On the cell wall composition of the apiculate yeasts

Summary Sonic oscillation was used for the purpose of obtaining clean, chemically intact cell walls. The rate of disruption was determined for cells ofHanseniaspora uvarum andSaccharomyces cerevisiae. The carbohydrate fractions of cell walls ofHanseniaspora uvarum, H. valbyensis, Kloeckera apiculata, Saccharomycodes ludwigii andSaccharmyces cerevisiae were shown to be similar. Chromatography of cell wall hydrolysates of all these species demonstrated that glucose and mannose were the only sugars present (in about equal amounts) besides traces of glucosamine. The cell walls ofH. uvarum contained 78.1 per cent carbohydrates, 7 per cent protein and approximately 0.05 per cent of chitin. Fractionation of the polysaccharides lead to a recovery of 83.3 per cent of the carbohydrates present (30.4 per cent glucan and 34.9 per cent mannan). Saccharomyces cerevisiae cell walls were found to have a carbohydrate content of 82.8 per cent, 6.5 per cent protein and a trace of chitin (0.04 per cent). Nadsonia elongata contained a relatively large amount of chitin (ca. 5 per cent) and lacked mannan in its cell walls. It was concluded thatHanseniaspora andSaccharomycodes are closely related to theSaccharomyceteae but they have little in common with species ofNadsonia.     

BIOCHEMICAL AND MICROCHEMICAL STUDY OF THE CELL WALLS OF RHIZIDIOMYCES SP.

Fuller , Melvin S. (Brown U., Providence, R. I.) Biochemical and microchemical study of the cell walls of Rhizidiomyces sp. Amer. Jour. Bot. 47(10): 838–842. lllus. 1960.—The presence of chitin in the cell walls of the fungus Rhizidiomyces is demonstrated by qualitative analysis of enzymatic and hydrochloric-acid hydrolysates of partially cleaned cell walls. Qualitative examination of the enzymatic and acid hydrolysates did not, however, serve for the detection of cellulose present in the cell walls of Rhizidiomyces. With microchemical tests, both chitin and cellulose can be detected. These microchemical tests served to indicate the localization of the chitin and cellulose in the cell walls of mature plants before and during zoospore discharge.     

Effect of Candida albicans cell wall components on the adhesion of the fungus to human and murine vaginal mucosa

In this study, cell walls from Candida albicans were separated and chitin was isolated from these cell walls. A chitin soluble extract (CSE) prepared from the chitin inhibited in vitro adhesion of C. albicans to human epithelial vaginal cells (VEC), and blocked in vivo attachment to murine vaginal mucosa, thereby preventing candidal infection in these animals. These findings suggest that the CSE acts as an adhesin-like substance.Fractionation of CSE yielded two fractions: FI and FII, of which only FI exhibited inhibitory activity. Chemical analysis of CSE and its two fractions revealed that CSE contains over 70% of proteins, most of which were found in the non-active fraction. In addition, 3% of amino-sugars were found in the FI active fraction. Lipids were also detected in the unfractionated CSE and in both fractions.Experiments to further characterize the component(s) in the CSE inhibiting the attachment of C. albicans are in progress in our laboratory.     

THE CHEMICAL COMPOSITION OF THE HYPHAL WALLS OF THE FUNGUS ALLOMYCES

Aronson , Jerome M., and Leonard Machlis . (U. California, Berkeley.) The chemical composition of the hyphal walls of the fungus Allomyees. Amer. Jour. Bot. 46(4): 292–300. Illus. 1959.—The hyphal walls of Allomyces macrogynus were isloated by both alkaline digestion methods and by sonic oscillation. Both types of preparations showed the walls to consist of chitin, glucan, and ash. In addition, the mechanically isolated walls contained a protein fraction, the properties and significance of which were not determined. Hemicellulose-type polysaccharides, pectic substances, ether soluble lipids, and constituents giving rise to 3–0-α-earboxyethyl hexosamine were not found to be present in the walls. The walls of plants grown for 60–70 hr. under the prescribed conditions contain approximately 60% chitin, 15% glucan, 10% ash, and 10% protein intimately associated with the walls. The percentage of wall material in a mycelium, as well as the percentage of chitin in the walls, increases with the chronological age of the mycelium. These percentages were not, however, affected by variations in the composition of the nutrient medium. The chitin in the walls could be hydrolyzed in the presence of chitinase; lysozyme, however, had no detectable effect on the walls.     

Metal loading and enzymatic degradation of fungal cell walls and chitin

The capacity of chitin (from crab shells) and of fungal cell walls from Trichoderma harzianum to accumulate zinc, cadmium and mercury was studied as well as the effects of adsorbed metals on the enzymatic hydrolysis by Novozym 234 of the two substrates. The total adsorbing capacity with respect to these metals was estimated to be at least 10 mmol kg^–1 chitin (dry weight) and 50 mmol kg^–1 fungal cell walls (dry weight), respectively, at pH 6.1. Enzymatic digestion of fungal cell walls preloaded with mercury and cadmium was significantly reduced, while zinc did not cause any significant inhibition. The effect of metal complexation by chitin on the enzymatic digestion was not as pronounced as for fungal cell walls. This could reflect the fact that chitin sorbed a lower total amount of metals. The inhibitory effect of metals on the enzymatic hydrolysis was caused by the association of the metals with the two substrates and not by the presence of free metals in solution.     

