Dissection of salicylic acid-mediated defense signaling networks

The small phenolic molecule salicylic acid (SA) plays a key role in plant defense. Significant progress has been made recently in understanding SA-mediated defense signaling networks. Functional analysis of a large number of genes involved in SA biosynthesis and regulation of SA accumulation and signal transduction has revealed distinct but interconnecting pathways that orchestrate the control of plant defense. Further studies utilizing combinatorial approaches in genetics, molecular biology, biochemistry and genomics will uncover finer details of SA-mediated defense networks as well as further insights into the crosstalk of SA with other defense signaling pathways. The complexity of defense networks illustrates the capacity of plants to integrate multiple developmental and environmental signals into a tight control of the costly defense responses.Key words: salicylic acid, disease resistance, signal transduction, Arabidopsis, Pseudomonas syringaePlants have evolved sophisticated defense mechanisms to ward off attacks from pathogens. In addition to pre-formed physical/chemical barriers, plants can actively monitor the presence of pathogens and subsequently activate defense signaling networks, which in turn restrict the further growth and spread of pathogens.The small phenolic compound salicylic acid (SA) plays a central role in plant defense signaling. It is required for recognition of pathogen-derived components and subsequent establishment of local resistance in the infected region as well as systemic resistance at the whole plant level.^1–3 SA accumulation is inducible upon infections of various pathogens, treatment with elicitors from pathogens, and stress conditions.^3–5 Exogenous application of SA and its synthetic analogs to plants is sufficient to invoke disease resistance.^6–9 Disruption of SA accumulation and/or signaling by mutations or by a transgenic SA hydrolase encoded by the bacterial gene nahG greatly compromises defense against pathogens.¹⁰ In addition, the phytohormones jasmonic acid (JA) and ethylene (ET) regulate SA-mediated defense as well as many aspects of plant development. Emerging evidence also implicates additional phytohormones in plant defense, two of which, auxin and abscisic acid, were recently shown to impact the SA pathway.^11,12The past two decades have witnessed exciting progress made towards a comprehensive understanding of defense networks in the model plant Arabidopsis, especially those regulated by SA. The discovery of an expanding array of genes involved in SA-mediated defense suggests the complexity of defense networks. Surprisingly, information on functional relationships among many defense genes is sparse. Connecting the dots (genes) on the defense map to form pathways, which are further interconnected into complex defense networks, still remains a challenging task. This review focuses on our current understanding of the interactions among genes that regulate three key sub-circuits of the SA pathway: SA biosynthesis, SA accumulation and SA signal transduction. Discussions of the crosstalk between components involved in the SA pathway and those in other defense pathways can be found in some excellent reviews.^13–17     

