High-affinity binding of fungal beta-glucan fragments to soybean (Glycine max L.) microsomal fractions and protoplasts

The regulatory mechanism of fungal elicitor-induced secondary metabolite biosynthesis in medical plants

A wide range of external stress stimuli trigger plant cells to undergo complex network of reactions that ultimately lead to the synthesis and accumulation of secondary metabolites. Accumulation of such metabolites often occurs in plants subjected to stresses including various elicitors or signal molecules. Throughout evolution, endophytic fungi, an important constituent in the environment of medicinal plants, have known to form long-term stable and mutually beneficial symbiosis with medicinal plants. The endophytic fungal elicitor can rapidly and specifically induce the expression of specific genes in medicinal plants which can result in the activation of a series of specific secondary metabolic pathways resulting in the significant accumulation of active ingredients. Here we summarize the progress made on the mechanisms of fungal elicitor including elicitor signal recognition, signal transduction, gene expression and activation of the key enzymes and its application. This review provides guidance on studies which may be conducted to promote the efficient synthesis and accumulation of active ingredients by the endogenous fungal elicitor in medicinal plant cells, and provides new ideas and methods of studying the regulation of secondary metabolism in medicinal plants.

Catalytic properties of the bifunctional soybean beta-glucan-binding protein, a member of family 81 glycoside hydrolases

The beta-glucan-binding protein (GBP) of soybean (Glycine max L.) has been shown to contain two different activities. As part of the plasma membrane-localized pathogen receptor complex, it binds a microbial cell wall elicitor, triggering the activation of defence responses. Additionally, the GBP is able to hydrolyze beta-1,3-glucans, as present in the cell walls of potential pathogens. The substrate specificity, the mode of action, and the stereochemistry of the catalysis have been elucidated. This defines for the first time the inverting mode of the catalytic mechanism of glycoside hydrolases belonging to family 81.

Cation fluxes cause plasma membrane depolarization involved in beta-glucan elicitor-signaling in soybean roots

Inducible and specific ion fluxes on plasma membranes represent very early events during elicitation of plant cells. The hierarchy of such ion fluxes involved is still unknown. The effect of Phytophthora sojae-derived beta-glucan elicitors on the plasma membrane potential as well as on surface K+, Ca2+, and H+ fluxes has been investigated on soybean roots using ion-selective microelectrodes. Beta-Glucans with different degrees of polymerization transiently depolarized the plasma membrane. The elicitor concentration necessary for half-maximal depolarization closely resembled the corresponding binding affinities of soybean root membranes toward the respective beta-glucans. Upon repeated elicitor treatment, the root cells responded partially refractory, suggesting a complex responsiveness of the system. Within the root hair space, characteristic decreasing K(+)- and Ca(2+)-free concentrations were induced by the elicitors, probably causing depolarization through the influx of positive charges. Whereas K+ fluxes were inverted after passing the K+ equilibrium (Nernst-) potential, Ca2+ influx continued. No anion fluxes sufficient to account for charge compensation were observed under the same experimental conditions. K+ and Ca2+ fluxes as well as depolarization were inhibited by 100 microM or less of the Ca2+ antagonist La3+. Contrasting other systems, in soybean the main cause for elicitor-induced plasma membrane depolarization is the activation of cation instead of anion fluxes.

The AVR4 elicitor protein of Cladosporium fulvum binds to fungal components with high affinity

The interaction between tomato and the fungal pathogen Cladosporium fulvum complies with the gene-for-gene system. Strains of C. fulvum that produce race-specific elicitor AVR4 induce a hypersensitive response, leading to resistance, in tomato plants that carry the Cf-4 resistance gene. The mechanism of AVR4 perception was examined by performing binding studies with 125I-AVR4 on microsomal membranes of tomato plants. We identified an AVR4 high-affinity binding site (KD = 0.05 nM) which exhibited all the characteristics expected for ligand-receptor interactions, such as saturability, reversibility, and specificity. Surprisingly, the AVR4 high-affinity binding site appeared to originate from fungi present on infected tomato plants rather than from the tomato plants themselves. Detailed analysis showed that this fungus-derived, AVR4-specific binding site is heat- and proteinase K-resistant. Affinity crosslinking demonstrated that AVR4 specifically binds to a component of approximately 75 kDa that is of fungal origin. Our data suggest that binding of AVR4 to a fungal component or components is related to the intrinsic virulence function of AVR4 for C. fulvum.

