Characterization of the Oligogalacturonide-Induced Oxidative Burst in Cultured Soybean (Glycine max) Cells

The rapid release of H2O2 by elicited plant cells, recently termed the oxidative burst, was investigated in suspension-cultured soybean (Glycine max Merr. cv Kent) cells stimulated with a purified polygalacturonic acid (PGA) elicitor. Examination of the elicited cells by fluorescence microscopy revealed that virtually every living cell participates in the elicitor-induced H2O2 burst. Measurement of the kinetics of the response using a macroscopic fluorescence-based assay indicated that approximately 100 molecules of H2O2 are generated per PGA molecule added, achieving a cumulative H2O2 concentration of approximately 1.2 mmol L-1 of packed cells. At the height of the defense response, 3 x 10-14 mol of H2O2 cell-1 min-1 are produced, a value comparable to the rate of H2O2 production by myeloid cells of mammals. Variables affecting the rate and magnitude of the soybean oxidative burst were found to be mechanical stress, extracellular pH, and cell age. The PGA-induced oxidative burst was shown to undergo both homologous and heterologous desensitization, a characteristic of signal transduction pathways in animals. Homologous desensitization was obtained with PGA, and heterologous desensitization was observed with the G protein activator mastoparan, consistent with earlier observations showing that G proteins perform a regulatory function in this pathway. Finally, a model describing the possible role of the PGA-induced oxidative burst in the overall scheme of plant defense is proposed.     

The elicitor-induced oxidative burst in cultured chickpea cells drives the rapid insolubilization of two cell wall structural proteins

Elicitation of cultured chickpea cells caused rapid insolubilization of two cell wall structural proteins, p190, a putative hydroxyproline-rich glycoprotein and p80, a putative proline-rich protein. This process appeared to result from an H₂O₂-mediated oxidative cross-linking mechanism and was initiated within 5 min and complete within 20 min. Further, elicitation of cells induced a rapid, transient generation of H₂O₂ (oxidative burst), with an onset after 5 min and a maximum H₂O₂-release after 20 min, as measured by a luminol-dependent chemiluminescence assay. Both chemiluminescence and protein insolubilization were suppressed by exogenous application of catalase or diphenylene iodonium, an inhibitor of plasma-membrane NADPH oxidase, respectively. In contrast, exogenous H₂O₂ mimicked the effect of the elicitor, suggesting that the putative oxidative crosslinking of the proteins depends directly on H₂O₂ from the oxidative burst. The peroxidase inhibitor salicylhydroxamic acid blocked both the elicitor- and the exogenous-H₂O₂-stimulated insolubilization, indicating that a peroxidase activity downstream of H₂O₂-supply is required. The protein kinase inhibitor staurosporine blocked the elicitation of the oxidative burst and protein insolubilization. In contrast, the protein phosphatase 2A inhibitor cantharidin accelerated, potentiated and extended the elicited oxidative burst. Cantharidin even stimulated the responses in the absence of the elicitor. The competitive effect of both inhibitors confirms that a coordinated activation of (i) protein kinase(s) and (ii) counteracting protein phosphates(s) is a poised signal transduction step for the induction of an NADPH-oxidase-dependent oxidative burst, which drives the putative peroxidase-catalyzed cross-linking of the cell wall proteins.Abbreviations DPI diphenylene iodonium - Ext-1 extensin-1 - gE1 anti-glycosylated extensin-1 antibodies - HRGP hydroxyp-roline-rich glycoprotein - LDC luminol-dependent chemiluminescence - POD peroxidase - PA polyacrylamide - PRP proline-rich proteins - SHAM salicylhydroxamic acid Financial support by Deutsche Forschungsgemeinschaft and Fonds der Chemischen Industrie is gratefully acknowledged. We thank Dr. C.J. Lamb (Salk Institute, La Jolla, Calif., USA) and Dr. L.A. Staehelin (University of Colorado, Boulder, Colo., USA) for their kind gifts of antibodies.     