Phospholipases in action during plant defense signaling

Eukaryotic organisms rely on intricate signaling networks to connect recognition of microbes with the activation of efficient defense reactions. Accumulating evidence indicates that phospholipids are more than mere structural components of biological membranes. Indeed, phospholipid-based signal transduction is widely used in plant cells to relay perception of extracellular signals. Upon perception of the invading microbe, several phospholipid hydrolyzing enzymes are activated that contribute to the establishment of an appropriate defense response. Activation of phospholipases is at the origin of the production of important defense signaling molecules, such as oxylipins and jasmonates, as well as the potent second messenger phosphatidic acid (PA), which has been shown to modulate the activity of a variety of proteins involved in defense signaling. Here, we provide an overview of recent reports describing the different plant phospholipase pathways that are activated during the establishment of plant defense reactions in response to pathogen attack.Key words: lipid signaling, PA, PLA, PLC, PLD, plant immunityIn plant cells, perception of pathogenic microbes largely relies on transmembrane pattern recognition receptors that specifically recognize highly conserved pathogen-derived molecules called PAMPs/MAMPs (pathogen-/microbial-associated molecular patterns), such as bacterial flagellin.¹ PAMP recognition by the plant leads to basal defense responses. A second layer of defense is based on the recognition of specific pathogen-derived molecules, called effectors, primarily by an additional class of plant cytoplasmic receptor proteins [nucleotide-binding leucine-rich repeat (NB-LRR) proteins] but also by protein receptors predicted to be located at the plasma membrane [receptor-like proteins (RLPs) and receptor-like kinases (RLKs)]. This recognition leads to the activation of plant immune responses that are frequently associated to the development of hypersensitive cell death (HR) at the inoculation site, which has been shown to contribute to plant resistance.²The activation of plant immunity involves a variety of early signaling events, including rapid accumulation of reactive oxygen species (ROS), changes in cellular ion fluxes, activation of protein kinase cascades, changes in gene expression and production of stress-related hormones.^3,4 During recent years, a substantial number of reports have also shown the importance of lipids and lipid-related molecules, including glycerolipids, sphingolipids, fatty acids, oxylipins, jasmonates and sterols, in the regulation of plant defense responses.⁵Phospholipids are more than structural components in biological membranes. Indeed, evidence that phospholipases and phospholipid-derived molecules are involved in plant signaling, and more particularly in plant immunity, is rapidly accumulating.^6,7 In plants, phosphatidic acid (PA) can be produced from phospholipids by phospholipase D (PLD) enzymes or from diacylyglycerol (DAG) by DAG kinases (DGKs) in the phospholipase C (PLC) pathway. PA is a potent secondary signal messenger molecule that modulates the activity of kinases, phosphatases, phospholipases and proteins involved in membrane-trafficking, Ca²⁺ signaling and the oxidative burst.^8,9 In addition, a growing body of evidence indicates that phospholipase A (PLA) [and related molecules such as lysophospholipids (LPLs) and free fatty acids (FFAs)] and phospholipase C (PLC) (and its related molecules DAG and DGK) play important roles in the control of the plant defense response to the attack by invading pathogens.⁷Here, we review the recent advances in understanding phospholipase-mediated signaling and its importance in the control of plant immune responses.     

Serine/threonine protein phosphatases: Multi-purpose enzymes in control of defense mechanisms

Depending on the threat to a plant, different pattern recognition receptors, such as receptor-like kinases, identify the stress and trigger action by appropriate defense response development.^1,2 The plant immunity system primary response to these challenges is rapid accumulation of phytohormones, such as ethylene (ET), salicylic acid (SA), and jasmonic acid (JA) and its derivatives. These phytohormones induce further signal transduction and appropriate defenses against biotic threats.^3,4 Phytohormones play crucial roles not only in the initiation of diverse downstream signaling events in plant defense but also in the activation of effective defenses through an essential process called signaling pathway crosstalk, a mechanism involved in transduction signals between two or more distinct, “linear signal transduction pathways simultaneously activated in the same cell.”⁵     

RALFs: Peptide regulators of plant growth

Peptide signaling regulates a variety of developmental processes and environmental responses in plants.^1–6 For example, the peptide systemin induces the systemic defense response in tomato⁷ and defensins are small cysteine-rich proteins that are involved in the innate immune system of plants.^8,9 The CLAVATA3 peptide regulates meristem size¹⁰ and the SCR peptide is the pollen self-incompatibility recognition factor in the Brassicaceae.^11,12 LURE peptides produced by synergid cells attract pollen tubes to the embryo sac.⁹ RALFs are a recently discovered family of plant peptides that play a role in plant cell growth.Key words: peptide, growth factor, alkalinization     

Matrix metalloproteinase (MMP) and TGFβ1-stimulated cell migration in skin and cornea wound healing

