Calcium opens the dialogue between plants and arbuscular mycorrhizal fungi

Calcium ion is considered a ubiquitous second messenger in all eukaryotic cells. Analysis of intracellular Ca²⁺ concentration dynamics has demonstrated its signalling role in plant cells in response to a wide array of environmental cues. The implication of Ca²⁺ in the early steps of the arbuscular mycorrhizal symbiosis has been frequently claimed, mainly by analogy with what firmly demonstrated in the rhizobium-legume symbiosis. We recently documented transient Ca²⁺ changes in plant cells challenged with diffusible molecules released by arbuscular mycorrhizal fungi. Ca²⁺ measurements by the recombinant aequorin method provided new insights into the molecular communications between plants and these beneficial fungi.Key words: legume symbioses, arbuscular mycorrhiza, calcium signalling, fungal signal, plant cell cultures, aequorinIn the rhizosphere plants meet a wide array of microorganisms. In favorable interactions, such as arbuscular mycorrhizal (AM) and nitrogen fixing symbioses, a dialogue is progressively established between the two interacting organisms to make the appropriate partner choice. These two-way communications rely on the interchange of signals released by both potential symbionts. After perception of the signalling molecules, a signal transduction pathway is induced, leading to the activation of the proper genetic and developmental program in both partners.Variations in intracellular free Ca²⁺ concentration occur as one of the initial steps in signalling pathways activated in plants when they encounter pathogens,¹ fungal biocontrol agents² and nitrogen-fixing bacteria.³ Molecules secreted by microorganisms, after binding to specific receptors, trigger in plant cells transient changes in cytosolic Ca²⁺ level, due to the influx of the ion from the extracellular environment and/or the release from internal Ca²⁺ storage compartments.^4,5 Ca²⁺ messages delivered to plant cells are at least partly deciphered on the basis of their spatial and temporal features. The occurrence of different Ca²⁺ signatures guarantees the specificity of the ensuing physiological responses.In the legume-rhizobium symbiosis a definite pattern of Ca²⁺ oscillations has been reported to occur in response to the rhizobial signalling molecule, the Nod factor, in the nucleus and perinuclear cytoplasm of the root hair.⁶ The Ca²⁺ spike number has been recently demonstrated to regulate nodulation gene expression.⁷Legumes are able to engage in a dual symbiotic interaction, with rhizobia and AM fungi. Components of the Ca²⁺-mediated signalling pathway are shared by the two symbioses.⁸ In the mycorrhizal signal transduction pathway the involvement of Ca²⁺ has long been speculated, based on the observed similarities with symbiotic nitrogen fixation.³To evaluate the possible participation of Ca²⁺ in the early steps of the AM symbiosis, we have used a simplified experimental system given by plant cell suspension cultures stably expressing the bioluminescent Ca²⁺-sensitive reporter aequorin.⁹ The use of cultured cells circumvents the problem posed by multilayered organs: in aequorin-transformed seedlings, possible Ca²⁺ changes occurring in rhizodermal cells—the first place where the AM fungal signals are perceived and transduced—can be misrecorded due to luminescence calibration over all root cell layers, resulting in an underestimation of the Ca²⁺ signal in the responsive cells. An experimental design based on challenging host plant cells with the culture medium of different AM fungi (Gigaspora margarita, Glomus mosseae and intraradices) provided the first firm evidence that Ca²⁺ is involved as intracellular messenger during mycorrhizal signalling, at least in a pre-contact stage. Cytosolic Ca²⁺ changes, characterized by specific kinetic parameters, were triggered by diffusates obtained from AM resting and germinating spores,⁹ and extraradical mycelium.