Protein phosphorylation in Nicotiana tabacum cells in response to perception of lipopolysaccharides from Burkholderia cepacia

Bacterial LPS have the ability to act as modulators of the innate immune response in plants. Complex and largely unresolved perception systems exist for LPS on the plant cell surfaces that lead to the activation of multiple intracellular defense signaling pathways. The aim of the present study was to investigate the perception mechanism of cultured Nicotiana tabacum cells towards LPS from Burkholderia cepacia (LPS(B.cep.)), with regard to the role of protein phosphorylation during signal perception-related responses to gain a better understanding of the chemosensory perception of LPS elicitor signals in plant cells. In vivo labeling of protein phosphorylation events during signal transduction indicated the rapid phosphorylation of several proteins with the hyperphosphorylation of two proteins of 28 and 2 kDa, respectively. Significant differences and de novo LPS-induced phosphorylation were also observed with two-dimensional analysis. The protein kinase inhibitor, staurosporine, totally inhibited the extracellular alkalinization response induced by LPS(B.cep.), while the oxidative burst was only partially inhibited by staurosporine. Inhibition of protein phosphatase activity by calyculin A intensified the LPS(B.cep.) responses. The results indicate that perception- and signal transduction responses during LPS(B.cep.) elicitation of tobacco cells require a balance between the actions of certain protein kinases and protein phosphatases.     

Characterization of binding proteins that recognize oligoglucoside elicitors of phytoalexin synthesis in soybean

We are studying the cellular signaling pathway leading to pterocarpan phytoalexin biosynthesis in soybean that is induced by a branched hepta-β-glucoside originally isolated from the mycelial walls of the phytopathogenic oomycete Phytophthora sojae. Our research has focused on the specific recognition of the hepta-β-glucoside elicitor by binding proteins in soybean cells. Elicitor-binding proteins with properties expected of physiological receptors for the hepta-β-glucoside elicitor have been identified in soybean root membranes. These elicitor-binding proteins co-migrate with a plasma membrane marker (vanadate-sensitive H⁺-ATPase) on linear sucrose density gradients. Binding of a radio-iodinated derivative of the hepta-β-glucoside elicitor by membrane-localized elicitor-binding proteins is specific, reversible, saturable, and of high affinity (K_d? 1 nM). After solubilization with the nonionic detergent, n-dodecylsucrose, the elicitor-binding proteins retain their high affinity (K_d= 1.8 nM) for the radiolabeled elicitor and their binding specificity for elicitor-active oligoglucosides. A direct correlation is observed between the ability of oligoglucosides to displace labeled elicitor from the elicitor-binding proteins and the elicitor activity of the oligosaccharides. Thus, the elicitor-binding proteins recognize the same structural elements of the hepta-β-glucoside elicitor that are essential for its phytoalexin-inducing activity, suggesting that the binding proteins are physiological receptors for the elicitor. Current research is directed toward the purification of the hepta-β-glucoside elicitor-binding proteins by using ligand affinity chromatography. Purification and characterization of the hepta-β-glucoside binding proteins are among the first steps toward elucidating how the hepta-β-glucoside elicitor triggers the signal transduction pathway that ultimately leads to the synthesis of phytoalexins in soybean.     

Identification of the bacterial superoxide dismutase (SodM) as plant-inducible elicitor of an oxidative burst reaction in tobacco cell suspension cultures