Cell migration during wound healing is a complex process that involves the expression of a number of growth factors and cytokines. One of these factors, transforming growth factor-beta (TGFβ) controls many aspects of normal and pathological cell behavior. It induces migration of keratinocytes in wounded skin and of epithelial cells in damaged cornea. Furthermore, this TGFβ-induced cell migration is correlated with the production of components of the extracellular matrix (ECM) proteins and expression of integrins and matrix metalloproteinases (MMPs). MMP digests ECMs and integrins during cell migration, but the mechanisms regulating their expression and the consequences of their induction remain unclear. It has been suggested that MMP-14 activates cellular signaling processes involved in the expression of MMPs and other molecules associated with cell migration. Because of the manifold effects of MMP-14, it is important to understand the roles of MMP-14 not only the cleavage of ECM but also in the activation of signaling pathways.Key words: wound healing, migration, matrix metalloproteinase, transforming growth factor, skin, corneaWound healing is a well-ordered but complex process involving many cellular activities including inflammation, growth factor or cytokine secretion, cell migration and proliferation. Migration of skin keratinocytes and corneal epithelial cells requires the coordinated expression of various growth factors such as platelet-derived growth factor (PDGF), fibroblast growth factor (FGF), transforming growth factor (TGF), keratinocyte growth factor (KGF), hepatocyte growth factor (HGF), insulin-like growth factor (IGF), epidermal growth factor (EGF), small GTPases, and macrophage stimulating protein (reviewed in refs. ¹ and ²). The epithelial cells in turn regulate the expression of matrix metalloproteinases (MMPs), extracellular matrix (ECM) proteins and integrins during cell migration.^1,3,4 TGF-β is a well-known cytokine involved in processes such as cell growth inhibition, embryogenesis, morphogenesis, tumorigenesis, differentiation, wound healing, senescence and apoptosis (reviewed in refs. ⁵ and ⁶). It is also one of the most important cytokines responsible for promoting the migration of skin keratinocytes and corneal epithelial cells.^3,6,7TGFβ has two quite different effects on skin keratinocytes: it suppresses their multiplication and promotes their migration. The TGFβ-induced cell growth inhibition is usually mediated by Smad signaling, which upregulates expression of the cell cycle inhibitor p21^WAF1/Cip1 or p12^CDK2-AP1 in HaCaT skin keratinocyte cells and human primary foreskin keratinocytes.^8,9 Keratinocyte migration in wounded skin is associated with strong expression of TGFβ and MMPs,¹ and TGFβ stimulates the migration of manually scratched wounded HaCaT cells.¹⁰ TGFβ also induces cell migration and inhibits proliferation of injured corneal epithelial cells, whereas it stimulates proliferation of normal corneal epithelial cells via effects on the MAPK family and Smad signaling.^2,7 Indeed, skin keratinocytes and corneal epithelial cells display the same two physiological responses to TGFβ during wound healing; cell migration and growth inhibition. However as mentioned above, TGFβ has a different effect on normal cells. For example, it induces the epithelial to mesenchymal transition (EMT) of normal mammary cells and lens epithelial cells.^11,12 It also promotes the differentiation of corneal epithelial cells, and induces the fibrosis of various tissues.^2,6The MMPs are a family of structurally related zinc-dependent endopeptidases that are secreted into the extracellular environment.¹³ Members of the MMP family have been classified into gelatinases, stromelysins, collagenases and membrane type-MMPs (MT-MMPs) depending on their substrate specificity and structural properties. Like TGFβ, MMPs influence normal physiological processes including wound healing, tissue remodeling, angiogenesis and embryonic development, as well as pathological conditions such as rheumatoid arthritis, atherosclerosis and tumor invasion.^13,14The expression patterns of MMPs during skin and cornea wound healing are well studied. In rats, MMP-2, -3, -9, -11, -13 and -14 are expressed,¹⁵ and in mice, MMP-1, -2, -3, -9, -10 and -14 are expressed during skin wound healing.¹ MMP-1, -3, -7 and -12 are increased in corneal epithelial cells during Wnt 7a-induced rat cornea wound healing.¹⁶ Wound repair after excimer laser keratectomy is characterized by increased expression of MMP-1, -2, -3 and -9 in the rabbit cornea, and MMP-2, -9 in the rat cornea.^17,18 The expression of MMP-2 and -9 during skin keratinocyte and corneal epithelial cell migration has been the most thoroughly investigated, and it has been shown that their expression generally depends on the activity of MMP-14. MMP-14 (MT1-MMP) is constitutively anchored to the cell membrane; it activates other MMPs such as MMP-2, and also cleaves various types of ECM molecules including collagens, laminins, fibronectin as well as its ligands, the integrins.¹³ The latent forms of some cytokines are also cleaved and activated by MMP-14.¹⁹ Overexpression of MMP-14 protein was found to stimulate HT1080 human fibrosarcoma cell migration.²⁰ In contrast, the attenuation of MMP-14 expression using siRNA method decreased fibroblast invasiveness,²¹ angiogenesis of human microvascular endothelial cells,²² and human skin keratinocyte migration.¹⁰ The latter effect was shown to result from lowering MMP-9 expression. Other studies have shown that EGF has a critical role in MMP-9 expression during keratinocyte tumorigenesis and migration.^23,24 On the other hand, TGFβ modulates MMP-9 production through the Ras/MAPK pathway in transformed mouse keratinocytes and NFκB induces cell migration by binding to the MMP-9 promoter in human skin primary cultures.^25,26 Enhanced levels of pro-MMP-9 and active MMP-9 have also been noted in scratched corneal epithelia of diabetic rats.²⁷There is evidence that MMP-14 activates a number of intracellular signaling pathways including the MAPK family pathway, focal adhesion kinase (FAK), Src family, Rac and CD44, during cell migration and tumor invasion.^19,20,28 In COS-7 cells, ERK activation is stimulated by overexpression of MMP-14 and is essential for cell migration.²⁹ These observations all indicate that MMP-14 plays an important role in cell migration, not only by regulating the activity or expression of downstream MMPs but also by processing and activating migration-associated molecules such as integrins, ECMs and a variety of intracellular signaling pathays.³⁰Cell migration during wound healing is a remarkably complex phenomenon. TGFβ is just one small component of the overall process of wound healing and yet it triggers a multitude of reactions needed for cell migration. It is important to know what kinds of molecules are expressed when cell migration is initiated, but it is equally important to investigate the roles of these molecules and how their expression is regulated. Despite the availability of some information about how MMPs and signaling molecules can influence each other, much remains to be discovered in this area. It will be especially important to clarify how MMP-14 influences other signaling pathways since its role in cell migration is not restricted to digesting ECM molecules but also includes direct or indirect activation of cellular signaling pathways.     