Binding site for chitin oligosaccharides in the soybean plasma membrane

Affinity cross-linking of the plasma membrane fraction to an (125)I-labeled chitin oligosaccharide led to the identification and characterization of an 85-kD, chitin binding protein in plasma membrane-enriched fractions from both suspension-cultured soybean cells and root tissue. Inhibition analysis indicated a binding preference for larger (i.e. degrees of polymerization = 8) N-acetylated chitin molecules with a 50% inhibition of initial activity value of approximately 50 nM. N-Acetyl-glucosamine and chitobiose showed no inhibitory effects at concentrations as high as 250 microM. It is noteworthy that the major lipo-chitin oligosaccharide Nod signal produced by Bradyrhizobium japonicum was also shown to be a competitive inhibitor of ligand binding. However, the binding site appeared to recognize the chitin portion of the Nod signal, and it is unlikely that this binding activity represents a specific Nod signal receptor. Chitooligosaccharide specificity for induction of medium alkalinization and the generation of reactive oxygen in suspension-cultured cells paralleled the binding activity. Taken together, the presence of the chitin binding protein in the plasma membrane fraction and the specificity and induction of a biological response upon ligand binding suggest a role for the protein as an initial response mechanism for chitin perception in soybean (Glycine max).

The hepta-beta-glucoside elicitor-binding proteins from legumes represent a putative receptor family

The ability of legumes to recognize and respond to beta-glucan elicitors by synthesizing phytoalexins is consistent with the existence of a membrane-bound beta-glucan-binding site. Related proteins of approximately 75 kDa and the corresponding mRNAs were detected in various species of legumes which respond to beta-glucans. The cDNAs for the beta-glucan-binding proteins of bean and soybean were cloned. The deduced 75-kDa proteins are predominantly hydrophilic and constitute a unique class of glucan-binding proteins with no currently recognizable functional domains. Heterologous expression of the soybean beta-glucan-binding protein in tomato cells resulted in the generation of a high-affinity binding site for the elicitor-active hepta-beta-glucoside conjugate (Kd = 4.5 nM). Ligand competition experiments with the recombinant binding sites demonstrated similar ligand specificities when compared with soybean. In both soybean and transgenic tomato, membrane-bound, active forms of the glucan-binding proteins coexist with immunologically detectable, soluble but inactive forms of the proteins. Reconstitution of a soluble protein fraction into lipid vesicles regained beta-glucoside-binding activity but with lower affinity (Kd = 130 nM). We conclude that the beta-glucan elicitor receptors of legumes are composed of the 75 kDa glucan-binding proteins as the critical components for ligand-recognition, and of an as yet unknown membrane anchor constituting the plasma membrane-associated receptor complex.

Critical role of Kupffer cell CR3 (CD11b/CD18) in the clearance of IgM-opsonized erythrocytes or soluble beta-glucan

Liver macrophages (Kupffer cells) play a major role in blood clearance of both C3-opsonized immune complexes and therapeutic beta-glucan polysaccharides. Human Kupffer cells express three types of C3-receptors: CR1 (C3b-receptor; CD35), CR3 (iC3b- and beta-glucan-receptor), and CR4 (iC3b-receptor; CD11c/CD18). Studies of isolated macrophages have suggested that CR3 is the major receptor mediating capture of either C3-opsonized erythrocytes (E) or beta-glucans. In this investigation, the organ distribution and function of CR3 in the clearance of IgM-opsonized E and soluble CR3-binding polysaccharides were explored in normal vs. CR3-knockout (CR3-KO) mice. Analysis of intravenously (i.v.) injected 125I-anti-CR3 showed that the major vascular reservoir of CR3 was the liver, followed by spleen and lungs. By contrast, clearance of 125I-anti-CR1 appeared to be mediated predominantly by splenic B lymphocytes, as only subsets of splenic macrophages or Kupffer cells were found to express CR1. Clearance of IgM-opsonized 51Cr-E occurred rapidly to the livers of normal mice but was nearly absent in CR3-KO mice. Soluble 125I-beta-glucan exhibited rapid clearance to the liver in normal mice, whereas clearance in CR3-KO mice was significantly reduced. In conclusion, Kupffer cell CR3 plays a crucial role in the clearance of both IgM-opsonized E and beta-glucans.

Pore-forming properties of elicitors of plant defense reactions and cellulolytic enzymes

Using the planar lipid bilayer technique, it is shown that a yeast elicitor as well as several cellulolytic enzymes used in protoplasting plant cells contain components which strongly interact with the bilayers. This results in the appearance of transmembrane ion fluxes which may pass through membrane defect structures and even large conductance pores with unitary conductances above 400 pS. Since membrane depolarization is an immediate response in the process of defense elicitation in plant cells, elicitors may act directly with the lipid phase of cell membranes, causing depolarizations and thus initiating the process of elicitation. When using enzymatically prepared protoplasts in electrophysiological work, contributions to electrical activity by membrane active constituents originating from the enzymes used must be expected.