¹⁰ Cultured plant cells demonstrated to be competent to perceive the diffusible signal released by AM fungi and to decode the message in a Ca²⁺-dependent pathway. Based on these experiments, it seems that AM fungi announce their presence to the plant through the constitutive release of a chemical signal, even before experiencing the proximity of the plant or its AM symbiotic signals. The notion that the secreted fungal molecules herald, through Ca²⁺, a beneficial message which can be acknowledged only by competent receivers, is supported by: (1) the lack of defense response induction and the upregulation of some genes essential for the AM symbiosis initiation in host plant cells; (2) the unresponsiveness of cultured cells from the nonhost plant Arabidopsis thaliana.Ca²⁺-mediated perception of both AM fungal and rhizobial signals by plant cells unifies the signalling pathways activated in the two symbioses. However, the actual occurrence of Ca²⁺ spiking in AM symbiosis remains to be ascertained, due to limitations of the recombinant aequorin method, when applied to an asynchronous cell population. Contribution of internal Ca²⁺ stores, in particular the nucleus, to the observed Ca²⁺ changes will be a future research goal to be achieved through a pharmacological approach and/or targeting of Ca²⁺ indicators to intracellular compartments.The identification of the plant-derived mycorrhizal signal as strigolactones¹¹ and their inducing activity on AM fungi¹² have represented a major breakthrough in the AM symbiosis research field. Elucidation of the chemical nature of the AM fungal factor, which plays several effects on host plants,^9,13–15 is eagerly awaited.Understanding how AM fungi and rhizobia select compatible plant hosts, thus activating the appropriate symbiotic program, is another facet to be considered in the future to get a complete overview of early signaling events in legume symbioses. Analysis of Ca²⁺ signalling implication in the microbial partner would require the delivery of reliable and sensitive Ca²⁺ probes (such as aequorinor GFP-based¹⁶) for Ca²⁺ measurements in living microorganisms. The recombinant aequorin method has been successfully applied to monitor dynamic changes in intracellular Ca²⁺ levels in the bacteria Anabaena sp.,¹⁷ E. coli,¹⁸ and recently by us in rhizobial strains.¹⁹ Unfortunately, AM fungi have proved not to be amenable to stable transformation, being coenocytic, multinucleate and heterokaryotic,^20,21 and only transient transformants have been obtained so far.^22,23 Further development of the transformation technologies may provide in the future a valuable tool to analyse, from the fungal side, signal perception and transduction during arbuscular mycorrhiza establishment.     

Endomembrane Ca2+-ATPases play a significant role in virus-induced adaptation to oxidative stress

Although the role of Ca²⁺ influx channels in oxidative stress signaling and cross-tolerance in plants is well established, little is known about the role of active Ca²⁺ efflux systems in this process. In our recent paper,¹⁷ we reported Potato Virus X (PVX)-induced acquired resistance to oxidative stress in Nicotiana benthamiana and showed the critical role of plasma membrane Ca²⁺/H⁺ exchangers in this process. The current study continues this research. Using biochemical and electrophysiological approaches, we reveal that both endomembrane P_2A and P_2B Ca²⁺-ATPases play significant roles in adaptive responses to oxidative stress by removing excessive Ca²⁺ from the cytosol, and that their functional expression is significantly altered in PVX-inoculated plants. These findings highlight the crucial role of Ca²⁺ efflux systems in acquired tolerance to oxidative stress and open up prospects for practical applications in agriculture, after in-depth comprehension of the fundamental mechanisms involved in common responses to environmental factors at the genomic, cellular and organismal levels.Key words: cytosolic calcium, reactive oxygen species, cross-tolerance, calcium pumpThe phenomenon of cross-tolerance to a variety of biotic and abiotic stresses is well-known.^1,2 Some of the demonstrated examples include the correlation between oxidative stress tolerance and pathogen resistance.^3–5 At the mechanistic level, changes in cytosolic Ca²⁺ levels [Ca²⁺]_cyt, have long been implicated as a quintessential component of this process.⁶ The rise in [Ca²⁺]_cyt is proven to be essential for the development of the oxidative burst required for triggering the activation of several plant defense reactions.^7,8 The observed elevation in H₂O₂ level is believed to result from Ca²⁺-dependent activation of the NADPH oxidase,⁸ which then causes a further increase in [Ca²⁺]_cyt via a positive feedback mechanism. This process is further accomplished by defense gene activation, phytoalexin synthesis and eventual cell death.