Roles of calcineurin B-like protein-interacting protein kinases in innate immunity in rice

Cytosolic free Ca²⁺ mobilization induced by microbe/pathogen-asssociated molecular patterns (MAMPs/PAMPs) plays key roles in plant innate immunity. However, components involved in Ca²⁺ signaling pathways still remain to be identified and possible involvement of the CBL (calcineurin B-like proteins)-CIPK (CBL-interacting protein kinases) system in biotic defense signaling have yet to be clarified. Recently we identified two CIPKs, OsCIPK14 and OsCIPK15, which are rapidly induced by MAMPs, involved in various MAMP-induced immune responses including defense-related gene expression, phytoalexin biosynthesis and hypersensitive cell death. MAMP-induced production of reactive oxygen species as well as cell browning were also suppressed in OsCIPK14/15-RNAi transgenic cell lines. Possible molecular mechanisms and physiological functions of the CIPKs in plant innate immunity are discussed.Key words: PAMPs/MAMPs, calcium signaling, CBL-CIPK, hypersensitive cell death, reactive oxygen speciesCa²⁺ plays an essential role as an intracellular second messenger in plants as well as in animals. Several families of Ca²⁺ sensor proteins have been identified in higher plants, which decode spatiotemporal patterns of intracellular Ca²⁺ concentration.^1,2 Calcineurin B-Like Proteins (CBLs) comprise a family of Ca²⁺ sensor proteins similar to both the regulatory β-subunit of calcineurin and neuronal Ca²⁺ sensors of animals.^3,4 Unlike calcineurin B that regulates protein phosphatases, CBLs specifically target a family of protein kinases referred to as CIPKs (CBL-Interacting Protein Kinases).⁵ The CBL-CIPK system has been shown to be involved in a wide range of signaling pathways, including abiotic stress responses such as drought and salt, plant hormone responses and K+ channel regulation.^6,7Following the recognition of pathogenic signals, plant cells initiate the activation of a widespread signal transduction network that trigger inducible defense responses, including the production of reactive oxygen species (ROS), biosynthesis of phytoalexins, expression of pathogenesis-related (PR) genes and reorganization of cytoskeletons and the vacuole,⁸ followed by a form of programmed cell death known as hypersensitive response (HR).^9,10 Because complexed spatiotemporal patterns of cytosolic free Ca²⁺ concentration ([Ca²⁺]_cyt) have been suggested to play pivotal roles in defense signaling,^1,9 multiple Ca²⁺ sensor proteins and their effectors should function in defense signaling pathways. Although possible involvement of some calmodulin isoforms^11–13 and the calmodulin-domain/calcium-dependent protein kinases (CDPKs)^14–19 has been suggested, other Ca²⁺-regulated signaling components still remain to be identified. No CBLs or CIPKs had so far been implicated as signaling components in innate immunity.     