On the cell wall composition ofSaccharomycopsis guttulata

Summary Cells ofSaccharomycopsis guttulata were ruptured by sonic oscillation and the resulting cell walls were purified by washing and centrifugation. The walls contained 43.7% carbohydrate (expressed as glucose), 39.6% protein and a trace of chitin. Paper chromatography of hydrolyzed cell walls showed that glucose and an unknown reducing compound make up the bulk of the carbohydrate fraction. Mannose and glucosamine were present in small amounts. The cell wall composition ofS. guttulata appears to differ considerably from that ofS. cerevisiae.     

A Peptide Inhibitor of Angiotensin I Converting Enzyme in the Tryptic Hydrolysate of Casein

Protoplasts of Pyricularia oryzae P₂ formed a cell wall and eventually reverted to a normal mycelial form in liquid medium. The process of the formation of two main cell-wall components, glucan and chitin, was studied from the onset of regeneration. Analyses using radioactive sugars suggested that chitin synthesis started after a short lag but glucan formation was delayed. Chemical analysis of regenerating cell walls using gas-liquid chromatography indicated clearly that chitin formation precedes glucan formation.     

Investigating chitin deacetylation and chitosan hydrolysis during vegetative growth in Magnaporthe oryzae

Chitin deacetylation results in the formation of chitosan, a polymer of β1,4‐linked glucosamine. Chitosan is known to have important functions in the cell walls of a number of fungal species, but its role during hyphal growth has not yet been investigated. In this study, we have characterized the role of chitin deacetylation during vegetative hyphal growth in the filamentous phytopathogen Magnaporthe oryzae. We found that chitosan localizes to the septa and lateral cell walls of vegetative hyphae and identified 2 chitin deacetylases expressed during vegetative growth—CDA1 and CDA4. Deletion strains and fluorescent protein fusions demonstrated that CDA1 is necessary for chitin deacetylation in the septa and lateral cell walls of mature hyphae in colony interiors, whereas CDA4 deacetylates chitin in the hyphae at colony margins. However, although the Δcda1 strain was more resistant to cell wall hydrolysis, growth and pathogenic development were otherwise unaffected in the deletion strains. The role of chitosan hydrolysis was also investigated. A single gene encoding a putative chitosanase (CSN) was discovered in M. oryzae and found to be expressed during vegetative growth. However, chitosan localization, vegetative growth, and pathogenic development were unaffected in a CSN deletion strain, rendering the role of this enzyme unclear.     

Insect chitin synthases: a review

Chitin is the most widespread amino polysaccharide in nature. The annual global amount of chitin is believed to be only one order of magnitude less than that of cellulose. It is a linear polymer composed of N-acetylglucosamines that are joined in a reaction catalyzed by the membrane-integral enzyme chitin synthase, a member of the family 2 of glycosyltransferases. The polymerization requires UDP–N-acetylglucosamines as a substrate and divalent cations as co-factors. Chitin formation can be divided into three distinct steps. In the first step, the enzymes‘ catalytic domain facing the cytoplasmic site forms the polymer. The second step involves the translocation of the nascent polymer across the membrane and its release into the extracellular space. The third step completes the process as single polymers spontaneously assemble to form crystalline microfibrils. In subsequent reactions the microfibrils combine with other sugars, proteins, glycoproteins and proteoglycans to form fungal septa and cell walls as well as arthropod cuticles and peritrophic matrices, notably in crustaceans and insects. In spite of the good effort by a hardy few, our present knowledge of the structure, topology and catalytic mechanism of chitin synthases is rather limited. Gaps remain in understanding chitin synthase biosynthesis, enzyme trafficking, regulation of enzyme activity, translocation of chitin chains across cell membranes, fibrillogenesis and the interaction of microfibrils with other components of the extracellular matrix. However, cumulating genomic data on chitin synthase genes and new experimental approaches allow increasingly clearer views of chitin synthase function and its regulation, and consequently chitin biosynthesis. In the present review, I will summarize recent advances in elucidating the structure, regulation and function of insect chitin synthases as they relate to what is known about fungal chitin synthases and other glycosyltransferases.     