⁹ Downstream from the stimulus-induced [Ca²⁺]_cyt elevation, cells possess an array of proteins that can respond to a message. Such proteins include calmodulin (CaM),¹⁰ Ca²⁺-dependent protein kinases¹¹ and CaM binding proteins.¹² Of note is that when Ca²⁺ channels are blocked, biosynthesis of ROS is prevented.¹³While the role of Ca²⁺ influx channels in oxidative stress signaling and cross-tolerance in plants is well established, little is known about the involvement of active Ca²⁺ efflux systems in this process. In contrast, in animal systems the essential role of re-establishing [Ca²⁺]_cyt to resting levels is widely reported. A sustained increase in [Ca²⁺]_cyt in the alveolar macrophage is thought to be the consequence of membrane Ca²⁺-ATPase dysfunction.¹⁴ In endothelial cells, inhibition of the Ca²⁺/Na⁺ electroneutral exchanger of the mitochondria was named as one of the reasons for [Ca²⁺]_cyt increases.¹⁵ A significant loss of the plasma membrane Ca²⁺-ATPase (PMCA) activity was reported in brain synapses in response to oxidative stress,¹⁶ suggesting that PMCA may be a downstream target of oxidative stress.In our recently published paper¹⁷ we reported the phenomenon of Potato Virus X (PVX)-induced acquired resistance to oxidative stress in Nicotiana benthamiana plants and showed the critical role of plasma membrane Ca²⁺/H⁺ exchangers in this process. Nonetheless, questions remain, is this transporter the only active Ca²⁺ efflux system involved in this process?In addition to Ca²⁺/H⁺ exchangers, active Ca²⁺ extrusion could also be achieved by Ca²⁺-ATPases. Two major types of Ca²⁺-ATPases that differ substantially in their pharmacology and sensitivity to CaM are known.¹⁸ Type P_2A pumps (also called ER-type or ECA^19,20) are predominantly ER-localized,¹⁹ although they are also present at other endomembranes (e.g., tonoplast and Golgi). Four members of this group have been identified in the Arabidopsis genome (named AtECAs 1 to 4).^18,21 These pumps lack an N-terminal autoregulatory domain, are insensitive to CaM and suppressed by cyclopropiazonic acid (CPA).¹⁹ P_2B (or ACA) pumps contain an autoinhibitory N-terminal domain that possesses a binding site for Ca²⁺-CaM.¹⁸ Ten members are known in Arabidopsis (termed AtACA1, 2, 4 and 7 to 13).²¹ Plant P_2B pumps are located at the plasma membrane²⁰ as well as in inner membranes such as tonoplast (e.g., ACA4), ER (e.g., ACA2) and plastids.^18,19 These pumps probably constitute the basis for precise cytosolic Ca²⁺ regulation; as the Ca²⁺ concentration increases, CaM is activated and binds to the autoinhibitory domain of the Ca²⁺ pump. This results in the activation of the pump.In our recent study,¹⁷ we found no significant difference between the purified plasma membranes fractions isolated from control and UV-treated tobacco plants (with or without PVX inoculation) either in the Ca²⁺-ATPase activity or in the Ca²⁺-ATPase expression level and its ability to bind CaM. This suggests that the plasma membrane P_2B type pumps (the only pump type known to be expressed at the plasma membrane) play no major role in removing excess Ca²⁺ from the cytosol under oxidative stress conditions. This led to an obvious question: what about endomembrane Ca²⁺-ATPases?To address this issue, microsomal membrane fractions were isolated from tobacco leaves in a manner previously described for plasma membrane fractions¹⁷ (Fig. 1A). Western blot and CaM overlay assays were then made to investigate the role of endomembrane P_2B Ca²⁺-ATPases in our reported phenomena of acquired resistance. The results show that the expression of the P_2B Ca²⁺ pumps in PVX-inoculated plants is significantly higher than in control plants (Fig. 1B), correlating well with the CaM overlay assay (Fig. 1C). As no difference was observed for the P_2B Ca²⁺-ATPase expression levels in the plasma membranes,¹⁷ the observed difference in the microsomal fractions of PVX-infected plants must be due to an increased expression of endomembrane P_2B Ca²⁺-ATPases. Given the fact that Ca²⁺ pumps have a high affinity for calcium, the observed increase in endomembrane P_2B-type Ca²⁺-ATPases expression in PVX-inoculated plants may be advantageous for more efficient Ca²⁺ removal from the cytosol into internal organelles.Open in a separate windowFigure 1Expression of P_2B Ca²⁺ in purified microsomal fractions from tobacco leaves. Measurements were undertaken C = mock controls; C-UV = mock controls treated with UV-light; PVX = PVX infected plants; PVX-UV = PVX inoculated plants treated with UV-light. (A) Coomassie Brilliant Blue-stained gel; (B) Protein blot immunostained with a non isoform-specific polyclonal antibody for P_2B Ca²⁺-ATPases; (C) CaM overlay assay.To decipher the possible role of P_2A Ca²⁺-ATPases in acquired resistance, a series of electrophysiological experiments were conducted using inhibitors of P_2A-type Ca²⁺-ATPases, such as thapsigargin (TG)²² and cyclopiazonic acid (CPA).