Sublethal concentrations of salicylic acid decrease the formation of reactive oxygen species but maintain an increased nitric oxide production in the root apex of the ethylene-insensitive Never ripe tomato mutants

The pattern of salicylic acid (SA)-induced production of reactive oxygen species (ROS) and nitric oxide (NO) were different in the apex of adventitious roots in wild-type and in the ethylene-insensitive Never ripe (Nr) mutants of tomato (Solanum lycopersicum L. cv Ailsa Craig). ROS were upregulated, while NO remained at the control level in apical root tissues of wildtype plants exposed to sublethal concentrations of SA. In contrast, Nr plants expressing a defective ethylene receptor displayed a reduced level of ROS and a higher NO content in the apical root cells. In wild-type plants NO production seems to be ROS(H₂O₂)-dependent at cell death-inducing concentrations of SA, indicating that ROS and NO may interact to trigger oxidative cell death. In the absence of significant ROS accumulation, the increased NO production caused moderate reduction in cell viability in root apex of Nr plants exposed to 10⁻³ M SA. This suggests that a functional ethylene signaling pathway is necessary for the control of ROS and NO production induced by SA.Key words: ethylene receptor mutant, never ripe, nitric oxide, reactive oxygen species, root apex, salicylic acid, tomatoSeveral signal molecules, including salicylic acid (SA) have been implicated in the response of plants to biotic^1–3 and abiotic stressors.^4–6 SA was identified as a central regulator of local defense against (hemi)biotophic pathogens inducing a hypersensitive response (HR), which is characterized by the development of lesions that restrict pathogen spread. It has also emerged as a possible signaling component involved in the activation of certain plant defense responses in non-infected part of the plants establishing the systemic acquired resistance (SAR).⁷The SA-induced biotic and abiotic stress adaptation most likely involves reactive oxygen species (ROS) and nitric oxide (NO) in primary signaling events that activate multiple signal transduction pathways. SA-induced ROS is required for the activation of antioxidant defense mechanisms⁴ and if the generation of ROS exceeds the capacity of antioxidant systems, the cells die.⁸ NO is another important player that is required for the induction of defense mechanisms⁹ or for ROS-induced cell death.¹⁰Accumulation of SA, and two other plant hormones, ethylene (ET) and jasmonic acid (JA) are intimately associated with the initiation or spread of cell death. In HR SA and ROS have been proposed to be on a positive feedback loop that amplifies signals and leads to programmed cell death (PCD). Ethylene caused increased spreading of cell death, while lesion containment can be achieved by JA through decreasing the sensitivity of the cells to ethylene and through the suppression of SA biosynthesis and signaling.⁸Ethylene evolution is associated with diverse physiological processes such as leaf and flower senescence, abscission of organs and fruit ripening.¹¹ The biosynthesis of ethylene is stimulated by a variety of abiotic and biotic stress factors. Ethylene overproducing mutants (eto1 and eto3) of Arabidopsis were found to be more sensitive to O₃, an abiotic stressor which induces ROS-dependent cell death.¹² Cadmium-induced cell death was also accompanied by increased production of ethylene and simultaneously by H₂O₂ accumulation in tomato cell suspension, and based on the effect of specific inhibitors of ethylene biosynthesis and action the authors concluded that the cell death process required H₂O₂ production and a functional ethylene signaling pathway.¹³ Ethylene signaling is also required for the susceptible disease response of tomato plants infected with Xanthomonas campestris pv vesicatoria.¹⁴ It was found that the accumulation of SA and increased production of ethylene were important components of the disease symptoms of this pathogen in wild-type plants, while in Never ripe (Nr) mutants, which have a non-functional ethylene receptor, the infected plants failed to accumulate SA, produced less ethylene, and the leaves exhibited reduced necrotic lesions.It has been also shown that SA enhances NO synthesis in a dose-dependent manner.¹⁵ ROS, such as ^·O₂⁻ and H₂O₂ as well as NO can act together in the cell death regulation and propagation.^8,16 The compartment-specific (down)regulation of ROS can be controlled by NO, accordingly, ROS and NO homeostasis may be essential for the induction or for the avoidance of cell death.     