Functional reconstitution of beta-glucan elicitor-binding activity upon incorporation into lipid vesicles

In temperature-induced Triton X-114 phase separation experiments the beta-glucan elicitor-binding site from soybean (Glycine max L.) root membranes was identified as (a) hydrophobic membrane protein(s). The Zwittergent 3-12-solubilized beta-glucan-binding proteins were incorporated into lipid vesicles by the detergent-dilution procedure. Reconstituted binding proteins were functional in that binding of the hepta-beta-glucoside ligand was saturable, reversible and of high affinity (K(d)=6-7 nM). Competition studies using beta-glucans with different degrees of polymerization (DP 7-15; DP 15-25) showed effective displacement of the radioligand from the binding site whereas beta-glucan fragments with DP <7 were ineffective. The total amount of reconstituted binding activity was dependent on the acyl chain length of the phospholipids used for the reconstitution with a preference for decanoic (C10) and dodecanoic (C12) chains. Restored ligand binding was maximally 37% as compared to the former detergent-solubilized binding activity. The presence of a lipid environment stabilized the purified beta-glucan-binding proteins.

Generation of Recombinant Fragments of CD11b Expressing the Functional β-Glucan-Binding Lectin Site of CR3 (CD11b/CD18)

CR3 (Mac-1; αMβ2 integrin) functions as both a receptor for the opsonic iC3b fragment of C3 triggering phagocytosis or cytotoxicity and an adhesion molecule mediating leukocyte diapedesis. Recent reports have suggested that a CR3 lectin site may be required for both cytotoxic responses and adhesion. Cytotoxic responses require dual recognition of iC3b via the I domain of CD11b and specific microbial surface polysaccharides (e.g., β-glucan) via a separate lectin site. Likewise, adhesion requires a lectin-dependent membrane complex between CR3 and CD87. To characterize the lectin site further, a recombinant baculovirus (rBv) system was developed that allowed high level expression of rCD11b on membranes and in the cytoplasm of Sf21 insect cells. Six rBv were generated that contained truncated cDNA encoding various CD11b domains. Immunoblotting of rBv-infected Sf21 cells showed that some native epitopes were expressed by five of six rCD11b fragments. Lectin activity of rCD11b proteins was evaluated by both flow cytometry with β-glucan-FITC and radioactive binding assays with [125I]β-glucan. Sf21 cells expressing rCD11b that included the C-terminal region, with or without the I-domain, exhibited lectin activity that was inhibited by unlabeled β-glucan or anti-CR3 mAbs. The smallest rCD11b fragment exhibiting lectin activity included the C-terminus and part of the divalent cation binding region. The β-glucan binding affinities of the three C-terminal region-containing rCD11bs expressed on Sf21 cell membranes were not significantly different from each other and were similar to that of neutrophil CR3. These data suggest that the lectin site may be located entirely within CD11b, although lectin site-dependent signaling through CD18 probably occurs with the heterodimer.

Isolation of a French bean (Phaseolus vulgaris L.) homolog to the beta-glucan elicitor-binding protein of soybean (Glycine max L.)

A high-affinity membrane-bound beta-glucan elicitor-binding protein has been purified from microsomal preparations of French bean (Phaseolus vulgaris L.) roots. A 5900-fold purification was achieved by affinity chromatography of functionally solubilized membrane proteins. The beta-glucan-binding protein had an apparent molecular mass of 78 kDa when subjected to SDS-PAGE. Western blot analysis showed specific crossreactivity of this French bean protein with an antiserum raised against a synthetic peptide representing an internal 15 amino acid fragment of the beta-glucan-binding protein from soybean. Northern blot analysis with a cDNA probe of the soybean beta-glucan-binding protein gene revealed a crosshybridizing transcript of 2.4 kb in French bean. These results indicate that the beta-glucan-binding proteins of French bean and soybean are conserved homologs involved in beta-glucan elicitor recognition.

Oligoglucoside elicitor-mediated activation of plant defense

Plants have acquired defense mechanisms to counteract potential pathogens. One such strategy involves inducible defense reactions that are activated by elicitors, signaling compounds of diverse nature. For one class of elicitors, oligoglucosides, recent developments in the characterization and isolation of an oligoclucan-binding protein, a putative elicitor receptor, and isolation of a cDNA that encodes the binding protein are discussed. Furthermore, the discovery of a role for calcium in the elicitation process is described. Finally, the identification of polymerase chain reaction products whose sequences indicate that they encode cytochrome P-450-dependent enzymes with possible roles in the formation of phytoalexins, antimicrobial plant defense compounds, is reported. These advances may lay the foundation for the first characterization of a receptor and subsequent signaling events in oligoglucan elicitor perception by higher plants.