²³ Ion-selective Ca²⁺ microelectrodes were prepared as described elsewhere in reference ²⁴ and ²⁵, and net Ca²⁺ fluxes were measured from tobacco mesophyll tissue following previously described protocols.¹⁷ Leaf pre-treatment for 2 h in either of these inhibitors dramatically suppressed the net Ca²⁺ efflux measured from tobacco mesophyll cells 2 h after UV light exposure (Fig. 2). Given the specificity of TG and CPA inhibitors for P_2A-type Ca²⁺-ATPases, these results strongly support a hypothesis that both endomembrane P_2A and P_2B Ca²⁺-ATPases play significant roles in plant adaptive responses to oxidative stress. This is achieved by removing excess Ca²⁺ from the cytosol.Open in a separate windowFigure 2Effect of known Ca²⁺-ATPase blockers on light-induced Ca²⁺ flux kinetics after 20 min of UV-C treatment. Leaf mesophyll segments were pre-treated in either 5 µM TG (thapsigargin) or 50 µM CPA (cyclopiazonic acid) for 1–1.5 h prior to exposure to UV-C light. Net Ca²⁺ fluxes were measured 2 h after the end of UV treatment. These were compared with two controls: (1) no pre-treatment/no UV exposure (closed circles) and (2) no pre-treatment/20 min UV exposure (open squares). Mean ± SE (n = 4 to 7).Combining these results with our previously reported observations in reference ¹⁷, the following model is proposed (Fig. 3). Oxidative stress (such as UV) causes increased ROS production in leaf chloroplasts, leading to the elevated [Ca²⁺]_cyt. Several Ca²⁺ efflux systems are involved in restoring basal cytosolic Ca²⁺ levels. Two of these, the plasma membrane Ca²⁺/H⁺ exchanger¹⁷ and endomembrane P_2A and P_2B Ca²⁺-ATPases (as reported in this study) are upregulated in PVX inoculated plants and contribute to the improved tolerance to oxidative stress. Overall, these findings highlight the potential role of Ca²⁺ efflux systems in virus-induced tolerance to oxidative stress in plants. This is consistent with our previous reports on the important role of Ca²⁺ efflux systems in biotic stress tolerance²⁶ and brings forth possibilities for genetic engineering of more tolerant plants by targeting expression and regulation of active Ca²⁺ efflux systems at either the plasma or endomembranes.Open in a separate windowFigure 3The proposed model of oxidative stress signaling and the role of Ca²⁺-efflux systems in acquired resistance and plant adaptation to oxidative stress.Overall, a better adaptation of virus-infected plants to a short wave UV irradiation as compared to uninfected controls may suggest that infection triggers common defense mechanisms that could be efficient against secondary unrelated stresses. This observation may lead to the development of novel strategies to protect plants against complex environmental stress conditions.     

Electrophysiological approach to examine a putative cold- and menthol-sensitive channel in the liverwort Conocephalum conicum

The mechanism of cold perception by plants is still poorly understood. It was found that temperature drop evokes changes in the activity of ion pumps and channels, which leads to plasma membrane depolarization.^1,2 The nature of the primary step of its action (alteration in membrane composition,³ transient influx of Ca²⁺ etc.,²) has not been elicited yet. Our electrophysiological experiments conducted on the liverwort Conocephalum conicum showed that its cells respond not only to sudden cooling⁴ but also to menthol, generating depolarization of the plasma membrane and action potentials (APs). Similar results are well documented in mammals; cold or “cooling compounds” including menthol cause activation of thermosenstitive channel TRPM8 permeable to Ca²⁺ and generation of AP series.⁵ TRP receptors are detected, among others, in green and brown algae. Possible existence of TRPM8-like channel-receptor in Conocephalum conicum is discussed here.Key words: action potential, cold, liverwort, menthol, thermoreceptors, voltage transient     