Three of the most abundant proteins (OmpW, MopB and SodM) of the extracellular proteome of Xanthomonas campestris pv. campestris were analysed in a luminol-based oxidative burst assay to identify novel pathogen-associated molecular patterns (PAMP). Tobacco cell suspension cultures were used as a model system to monitor elicitor induced plant defence reaction. The candidate proteins were isolated from two-dimensional gels prior to application to the oxidative burst assay. The superoxide dismutase (SodM) was the only isolated protein that could elicit a notable hydrogen peroxide (H2O2) production in tobacco cell cultures indicating the initiation of plant defence. An alignment of the SodM sequences from X. campestris pv. campestris and Escherichia coli revealed 55.7% identity and 29% of the sequence were substitutions for amino acids with similar physico-chemical properties. By using a commercially available purified E. coli derived SodM preparation, it was possible to show that the amino acid sequence of this protein is responsible for the elicitation of an oxidative burst reaction in the tobacco cell culture model. This suggests that the bacterial superoxide dismutase is a novel pathogen-associated molecular pattern. The minimal elicitor active sequence, however, is still elusive.     

Signal transduction in monocytes and granulocytes measured by multiparameter flow cytometry.

The novel calcium indicator fura red and the oxidative burst indicator dihydrorhodamine (both excited at 488 nm) were used in combination with multiparameter flow cytometry to allow simultaneous kinetic measurements of calcium fluxes and oxidative bursts in monocytes and granulocytes. Using this method it was possible to obtain direct evidence for the following cell type- and stimulus-specific differences in signal transduction pathways: 1) n-formyl-methionyl-leucyl-phenylalanine (FMLP)/cytochalasin B-induced oxidative burst is several-fold higher in granulocytes than in monocytes although the calcium fluxes have similar amplitudes in the two cell types; 2) stimulus-induced calcium fluxes in granulocytes are mainly due to release from intracellular stores, whereas monocytes mobilize calcium mainly by influx from the medium; 3) the FMLP/cytochalasin B-induced calcium flux in monocytes is less sensitive to the G-protein inhibitor pertussis toxin than the flux in granulocytes; 4) in contrast to FMLP/cytochalasin B, the protein kinase C activator phorbol myristate acetate (PMA) induces an oxidative burst that is not preceded by a cytoplasmic calcium flux; 5) the PMA-induced oxidative burst can be triggered in monocytes and granulocytes that are depleted of intracellular calcium ions, whereas that induced by FMLP/cytochalasin B can not; 6) the G-protein inhibitor pertussis toxin blocks an early event in the signal transduction pathway of FMLP/cytochalasin B, as shown by inhibition of both calcium fluxes and oxidative burst; and 7) 100 nM of the protein kinase inhibitor staurosporine blocks the FMLP/cytochalasin B-induced respiratory burst by interfering with a step downstream to cytoplasmic calcium fluxes, whereas only 10-20 nM is necessary to block PMA-induced oxidative burst.     

Activation of Phospholipase A by Plant Defense Elicitors

Participation of phospholipase A (PLase A) in plant signal transduction has been documented for auxin stimulation of growth but not for elicitation of any plant defense response. In this paper, we report two independent assays for monitoring PLase A induction in plant cells and have used these assays to evaluate whether transduction of defense-related signals might require PLase A activation. Oligogalacturonic acid, a potent elicitor of the soybean (Glycine max) H2O2 burst, was unable to stimulate endogenous PLase A, suggesting that PLase A activation is not an obligate intermediate in the oligogalacturonic acid-induced burst pathway. In contrast, harpin and an extract from the pathogenic fungus Verticillium dahliae both stimulated the oxidative burst and promoted a rapid increase in PLase A activity. To evaluate the possible role of this inducible PLase A activity in transducing the oxidative burst, we tested the effect of chlorpromazine-HCl, a PLase A inhibitor on elicitor-stimulated burst activity. Pretreatment with chloropromazine was found to inhibit the H2O2 burst triggered by V. dahliae extract at the same concentration at which it blocked PLase A activation. In contrast, neither the harpin- nor oligogalacturonic acid-induced burst was altered by addition of chlorpromazine. These data suggest that PLase A stimulation may be important in certain elicitor-induced oxidative bursts (e.g. V. dahliae) and that other elicitors such as oligogalacturonic acid and harpin must operate through independent signaling intermediates to activate the same defense response.     

