c.i.-fluorescent-brightening-agent-28 and aniline-blue

Fungal cell walls are composed of polysaccharide scaffold that changes in response to environment. The structure and biosynthesis of the wall are unique to fungi, with plant and mammalian immune systems evolved to recognize wall components. Additionally, the enzymes that assemble fungal cell wall components are excellent targets for antifungal chemotherapies and fungicides. Understanding changes in the cell wall are important for fundamental understanding of cell wall dynamics and for drug development. Here we describe a screening technique to monitor the gross morphological changes of two key cell wall polysaccharides of chitin and β-1,3-glucan combined with polymerase chain reaction (PCR) genotyping. Changes in chitin and β-1,3-glucan were detected microscopically by using the dyes calcofluor white and aniline blue. Combining PCR and fluorescence microscopy, as a quick and easy screening technique, confirmed both the phenotype and genotype of the wild-type, h chitin synthase mutants (chs1Δ and chs3Δ) and one β-1,3-glucan synthase mutant fks2Δ from Saccharomyces cerevisiae knockout library. This combined screening method highlighted that the fks1Δ strain obtained commercially was in fact not FKS1 deletion strain, and instead had both wild-type genotype and phenotype. A new β-1,3-glucan synthase knockout fks1::URA3 strain was created. Fluorescence microscopy confirmed its phenotype revealing that the chitin and the new β-1,3-glucan profiles were elevated in the mother cells and in the emerging buds respectively in the fks1Δ cell walls. This combination of PCR with fluorescence microscopy is a quick and easy screening method to determine and verify morphological changes in the S. cerevisiae cell wall.

Topics: Aniline Compounds; Benzenesulfonates; Cell Wall; Chitin; Echinocandins; Glucans; Glucosyltransferases; Membrane Proteins; Saccharomyces cerevisiae; Saccharomyces cerevisiae Proteins

Freshwater green algae started to colonize terrestrial habitats about 460 million years ago, giving rise to the evolution of land plants. Today, several streptophyte green algae occur in aero-terrestrial habitats with unpredictable fluctuations in water availability, serving as ideal models for investigating desiccation tolerance. We tested the hypothesis that callose, a β-d-1,3-glucan, is incorporated specifically in strained areas of the cell wall due to cellular water loss, implicating a contribution to desiccation tolerance. In the early diverging genus Klebsormidium, callose was drastically increased already after 30 min of desiccation stress. Localization studies demonstrated an increase in callose in the undulating cross cell walls during cellular water loss, allowing a regulated shrinkage and expansion after rehydration. This correlates with a high desiccation tolerance demonstrated by a full recovery of the photosynthetic yield visualized at the subcellular level by Imaging-PAM. Furthermore, abundant callose in terminal cell walls might facilitate cell detachment to release dispersal units. In contrast, in the late diverging Zygnema, the callose content did not change upon desiccation for up to 3.5 h and was primarily localized in the corners between individual cells and at terminal cells. While these callose deposits still imply reduction of mechanical damage, the photosynthetic yield did not recover fully in the investigated young cultures of Zygnema upon rehydration. The abundance and specific localization of callose correlates with the higher desiccation tolerance in Klebsormidium when compared with Zygnema.

Topics: Aniline Compounds; Benzenesulfonates; Biological Evolution; Cell Wall; Chlorophyta; Desiccation; Glucans; Staining and Labeling

beta-Glucanases were detected after polyacrylamide gel electrophoresis under native and denaturing conditions using various beta-1,3- and beta-1,4-glucans, including mixed glucans (laminarin, pachyman, carboxymethyl cellulose, lichenan and barley beta-glucan). After electrophoresis and incubation of gels, substrates incorporated into polyacrylamide gels were stained with specific fluorochromes, Sirofluor for beta-1,3 linkages and Calcofluor White M2R for beta-1,4 linkages. Under UV illumination, lysis zones appeared as dark bands against a fluorescent background. Enzymes of bacterial, fungal and plant sources could be revealed sequentially in gles containing mixed beta-(1,3)(1,4)-glucans by staining first with sirofluor followed by staining with Calcofluor White M2R. Active profiles were more diverse when substrates were stained with sirofluor. The use of purified sirofluor at pH 11.5 compared with Aniline Blue at pH 8.6 allowed better detection of beta-1,3-glucanase activities. In gels containing laminarin stained with sirofluor, bands exhibiting a more intense fluorescence than the background fluorescence were observed in addition to dark nonfluorescent bands. It is postulated that these two types of beta-1,3-glucanase activities differ by their enzymatic action (partial versus extensive hydrolysis). Analysis of fungal extracts using denaturing gels embedded with various beta-glucans displayed lysis bands migrating between 32 and 35 kDa.

Topics: Aniline Compounds; Benzenesulfonates; beta-Glucosidase; Electrophoresis, Polyacrylamide Gel; Fluorescent Dyes; Glucan 1,3-beta-Glucosidase; Glucans; Polysaccharides; Protein Denaturation; Staining and Labeling