MOTHER OF FT AND TFL1 regulates seed germination and fertility relevant to the brassinosteroid signaling pathway

Brassinosteroids (BRs) are a family of plant steroid hormones that play diverse roles in many aspects of plant growth and development. For example, BRs promote seed germination by counteracting the inhibitory effect of ABA and regulate plant reproductive development, thus affecting seed yield. We have recently reported that MOTHER OF FT AND TFL1 (MFT) regulates seed germination through a negative feedback loop modulating ABA signaling in Arabidopsis. Here, we show that MFT function is also relevant to the BR signaling pathway. In mft loss-of-function mutants, the application of BR could not fully antagonize the inhibitory effect of exogenous ABA on seed germination, suggesting that BR promotes seed germination against ABA partly through MFT. In addition, mft enhances the low-fertility phenotype of det2 in which BR biosynthesis is blocked. This phenotype, together with the observation that MFT is expressed in gametophytes and developing seeds, suggests that MFT and BR play redundant roles in regulating fertility. Therefore, these results suggest that MFT affects seed germination and fertility relevant to the BR signaling pathway.Key words: Arabidopsis, brassinosteroid, abscisic acid, fertility, seed germinationPlant hormones exert profound effects on many fundamental processes during plant growth and development. With respect to seed development and germination, it has long been known that abscisic acid (ABA) and gibberellin (GA) are two major types of phytohormones that play antagonistic roles in regulating these events. Not until recently, another group of phytohormones, namely brassinosteroids (BRs), has also been found to counteract the inhibitory effect of ABA on seed germination.^1,2 In addition, BR has been suggested to act in parallel with GA to promote cell elongation and germination.^1,3,4BRs are a class of polyhydroxysteroids that are found in a wide variety of plant species.⁵ They can be detected in almost every plant tissue, with the highest abundance in the pollen and seeds.⁶ The most active component in the family of BRs is 24-epibrassinolide (BL), which is capable of activating BR signaling.⁶ In Arabidopsis, when the early steps of BR biosynthesis are blocked, the resulting defects include reduced male fertility under normal growth conditions^7,8 and decreased germination percentage in the presence of exogenous ABA.¹ Thus, BR plays an indispensible role in the control of seed development and also contributes to the regulation of seed germination.We have previously reported that MOTHER OF FT AND TFL1 (MFT) responds to both ABA and GA signals to regulate seed germination.⁹ Here we show that MFT functions in regulating seed germination and fertility, which is also relevant to the BR signaling pathway. Thus, MFT seems to function specifically in seeds in response to various phytohormones.     

Nitric oxide (NO)-dependent and NO-independent signaling pathways act in ABA-inhibition of stomatal opening

We investigated the role of nitric oxide (NO) in ABA-inhibition of stomatal opening in Vicia faba L. in different size dishes. When a large dish (9 cm diameter) was used, ABA induced NO synthesis and the NO scavenger reduced ABA-inhibition of stomatal opening. When a small dish (6 cm diameter) was used, ABA induced stomatal closure and inhibited stomatal opening. The NO scavenger was able to reduce ABA-induced stomatal closure, but unable to reverse ABA-inhibition of stomatal opening. Furthermore, NO was not synthesized in response to ABA, indicating that NO is not required for ABA-inhibition of stomatal opening in the small dish. These results indicated that an NO-dependent and an NO-independent signaling pathway participate in ABA signaling pathway. An NO-dependent pathway is the major player in ABA-induced stomatal closure. However, in ABA-inhibition of stomatal opening, an NO-dependent and an NO-independent pathway act: different signaling molecules participate in ABA-signaling cascade under different environmental condition.Key words: ABA, environmental condition, nitric oxide, stomata, Vicia faba LNitric oxide (NO) is a key signaling molecule in plants.^1,2 It functions in disease resistance and programmed cell death,^3,4 root development,^5,6 and plant responses to various abiotic stresses.^1,2,7,8 In addition, NO is required for stomatal closure in response to ABA in several species including Arabidopsis, Vicia faba, pea, tomato, barley, and wheat.^9–11 ABA-inhibition of stomatal opening is a distinct process from ABA-induced stomatal closure.^12,13 In V. faba, these two processes employ a similar signaling pathway; NO is also a second messenger molecule for ABA-inhibition of stomatal opening in a large dish.¹⁴ In this study, we examined the role of NO in ABA-inhibition of stomatal opening using different dish sizes. In a small dish, NO is not involved in ABA-inhibition of stomatal opening: the NO-independent signaling pathway is the major player in it.     