Use of molecular cytology to study the structure and biology of phytopathogenic and mycorrhizal fungi

Molecular cytology, that is, the in situ localization of selected molecules by labeling with lectins, enzymes, and antibodies, has made a major contribution to our understanding of the structure and biology of fungi and is increasingly becoming an integral part of molecular, genetic, and biochemical studies. The review presented in this article concentrates on recent advances in the application of molecular cytology in investigations of the structure and biology of phytopathogenic and mycorrhizal fungi and of the molecular basis of their infection of host plants. The review examines details of the structure and molecular composition of fungal cell walls revealed by lectin, enzyme, and antibody labeling. Molecular composition is shown to vary according to taxonomic relationships and as a reflection of differences in cell type, location within the cell, and within thickness of the wall. Sites of synthesis and secretion of wall components are also detected through the labeling of selected molecules. In situ labeling of cytoskeletal elements, microtubules and actin microfilaments, has provided much information on the role of these elements in tip growth, organelle distribution, and spore development. Molecular cytology, particularly through the generation of monoclonal antibodies, has also revealed new and exciting information on specialized infection structures formed by fungi in order to infect host plants. The sites of storage and secretion of adhesives and degradative enzymes have been documented, as have surface specializations that may be associated with avoidance of detection by the host. In addition, in situ labeling with enzymes and antibodies has aided studies of the host defense response, including mechanisms of detection of fungal elicitor molecules, changes in wall composition, and the secretion of antifungal compounds. With the increasing production of monoclonal antibodies to fungal molecules, molecular cytology promises to continue to make an important contribution to our understanding of fungal cell structure and function in the future.

Phytosulfokine-alpha, a sulfated pentapeptide, stimulates the proliferation of rice cells by means of specific high- and low-affinity binding sites

Peptide growth factors were isolated from conditioned medium derived from rice (Oryza sativa L.) suspension cultures and identified to be a sulfated pentapeptide [H-Tyr(SO3H)-Ile-Tyr(SO3H)-Thr-Gln-OH] and its C-terminal-truncated tetrapeptide [H-Tyr(SO3H)-Ile-Tyr(SO3H)-Thr-OH]. These structures were identical to the phytosulfokines originally found in asparagus (Asparagus officinalis L.) mesophyll cultures. The pentapeptide [phytosulfokine-alpha (PSK-alpha)] very strongly stimulated colony formation of rice protoplasts at concentrations above 10(-8) M, indicating a similar mode of action in rice of phytosulfokines. Binding assays using 35S-labeled PSK-alpha demonstrated the existence of both high- and low-affinity specific saturable binding sites on the surface of rice cells in suspension. Analysis of [35S]PSK-alpha binding in differential centrifugation fractions suggested association of the binding with a plasma membrane-enriched fraction. The apparent Kd values for [35S]PSK-alpha binding were found to be 1 x 10(-9) M for the high-affinity type and 1 x 10(-7) M for the low-affinity type, with maximal numbers of binding sites of 1 x 10(4) sites per cell and 1 x 10(5) sites per cell, respectively. Competition studies with [35S]PSK-alpha and several synthetic PSK-alpha analogs demonstrated that only peptides that possesses mitogenic activity can effectively displace the radioligand. These results suggest that a signal transduction pathway mediated by peptide factors is involved in plant cell proliferation.

The structure and function of a soybean beta-glucan-elicitor-binding protein

beta-Glucan elicitor (GE), released from the cell wall of the phytopathogenic fungus Phytophthora megasperma by soybean glucanases, causes defense reactions in soybean. A GE-binding protein (GEBP) was purified from the membrane fraction of soybean root cells, and its cDNA was isolated. Expression of the cDNA clone in tobacco suspension cultured cells and in Escherichia coli conferred GE-binding activity to both. An antibody against the recombinant protein was found to inhibit the GE binding with the soybean cotyledon membrane fraction as well as the resulting accumulation of phytoalexin. Immunolocalization assays indicated that the GEBPs are located in the plasma membrane of root cells. These results suggest that the cDNA encodes a GE receptor and may mediate the signaling of the elicitor.

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 O(2-)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.

One-step purification of the beta-glucan elicitor-binding protein from soybean (Glycine max L.) roots and characterization of an anti-peptide antiserum

A low abundance beta-glucan elicitor-binding protein from soybean was isolated by a rapid, simple and one-step purification method yielding about 9000-fold enrichment. The affinity-based purification technique was more efficient than a procedure that uses conventional methods and preserved the binding activity to a much larger extent. The final preparation consisted of one major protein with an apparent molecular mass of about 75 kDa. Electrophoretic analyses of the purified and photoaffinity-labeled binding protein showed that the native protein was an oligomer with apparent molecular mass of about 240 kDa. A polyclonal anti-peptide antiserum was raised against a synthetic 15-mer internal oligopeptide sequence derived from the 75-kDa protein. The antiserum recognized the purified binding protein in immunoblotting experiments and precipitated the affinity-labeled protein from a crude extract of the membrane fraction.

