Several biotic and abiotic elicitors act synergistically in the induction of phytoalexin accumulation in soybean

Summary Plants often respond to microbial infection by producing antimicrobial compounds called phytoalexins. Plants also produce phytoalexins in response to in vitro treatment with molecules called elicitors. Specific elicitors, including a hexa--glucosyl glucitol derived from fungal cell walls, the pectin-degrading enzyme endopolygalacturonic acid lyase, and oligogalacturonides obtained by either partial acid hydrolysis or enzymatic degradation of plant cell walls or citrus polygalacturonic acid, induce soybean (Glycine max. L.) cytoledons to accumulate phytoalexins. The experiments reported here demonstrate that the elicitor-active hexa--glucosyl glucitol acts synergistically with several biotic and abiotic elicitors in the induction of phytoalexins in soybean cotyledons. At concentrations below 50 ng/ml, the hexa--glucosyl glucitol does not induce significant phytoalexin accumulation. When assayed in combination with either endopolygalacturonic acid lyase or with a decagalacturonide released from citrus polygalacturonic acid by this lyase, however, the observed elicitor activity of the hexa--glucosyl glucitol is as much as 35-fold higher than the sum of the responses of these elicitors assayed separately. A similar synergism was also demonstrated for the combination of the hexa--glucosyl glucitol with dilute solutions of sodium acetate, sodium formate, or sodium propionate buffers. These buffers are thought to damage or kill plant cells, which may cause the release of oligogalacturonides from the plant cell wall. The results suggest that oligogalacturonides act as signals of tissue damage and, as such, can enhance the response of plant tissues to other elicitor-active molecules during the initiation of phytoalexin accumulation.Supported by the United States Department of Energy DE-ACO2-84ER13161. This paper is number XXXI in a series, Host-Pathogen Interactions. The preceding paper, Host-Pathogen Interactions XXX is Characterization of elicitors of phytoalexin accumulation in soybean released from soybean cells by endopolygalacturonic acid lyase, by K. R. Davis, A. G. Darvill, P. Albersheim, and A. Dell. Zeitschrift für Naturforsschung, in press.     

Rhizosphere salinity and phytoalexin accumulation in soybean

Summary Rhizosphere salinity decreased the capacity of soybean to accumulate a pterocarpanoid phytoalexin (glyceollin) in the stem in response toPhytophthora megasperma var.sojae. Rapid (48h) accumulation was depressed by NaCl, Na₂SO₄, CaCl₂ and MgSO₄ applications. Time-course accumulations was slowed by applications. Time-course accumulation was slowed by application of 0.131M NaCl. Glyceollin accumulation was also reduced in plants subjected to a period of high salinity stress (0.177M NaCl, 72 h) after a period of nonsalinized growth. Calcium chloride completely suppressed glyceollin accumulation in normally-resistant plants but no susceptibility to the fungus was observed.     

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.     

A receptor on soybean membranes for a fungal elicitor of phytoalexin accumulation

Soybean membrane preparations specifically bound [¹⁴C]mycolaminaran, a branched β-1,3-glucan produced by Phytophthora sp. which elicits production of the phytoalexin glyceollin in soybean tissues. A Scatchard plot of the binding data disclosed the presence of a single affinity class of binding sites with a K_d value of 11.5 micromolar for the glucan. To assess the physiologic importance of mycolaminaran binding in phytoalexin elicitation, several derivatives of mycolaminaran were prepared. Reduced mycolaminaran had slightly greater elicitor activity and binding affinity than the native substance, while periodinated mycolaminaran was virtually devoid of either elicitor activity orbinding capability. Phosphorylated mycolaminaran, on the other hand, gave values for both elicitor activity and membrane binding which were intermediate between the native and periodinated preparations. No other tested carbohydrates competed with the binding of [¹⁴C]mycolaminaran. Soybean membrane preparations contained β-1,3-endoglucanase activity that degraded mycolaminaran and reduced both its efficiency as a phytoalexin elicitor and its membrane binding at temperatures above 0°C. Once [¹⁴C]mycolaminaran bound to membranes, however, it was not appreciably susceptible to glucanase attack and could not be displaced with excess unlabeled ligand. Taken collectively, the observations suggest that the membrane binding sites are mycolaminaran-specific receptors which are physiologically involved in the initiation of phytoalexin production in soybean cotyledons. Because the binding of mycolaminaran to membranes was abolished by heat and proteolytic enzymes, the receptor is probably a protein(s) or glycoprotein(s).     