GCR2 is a new member of the eukaryotic lanthionine synthetase component C-like protein family

GCR2 was recently proposed to represent a G-protein-coupled receptor (GPCR) for the plant hormone, abscisic acid (ABA). We and others provided evidence that GCR2 is unlikely to be a bona fide GPCR because it is not clearly predicted to contain seven transmembrane domains, a structural hallmark for classical GPCRs. Instead, GCR2 shows significant sequence similarity to homologs of bacterial lanthionine synthetase component C (LanC). Here, we provide additional analysis of GCR2 and LanC-like (LANCL) proteins in plants, and propose that GCR2 is a new member of the eukaryotic LANCL protein family.Key words: GCR2, G-protein-coupled receptor, abscisic acid (ABA), lanthionine synthetaseSeven transmembrane (7TM) G-protein-coupled receptors (GPCRs) comprise the largest protein family in mammals, and are the most pharmacologically important receptor family, being the target of approximately half of all modern medicinal drugs. All canonical GPCRs are integral membrane proteins and are predicted to contain 7TM-spanning domains as their structural hallmark, a pattern confirmed by the high-resolution crystal structure of human β2-adrenergic GPCR.^1,2 GPCRs sense extracellular molecules and activate intracellular cell signaling via coupling with heterotrimeric G-proteins. Heterotrimeric G-protein subunits are conserved in plants, but the repertoire of heterotrimeric G-protein complexes to which they contribute in plants is much simpler than in mammals.^3,4 Liu et al. (2007) proposed that GCR2 is a GPCR for the plant hormone abscisic acid (ABA) in Arabidopsis.⁵ However, GCR2 was predicted not to be a 7TM protein when its amino acid sequence was analyzed in robust transmembrane prediction systems.^6,7 On the other hand, GCR2 has significant sequence similarity to homologs of bacterial lanthionine synthetase component C (LanC) that are found in diverse eukaryotes and which have predicted structural similarity to prokaryotic LanC.^6,7 These findings raise the possibility that GCR2 belongs to the LanC protein superfamily, rather than the GPCR superfamily.     