Cell Migration from Baby to Mother

Fetal cells migrate into the mother during pregnancy. Fetomaternal transfer probably occurs in all pregnancies and in humans the fetal cells can persist for decades. Microchimeric fetal cells are found in various maternal tissues and organs including blood, bone marrow, skin and liver. In mice, fetal cells have also been found in the brain. The fetal cells also appear to target sites of injury. Fetomaternal microchimerism may have important implications for the immune status of women, influencing autoimmunity and tolerance to transplants. Further understanding of the ability of fetal cells to cross both the placental and blood-brain barriers, to migrate into diverse tissues, and to differentiate into multiple cell types may also advance strategies for intravenous transplantation of stem cells for cytotherapeutic repair. Here we discuss hypotheses for how fetal cells cross the placental and blood-brain barriers and the persistence and distribution of fetal cells in the mother.Key Words: fetomaternal microchimerism, stem cells, progenitor cells, placental barrier, blood-brain barrier, adhesion, migrationMicrochimerism is the presence of a small population of genetically distinct and separately derived cells within an individual. This commonly occurs following transfusion or transplantation.^1–3 Microchimerism can also occur between mother and fetus. Small numbers of cells traffic across the placenta during pregnancy. This exchange occurs both from the fetus to the mother (fetomaternal)^4–7 and from the mother to the fetus.^8–10 Similar exchange may also occur between monochorionic twins in utero.^11–13 There is increasing evidence that fetomaternal microchimerism persists lifelong in many child-bearing women.^7,14 The significance of fetomaternal microchimerism remains unclear. It could be that fetomaternal microchimerism is an epiphenomenon of pregnancy. Alternatively, it could be a mechanism by which the fetus ensures maternal fitness in order to enhance its own chances of survival. In either case, the occurrence of pregnancy-acquired microchimerism in women may have implications for graft survival and autoimmunity. More detailed understanding of the biology of microchimeric fetal cells may also advance progress towards cytotherapeutic repair via intravenous transplantation of stem or progenitor cells.Trophoblasts were the first zygote-derived cell type found to cross into the mother. In 1893, Schmorl reported the appearance of trophoblasts in the maternal pulmonary vasculature.¹⁵ Later, trophoblasts were also observed in the maternal circulation.^16–20 Subsequently various other fetal cell types derived from fetal blood were also found in the maternal circulation.^21,22 These fetal cell types included lymphocytes,²³ erythroblasts or nucleated red blood cells,^24,25 haematopoietic progenitors^7,26,27 and putative mesenchymal progenitors.^14,28 While it has been suggested that small numbers of fetal cells traffic across the placenta in every human pregnancy,^29–31 trophoblast release does not appear to occur in all pregnancies.³² Likewise, in mice, fetal cells have also been reported in maternal blood.^33,34 In the mouse, fetomaternal transfer also appears to occur during all pregnancies.³⁵     