The oxidative burst in plant defense: Function and signal transduction

The rapid production and accumulation of active oxygen species (AOS), the oxidative burst, has been shown to occur in a variety of plant/pathogen systems. In particular, two species, hydrogen peroxide (H₂O₂) and the superoxide radical anion O₂^? have received considerable attention. H₂O₂ and O₂^?, while acting directly as antimicrobial agents, may also serve as second messengers or catalysts in plants to activate a more diverse set of defense responses. Some of the better studied downstream responses promoted by AOS are (1) the cross-linking of cell wall proteins, (2) the induction of defense-related genes, (3) the stimulation of phytoalexin biosynthesis and (4) promotion of the hypersensitive response (HR). A useful model for studying the oxidative burst in plants is the neutrophil NADPH ox-idase complex, the primary source of AOS production in mammals. Several of the subunits of the neutrophil NADPH oxidase complex have been immunologically identified in plants. Furthermore, many of the components known to be involved in the signal transduction pathway in neutrophils have also been found to play a role in the oxidative burst in plants. Just as various ligands activate the oxidase complex in neutrophils, several ligands (elicitors or pathogens) also lead to induction of the oxidative burst in plant cells. The similarities between the neutrophil and plant oxidative bursts will be elaborated in this review. Following stimulation with elicitors, different signal transduction pathways are activated in plants, depending on the source of elicitor used. While the identities and chronologies of the major intermediates in these pathways remain largely unknown, there is strong evidence at least for participation of phospholipases, H⁺/K⁺ exchange, Ca²⁺ influxes, protein kinases and phosphatases, and GTP binding proteins. In an effort to integrate these various signaling events into a single scheme, we have constructed a hypothetical model that proposes how different elicitors might induce the oxidative burst in the same cell by different pathways.     

Differential degradation rates of the G protein alpha o in cultured cardiac and pituitary cells

Signal transduction in biological membranes is modulated by a family of GTP-binding proteins termed G proteins. Differences in the tissue-specific expression of G protein subtypes suggest that the levels of individual G proteins may be an important determinant of the hormonal response in a given cell type. We have used a polyclonal antibody raised against the purified G protein, alpha o to study alpha o in the rat pituitary cell line GH4 and in primary rat cardiocytes in culture by quantitative immunoprecipitation. Biosynthetic labeling and specific immunoprecipitation of alpha o in pulse-chase experiments demonstrated that the t1/2 for alpha o degradation is 28 +/- 7 h (n = 4) in GH4 pituitary cells and is greater than 72 h (n = 4) in cardiocytes. The steady-state level of alpha o protein is similar in both cell types as measured by Western blots. Northern blots of poly(A)-selected mRNA from these two cell types were probed with labeled alpha o cDNA and showed they have similar alpha o mRNA levels. The observation of different degradation rates, but similar steady-state protein levels, suggests that the rate of alpha o synthesis is different in GH4 cells and cardiocytes. Since mRNA levels are approximately equal in both, our studies imply that protein translation controls may be important determinants of G protein alpha subunit concentrations in biological membranes.     

The oxidative burst protects plants against pathogen attack: Mechanism and role as an emergency signal for plant bio-defence — a review

Various aspects, mechanisms and functions of the oxidative burst with generation of O₂⁻ superoxide anions in plant cells, which is stimulated by active defence-inducing agents such as fungal infection or elicitor treatment, were reviewed mainly on the basis of experimental evidence obtained in a system of Solanaceae plants and Phytophthora spp. The oxidative burst may be due to an O₂⁻-generating NADPH oxidase in the plasma membrane, which is activated with combinations of cytosolic proteins, Ca²⁺, calmodulin and protein kinase, following stimulation by elicitor molecules. The oxidative burst may play the role of an internal emergency signal for induction of the metabolic cascade for active defence.     