Nitric oxide production is not required for dihydrosphingosine-induced cell death in tobacco BY-2 cells

Sphinganine or dihydrosphingosine (d18:0, DHS), one of the most abundant free sphingoid Long Chain Base (LCB) in plants, is known to induce a calcium-dependent programmed cell death (PCD) in tobacco BY-2 cells. We have recently shown that DHS triggers a production of H₂O₂, via the activation of NADPH oxidase(s). However, this production of H₂O₂ is not correlated with the DHS-induced cell death but would rather be associated with basal cell defense mechanisms. In the present study, we extend our current knowledge of the DHS signaling pathway, by demonstrating that DHS also promotes a production of nitric oxide (NO) in tobacco BY-2 cells. As for H₂O₂, this NO production is not necessary for cell death induction.Key words: tobacco BY-2 cells, sphingolipids, LCBs, dihydrosphingosine, sphinganine, apoptosis, programmed cell death (PCD), nitric oxide (NO)These last few years, it has been demonstrated in plants that long chain bases (LCBs), the sphingolipid precursors, are important regulators of different cellular processes including programmed cell death (PCD).^1–3 Indeed, plant treatment with fumonisin B1 or AAL toxin, two mycotoxins that disrupt sphingolipid metabolism, leads to an accumulation of the dihydrosphingosine (d18:0, DHS), one of the most abundant free LCB in plants and correlatively to the induction of cell death symptoms.^4,5 A more recent study shows a rapid and sustained increase of phytosphingosine (t18:0), due to a de novo synthesis from DHS, when Arabidopsis thaliana leaves are inoculated with the avirulent strain Pseudomonas syringae pv. tomato (avrRpm1), known to induce a localized PCD called hypersensitive response (HR).⁶ More direct evidences were obtained from experiments on Arabidopsis cells where external application of 100 µM C2-ceramide, a non-natural acylated LCB, induced PCD in a calcium (Ca²⁺)-dependent manner.⁷ Recently, we have shown that DHS elicited rapid Ca²⁺ increases both in the cytosol and the nucleus of tobacco BY-2 cells and correlatively induced apoptotic-like response. Interestingly, blocking nuclear Ca²⁺ changes without affecting the cytosolic Ca²⁺ increases prevented DHS-induced PCD.⁸Besides calcium ions, reactive oxygen species (ROS) have also been suggested to play an important role in the control of PCD induced by sphingolipids in plants.⁹ Thus, the C2-ceramide-induced PCD in Arabidopsis is preceded by an increase in H₂O₂.⁷ However, inhibition of ROS production by catalase, a ROS-scavenging enzyme, did not prevent C2-ceramide-induced cell death, suggesting that this PCD is independent of ROS generation. Moreover, we recently showed in tobacco BY-2 cells that DHS triggers a dose-dependent production of H₂O₂ via activation of a NADPH oxidase.¹⁰ The DHS-induced cytosolic Ca²⁺ transient is required for this H₂O₂ production while the nuclear calcium variation is not necessary. In agreement with the results of Townley et al. blocking the ROS production using diphenyleniodonium (DPI), a known inhibitor of NADPH oxidases, does not prevent DHS-induced cell death. Gene expression analysis of defense-related genes, using real-time quantitative PCR (RT-qPCR) experiments, rather indicates that H₂O₂ generation is likely associated with basal defense mechanisms.¹⁰In the present study, we further investigated the DHS signaling cascade leading to cell death in tobacco BY-2 cells, by evaluating the involvement of another key signaling molecule i.e., nitric oxide (NO). In plants, NO is known to play important roles in numerous physiological processes including germination, root growth, stomatal closing and adapative response to biotic and abiotic stresses (reviewed in ref. ^11–14). NO has also been shown to be implicated in the induction of PCD in animal cells,¹⁵ in yeast,¹⁶ as well as in plant cells, in which it is required for tracheid differentiation¹⁷ or HR activation.^18,19 Interestingly in the latter case, the balance between NO and H₂O₂ production appears to be crucial to induce cell death.²⁰ Here we show in tobacco BY-2 cells that although DHS elicits a production of NO, this production is not necessary for the induction of PCD.     

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.     

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     

Is,indeed, the prion protein a Harlequin servant of “many” masters?

