Enzymatic synthesis of lignin: purification to homogeneity of the three O-methyltransferases of tobacco and production of specific antibodies

Three o-diphenol-O-methyltransferases (OMTs; EC 2.1.1.6) involved in the biosynthesis of lignin have been purified to homogeneity from tobacco leaves. Seven different fractionation steps which included (NH4)2 SO4 precipitation, conventional low-pressure chromatography on Ultrogel AcA34 and DEAE-cellulose columns, high-performance liquid chromatography (HPLC) on three different supports (Mono Q, Mono P, and TSK G-3000 SW columns), and finally preparative electrophoresis were necessary. At each step of purification, the protein content of the enzymatic fractions was analyzed by electrophoresis on polyacrylamide gels under denaturing conditions. Purified OMT I appeared on sodium dodecyl sulfate-polyacrylamide gel as a doublet with electrophoretic mobilities corresponding to molecular weights of 38,500 +/- 2000 and 39,500 +/- 2000. The other two enzymes migrated as single but rather broad bands with molecular weights of 42,000 (OMT II) and 43,000 (OMT III). Polyclonal antibodies were raised in rabbits. The titers of antibodies were measured by an indirect enzyme-linked immunosorbent assay method, and their specificity was demonstrated by immunoblotting enzyme preparations at different stages of purification. Immunodetection of the three enzymes with a specific antiserum suggested serological relationships between the three OMTs of tobacco.     

O-diphenol O-methyltransferases of healthy and tobacco-mosaic-virus-infected hypersensitive tobacco

Three distinct o-diphenol O-methyltransferases (OMTs) were found in leaves of Nicotiana tabacum, variety Samsun NN. They could be clearly distinguished by differences in elution pattern upon chromatography on DEAE-cellulose and in specificity towards 16 diphenolic substrates. The phenylpropanoids caffeic acid and 5-hydroxyferulic acid, whose importance as lignin precursors is well known, were the best substrates of OMT I, but they were also efficiently methylated by the two other OMTs that showed a broader substrate specificity. The highest rates of methylation were observed by assaying these latter enzymes with catechol, homocatechol and protocatechuic aldehyde. The flavonoid quercetin, the major o-diphenol of tobacco leaves, was a good substrate for OMTs II and III, but was also methylated significantly by OMT I. The tobacco OMTs showed both para-and meta-directing activities with protocatechuic acid, protocatechuic aldehyde and esculetin as substrates. Para-O-methylation of the former substrate arose almost exclusively from OMT I whereas that of the two latter substrates from all three enzymes. In healthy leaves the total O-methylating activity varied very much with the batch of plants whereas the relative contributions of the three enzymes were rather constant. On an average, OMTs I, II and III acounted towards caffeic acid, respectively. In tobacco mosaic virus-infected leaves carrying local necrotic lesions we found the same three OMTs with the same substrate specificities, but with increased activities. The degree of stimulation of both OMTs II and III was 2–3 times greater than that of OMT I when the leaves had a moderate number of lesions, and 3–5 times greater with large number of lesions. It is very likely that the changes in both the pattern of the O-methylating enzymes and the concentrations of the naturally occuring o-diphenolic substrates are related to an increased biosynthesis of lignins and of lignin-like compounds. These aromatic polymers could be involved in the cell wall thickening associated with the hypersensitive reaction and with the resistance to virus spread that occur in the cells surrounding the local lesions.Abbreviations OMT O-methyltransferase - TMV tobacco mosaic virus - SAM S-adenosyl-L-methionine     

Phenylalanine ammonia-lyase in tobacco mosaic virus-infected hypersensitive tobacco. Density-labelling evidence of de novo synthesis.