Tansley Review No. 86 Accumulation of phytoalexins: defence mechanism and stimulus response system

Phytoalexin synthesis is a defence-response- that is characterized by a requirement for a number of distinct elements, all of which must be present for the response to be expressed fully. These same elements: a signal, a cellular receptor, a signal transduction system and a responsive metabolic system, are also used to describe a stimulus-response system. A number of molecular species can function as signal molecules or elicitors of phytoalexin synthesis, including poly- and oligosaccharides, proteins and polypeptides, and fatty acids. Few receptors for elicitors have been identified but those that have been are proteins located on the plasma membrane of the plant. Induction of phytoalexin synthesis involves selective and co-ordinated activation of specific defence response genes, including those encoding the enzymes of phytoalexin synthesis, and these genes constitute the responsive metabolic system. The separate, and distant, locations of the receptor and the responsive genes means that the event in which the signal is perceived by the receptor must be relayed to the genes by means of a second messenger system. Several second messengers are candidates for such a coupling- or signal transduction-system, including udenosine-3',5'-cyclic monophosphate, Ca²⁺ , diacylglycerol and inositol 1,4,5-trisphosphate, active oxygen species and jasmonic acid. Each has been examined as a possible component of the signal transduction system mediating between the elicitor receptor interaction and the phytoalexin synthesis it induces. Analysis of the signalling events is made complex by the simultaneous solicitation by the invading micro-organism of several defence responses, each of which might involve elements of a different signal system. The same complexity is evident which the role of phytoalexin accumulation in resistance is analysed. Evaluation of the contribution made by phytoalexin accumulation towards resistance has been attempted by the use of various inhibitors and enhancers of the process. Transgenic and mutant plants with specific alterations in one or more ot those elements necessary for the plant to respond to the signals for phytoalexin synthesis and other defence responses, are beginning to aid resolution of the complex pattern ot signalling events and the respective roles of the inducible defence mechanisms in resistance. CONTENTS Summary 1 I. Introduction 2 II. Chemistry of phytoalexins 3 III. Phytoalexin accumulation as a determinant of resistance 6 IV. Elicitation of phytoalexin accumulation 11 References 34.

Microbial elicitors and their receptors in plants

Elicitors are molecules that stimulate any of a number of defense responses in plants. Research over the past decade has focused on the mechanisms by which plant cells perceive and transduce these biological signals to activate defense responses. Of particular interest has been the identification of specific elicitor-binding proteins that might function as physiological receptors in the signal transduction cascade. The existence of specific high-affinity binding sites has been demonstrated for oligosaccharide, glycopeptide, and peptide elicitors, and candidate elicitor-binding proteins have been identified for several of them. The properties of these binding sites/proteins are consistent with those expected of physiologically important receptors, although experimental verification of the role of these binding proteins as receptors has not yet been obtained. The purification and characterization of specific elicitor-binding proteins is essential for a detailed understanding of the molecular basis for the signal exchange between plant hosts and microbial pathogens that leads to activation of host defenses.

Elicitor-binding proteins and signal transduction in the activation of a phytoalexin defense response

Inducible plant defenses against potential pathogens are thought to be activated by signal compounds released during early stages of the infection process. In the incompatible interaction between soybean (Glycine max L.) and the oomycete Phytophthora megasperma f.sp. glycinea (= Phytophthora sojae) a rapid, localized phytoalexin response is activated at the level of transcription. The phytoalexin response is also stimulated in various soybean tissues, including cultured cells, following treatment with an elicitor derived from the cell walls of the fungus. The best characterized elicitors of P. megasperma for soybean are the branched (1→3)- and (1→6)-linked β-glucans, structural polysaccharides of the hyphal walls. The glucans are naturally released during the early stages of germination of the fungal cysts in a host-independent manner. Cyclic β-glucans of Bradyrhizobium japonicum USDA 110, a symbiont of soybean, arc not active in inducing phytoalexin production in soybean. When tested in combination, B. japonicum β-glucans inhibited stimulation of phytoalexin accumulation by the fungal glucans. Surface-localized glucan-binding proteins exist in soybean cells that display high affinity and specificity for the fungal β-glucans, including an elicitor-active hepta-β-glucoside fragment derived from the polysaccharide, suggesting that elicitor action involves a transmembrane signalling process. The main component of the soybean β-glucan binding sites appears to be a 70-kDa protein. Hepta-β-glucoside binding sites exist in several other legumes, such as bean (Phaseolus vulgaris L.), pea (Pisum sativum L.), and lupine (Lupinus albus L.). The signalling process initiated by the β-glucan elicitor, which leads to the activation of the phytoalexin defense response in soybean, involves changes in the permeability of the plasma membrane to Ca2+and H+. Chloride channel antagonists are more efficient than calcium channel antagonists in inhibiting both the phytoalexin response and the inducible ion fluxes. The results present evidence that the observed permeability changes of the plasma membrane are primary events in the transduction of the elicitor signal(s) by the challenged soybean cells. Key words: soybean (Glycine max), Phytophthora megasperma f.sp. glycinea, β-glucan elicitor, elicitor-binding proteins, phytoalexins, Ca2+.

