Terrence L. Graham

Bio: Terrence L. Graham is an academic researcher from Ohio State University. The author has contributed to research in topics: Phytophthora sojae & Glyceollin. The author has an hindex of 18, co-authored 25 publications receiving 2028 citations.

Flavonoid and isoflavonoid distribution in developing soybean seedling tissues and in seed and root exudates.

Abstract: The distribution of flavonoids, isoflavonoids, and their conjugates in developing soybean (Glycine max L.) seedling organs and in root and seed exudates has been examined. Conjugates of the isoflavones daidzein and genistein are major metabolites in all embryonic organs within the dry seed and in seedling roots, hypocotyl, and cotyledon tissues at all times after germination. Primary leaf tissues undergo a programmed shift from isoflavonoid to flavonoid metabolism 3 days after germination and become largely predominated by glycosides of the flavonols kampferol, quercetin, and isorhamnetin by 5 days. Cotyledons contain relatively constant and very high levels of conjugates of both daidzein and genistein. Hypocotyl tissues contain a third unidentified compound, P19.3, also present in multiple conjugated forms. Conjugates of daidzein, genistein, and P19.3 are at their highest levels in the hypocotyl hook and fall off progressively down the hypocotyl. These isoflavones also undergo a programmed and dramatic decrease between 2 and 4 days in the hypocotyl hook. All root sections are predominated by daidzein and its conjugates, particularly in the root tip, where they reach the highest levels in the seedling. Light has a pronounced effect on the distribution of the isoflavones; in the dark, isoflavone levels in the root tips are greatly reduced, while those in the cotyledons are higher. Finally, the conjugates of daidzein and genistein and several unidentified aromatic metabolites are selectively excreted into root and seed exudates. Analysis of seed exudates suggests that this is a continuous, but saturable event.

RNA interference of soybean isoflavone synthase genes leads to silencing in tissues distal to the transformation site and to enhanced susceptibility to Phytophthora sojae.

Abstract: Isoflavones are thought to play diverse roles in plant-microbe interactions and are also potentially important to human nutrition and medicine. Isoflavone synthase (IFS) is a key enzyme for the formation of the isoflavones. Here, we examined the consequences of RNAi silencing of genes for this enzyme in soybean (Glycine max). Soybean cotyledon tissues were transformed with Agrobacterium rhizogenes carrying an RNAi silencing construct designed to silence expression of both copies of IFS genes. Approximately 50% of emerging roots were transformed with the RNAi construct, and most transformed roots exhibited >95% silencing of isoflavone accumulation. Silencing of IFS was also demonstrated throughout the entire cotyledon (in tissues distal to the transformation site) both by high-performance liquid chromatography analysis of isoflavones and by real-time reverse transcription-PCR. This distal silencing led to a nearly complete suppression of mRNA accumulation for both the IFS1 and IFS2 genes and of isoflavone accumulations induced by wounding or treatment with the cell wall glucan elicitor from Phytophthora sojae. Preformed isoflavone conjugates were not reduced in distal tissues, suggesting little turnover of these stored isoflavone pools. Distal silencing was established within just 5 d of transformation and was highly efficient for a 3- to 4-d period, after which it was no longer apparent in most experiments. Silencing of IFS was effective in at least two genotypes and led to enhanced susceptibility to P. sojae, disrupting both R gene-mediated resistance in roots and nonrace-specific resistance in cotyledon tissues. The soybean cotyledon system, already a model system for defense signal-response and cell-to-cell signaling, may provide a convenient and effective system for functional analysis of plant genes through gene silencing.

Role of constitutive isoflavone conjugates in the accumulation of glyceollin in soybean infected with Phytophthora megasperma.

Abstract: These results suggest that 1) glyceollin biosynthesis may not be solely dependent on the induction of enzymes of early phenylpropanoid and flavonoid metabolism in this organ and 2) resistance to P. m. f. sp. glycinea race 1, as defined by the Rps 1 c gene in this organ, may reside partly in the rapid release of the isoflavone aglycones from their conjugates and/or in the later steps of glyceollin biosynthesis

Rapid Accumulation of Anionic Peroxidases and Phenolic Polymers in Soybean Cotyledon Tissues following Treatment with Phytophthora megasperma f. sp. Glycinea Wall Glucan

Abstract: Phytophthora megasperma Drechs. f. sp. glycinea Kuan & Erwin (PMG) cell wall glucan has been extensively characterized as an elicitor of the pterocarpan phytoalexins, the glyceollins in soybean (Glycine max L.). Just recently, this glucan was shown to be a potent elicitor of conjugates of the isoflavones, daidzein and genistein as well. Here we report that PMG wall glucan also induces a rapid and massive accumulation of phenolic polymers in soybean cotyledon cells proximal to the point of elicitor application. Deposition of phenolic polymers is over then times that in wounded controls within just 4 hours of elicitor treatment and reaches a maximum by 24 hours. In the same tissues, isoflavone conjugates begin to accumulate at 8 hours and glyceollin at 12 hours. By 24 hours, the total deposition of wall bound phenolics in elicitor-treated tissues is several times greater than the peak glyceollin and isoflavone responses combined. Histochemical stains and quantitation of phenolic residues released after saponification and nitrobenzene or copper oxide oxidation suggest that the covalently linked phenolics include both lignin- and suberin-like polymers as well as simple esterified coumaric and ferulic acid monomers. Accumulations of phenolic polymers are accompanied by equally rapid and massive increases in activity of a specific group of anionic peroxidases. Although increases in peroxidase activity are not strictly limited to cells immediately adjacent to the area of elicitor treatment, the deposition of phenolic polymers is significantly less extensive in distal cells.

