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.     

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.     

Hypoxia-mediated activation of Dll4-Notch-Hey2 signaling in endothelial progenitor cells and adoption of arterial cell fate

Adequate response to low oxygen levels (hypoxia) by hypoxia inducible factor (HIF) is essential for normal development and physiology, but this pathway may also contribute to pathological processes like tumor angiogenesis. Here we show that hypoxia is an inducer of Notch signaling. Hypoxic conditions lead to induction of the Notch ligand Dll4 and the Notch target genes Hey1 and Hey2 in various cell lines. Promoter analysis revealed that Hey1, Hey2 and Dll4 are induced by HIF-1alpha and Notch activation. Hypoxia-induced Notch signaling may also determine endothelial identity. Endothelial progenitor cells (EPCs) contain high amounts of COUP-TFII, a regulator of vein identity, while levels of the arterial regulators Dll4 and Hey2 are low. Hypoxia-mediated upregulation of Dll4 and Hey2 leads to repression of COUP-TFII in eEPCs. Finally, we show that Hey factors are capable of repressing HIF-1alpha-induced gene expression, suggesting a negative feedback loop to prevent excessive hypoxic gene induction. Thus, reduced oxygen levels lead to activation of the Dll4-Notch-Hey2 signaling cascade and subsequent repression of COUP-TFII in endothelial progenitor cells. We propose that this is an important step in the developmental regulation of arterial cell fate decision.     

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.     

The involvement of the Arabidopsis CRT1 ATPase family in disease resistance protein-mediated signaling

Resistance (R) gene-mediated immunity provides plants with rapid and strain-specific protection against pathogen infection. Our recent study using the genetically tractable Arabidopsis and turnip crinkle virus (TCV) pathosystem revealed a novel component, named CRT1 (compromised for recognition of the TCV CP), that is involved in general R gene-mediated signaling, including that mediated by HRT, an R gene against TCV. The Arabidopsis CRT1 gene family contains six additional members, of which two share high homology to CRT1 (75 and 81% a.a. identity); either CRT1 or its closest homolog restore the cell death phenotype suppressed by crt1. Analysis of single knock-out mutants for CRT1 and its closest homologs suggest that each may have unique and redundant functions. Here, we provide insight into the screening conditions that enabled identification of a mutant gene despite the presence of functionally redundant family members. We also discuss a potential mechanism that may regulate the interaction between CRT1 and R proteins.Key words: resistance gene, ATPase, suppressor screening, Arabidopsis, turnip crinkle virusPlant resistance (R) proteins activate defense signaling pathways following detection of a specific pathogen-encoded effector, or perception that a host factor has been altered by a pathogen effector. The vast majority of R proteins contain nucleotide binding site (NBS) and leucine-rich repeat (LRR) domains. These R proteins can be further divided into two subgroups, TIR-NBS-LRR and CC-NBS-LRR, depending on whether the N terminus consists of a Toll-interleukin 1 receptor (TIR) or a coiled-coiled (CC) domain, respectively.¹ Subsequent to pathogen perception, the signal(s) generated by various R proteins likely converge into a limited set of pathways, with CC-NBS-LRR proteins usually utilizing NDR1 and TIR-NBS-LRR proteins generally requiring EDS1.² However, the molecular mechanism(s) through which R proteins recognize a pathogen(s) and initiate a defense signal(s) remains unclear.To gain insights into this elusive signaling process, several groups have performed genetic screens to isolate mutants whose R gene-mediated resistance responses are suppressed following either pathogen infection or expression of a transgene-encoded bacterial effector protein. Several proteins, including HSP90, SGT1 and RAR1, were shown to be required for resistance triggered by a variety of R proteins, suggesting their universal function in R protein-mediated resistance.^3–7 However, while some R protein-mediated signaling pathways required both RAR1 and SGT1, others needed only one or neither protein. Thus, the requirement for RAR1 and SGT1 appears to be specific to each pathway.⁸ Further studies revealed that SGT1, RAR1 and HSP90 regulate the stability/accumulation of various R proteins,^8–11 raising the possibility that they serve as (co)chaperones for assembling an active R protein complex.The Arabidopsis R protein HRT was previously shown to recognize the coat protein (CP) of turnip crinkle virus (TCV) and trigger necrotic lesion formation in the inoculated leaf, as well as local and systemic defense responses.¹² To identify components of the HRT-mediated signaling pathway, a line containing HRT and an inducible CP transgene was constructed and screened for suppressors of CP-induced cell death.¹³ One mutant, named crt1 (compromised for recognition of the TCV CP), was identified; it contains a mutation in a GHKL (Gyrase, Hsp90, histidine kinase, MutL) ATPase.¹³ Interestingly, HSP90 also belongs to this recently recognized ATPase superfamily, although sequence homology between HSP90 and CRT1 is limited to the ATPase domain.¹⁴ Either wt CRT1 or its closest homolog, CRT1-h1 (81% a.a. identity to CRT1; 13 suggesting that CRT1 and CRT1-h1 are functionally redundant.

Table 1

Amino-acid sequence identity between CRTI family members in Arabidopsis

Surprise in the Battle Field of Vein vs. Artery

Formation of arteries and veins is a complex process. It was shown that activation of the notch signaling pathway in the artery results on the activation of arterial markers and the suppression of vein markers. However, factor, which instructs endothelial cells to take on the vein or artery identity, has not been defined. It was assumed that VEGF, the key molecule which stimulates notch signaling pathway in the artery, is not available in the vein. Thus, endothelial cells, lacking notch signaling, acquire vein identity. Recently, Drs. Tsai and their colleague demonstrated that COUP-TFII, an orphan nuclear receptor, is an important factor that regulates vein identity through suppression of the notch signaling.