Ethylene is required for elicitin-induced oxidative burst but not for cell death induction in tobacco cell suspension cultures

The signal compound ethylene and its relationships with oxidative burst and cell death were analyzed in cultured tobacco cells treated with the proteinaceous elicitor quercinin. Quercinin belongs to the protein family of elicitins and was isolated from the soil-born oak pathogen Phytophthora quercina. It was shown to induce a dose-dependent oxidative burst in tobacco cell culture in concentrations from 0.05 to 0.5 nM, and subsequently, cell death. The characteristics of quercinin-induced cell death included both membrane damage and DNA fragmentation in tobacco cell culture.

At higher quercinin concentrations (2 nM), H₂O₂ formation and ethylene biosynthesis were inhibited. Ethylene at low concentrations proved to be necessary for induction and maintenance of H₂O₂ production in tobacco cells treated with quercinin. It was demonstrated that external addition of inhibitors of ethylene biosynthesis such as -amino-oxy-acetic acid (AOA) and CoCl₂ also decreased or even inhibited the quercinin-induced oxidative burst, but did not influence cell death induction. These results demonstrate evidence for a requirement of the plant hormone ethylene for the onset of the quercinin-induced oxidative burst.     

Fungal elicitor triggers rapid, transient, and specific protein phosphorylation in parsley cell suspension cultures

Treatment of suspension-cultured parsley (Petroselinum crispum) cells with fungal elicitor triggers rapid, transient and sequential phosphorylation of a number of proteins, as shown by electrophoretic analysis on two-dimensional gels. This response is rapidly reversed by removal of the elicitor from the medium and appears to be specific. It is not observed in cells exposed to other environmental stress factors, such as heat shock, UV irradiation or treatment with mercuric chloride. Pronase digestion of the elicitor has the same negative effect on protein phosphorylation as its previously demonstrated effect on the activation of some pathogen defense-related genes, suggesting a link between these two phenomena. Some of the changes in protein phosphorylation are among the earliest known events following elicitation. The phosphorylation of a neutral 45-kDa protein, which is found in both the microsomal and cytoplasmic fractions, can be observed as early as 1 min after the onset of elicitor treatment. The phosphorylation of a 26-kDa nuclear protein also starts increasing very early. The changes in protein phosphorylation in response to the elicitor are dependent on the presence of Ca2+ in the medium. Our data are compatible with the hypothesis that protein phosphorylation is involved in the signal transduction processes following elicitor recognition by parsley cells.     

Guanine nucleotide-dependent carboxyl methylation of mammalian membrane proteins

A guanine nucleotide-dependent protein carboxyl methylation is demonstrated in mammalian cell membranes. The methylation of membrane proteins of Mr 20,000-23,000 requires S-adenosylmethionine, GTP or nonhydrolyzable GTP analogs, and a cytoplasmic methyltransferase. The protein methyl groups are stable at neutral pH and under basic conditions hydrolyze to produce methanol. The specific methyl acceptor proteins and methyltransferases varied between tissues and cell types, suggesting that these methylations have cell-specific functions. The guanine nucleotide-dependent carboxyl methylations provide a possible mechanism for regulating the function of GTP-binding membrane proteins in the transduction of receptor-mediated signals of eukaryotic cells.     

Rapid Stimulation of an Oxidative Burst during Elicitation of Cultured Plant Cells : Role in Defense and Signal Transduction

Stimulation of cultured plant cells with elicitors of the defense response leads to the rapid destruction of a variety of water-soluble compounds including indoleacetic acid and certain fluorescent dyes. This destructive activity, which is often vigorously manifested within 5 minutes of elicitor addition, is shown to derive from the rapid production of H₂O₂ and its use by extracellular peroxidases. Because of its speed of appearance, this oxidative burst may qualify as the first induced line of defense against invading pathogens. Since H₂O₂ has been implicated as a second messenger of hormone-stimulated metabolic changes in some animal cells, its possible role in transduction of the defense signal in plants was also examined. Not only did exogenous H₂O₂ alone stimulate phytoalexin production in the plant cell suspension, but inhibition of elicitor-stimulated phytoalexin production was observed upon addition of catalase and other inhibitors of the oxidative burst. Furthermore, for inhibition to occur, the presence of catalase was required during elicitor addition, since if introduction of the enzyme was delayed until 1 hour after addition of the elicitor, no inhibition resulted. These results suggest that H₂O₂ also plays an important role in inducing subsequent defense responses such as phytoalexin production.     