Molecular characterization of nucleotide sequences encoding the extracellular glycoprotein elicitor from Phytophthora megasperma

cDNA sequences encoding the 42 kDa glycoprotein elicitor from the oomycete, Phytophthora megasperma, that induces the defense response in parsley have been cloned and sequenced. The 5' end of the mRNA matches a consensus derived from sequences surrounding the transcription initiation sites of seven other oomycete genes. The major transcript of 1802 nucleotides contains a 529-codon open reading frame, which was predicted to encode a 57 kDa precursor protein. On the basis of peptide sequencing, the N-terminus of the mature protein is at position 163, suggesting that proteolytic processing events, in addition to signal peptide cleavage, generate the protein purified from the fungal culture filtrate. Expression studies in Escherichia coli with the cDNA as well as smaller subfragments demonstrated that a region of 47 amino acids located in the C-terminal third of the protein was sufficient to confer elicitor activity. The gene encoding the elicitor was found to be a member of a multigene family in P. megasperma. Homologous families of differing sizes were found in all eight other Phytophthora species tested, but not in other filamentous fungi including other Oomycetes. No significant similarity of the elicitor preprotein to sequences present in the databases has yet been detected.

High affinity binding of a fungal oligopeptide elicitor to parsley plasma membranes triggers multiple defense responses

An oligopeptide of 13 amino acids (Pep-13) identified within a 42 kDa glycoprotein elicitor from P. mega-sperma was shown to be necessary and sufficient to stimulate a complex defense response in parsley cells comprising H+/Ca2+ influxes, K+/Cl- effluxes, an oxidative burst, defense-related gene activation, and phytoalexin formation. Binding of radiolabeled Pep-13 to parsley microsomes and protoplasts was specific, reversible, and saturable. Identical structural features of Pep-13 were found to be responsible for specific binding and initiation of all plant responses analyzed. The high affinity binding site recognizing the peptide ligand (KD = 2.4 nM) may therefore represent a novel class of receptors in plants, and the rapidly induced ion fluxes may constitute elements of the signal transduction cascade triggering pathogen defense in plants.

Self-incompatibility: how plants avoid illegitimate offspring

In some families of flowering plants, a single self-incompatibility (S) locus prevents the fertilization of flowers by pollen from the same plant. Self-incompatibility of this type involves the interaction of molecules produced by the S locus in pollen with those present in the female tissues (pistil). Until recently, the pistil products of the S locus were known in only two families, the Brassicaceae (which includes the cabbages and mustards) and Solanaceae (potatoes and tomatoes). A paper in this issue of the Proceedings describes the molecules associated with self-incompatibility in a third family, the Papaveraceae (poppies). We review current research on self-incompatibility in these three families and discuss the implications of the latest findings in poppy on the likely evolution of self-incompatibility in flowering plants. We also compare research into self-incompatibility with recent progress in understanding the mechanisms by which plants overcome infection by certain pathogens.

Production of Bacteriolytic Enzymes by Streptomyces globisporus Regulated by Exogenous Bacterial Cell Walls

Mutanolysin biosynthesis and pigment production in Streptomyces globisporus ATCC 21553 were stimulated by adding bacterial cell walls to the medium. The increased bacteriolytic activity in the supernatant correlated with an increased de novo synthesis of mutanolysin and was between 4- and 20-fold higher than in cultures grown without bacterial cell walls. The increase in mutanolysin synthesis was brought about by enhanced transcription of the mutanolysin gene. The stimulation was only observed in medium which contained dextrin or starch as the carbon source. Glucose abolished the stimulation and also inhibited the low constitutive synthesis of mutanolysin. The induction of lytic activity was observed to require minimally 0.4 mg of bacterial cell walls per ml, whereas 0.6 mg of bacterial cell walls per ml yielded maximal lytic activity. Further supplements of bacterial cell walls did not result in enhanced lytic activity. The stimulation could be achieved independently of the phase of growth of the Streptomyces strain. Cultures grown in the presence of bacterial cell walls exhibited a higher growth yield. However, the accelerated growth was not the reason for the increased amount of mutanolysin produced. The growth of cultures with peptidoglycan monomers added to the medium instead of cell walls was similarly increased, but an effect on the biosynthesis of mutanolysin was not observed. All bacterial cell walls tested were capable of eliciting the stimulation of lytic activity, including cell walls of archaea, which contained pseudomurein.