Tens of putative interacting partners of the cellular prion protein (PrP^C) have been identified, yet the physiologic role of PrP^C remains unclear. For the first time, however, a recent paper has demonstrated that the absence of PrP^C produces a lethal phenotype. Starting from this evidence, here we discuss the validity of past and more recent literature supporting that, as part of protein platforms at the cell surface, PrP^C may bridge extracellular matrix molecules and/or membrane proteins to intracellular signaling pathways.Key words: prion protein, PrP^C, extracellular matrix, cell adhesion molecules, neuritogenesis, p59fyn, Ca²⁺Initially, the discovery that the prion protein was the major, if not the unique, component of the prion agent causing transmissible spongiform encephalopathies (TSE)¹ has placed the protein in an extremely unfavorable light. Thereafter, however, a wealth of evidence has supported the notion that the protein positively influences several aspects of the cell physiology, and that its duality—in harboring both lethal and beneficial potentials—could be rationalized in terms of a structural switch. Indeed, the protein exists in at least two conformational states: the cellular, α helix-rich isoform, PrP^C, and the prion-associated β sheet-rich isoform, PrP^Sc.² If it is now unquestionable that the presence of PrP^C in the cell is mandatory for prion replication and neurotoxicity to occur,^3,4 nonetheless its physiologic function is still debatable, despite the long lasting effort, and the numerous, frequently genetically advanced, animal and cell model systems dedicated to the issue. From these studies the picture of an extremely versatile protein has emerged, whereby PrP^C acts in the cell defense against oxidative and apoptotic challenges, but also in cell adhesion, proliferation and differentiation, and in synaptic plasticity.^5,6 In an effort to converge these multiple propositions in an unifying functional model, different murine lines devoid of PrP^C have been studied. These animals, however, displayed no obvious phenotype,^7–9 suggesting that either PrP^C is dispensable during development and adult life or that compensative mechanisms mask the loss of PrP^C function in these paradigms. Thus, identifying the exact role of PrP^C in the cell would not only resolve an important biological question, but would also help elucidate the cellular steps of prion pathogenesis necessary for designing early diagnostic tools and therapeutic strategies for TSE.As is often the case, the employment of a model system unprecedented in prion research has recently disclosed a most interesting scenario with regards to PrP^C physiology, having unravelled, for the first time, a lethal phenotype linked to the absence of the protein.¹⁰ The paradigm is the zebrafish, which expresses two PrP^C isoforms (PrP1 and PrP2). Similarly to mammalian PrP^C, they are glycosylated and attached to the external side of the plasma membrane through a glycolipid anchor. PrP1 and PrP2 are, however, expressed in distinct time frames of the zebrafish embryogenesis. Accordingly, the knockdown of the PrP1, or PrP2, gene very early in embryogenesis impaired development at different stages, bypassing putative compensatory mechanisms. By focusing on PrP1, Malaga-Trillo et al. showed that the protein was essential for cell adhesion, and that this event occurred through PrP1 homophilic trans-interactions and signaling. This comprised activation of the Src-related tyrosine (Tyr) kinase p59fyn, and, possibly, Ca²⁺ metabolism, leading to the regulation of the trafficking of E-cadherin, a member of surface-expressed cell adhesion molecules (CAMs) responsible for cell growth and differentiation.¹¹ It was also reported that overlapping PrP1 functions were performed by PrP^Cs from other species, while the murine PrP^C was capable to replace PrP1 in rescuing, at least in part, the knockdown developmental phenotype. Apart from providing the long-sought proof for a vital role of PrP^C, the demonstration that a mammalian isoform corrected the lethal zebrafish phenotype strongly reinforces previous results—mainly obtained in a variety of mammalian primary neurons and cell lines—pointing to a functional interplay of PrP^C with CAMs, or extra cellular matrix (ECM) proteins, and cell signaling, to promote neuritogenesis and neuronal survival. A revisit of these data is the main topic of the present minireview.As mentioned, the capacity of PrP^C to act as a cell adhesion, or recognition, molecule, and to entertain interactions with proteins implicated in growth and survival, has already been reported for the mammalian PrP^C. A case in point is the interaction, both in cis- and trans-configurations, with the neuronal adhesion protein N-CAM12 that led to neurite outgrowth.¹³ Like cadherins, N-CAM belongs to the CAM superfamily. Following homo- or heterophylic interactions, it can not only mediate adhesion of cells, or link ECM proteins to the cytoskeleton, but also act as a receptor to transduce signals ultimately resulting in modulating neurite outgrowth, neuronal survival and synaptic plasticity.