Characterization of a monoclonal antibody against the lymphoblast substance P receptor

A murine monoclonal antibody to the IM-9 lymphoblast substance P (SP) receptor has been produced which recognizes the membrane-associated proteins of the SP receptor as demonstrated by immunoprecipitation of [125I]SP affinity-labeled and [35S]methionine biosynthetically labeled IM-9 soluble membranes. SP and anti-SP receptor binding to [35S]methionine-labeled IM-9 cell proteins were directly compared by attachment of each to affinity supports. Eluants from these affinity columns were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and revealed an equivalent 33-kDa protein in both cases. This protein corresponds to one of the previously described [125I]SP specifically affinity-labeled membrane-associated proteins. In addition, two-color fluorescence-activated cell sorter analysis with human peripheral blood T lymphocytes with fluorescein-SP and rhodamine-labeled antireceptor antibody revealed a distinct population of cells (20 to 30%) that were equally labeled by both the fluorescent peptide and antibody. This result indicates that the anti-SP receptor antibody recognizes an epitope of the receptor that is common to both human peripheral blood T lymphocytes and IM-9 lymphoblast cells.     

Involvement of G-proteins in chitosan-induced Anthraquinone synthesis in Rubia tinctorum

We have previously shown that chitosan stimulates anthraquinone synthesis in Rubia tinctorum L. cells through activation of the PLC\PKC, PI3K, MAPK and Ca²⁺ messenger systems. In view of this evidence, we have now investigated whether guanine nucleotide-binding G-proteins are part of the signal transduction mechanism which mediates the elicitor action. The G-protein agonists mastoparan, AlF₄^– and GTPyS increased anthraquinone levels to the same extent as chitosan. No additive effects were observed when cultured R. tinctorum cells were treated with agonist and the elicitor together. In agreement with these observations, the G-protein antagonists suramin and GDPβS abolished the increase in anthraquinone synthesis induced by chitosan. Furthermore, elicitation was not affected in the presence of pertussis toxin. Consistent with this result, when cell cultures were preincubated with a monoclonal anti-Gαq\11 antibody, the chitosan-dependent increase in anthraquinone levels was fully inhibited. Moreover, the presence of an immunoreactive protein of the expected size for Gαq\11 (42 kDa) was observed in R. tinctorum microsomal membranes by Western blot analysis using the same antibody. These results indicate that chitosan stimulates anthraquinone synthesis in R. tinctorum cells through a heterotrimeric G-protein, most likely belonging to the Gαq family.     

CD36-mediated signal transduction in human monocytes by anti-CD36 antibodies but not by anti-thrombospondin antibodies recognizing cell membrane-bound thrombospondin

Mononuclear cells (MNC) treated with anti-CD36 Fab or F(ab')2 fragments and then stimulated with anti-rabbit (F(ab')2 displayed an oxidative burst, suggesting that the crosslinking of CD36 promotes signal transduction in the absence of an Fc receptor involvement. Moreover, intact anti-TSP mediates a weak oxidative burst in MNC, which was strongly enhanced upon pretreatment of monocytes (but not lymphocytes) with TSP. This response, however, was mediated by Fc receptors, not by an involvement of CD36. Other means of crosslinking cell-bound TSP and exposure of MNC to surface-bound TSP failed to promote an oxidative burst. Crosscompetition tests confirmed that the interaction site(s) of TSP with monocytes are distinct from the signal-promoting sites recognized by polyclonal and 3 monoclonal anti-CD36 antibodies.