High-affinity binding of a protein-lipopolysaccharide phytotoxin from Verticillium dahliae to cotton membranes

The presence of a specific binding site for a protein-lipopolysaccharide (PLP) phytotoxin isolated from culture filtrates of Verticillium dahliae has been demonstrated in plasma membranes from cotton seedlings. The 125I-labelled PLP was used as a ligand in binding assays with plasma membrane enriched fractions. Root tissue exhibited the highest amount of binding activity compared to hypocotyl and cotyledon tissue. Binding of the [125I]PLP was saturable, reversible, and with an affinity (Kd = 1.42 x 10(-8) M) comparable with the concentration required for biological activity. A single class of binding site was found, and the maximal number of binding sites were estimated as 5.4 x 10(-15) mol/micrograms protein.

Identification of a novel high-affinity binding site for N-acetylchitooligosaccharide elicitor in the membrane fraction from suspension-cultured rice cells

Binding experiments using a 125I-labeled tyramine conjugate of N-acetylchitooctaose, a highly potent elicitor for the induction of phytoalexin production in rice cells, and a microsomal membrane preparation from suspension-cultured rice cells showed the presence of a novel high-affinity binding site for this oligosaccharide. The binding of the ligand was saturable and the Scatchard plot analysis of the results indicated the presence of a single class of binding site with a Kd of 5.4 nM which is comparable with that reported for the binding of the hepta-beta-glucoside elicitor in soybean membrane. The ligand binding was inhibited by unlabeled N-acetylchitoheptaose but not by its deacetylated form. These characteristics of this binding site coincide well with the specificity and sensitivity for the elicitor in several assay systems, suggesting the possible involvement of this binding site in the recognition of the elicitor in vivo.

Purification and biochemical characterization of proteins which bind to the H-box cis-element implicated in transcriptional activation of plant defense genes

The H-box (CCTACC(N)7CT(N)4A), which occurs three times within the -154 to -42 region of the bean chalcone synthase chs15 promoter, is important for developmental regulation of chs15, and induction of chs15 and coordinately regulated defense genes by elicitors and other stress stimuli. Two protein factors, KAP-1 and KAP-2, which recognize conserved features in the H-box motif, were purified from bean cell suspension cultures by a combination of ion exchange chromatography and DNA affinity chromatography. KAP-1 is a 97 kDa polypeptide, whereas KAP-2 comprises two polypeptides of 76 and 56 kDa. KAP-1 and KAP-2 also differ in the sensitivity of their DNA-bound forms to trypsin. Dephosphorylation of KAP-1 or KAP-2 affects the mobility of the protein/H-box binding complex in gel shift assays but does not inhibit DNA binding. Elicitation of bean cell suspensions with glutathione does not affect the total cellular activities of KAP-1 or KAP-2, but causes a rapid increase in the specific activities of both factors in the nuclear fraction, consistent with a role for these factors in the signal pathway for elicitor induction of chs15 and related defense genes.

Identification of a high-affinity binding protein for a hepta-beta-glucoside phytoalexin elicitor in soybean

A putative receptor protein for a hepta-beta-glucoside phytoalexin elicitor was identified by photoaffinity labeling of detergent-solubilized proteins from soybean root membranes. Incubation of partially purified beta-glucan-binding proteins with a photolabile 125I-labeled 2-(4-azidophenyl)ethyl-amino conjugate of the heptaglucoside elicitor, followed by irradiation with ultraviolet light (366 nm) resulted in specific labeling of a 70-kDa band in SDS/PAGE. Half-maximal inhibition of the 125I-labeling of the protein band by underivatized hepta-beta-glucoside was achieved by 15 nM heptaglucoside. Analysis of the affinity of radiolabel incorporation into the protein by ligand-saturation experiments, gave an apparent Kd value of 3 nM, in full agreement with the results from radioligand-binding studies. Good correlation was also observed between the amount of radiolabel incorporated into the protein and the binding activity of the fractions obtained at different stages in the purification of heptaglucoside-binding activity. Photoaffinity labeling of proteins purified by glucan-affinity chromatography showed the 70-kDa band as the main component along with weak 125I-labeling of a 100-kDa band. The 70-kDa band was also the major protein visualized by silver staining after SDS/PAGE of this fraction, suggesting that it is the predominant form of the heptaglucoside-binding proteins in detergent-solubilized soybean membranes.