¹¹ Another example is the binding of PrPC to laminin, an ECM heterotrimeric glycoprotein, which induced neuritogenesis together with neurite adhesion and maintenance,^14,15 but also learning and memory consolidation.¹⁶ Further, it has been described that PrPC interacted with the mature 67 kDa-receptor (67LR) (and its 37 kDa-precursor) for laminin, and with glycosamminoglycans (GAGs), each of which is involved in neuronal differentiation and axon growth.^17–21 More recently, Hajj et al.²² have reported that the direct interaction of PrP^C with another ECM protein, vitronectin, could accomplish the same process, and that the absence of PrP^C could be functionally compensated by the overexpression of integrin, another laminin receptor.²³ Incidentally, the latter finding may provide a plausible explanation for the absence of clear phenotypes in mammalian PrP-null paradigms. By exposing primary cultured neurons to recombinant PrPs, others have shown that trans-interactions of PrP^C are equally important for neuronal outgrowth,^24,25 including the formation of synaptic contacts.²⁵ Finally, it has been demonstrated that the binding of PrP^C with the secreted co-chaperone stress-inducible protein 1 (STI1) stimulated neuritogenesis.²⁶ This same interaction had also a pro-survival effect, as did the interaction of PrP^C with its recombinant form.²⁴ Notably, the involvement of PrP^C in cell protection has been heightened by experiments with whole animals. By applying transient or permanent focal cerebral ischemia to the animals, it was found that their reduced brain damage correlated with spontaneous or adenoviral-mediated, upregulation of PrP^C,^27–29 (reviewed in ref. ³⁰), and that PrP^C deficiency aggravated their ischemic brain injury.^30,31 Thus, now that data are available from phylogenetically distant paradigms (zebrafish and mammalian model systems), it acquires more solid grounds the advocated engagement of PrP^C in homo/heterophilic cis/trans interactions to trigger signaling events aiming at neuronal—or, in more general terms, cell—survival and neuritogenesis. The latter notion is consistent with the delayed maturation of different types of PrP^C-less neurons, observed both in vitro and in vivo.^32,33If one assumes that the interaction of PrP^C with multiple partners (45 for PrP^C and PrP^Sc, as reviewed in Aguzzi et al.,⁵ or 46 considering the homophylic interaction) are all functionally significant, the most immediate interpretation of this “sticky” behavior entails that PrP^C acts as a scaffolding protein in different membrane protein complexes.^5,6 Each complex could then activate a specific signaling pathway depending on the type and maturation of cells, the expression and glycosylation of PrP^C, and availability of extra- and intra-cellular signaling partners. At large, all these signals have been shown to be advantageous to the cell. However, because in a cell only a subtle line divides the “good” from the “bad,” instances can be envisioned in which a pro-life signal turns into a pro-death signal. A typical example of this possibility is glutamate excitotoxicity resulting in dangerous, glutamate receptor-linked, Ca²⁺ overload. Likewise, an excessive or over-stimulated signal elicited by PrP^C, or by the putative complex housing the protein could become noxious to the cell. This possibility may explain why the massive expression of PrP^C caused degeneration of the nervous system,³⁴ and of skeletal muscles,^34,35 in transgenic animals. More intriguing is the finding that—in a mouse line expressing anchorless PrP^C—PrP^Sc was capable to replicate without threatening the integrity of neurons.³⁶ This may suggest that native membrane-bound PrP^C acts as, or takes part into, a “receptor for PrP^Sc”, and that lasting PrP^Sc-PrP^C interactions distort the otherwise beneficial signal of the protein/complex and cause neurodegeneration.³⁷ Consistent with this hypothesis is the finding that the in vivo antibody-mediated ligation of PrP^C provoked apoptosis of the antibody-injected brain area.³⁸ Speculatively, the action of N-terminally, or N-proximally truncated PrPs whose expression in PrP-less transgenic mice induced extensive neurodegeneration,^39–41 may be traced back to the same hyper-activation of PrP^C signaling. Possibly, this may hold true also for the synaptic impairment that, recorded only in PrP^C-expressing neurons, was attributed to the binding of amyloid beta (Aβ) peptide oligomers implicated in Alzheimer disease, to PrP^C.^42,43But which is (are) the cellular signaling pathway(s) conveyed by the engagement of PrP^C in different signaling complexes? In line with its multifaceted behavior, several intracellular effectors have been proposed, including p59fyn, mitogen-activated kinases (MAPK) Erk1/2, PI3K/Akt and cAMP-PKA. p59fyn is the most reported downstream effector, suggesting that, in accordance with its behavior, p59fyn could serve as the sorting point for multiple incoming and outgoing signals also in the case of PrP^C. The initial evidence of the PrP^C-p59fyn connection came from cells subjected to antibody-mediated cross-linking of PrP^C.