Flowering time regulation by the SUMO E3 ligase SIZ1

Flowering is a developmental process, which is influenced by chemical and environmental stimuli. Recently, our research established that the Arabidopsis SUMO E3 ligase, AtSIZ1, is a negative regulator of transition to flowering through mechanisms that reduce salicylic acid (SA) accumulation and involve SUMO modification of FLOWERING LOCUS D (FLD). FLD is an autonomous pathway determinant that represses the expression of FLOWERING LOCUS C (FLC), a floral repressor. This addendum postulates mechanisms by which SIZ1-mediated SUMO conjugation regulates SA accumulation and FLD activity.Key words: SIZ1, SA, flowering, SUMO, FLD, FLCSUMO conjugation and deconjugation are post-translational processes implicated in plant defense against pathogens, abscisic acid (ABA) and phosphate (Pi) starvation signaling, development, and drought and temperature stress tolerance, albeit only a few of the modified proteins have been identified.^1–8 The Arabidopsis AtSIZ1 locus encodes a SUMO E3 ligase that regulates floral transition and leaf development.^8,9 siz1 plants accumulate substantial levels of SA, which is the primary cause for dwarfism and early short-day flowering exhibited by these plants.^1,9 How SA promotes transition to flowering is not yet known but apparently, it is through a mechanism that is independent of the known floral signaling pathways.^9,10 Exogenous SA reduces expression of AGAMOUS-like 15 (AGL15), a floral repressor that functions redundantly with AGL18.^11,12 A possible mechanism by which SA promotes transition to flowering may be by repressing expression of AGL15 and AGL18 (Fig. 1).Open in a separate windowFigure 1Model of how SUMO conjugation and deconjugation regulate plant development in Arabidopsis. SIZ1 and Avr proteins regulate biosynthesis and accumulation of SA, a plant stress hormone that is involved in plant innate immunity, leaf development and regulation of flowering time. SA promotes transition to flowering may through AGL15/AGL18 dependent and independent pathways. FLC expression is activated by FRIGIDA but repressed by the autonomous pathway gene FLD, and SIZ1-mediated sumoylation of FLD represses its activity. Lines with arrows indicate upregulation (activation), and those with bars identify downregulation (repression).siz1 mutations also cause constitutive induction of pathogenesis-related protein genes leading to enhanced resistance against biotrophic pathogens.¹ Several bacterial type III effector proteins, such as YopJ, XopD and AvrXv4, have SUMO isopeptidase activity.^13–15 PopP2, a member of YopJ/AvrRxv bacterial type III effector protein family, physically interacts with the TIR-NBS-LRR type R protein RRS1, and possibly stabilizes the RRS1 protein.¹⁶ Phytopathogen effector and plant R protein interactions lead to increased SA biosynthesis and accumulation, which in turn activates expression of pathogenesis-related proteins that facilitate plant defense.¹⁷ SIZ1 may participate in SUMO conjugation of plant R proteins to regulate Avr and R protein interactions leading to SA accumulation, which, in turn, affects phenotypes such as diseases resistance, dwarfism and flowering time (Fig. 1).Our recent work revealed also that AtSIZ1 facilitates FLC expression, negatively regulating flowering.⁹ AtSIZ1 promotes FLC expression by repressing FLD activity.⁹ Site-specific mutations that prevent SUMO1/2 conjugation to FLD result in enhanced activity of the protein to represses FLC expression, which is associated with reduced acetylation of histone 4 (H4) in FLC chromatin.⁹ FLD, an Arabidopsis ortholog of Lysine-Specific Demethylase 1 (LSD1), is a floral activator that downregulates methylation of H3K4 in FLC chromatin and represses FLC expression.^18,19 Interestingly, bacteria expressing recombinant FLD protein did not demethylate H3K4me2, inferring that the demethylase activity requires additional co-factors as are necessary for LSD1.^18,20 Together, these results suggest that SIZ1-mediated SUMO modification of FLD may affect interactions between FLD and co-factors, which is necessary for FLC chromatin modification.Despite our results that implicate SA in flowering time control, how SIZ1 regulates SA accumulation and the identity of the effectors involved remain to be discovered. In addition, it remains to be determined if SIZ1 is involved in other mechanisms that modulate FLD activity and FLC expression, or the function of other autonomous pathway determinants.     

Tuba and N-WASP function cooperatively to position the central lumen during epithelial cyst morphogenesis