A strong increase in phenylalanine ammonia-lyase (EC 4.3.1.5) activity occurs in tobacco mosaic virus-infected tobacco leaves developing necrotic local lesions. Comparison of physicochemical properties of the partially purified enzymes extracted from healthy and infected leaves showed that the hypersensitive reaction leads to an increase in the pool size of the same active enzyme molecules as those present in non-infected material. The molecular mechanism of enzyme formation was investigated by radiolabelling with [3H]leucine and by density labelling with 2H2O. Abnormal patterns of incorporation of radioactivity into all soluble proteins were found in infected leaves carrying local lesions. In contrast, uptake of deuterium into the amino acid pool was the same in healthy and infected leaves. Unstimulated phenylalanine ammonia-lyase was shown to be a long-lived enzyme (half-life: 25-35 h). Results of comparative density labelling experiments unequivocally demonstrated that the increased enzyme pool size arose from an increased rate of synthesis mediated by the hypersensitive reaction.     

Plant disease and the regulation of enzymes involved in lignification

Tobacco varieties carrying the N gene from Nicotiana glutinosa respond to infection by Tobacco Mosaic Virus (TMV) by forming necrotic local lesions (hypersensitive reaction), thereby localizing the infection. In this study, infected mesophyll leaf tissue of N. tabacum Samsun NN was treated with the non-permeating, non-metabolizable carbohydrate mannitol. The local lesions developed under iso-osmotic conditions (0.28 M mannitol), though with a slight delay and with a reduced rate of growth, as compared to those on attached leaves. At increasing plasmolysing concentrations of mannitol, necrotization was progressively inhibited, but not completely suppressed. The leaf tissue produced tiny translucent zones, with a delay that increased between the virus inoculation and application of the plasmolytica. Activities of phenylalanine ammonia-lyase (PAL, EC 4.3.1.5) and O-methyltransferase (OMT, EC 2.1.1.6) are strongly stimulated in hypersensitively reacting tobacco and were used as biochemical markers in the present study. This study was done to determine whether the inhibitory effect of plasmolysis on the elicitation of the hypersensitive response is due to a decrease in virus spread, resulting from the rupture of plasmodesmata or, at least in part, to metabolic alterations of the host cell exposed to osmotic stress. Since necrotization is normally preceded by intense virus multiplication, the inhibitory effects found for early applications (i.e., before local lesion appearance) of plasmolytica could easily be related to an inhibition of virus spread which also occurred in similarly treated leaf tissue of the systemically reacting variety Samsun. The most meaningful data were obtained from mannitol treatments performed on leaf tissue already carrying local lesions, i.e., in which the elicitor(s) and/or the factor(s) of necrotization were already operating. Under iso-osmotic conditions, we found the stimulated PAL and OMT activities characteristic of the hypersensitive response. At plasmolysing concentrations of mannitol, we observed the counteracting effects of two different mechanisms controlling the phenylpropanoid enzymes. Floating the leaf material on the liquid medium induced an ageing-like effect with a continuous increase in enzyme activities that was independent on osmotic pressure and sensitive to cycloheximide. At the same time, the stimulated enzyme activities related to hypersensitivity decreased at a rate related to osmotic pressure. Since PAL and OMT of tobacco leaves are long-lived enzymes, it is likely that the increased de novo synthesis of the enzymes was suppressed by plasmolysis while their degradation and/or inactivation was maintained or even increased. From these results it is concluded that the apparent inhibition of the hypersensitive response by plasmolysis is due to both a decrease in virus spead (artificially caused by the rupture of connections between cells) and to drastic metabolic alterations of the host cell exposed to high osmotic pressure.     