Signaling in Soybean Phenylpropanoid Responses (Dissection of Primary, Secondary, and Conditioning Effects of Light, Wounding, and Elicitor Treatments)

Abstract: The spatial and temporal deployment of plant defense responses involves a complex interplay of signal events, often resulting in superimposition of signaling processes. We have employed a minimal-wound protocol to clearly separate and characterize the specific contributions of light, wounding, and a wall glucan elicitor preparation (PWG) from Phytophthora sojae (Kauf. and Gerde.) to the regulation of phenylpropanoid defense responses in soybean (Glycine max L. [Merr.]) cotyledon tissues. The assay also allowed us to clearly reconstitute responses to combinations of these primary signals and to examine the effects of other pathogenesis-related molecules on the responses in a defined manner. Light specifically triggers accumulation of malonylglucosyl conjugates of the 5-hydroxy-isoflavone, genistein, which is normally found in epidermal cells. PWG selectively induces accumulation of conjugates of the 5-deoxy-isoflavone daidzein, the first committed precursor of the phytoalexin glyceollin. Wounding initiates phenolic polymer deposition, a process greatly potentiated by PWG and light. Whereas glutathione selectively enhances light induction of genistein conjugates, methyl jasmonate enhances both light and PWG-induced isoflavone conjugate accumulations. Wound exudate fully activates the cell's capacity (competency) for the phenolic polymer and glyceollin responses to PWG, whereas glutathione partially restores competency, favoring coumestrol and phenolic polymer responses to PWG. Abscisic acid inhibits all induced phenylpropanoid responses.

Stress-Induced Phenylpropanoid Metabolism.

Abstract: Phenylpropanoid compounds encompass a wide range of structural classes and biological functions. Limiting discussion to stress-induced phenylpropanoids eliminates few of the structural classes, because many compounds thst are constitutive in one plant species or tissue can be induced by various stresses in another species or in another tissue of the same plant (Beggs et al., 1987; Christie et al., 1994).

Secondary metabolites in plant defence mechanisms

Abstract: SUMMARY Many secondary metabolites found in plants have a role in defence against herbivores, pests and pathogens. In this review, a few examples are described and discussed, and some of the problems in determining the precise role(s) of such metabolites highlighted. The role of secondary metabolites in defence may involve deterrence/anti-feedant activity, toxicity or acting as precursors to physical defence systems. Many specialist herbivores and pathogens do not merely circumvent the deterrent or toxic effects of secondary metabolites but actually utilize these compounds as either host recognition cues or nutrients (or both). This is true of both cyanogenic glucosides and glucosinolates, which art discussed in detail as examples of defensive compounds. Their biochemistry is compared and contrasted. An enormous variety of secondary metabolites are derived from shikimic acid or aromatic amino acids, many of which have important roles in defence mechanisms. Several classes of secondary products are ‘induced’ by infection, wounding or herbivory, and examples of these are given. Genetic variation in the speed and extent of such induction may account, at least in part, for the difference between resistant and susceptible varieties. Both salicylates and jasmonates have been implicated as signals in such responses and in many other physiological processes, though their prescise roles and interactions in signalling and development are not fully understood.

Environmental Significance of Anthocyanins in Plant Stress Responses

Abstract: — Anthocyanins are water-soluble pigments found in all plant tissues throughout the plant kingdom. Our understanding of anthocyanin biosynthesis and its molecular control has greatly improved in the last decade. The adaptive advantages of anthocyanins, especially in non-reproductive tissues, is much less clear. Anthocyanins often appear transiently at specific developmental stages and may be induced by a number of environmental factors including visible and UVB radiation, cold temperatures and water stress. The subsequent production and localization of anthocyanins in root, stem and especially leaf tissues may allow the plant to develop resistance to a number of environmental stresses. This article reviews the environmental induction of anthocyanins and their proposed importance in ameliorating environmental stresses induced by visible and UVB radiation, drought and cold temperatures.

Phenolic Compounds and Their Role in Disease Resistance

Abstract: Antibiotic phenols have been found in all plants investigated to date. Some occur constitutively and are thought to function as preformed inhibitors associated with nonhost resistance (84, 94, 128, 134). Others, which are the subject of this review, are formed in response to the ingress of pathogens, and their appearance is considered as part of an active defense response. Since the first suggestions that phenolic intermediates have a role in the active expres­ sion of resistance, an underlying problem in ascertaining that such secondary metabolites are of primary (rather than secondary) importance has been the localization and timing of the host response. In this review we address the problem of response localization and localization of phenolics relative to the sequential development of stages of disease that lead ultimately to resistance expression. Initial demonstrations that phenols are significant components of the host