al., 1998, 2000), while immunocytochemical tests showed the presence of actin and tubulin in phloem exudates of pumpkin (Cucurbita maxima; Kulikova and Puryaseva, 2002). Proteome analyses gave further credence to the occurrence of microfilaments in SEs in castor bean (Ricinus communis; profilin; Barnes et al., 2004), pumpkin (actin; Walz et al., 2004), canola (Brassica napus; actin, profilin1 and profilin2, actin-depolymerizing factor4; Giavalisco et al., 2006), and rice (Oryza sativa; actin1, actin-depolymerizing factor2, actin depolymerizing-factor3, and actin-depolymerizing factor6; Aki et al., 2008). Moreover, cytological evidence suggests residues of a cytoskeleton in SEs; fluorescent immunolabeling identified an actin/myosin system at the sieve plates (Chaffey and Barlow, 2002).Theoretical considerations also call for the presence of a cytoskeleton in SEs. Turnover and addressing of macromolecules (Fisher et al., 1992; Leineweber et al., 2000) requires a local distribution network in SEs. This function was attributed to an endoplasmic reticulum (ER) continuous to the ER strands running through pore plasmodesma units (Blackman et al., 1998) into the companion cells. Although such a mechanism is essentially conceivable, an interaction between the ER and cytoskeleton would provide a more conventional mode of intracellular distribution (Hepler et al., 1990; Boevink et al., 1998; Ueda et al., 2010; Yokota et al., 2011; Chen et al., 2012). Moreover, macromolecular trafficking through pore plasmodesma units (Lucas et al., 2001) was proposed to be executed by actin and myosin (Oparka, 2004), implying the presence of a cytoskeleton in SEs. Despite the massive circumstantial evidence, however, a complete cytoskeleton network and its spatial distribution in SEs have not been visually documented thus far.The existence of an SE cytoskeleton would raise questions regarding its task(s) in this highly specialized cell type. In other plant cells, the cytoskeleton was proposed to be engaged, among others, in ion channel operation and intracellular signaling (Trewavas and Malho, 1997; Mazars et al., 1997, and refs. therein; Thuleau et al., 1998; Örvar et al., 2000; Sangwan et al., 2001; Drøbak et al., 2004; Davies and Stankovic, 2006), as in animal cells (Janmey, 1998; Lange and Gartzke, 2006). For instance, K⁺ fluxes are regulated by actin dynamics (Hwang et al., 1997; Liu and Luan, 1998; Chérel, 2004), while Ca²⁺ influx into the cytoplasm appears to be mediated by voltage-dependent Ca²⁺-permeable channels associated with microtubules (Mazars et al., 1997; Thion et al., 1998) or by mechanosensitive channels possibly associated with microfilaments (Wang et al., 2004; Zhang et al., 2007).Both types of Ca²⁺-permeable channels probably reside in the SE plasma membrane (Knoblauch et al., 2001; Hafke et al., 2007, 2009; Furch et al., 2009), where they are likely involved in Ca²⁺-dependent systemic signaling (Furch et al., 2009; Hafke et al., 2009; van Bel et al., 2011; Hafke and van Bel, 2013). These channels are also putative initiators of Ca²⁺-induced signal transduction in SEs, leading to sieve-plate occlusion in response to local cold shocks (Thorpe et al., 2010). In fava bean (Vicia faba), Ca²⁺-dependent sieve tube occlusion by dispersion of special phloem-specific proteins (P-proteins) known as forisomes has been studied intensely (Knoblauch et al., 2001; Furch et al., 2007, 2009; Thorpe et al., 2010). Thus, apart from its distributive tasks, a cytoskeleton may be of major importance for intracellular signaling cascades in the highly specialized, sparsely equipped SEs.Our objective was to investigate the existence and spatial distribution of an SE cytoskeleton and its engagement in local signaling through Ca²⁺ influx brought about by cold shocks. This study dealt with the visualization of cytoskeletal components in intact sieve tubes using microinjection of fluorescent phalloidin and immunocytochemistry. Confocal laser-scanning micrography (CLSM) and transmission electron microscopy unequivocally showed a parietally located cylindrical actin meshwork. We demonstrated the engagement of the network in local cold shock-induced electrical responses and its association with Ca²⁺ influx, since we found effects of the Ca²⁺ channel blocker La³⁺ and of the cytoskeleton disruptor latrunculin A (LatA) on electrical signatures triggered by cold shocks and, by consequence, on forisome conformation changes.