Biological and molecular comparison between localized and systemic acquired resistance induced in tobacco by a Phytophthora megasperma glycoprotein elicitin

We have compared localized (LAR) and systemic (SAR) acquired resistance induced in tobacco by a hypersensitive response (HR) inducing Phytophthora megasperma glycoprotein elicitin. Three different zones were taken into account: LAR, SAR_T and SAR_S. The LAR zone was 5–10 mm wide and surrounded the HR lesion. SAR_T was the tissue of the elicitor-treated leaf immediately beyond the LAR zone. The systemic leaf was called SAR_S. Glycoprotein-treated plants showed enhanced resistance to challenge infection by tobacco mosaic virus (TMV). Disease resistance was similar in SAR_T and SAR_S, and higher in LAR. The expression pattern, in glycoprotein-treated plants, of acidic and basic PR1, PR2, PR3 and PR5 proteins and of O-methyltransferases (OMT), enzymes of the phenylpropanoid pathway, was similar to that in TMV-infected plants. OMT was stimulated in LAR but not in SAR_T and SAR_S. The four classes of acidic and basic PR proteins accumulated strongly in LAR. Reduced amounts of acidic PR1, PR2, PR3 and only minute amounts of basic PR2 and PR3 accumulated in SAR_T and SAR_S. In glycoprotein-treated plants, expression of the acidic and basic PR proteins in LAR and SAR of transgenic NahG and ETR tobacco plants and in LAR of plants treated with inhibitors of salicylic acid accumulation and of ethylene biosynthesis indicated a salicylic acid-dependent signalling pathway for acidic isoform activation and an ethylene-dependent signalling pathway for basic isoform activation.     

A pharmacological approach to test the diffusible signal activity of reactive oxygen intermediates in elicitor-treated tobacco leaves

The capacity of H(2)O(2), the most stable of the reactive oxygen species (ROI), to diffuse freely across biological membranes and to signal gene expression suggests that H(2)O(2) could function as a short-lived second messenger diffusing from cell to cell. We tested this hypothesis in tobacco plants treated with a glycoprotein elicitor. Applied at 50 nM, it induces H(2)O(2) accumulation and the hypersensitive response restricted to the infiltrated zone 1 tissue. Stimulation of a set of defense responses also occurs in the surrounding zone 2 tissue without diffusion of the elicitor. ROI levels in zone 1 were modulated using N-acetyl-L-cysteine (NAC) as a ROI scavenger and Rose Bengal (RB) as a ROI generator. We found that ROI appeared to act as signalling intermediates in pathways leading to salicylic acid accumulation, to PR1, PR5 and 3-hydroxy-3-methylglutarylCoA reductase expression in glycoprotein-treated zone 1 tissues. Compared to the treatment with the elicitor alone, co-infiltration of the glycoprotein and NAC increased the surface of zone 2 showing PR1 and O-methyltransferase expression. Application of RB had the opposite effect. The data suggest that, in our system, ROI did not act as a cell-to-cell diffusible signal to activate PR protein and O-methyltransferase expression in zone 2.     

Plant Disease and the Regulation of Enzymes Involved in Lignification: Increased Rate of De Novo Synthesis of the Three Tobacco O-Methyltransferases during the Hypersensitive Response to Infection by Tobacco Mosaic Virus

The mechanism underlying the increase of activity of the three O-methyltransferases of tobacco (Nicotiana tabacum) after infection by tobacco mosaic virus (TMV) has been investigated with a density-labeling method. The three O-methyltransferases from healthy or TMV-infected leaves fed with H₂O or ²H₂O were purified by ion-exchange chromatography and their mean buoyant densities were calculated from their respective distribution profiles after centrifugation to equilibrium on RbCl gradients. Densities were corrected with respect to the mean buoyant density of a radioactive density marker prepared from tobacco leaves floated on a solution containing l-[³H]leucine and selected on a preparative gradient for its density close to those of the O-methyltransferases. The introduction of ²H into the pool of amino acids from which the enzymic proteins were synthesized was monitored. By measurement of the labeling of β-galactosidase synthesized by bacteria from the plant amino acids, it was shown that infection did not alter the rate of labeling of the pool of amino acids. The buoyant-density values of the three O-methyltransferases were determined, and density-labeled enzymes from healthy and infected materials were compared. The largest density shifts from the native enzyme were measured for O-methyltransferases from infected leaves. These results show that the increase in activity of the three enzymes after infection is due to the stimulation of the rate of de novo synthesis of enzyme proteins.