Regulation of neuronal survival and morphology by the E3 ubiquitin ligase RNF157

Neuronal health is essential for the long-term integrity of the brain. In this study, we characterized the novel E3 ubiquitin ligase ring finger protein 157 (RNF157), which displays a brain-dominant expression in mouse. RNF157 is a homolog of the E3 ligase mahogunin ring finger-1, which has been previously implicated in spongiform neurodegeneration. We identified RNF157 as a regulator of survival in cultured neurons and established that the ligase activity of RNF157 is crucial for this process. We also uncovered that independently of its ligase activity, RNF157 regulates dendrite growth and maintenance. We further identified the adaptor protein APBB1 (amyloid beta precursor protein-binding, family B, member 1 or Fe65) as an interactor and proteolytic substrate of RNF157 in the control of neuronal survival. Here, the nuclear localization of Fe65 together with its interaction partner RNA-binding protein SART3 (squamous cell carcinoma antigen recognized by T cells 3 or Tip110) is crucial to trigger apoptosis. In summary, we described that the E3 ligase RNF157 regulates important aspects of neuronal development.Neurodegeneration leads to loss of neurons and thus to severe and irreparable damage of the brain. A common histopathological feature in postmortem brains of patients with neurodegenerative diseases such as Parkinson''s or Alzheimer''s disease is the presence of ubiquitin-laden protein deposits.^{1, 2, 3} These deposits implicate the ubiquitin proteasome system (UPS) in neurodegeneration. In addition to histopathological clues, genetic evidence demonstrates that erroneous UPS components have detrimental effects on the developing and adult brain resulting in neurodegenerative disorders.^4,5The UPS is responsible for the posttranslational modification of proteins by ubiquitin, which requires an enzymatic cascade.⁶ The E3 ubiquitin ligases specifically recognize the substrate proteins and mediate their ubiquitination, which can result in their degradation that ensures the homeostasis in cells or in non-proteolytic signaling events.^7,8 The largest group of E3 ligases constitutes the RING (really interesting new gene) ligases, which serve as scaffold proteins to recruit both the substrate and the E2 ubiquitin-conjugating enzyme that binds to the RING domain,⁹ facilitating the transfer of ubiquitin from the E2 to the substrate.Although there are several hundred E3 ligases,¹⁰ only a few have been studied so far in the context of neuronal survival or neurodegeneration.^{11, 12, 13, 14, 15} Among those, mahogunin ring finger-1 (MGRN1) has been implicated in an age-dependent spongiform encephalopathy characterized in a mouse model.¹⁵In this study, we characterized the novel E3 ubiquitin ligase ring finger protein 157 (RNF157), the homolog of MGRN1. We described that RNF157, which is predominantly expressed in the brain, regulates neuronal survival and morphology in cultured neurons. We further identified the adaptor protein APBB1 (amyloid beta precursor protein-binding, family B, member 1 or Fe65) as a substrate and a downstream component in RNF157-regulated neuronal survival. Also, we demonstrated that nuclear Fe65 together with the RNA-binding protein SART3 (squamous cell carcinoma antigen recognized by T cells 3 or Tip110) triggers apoptosis. Taken together, we described that the E3 ligase RNF157 acts in different aspects of neuronal development.     

Methyl jasmonate signaling and signal crosstalk between methyl jasmonate and abscisic acid in guard cells

Plants tightly control stomatal aperture in response to various environmental changes. A drought-inducible phytohormone, abscisic acid (ABA), triggers stomatal closure and ABA signaling pathway in guard cells has been well studied. Similar to ABA, methyl jasmonate (MeJA) induces stomatal closure in various plant species but MeJA signaling pathway is still far from clear. Recently we found that Arabidopsis calcium dependent protein kinase CPK6 functions as a positive regulator in guard cell MeJA signaling and provided new insights into cytosolic Ca²⁺-dependent MeJA signaling. Here we discuss the MeJA signaling and also signal crosstalk between MeJA and ABA pathways in guard cells.Key words: methyl jasmonate, abscisic acid, guard cell, reactive oxygen species, nitric oxide, calciumStomata, which are formed by pairs of specialized cells called guard cells, control gas exchanges and transpirational water loss. Guard cells can shrink and swell in response to various physiological stimuli, resulting in stomatal closing and opening.^1,2 To optimize growth under various environmental conditions, plants have developed fine-tuned signal pathway in guard cells. Abscisic acid (ABA) is synthesized under drought stress and induces stomatal closure to reduce transpirational water loss.² ABA signal transduction in guard cells has been widely studied. ABA induces increases of various second messengers such as cytosolic Ca²⁺, reactive oxygen species (ROS) and nitric oxide (NO) in guard cells. These early signal components finally evoke ion efflux through plasma membrane ion channels, resulting in reduction of guard cell turgor pressure.Jasmonates are plant hormones synthesized via the octadecanoid pathway and regulate various physiological processes in plants such as pollen maturation, tendril coiling, senescence and responses to wounding and pathogen attacks.³ Similar to ABA, jasmonates also trigger stomatal closure and the response is conserved among various plant species including Arabidopsis thaliana,⁴ Hordeum vulgare,⁵ Commelina benghalensis,⁶ Vicia faba,⁷ Nicotiana glauca,⁸ Paphiopedilum Supersuk⁹ and Paphiopedilum tonsum.⁹ A volatile methyl ester of jasmonic acid (JA), methy jasmonate (MeJA), has been widely used for studying jasmonate signaling pathway. To date, pharmacological and reverse genetic approaches have revealed many important signal components involved in MeJA-induced stomatal closure and suggest a signal crosstalk between MeJA and ABA in guard cells. In this review, we mainly focus on the three important second messengers, ROS, NO and cytosolic Ca²⁺ and discuss recent advance about MeJA signaling and signal interaction between MeJA and ABA in guard cells.     