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.     

Investigation of the mechanism of phytoalexin accumulation in soybean induced by glucan or mercuric chloride

Soybean cotyledons which had been treated with glucan from Phytophthora megasperma f.sp. glycinea or with mercuric chloride were pulse-labeled with ¹⁴CO₂ and then the ¹⁴C-incorporation into the phytoalexins was determined. The kinetics of ¹⁴C-incorporation into phytoalexins (glyceollin isomers and 3,6α,9-trihydroxypterocarpan) was very similar with the two types of elicitors. Metabolic rates of phytoalexins were determined by pulse-chase experiments. The apparent half-life of metabolism was about 100 h for glyceollin with either glucan or HgCl₂. The half-lives for trihydroxypterocarpan were 39 h with glucan and 14 h with HgCl₂. According to our results levels of glyceollins in soybean cotyledons are mainly controlled by their rates of synthesis. Biotic (glucan) and abiotic (HgCl₂) elicitors have similar induction effects. Both types of elicitors could act by effecting the release of endogenous elicitors.     

A comparison of the sites of phytoalexin accumulation and of biosynthetic activity in potato tuber tissue inoculated with biotic elicitors

Aged discs cut from Kennebec potato tubers were inoculated with one of the following: an elicitor preparation from mycelia of Phytophthora infestans race 4, zoospores from either race 4 or race TY complex of this fungus, or sodium arachidonate. At 24 hr intervals after inoculation, four successive 0.5 mm thick layers of tissue were cut from the discs. This tissue was analysed for accumulated phytoalexins and also used to prepare cell-free enzyme systems for lubimin biosynthesis. In tissue treated with either the elicitor preparation or race 4 zoospores, levels of phytoalexin accumulation were highest in the first layer of tissue. Surprisingly, however, cell-free lubimin biosynthesis from [1-¹⁴C]isopentenyl pyrophosphate was also generally greater in preparations derived from the first 0.5 mm of tissue. Accumulation of phytoalexins in tissue inoculated with zoospores from race TY complex was very low, whereas cell-free biosynthetic activity was initially comparable to that seen in preparations from tissue treated with the elicitor preparation. By the end of the experimental period lower layers of tissue from discs treated with sodium arachidonate contained the highest levels of phytoalexins and yielded cell-free enzyme preparations with the greatest lubimin biosynthetic activity.     

Nitric oxide synthase-mediated phytoalexin accumulation in soybean cotyledons in response to the Diaporthe phaseolorum f. sp. meridionalis elicitor

Phytoalexin biosynthesis is part of the defense mechanism of soybean (Glycine max) plants against attack by the fungus Diaporthe phaseolorum f. sp. meridionalis (Dpm), the causal agent of stem canker disease. The treatment of soybean cotyledons with Dpm elicitor or with sodium nitroprusside (SNP), a nitric oxide (NO) donor, resulted in a high accumulation of phytoalexins. This response did not occur when SNP was replaced by ferricyanide, a structural analog of SNP devoid of the NO moiety. Phytoalexin accumulation induced by the fungal elicitor, but not by SNP, was prevented when cotyledons were pretreated with NO synthase (NOS) inhibitors. The Dpm elicitor also induced NOS activity in soybean tissues proximal to the site of inoculation. The induced NOS activity was Ca(2+)- and NADPH-dependent and was sensitive to the NOS inhibitors N(G)-nitro-L-arginine methyl ester, aminoguanidine, and L-N(6)-(iminoethyl) lysine. NOS activity was not observed in SNP-elicited tissues. An antibody to brain NOS labeled a 166-kD protein in elicited and nonelicited cotyledons. Isoflavones (daidzein and genistein), pterocarpans (glyceollins), and flavones (apigenin and luteolin) were identified after exposure to the elicitor or SNP, although the accumulation of glyceollins and apigenin was limited in SNP-elicited compared with fungal-elicited cotyledons. NOS activity preceded the accumulation of these flavonoids in tissues treated with the Dpm elicitor. The accumulation of these metabolites was faster in SNP-elicited than in fungal-elicited cotyledons. We conclude that the response of soybean cotyledons to Dpm elicitor involves NO formation via a constitutive NOS-like enzyme that triggers the biosynthesis of antimicrobial flavonoids.     

