Elicitors and suppressors of hydroxyproline-rich glycoprotein accumulation are solubilized from plant cell walls by endopolygalacturonase.

Treatment of bean cell walls with a pure endopolygalacturonase of the bean pathogen Colletotrichum lindemuthianum race beta released oligogalacturonides and pectic fragments which were separated according to their charge and size. Among galacturonic-acid-containing components, elicitors and suppressors of the plant cell wall hydroxyproline-rich glycoprotein (HRGP) were recovered. Two active small oligogalacturonides with degrees of polymerization of 2 and 3 were characterized by high-performance anion-exchange-chromatography pulsed amperometric detection and fast-atom-bombardment mass spectrometry; they elicited 40-70% hydroxyproline increase within 48 hours at 450 nmol/bean cutting. In contrast, pectic fragments of higher molecular mass, predominantly composed of galacturonic acid and containing sugars typical of the rhamnogalacturonan II domain of pectic polysaccharides, had the ability to substantially suppress hydroxyproline deposition. Maximum suppressor activity, 30-40% below the activity of the control, occurred in 48 hours. In view of the low one-cycle turnover of these proteins in the cell wall and of their structural role, these changes might significantly affect cell wall properties. Elicitation and/or suppression of hydroxyproline were correlated to modifications of HRGP-extensin gene expression. Northern-blot analysis of RNA showed that changes in the transcript intensity became clearly visible within the first 12 hours after the start of either treatment. The results show that pectic components of the plant extracellular matrix have the potential to regulate wall matrix biogenesis. Implications of this finding in plant defense and development are discussed.

Purification and characterization of two basic beta-1,3-glucanases induced in Colletotrichum lindemuthianum-infected bean seedlings.

Two beta-1,3-glucanases which are rapidly induced in the incompatible interaction between bean (cv. Processor) and Colletotrichum lindemuthianum race beta were purified to homogeneity. Characterization of the two enzymes, GE1 and GE2, showed that they both had a basic isolectric point and a similar molecular weight (36,500 for GE1 and 36,000 for GE2), but differed in their pH optimum, thermal stability, and specific activity. GE2 was present in higher amounts but was shown to be less active than GE1 against laminarin and fungal cell walls isolated from race beta of the fungus. Both enzymes were specific for beta-1,3 linkages and showed a strict endolytic mode of action. Further characterization of GE2 was achieved by amino acid sequence analysis of tryptic peptides; the degree of homology shared with other basic beta-1,3-glucanases depended on the plant source. A time-course study showed that GE1 and GE2 were increased during infection. They were also induced by fungal elicitors, thereby indicating that they originate from the host.

Cell Surface Interactions between Bean Leaf Cells and Colletotrichum lindemuthianum: Cytochemical Aspects of Pectin Breakdown and Fungal Endopolygalacturonase Accumulation.

After a brief period of biotrophic growth, the anthracnose fungus Colletotrichum lindemuthianum (Sacc. et Mgn.) Bri et Cav. develops extensively in bean leaf cells, causing severe wall alterations and death of the host protoplast. Aplysia gonad lectin, a polygalacturonic acid-binding agglutinin, was complexed to gold and used to study the extent of pectin breakdown during the necrotrophic phase of the infection process. In view of its specific binding properties for the endopolygalacturonase produced by C. lindemuthianum, a polygalacturonase-inhibiting protein isolated from bean cell walls was successfully tagged with gold particles and used for localizing the sites of enzyme accumulation in infected host tissues. The basal level of endopolygalacturonase produced by C. lindemuthianum grown in culture was found to increase severalfold when the fungus developed in host plant tissues. The enzyme was able to diffuse freely in the host cell wall, causing drastic degradation of the pectic material of primary walls and middle lamella matrices. The enzymatic alteration of plant cell walls was accompanied by the release of pectic fragments and by the accumulation of pectic molecules at specific sites, such as intercellular spaces and aggregated cytoplasm of infected host cells. The occurrence of pectic molecules at those sites where fungal growth is likely to be restricted is discussed in relation to their origin and their implication in the plant's defense system.

[Primary intestinal lymphangiectasis or Waldmann's disease (author's transl)]. / Lymphangiectasie intestinale primitive ou maladie de Waldmann.

The authors report the observation of a primary intestinal lymphangiectasy diagnosed on a young girl sent for isolated edema of her inferior members, recently appeared. Clinical examination was normal. Biology found a low protein rate at 33 g/l and a low lymph rate : 183 L/mm3. Hepatic and renal records were normal. Test to marked albumin asserted the exsudative enteropathy with a fecal radio-activity of 3.6% (N 1%). Biopsy of the small intestines set out lymphangiectasies of the intestinal mucosa. Referring to this observation and to literature date, the authors realise a clinical and physiopathological analysis of Waldmann's disease or primary intestinal lymphangiectasy.

Mise en evidence par focalisation isoelectrique de trois isoenzymes de la polyphenoloxydase chez Quercus pedunculata Ehrh.

Electrofocusing procedure resolves phenolase of oak's bark in three distinct major isozymes showing cresolase and catecholase activities. Their pI are: 6, 7.8 and 8.2. Little change in ratio of the two activities occurs during isoelectric separation. The ultracentrifuged isozymes exhibit sedimentation constant similar to the crude enzyme phenolase.