High-affinity binding of a synthetic heptaglucoside and fungal glucan phytoalexin elicitors to soybean membranes

Soybean membranes possess high-affinity binding sites for fungal beta-glucans that elicit phytoalexin synthesis. The ability of 1,3-1,6-beta-glucans, released by acid hydrolysis from mycelial walls of Phytophthora megasperma f.sp. glycinea, to compete for the putative phytoalexin elicitor receptors increases with their average degree of polymerization (DP). The results suggest a function where the probability for glucan fragments of containing a structural determinant that is optimal for binding approaches 1 as the DP tends to infinity. Ligand displacement data obtained against a 125I-labeled glucan elicitor (average DP = 18) provided a theoretical minimum IC50 (50% inhibitory concentration) for 1,3-1,6-beta-glucans of 3 nM. The IC50 value obtained for a synthetic hepta-beta-glucoside having a known elicitor-active structure was 8 nM, remarkably close to the predicted value. Displacement of the 125I-glucan of large DP was uniform and complete showing that the heptaglucoside had access, with similar affinity, to all sites available to the radioligand. Further analysis using a 125I-labeled aminophenethylamine derivative of the heptaglucoside suggested that the putative glucan-elicitor receptors bind a basic structural determinant present in all elicitor-active glucans from the soybean pathogen P. megasperma.

Solubilization of soybean membrane binding sites for fungal beta-glucans that elicit phytoalexin accumulation

Soybean membranes contain high-affinity binding sites for fungal beta-glucans. These sites may play a role in the recognition by soybean tissues of fungal phytoalexin elicitors. We have solubilized beta-glucan-binding activity from microsomal membranes using two C12-alkyl zwitterionic detergents, Zwittergent 3-12 (ZW 3-12) and the lysolecithin analog 1-dodecanoyl propanediol-3-phosphorylcholine [corrected] (ES12H). The solubilized binding sites displayed identical affinity for beta-glucans as that found in membranes (KD = 11-34 nM). Detergent-protein micelles with glucan binding activity eluted with approximate Mr values of 300,000 in ZW 3-12 and 380,000 in ES12H in gel permeation chromatography. Maximal binding activity eluted from a chromatofocusing column in the pH range between 6.2 and 6.6 with both ES12H and ZW 3-12, suggesting an apparent pI close to neutral.

An endogenous factor from soybean (Glycine max L.) cell cultures activates phosphorylation of a protein which is dephosphorylated in vivo in elicitor-challenged cells

The existence of specific binding sites for a β-glucan elicitor of phytoalexin synthesis derived from the fungus Phytophthora megasperma f.sp. glycinea at the plasma membrane of soybean (Glycine max L.) tissues (W.E. Schmidt, J. Ebel (1987) Proc. Natl. Acad. Sci. USA 84, 4117-4121) might imply that stimulation of phytoalexin formation by the elicitor is a membrane-mediated process. Addition of the β-glucan elicitor to soybean cellsuspension cultures, which has previously been shown to induce phytoalexin accumulation, also results in rapid changes in the phosphate turnover of several phosphoproteins. The effect of the elicitor on protein phosphorylation was tested after labeling of the cells with [(32)P]orthophosphate. As shown by analysis using one-and two-dimensional gel electrophoresis, decreases as well as increases in the labeling of several phosphoroteins occurred rapidly, being detectable within 5 min after elicitor application, and persisted for at least 15 min. As judged by their relative molecular masses (Mr) and isoelectric points (pI), a number of proteins which were radioactively labeled in vivo were also phosphorylated in vitro by endogenous protein-kinase activity in the presence of Ca(2+). The most pronounced effect was observed with a protein substrate with Mr=69000 and pI=5.7 (pp69) whose phosphate labeling markedly decreased in response to elicitor treatment in vivo. Phosphorylation of pp69 in vitro in the presence of γ-[(32)P]ATP was strongly enhanced by a phosphorylation-stimulating factor (effector) derived from soybean cell cultures and occurred predominantly at serine residues. The effector possessed a low apparent Mr (≤1000), was negatively charged at pH 7.3, and was relatively heat stable. The effector was inactivated by treatment with alkaline phosphatase from calf intestine. Phosphorylation of pp69 was only slightly stimulated by Ca(2+), and was insensitive to cAMP, cGMP, calmodulin, a lipid mixture, a ganglioside mixture, or spermine under the assay conditions used. A 10 mM concentration of 3-phosphoglycerate increased pp69 phosphorylation to the extent of about 50% of that induced by the soybean effector. There was no evidence, however, that such concentrations of 3-phosphoglycerate occurred in effector preparations. The results are discussed in relation to hypothetical signal transduction during elicitor action on soybean cells.