Potato phytoalexin elicitors in Phytophthora infestans spore germination fluids

Media from germinating spores of Phytophthora infestans contain substances that elicit accumulation of the phytoalexin rishitin in potato tuber slices. Gel permeation chromatography of media extracts indicates the presence of several substancec. The active substances can be precipitated with ammonium sulfate, are heat labile and pronase-sensitive, which suggests that they are proteins.     

Isoflavonoid-inducible resistance to the phytoalexin glyceollin in soybean rhizobia.

The antibacterial effect of the soybean phytoalexin glyceollin was assayed using a liquid microculture technique. Log-phase cells of Bradyrhizobium japonicum and Sinorhizobium fredii were sensitive to glyceollin. As revealed by growth rates and survival tests, these species were able to tolerate glyceollin after adaptation. Incubation in low concentrations of the isoflavones genistein and daidzein induced resistance to potentially bactericidal concentrations of glyceollin. This inducible resistance is not due to degradation or detoxification of the phytoalexin. The inducible resistance could be detected in B. japonicum 110spc4 and 61A101, representing the two taxonomically divergent groups of this species, as well as in S. fredii HH103, suggesting that this trait is a feature of all soybean-nodulating rhizobia. Glyceollin resistance was also inducible in a nodD1D2YABC deletion mutant of B. japonicum 110spc4, suggesting that there exists another recognition site for flavonoids besides the nodD genes identified so far. Exudate preparations from roots infected with Phytophthora megasperma f. sp. glycinea exhibited a strong bactericidal effect toward glyceollin-sensitive cells of B. japonicum. This killing effect was not solely due to glyceollin since purified glyceollin at concentrations similar to those present in exudate preparations had a much lower toxicity. However, glyceollin-resistant cells were also more resistant to exudate preparations than glyceollin-sensitive cells. Isoflavonoid-inducible resistance must therefore be ascribed an important role for survival of rhizobia in the rhizosphere of soybean roots.     

Structure-activity relationships in nitrothiophenes

The structure and electronic properties of a series of biologically active 2-nitrothiophenes (1) have been calculated using both semi-empirical and ab initio molecular orbital methods. Multi-linear regression analysis suggests that there is a reasonable correlation between the experimental activity of the derivatives against either Escherichia coli or Micrococcus luteus and calculated properties such as the HOMO energies, the total atomic charges and ring angles at the heterocyclic sulfur atom, but there is no correlation with the calculated solvation energies or dipole moments. The presence or absence of an additional nitro group at the 3-position of the ring also has a significant effect on the activity. From the derived QSAR equations, the 2-chloro- or 2-bromo-3,5-dinitrothiophenes (1a and 1c) are predicted to show the highest activity against both bacteria, while 2-nitrothiophene (1n) is predicted to be the least active, in line with the experimental results.     

Structure-activity relationships of synthetic diosgenyl diglycosides.

The haemolytic and antifungal activities of six synthetic diosgenyl diglycosides and diosgenyl maltotrioside were compared with each other and with those of the parent glucoside. In general, the haemolytic activity of each of these glycosides was higher than, and the antifungal activity as strong as, that of the glucoside. However, both activities of the lactoside were much lower than those of the others.     

Structure-activity relationships of cytokinins

Structure-activity relationships of cytokinins, which regulate many aspects of plant growth, have been reviewed.