⁴⁴ Later, it was shown that the PrP^C-p59fyn signal converged to Erk1/2 through a pathway dependent on (but also independent of) reactive oxygen species generated by NADPH oxidase.⁴⁵ A PrP^C-dependent activation of p59fyn^13,25 and Erk1/2 (but also of PI3K and cAMP-PKA)²⁴ was evident in other neuronal cell paradigms and consistent with the almost ubiquitous expression of PrP^C, in non-neuronal cells such as Jurkat and T cells.⁴⁶ Not to forget that in zebrafish embryonic cells activated p59fyn was found in the same focal adhesion sites harboring PrP1.¹⁰ Regarding the activation of the ERK1/2 pathway promoted by the PrP^C-STI1 complex, and leading to neuritogenesis, the role of p59fyn was not investigated.²⁶ The same holds true for the transduction of a neuroprotective signal by the PrP^C-STI1 complex involving the cAMP-PKA pathway.²⁶ Interestingly, this is not the only example reporting that engagement of PrP^C activates simultaneously two independent pathways. In fact, possibly after transactivating the receptor for the epidermal growth factor, the antibody-mediated clustering of PrP^C was shown to impinge on both the Erk1/2 pathway, and on a protein (stathmin) involved in controlling microtubule dynamics.⁴⁷Yet, if p59fyn is implicated in mammalian PrP^C-activated signaling cascade, a protein linking extracellular PrP^C to p59fyn is needed, given the attachment of the enzyme to the inner leaflet of the plasma membrane through palmitoylated/myristoylated anchors. In this, the PrP^C partner N-CAM (isoform 140) seems ideal to fulfill the task, given that p59fyn is part of N-CAM-mediated signaling. Indeed, after recruitment of N-CAM to lipid rafts—which may also depend on PrP^C,¹³—together with the receptor protein Tyr phosphatase α (RPTPα), the Tyr-phosphate removing activity of RPTPα allows the subsequent activation of p59fyn through an autophosphorylation step.⁴⁸ This event recruits and activates the focal adhesion kinase (FAK),¹¹ another non-receptor Tyr kinase. Finally, formation of the FAK-p59fyn complex triggers neuritogenesis through both Erk1/2 and PI3K/Akt pathways.^49,50 Parenthetically, the FAK-p59fyn and PI3K/Akt connection would be suitable to explain why aggravation of ischemic brain injury in PrP-deficient brains was linked to a depressed Akt activation.³¹ FAK-p59fyn complex, however, may be also involved in the signal triggered by the still mysterious PrP^C partner, 67LR. This protein was reported not only to act as a laminin receptor but also to facilitate the interaction of laminin with integrins,⁵¹ thereby possibly activating (through integrins) FAK-p59fyn-regulated pathways.⁴⁹ Conversely, other data have supported the candidature of caveolin-1 for coordinating the signal that from PrP^C reaches Erk1/2 through p59fyn.^44,45,52 Further scrutiny of this route has shown that it comprised players such as laminin and integrins (upstream), FAK-p59fyn, paxillin and the Src-homology-2 domain containing adaptor protein (downstream), and that caveolin-1, a substrate of the FAK-p59fyn complex, facilitated the interaction of these signaling partners by recruiting them in caveolae-like membrane domains.⁵³For the relevance they bear, we need to acknowledge recent propositions supporting the commitment of PrP^C with proteins whose function is unrelated from the above-mentioned cell adhesion or ECM molecules; namely, the β-site amyloid precursor protein (APP) cleaving enzime (BACE1) and the N-methyl-D-aspartate (NMDA)-receptor. BACE1 is a proteolytic enzyme involved in Aβ production. It has been shown that overexpressed PrP^C restricted, while depletion of PrP^C increased the access of BACE1 to APP, possibly because PrP^C interacts with BACE1 via GAGs.⁵⁴ Thus, native PrP^C reduces the production of Aβ peptides. A beneficial effect of PrP^C was also highlighted by Khosravani et al.⁵⁵ showing that, by physically associating with the subunit 2D of the NMDA-receptor, PrP^C attenuated neuronal Ca²⁺ entry and its possible excitotoxic effect. This clear example for the control of PrP^C on Ca²⁺ metabolism is particularly intriguing in light of previous reports linking Ca²⁺ homeostasis to PrP^C pathophysiology (reviewed in ref. ⁵⁶). Also, it is important to mention that a few partners of PrP^C or downstream effectors may initiate signals that increase intracellular Ca²⁺, and that, in turn, local Ca²⁺ fluctuations regulate some of the afore-mentioned pathways.^11,49,57,58In conclusion, although still somehow speculative, the implication of Ca²⁺ in PrP^C-dependent pathways raises the possibility that the different input signals originating from the interaction of PrP^C with diverse partners may all converge to the universal, highly versatile Ca²⁺ signaling. Were indeed this the case, then clearly the acting of PrP^C as Harlequin, the famous character of the 18^th century Venetian playwright Carlo Goldoni, who struggles to fill the orders of two masters, would be merely circumstantial.     

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.