Timing the switch to phototrophic growth: A possible role of GUN1

In young Arabidopsis seedlings, retrograde signaling from plastids regulates the expression of photosynthesis-associated nuclear genes in response to the developmental and functional state of the chloroplasts. The chloroplast-located PPR protein GUN1 is required for signalling following disruption of plastid protein synthesis early in seedling development before full photosynthetic competence has been achieved. Recently we showed that sucrose repression and the correct temporal expression of LHCB1, encoding a light-harvesting chlorophyll protein associated with photosystem II, are perturbed in gun1 mutant seedlings.¹ Additionally, we demonstrated that in gun1 seedlings anthocyanin accumulation and the expression of the “early” anthocyanin-biosynthesis genes is perturbed. Early seedling development, predominantly at the stage of hypocotyl elongation and cotyledon expansion, is also affected in gun1 seedlings in response to sucrose, ABA and disruption of plastid protein synthesis by lincomycin. These findings indicate a central role for GUN1 in plastid, sucrose and ABA signalling in early seedling development.Key words: ABA, ABI4, anthocyanin, chloroplast, GUN1, retrograde signalling, sucroseArabidopsis seedlings develop in response to light and other environmental cues. In young seedlings, development is fuelled by mobilization of lipid reserves until chloroplast biogenesis is complete and the seedlings can make the transition to phototrophic growth. The majority of proteins with functions related to photosynthesis are encoded by the nuclear genome, and their expression is coordinated with the expression of genes in the chloroplast genome. In developing seedlings, retrograde signaling from chloroplasts to the nucleus regulates the expression of these nuclear genes and is dependent on the developmental and functional status of the chloroplast. Two classes of gun (genomes uncoupled) mutants defective in retrograde signalling have been identified in Arabidopsis: the first, which comprises gun2–gun5, involves mutations in genes encoding components of tetrapyrrole biosynthesis.^2,3 The other comprises gun1, which has mutations in a nuclear gene encoding a plastid-located pentatricopeptide repeat (PPR) protein with an SMR (small MutS-related) domain near the C-terminus.^4,5 PPR proteins are known to have roles in RNA processing⁶ and the SMR domain of GUN1 has been shown to bind DNA,⁴ but the specific functions of these domains in GUN1 are not yet established. However, GUN1 has been shown to be involved in plastid gene expression-dependent,⁷ redox,⁴ ABA1,⁴ and sucrose signaling,^1,4,8 as well as light quality and intensity sensing pathways.^9–11 In addition, GUN1 has been shown to influence anthocyanin biosynthesis, hypocotyl extension and cotyledon expansion.^1,11     

Vascular system is a node of systemic stress responses: Competence of the cell to synthesize abscisic acid and its responsiveness to external cues

Activation of abscisic acid (ABA) biosynthesis is a trigger to elicit ABA-mediated biological events. We recently reported that drought-induced ABA biosynthesis occurs predominantly in vascular parenchyma cells. This work also showed that a particular set of drought inducible gene expressions initiated in the vascular system. The spatial constraint of ABA biosynthesis is supposed to be critical for directing systemic stress responses. Cellular competence to synthesize ABA and its responsiveness to developmental and environmental signals is discussed.Key words: abscisic acid, biosynthesis, competence, responsiveness, vascular systemPlants live in a changing environment by optimizing their growth to given external cues. Among such environmental factors, regulation of water status is essential for plant life. Plant cells have machinery to adapt to the drought stress for itself as well as adaptation machinery to protect other cells by generating mobile signals to distal organs. Abscisic acid (ABA) is one of such mobile signals in which signaling and metabolic pathways are well documented. When subjected to drought stress, plants activate both ABA-dependent and ABA-independent cascades, and in turn induce the expression of large number of stress responsive genes and post-translational modifications.¹ Endo et al.,² demonstrated that vascular parenchyma cells play a key role in the activation of ABA-dependent pathway via producing drought-induced ABA.² This work also showed that the subset of drought stress-responsive genes was induced earlier in the vascular tissues than in mesophyll tissues.²