The process of epithelial lumenogenesis requires coordination of a network of signaling machinery communicated to each cell through subsequent cell divisions. Formation of a single hollow lumen has previously been shown to require Tuba, a Cdc42 GEF, for Cdc42 activation and correct spindle orientation. Using a Caco-2 model of lumenogenesis, we show that knockdown (KD) of the actin regulator N-WASP, causes a multilumen phenotype similar to Tuba KD. Defects in lumenogenesis in Tuba KD and N-WASP KD cells are observed at the two-cell stage with inappropriate marking of the pre-apical patch (PAP )—the precursor to lumen formation. Strikingly, both Tuba and N-WASP depend on each other for localization to the PAP. We conclude that N-WASP functions cooperatively with Tuba to facilitate lumenogenesis and this requires the polyproline region of N-WASP.Key words: lumen, N-WASP, tuba, E-cadherin, pre-apical patchMany epithelial tissues are organized as hollow tubes whose open lumina connect the body with its external environment.^1,2 These tubes consist of a monolayer of polarized cells that envelope the central lumen. Lumen formation is thus a key process in epithelial morphogenesis that depends upon cell polarity to establish three cell surface domains: a basal surface adherent to the extracellular matrix, a lateral surface between cells, and an apical surface that is exposed to the luminal fluids. Of note, the apical membrane is biochemically and morphologically distinct from the baso-lateral surfaces and effectively defines the luminal surface.^3,4For a lumen to form, cells must first mark the site at which apical membrane is to be inserted, something that is achieved at the first cell division.⁵ Targeted trafficking of apical membrane constituents defines a pre-apical patch (PAP), the precursor to the definitive lumen.⁵ Such insertion of apical membrane must presumably be coordinated with the assembly of apical junctions to segregate nascent apical from lateral membrane domains.² Subsequent cell divisions direct apical membrane and protein constituents to this point of initial apical membrane placement.⁶ Coordinated luminal positioning enables the initial formation of a single hollow lumen that subsequently expands through polarized fluid secretion to separate apical membranes, such as occurs in the embryonic gastrointestinal tract,⁷ or by apoptosis or autophagy of the central cells as is observed in mammary gland development.^8,9 Failure to establish initial luminal positioning causes defective lumenogenesis, often resulting in multiple, morphologically abnormal lumina.^5,6Crucial to lumenal morphogenesis is then the mechanism(s) that mark the site where the PAP will form. Cdc42 signaling is increasingly implicated in this process,^2,10 with downstream consequences that include control of mitotic spindle orientation,⁵ which itself influences PAP placement⁵ and potentially regulation of cell-cell junctions. Like other Rho family GTPases, the subcellular location of Cdc42 signaling is determined by the action of upstream proteins, notably guanine nucleotide exchange factors (GEFs).^11,12 Of these, Tuba, a Cdc42-specific GEF,¹³ has emerged as a regulator of lumenal morphogenesis that controls PAP placement through mitotic spindle orientation.¹⁰Tuba is also a scaffolding protein¹³ capable of linking the actin assembly machinery with trafficking pathways. Not only is Tuba required for Cdc42 activation to direct spindle orientation,⁵ it also has the potential to interact with phosphoinositides that define the PAP.¹⁴ Additionally, Tuba binds directly to the actin regulator N-WASP, a key molecule in the organization of actin and itself a Cdc42 effector.¹⁵ Further, Tuba and N-WASP cooperate in various forms of actin-driven cellular motility, such as vesicle propulsion and cell invasive behavior.¹⁶ Interestingly, in epithelial cells N-WASP is also found at cadherin-based cell-cell junctions.¹⁷ In fact it has been proposed that N-WASP functions downstream of Tuba in the maintenance of epithelial junctional homeostasis as N-WASP overexpression was capable of rescuing a Tuba KD phenotype.¹⁸ Therefore, Tuba has the potential to play a central role in coordinating the molecular complexes required for productive polarization of epithelial cells and placement of the PAP during lumenogenesis. However, whether other protein interactions contribute to the morphogenetic impact of Tuba remain to be assessed.Three-dimensional cell culture systems are being utilized to identify critical components in lumen formation. In particular, Madin-Darby canine kidney cells (MDCK) and Caco-2 gastrointestinal cells are commonly used to study cyst and/or tubule formation. MDCK cells undergo both cyst and tubule growth, apoptosis being primarily responsible for the final step in lumen formation,¹⁹ while Caco-2 cells primarily utilize fluid influx to expand cysts.⁵ Cyst culture systems replicate aspects of in vivo organogenesis²⁰ providing tangible, powerful models to analyze and dissect the coordinated cellular mechanisms and processes that occur during epithelial morphogenesis.In this study we examined the relationship between Tuba and N-WASP in early epithelial lumenogenesis using Caco-2 three dimensional cyst cultures. Both Tuba and N-WASP RNAi cell lines result in mature cysts with multiple lumina, and at the two-cell stage, formed multiple PAPs. Interestingly, N-WASP KD perturbed Tuba localization at the PAP, however, N-WASP localization to the PAP was not affected to the same extent by Tuba KD. Taken together, these results suggest a complex interrelationship between Tuba and N-WASP for the coordinated formation of a single hollow lumen.