Hyphal walls of isolated lichen fungi

The hyphal walls of three mycobionts, isolated from the lichens Xanthoria parietina, Tornabenia intricata and Sarcogyne sp. were investigated by two techniques: microautoradiography of fungal colonies exposed to radioactive carbohydrate precursors; and binding, in vivo, of fluorescein conjugated lectins to hyphal walls of such colonies.N-[³H] acetylglucosamine was readily incorporated into tips, young hyphal walls and septa of the three mycobionts and the free-living fungus Trichoderma viride, but not into Phytophthora citrophthora, indicating that chitin is a major component of the mycobionts' hyphal walls. All three mycobionts, but neither of the free-living fungi, incorporated [³H] mannose and [³H] mannitol into their hyphal walls.Fluorescein-conjugated wheat germ agglutinin was bound to the hyphal walls of the three mycobionts and T. viride, but not to the walls of P. citrophthora; the binding pattern was similar to the grain pattern obtained in autoradiographs after short N-[³H] acetylglucosamine labelling. As wheat germ agglutinin binds specifically to chitin oligomers, the lectin binding tests further confirmed that chitin is a mycobiont hyphal wall component.Binding characteristics of several fluorescein-conjugated lectins to the three mycobionts indicated that this technique can yield useful information concerning the chemical composition of hyphal wall surfaces.List of abbreviations FITC fluorescein isothiocyanate - WGA wheat germ agglutinin - TCA trichloroacetic acid - PNA peanut agglutinin - LA lotus agglutinin - Glc NAc N-acetylglucosamine - ConA concanavalin A - SBA soybean agglutinin - WBA waxbean agglutinin Part of an M.Sc. thesis submitted by A. Braun to the Department of Botany, Tel Aviv University.     

Attempted localization of a substrate for chitinases in plant cells reveals abundant N-acetyl-d-glucosamine residues in secondary walls

Ultrathin sections of healthy and fungus-infected plant tissue were treated with either wheat-germ agglutinin (WGA) ovomucoid-gold complex or microbial chitinase-gold complexes for localizing putative chitin-like macromolecules. Fungal cell walls, known to contain chitin, were labeled with both probes and were considered as positive controls. Plant secondary cell walls of both healthy and infected tissues were also intensely labeled whereas compound middle lamella-primary walls and cell cytoplasm were free of labeling. Enzymatic digestion of plant tissues with chitinase from Streptomyces griseus abolished the fungal cell wall labeling but did not interfere with that of plant secondary cell walls. This suggests that polymers analogous to fungal chitin are absent in plant cell walls. Tissue digestions with either proteinase K or lipase led to surprising results as far as the possible nature of N-acetylglucosamine-containing molecules is concerned. The loss of labeling over plant secondary walls following lipase digestion suggests that N-acetylglucosamine residues may be linked to lipids to form glycolipids. However, these results have to be viewed with caution since the possibility that peptides may be present but inacessible to proteinase K should be considered. The role of the detected N-acetylglucosamine containing molecules as possible substrates for plant chitinases is discussed.     

Ultrastructure of chitin in hyphae ofCandida albicans and other dimorphic and mycelial fungi

Summary Chitin microfibrils exposed by chemical extraction of hyphal walls ofCandida albicans, Histoplasma capsulatum, Blastomyces dermatitidis, Paracoccidiodes brasiliensis, Coprinus cinereus andMucor mucedo were of variable morphology but gave identical infrared spectra and behaved as pure chitin in chromatographic analyses. The microfibrils of the four dimorphic fungi studied were shorter than those in the mouldsC. cinereus andM. mucedo but were similar to those reported for the yeastSaccharomyces cerevisiae. InC. albicans the microfibrils in the septal plates of hyphae were predominantly tangentially orientated and were longer than those in the lateral walls. Microfibrils produced by chitin synthasein vitro were very much longer than any observed from hyphal preparations.     

Irregular growth forms and cell wall modifications,polygalacturonase detection,and endocell formation in <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">radicis-lycopersici</Emphasis> infecting tomato plants,as studied ultrastructurally and cytochemically

Pathogen cells of Fusarium oxysporum f.sp. radicis-lycopersici infecting container-grown tomato plants were characterized ultrastructurally, using gold-complexed probes, chitinase and wheat germ agglutinin to localize chitin, and polyclonal antibodies to a polygalacturonase to localize this enzyme. It was isolated and purified from the pathogen growing in culture. Many fungal cells were of irregular forms (microhyphal, frondose) with modified, thin or imperceptible lucent wall layers, in which were often included components seemingly of host origin. Gold particles of the polygalacturonase probe were concentrated on portions of penetration hyphae and in areas of associated altered host wall. Fine filamentous-like structures, often linked to fungal cells, reached into extracellular matter and into host walls. Examination of 0.2–0.25 μm-thick sections at 120 kV, and tilted at various angles, indicated that fungal cells frequently had a pronounced wavy contour. Labelling of thin walls for chitin was mostly nil, particularly in contact with host walls, as of also thicker walls in similar situations, or it was then associated with the outside opaque layer. Cells of diverse dimensions with thin or thicker walls and with altered or normal content, contained endocells. Walls of the encodcells and of the enclosing cells often labelled differently for chitin with both probes. Endocells mostly did not originate from proliferation of a living into a dead cell but often ensuing as an apparent fragmentation of the cell content or following its retraction. The bearing of these observations on the host-pathogen relationship, particularly concerning the role of thin-walled hyphae and irregular forms, is discussed.     

The genusCandida berkhout

The aim of the study was to verify the accuracy of the taxonomic classification of rough variants of the speciesCandida guilliermondii on the basis of comprehensive study of phenetic manifestation and to determine differences in cell wall structure with special reference to polysaccharides (1) According to their phenotype, the test strainsCandida guilliermondii (Cast.) Langeron et Guerra andCandida guilliermondii var.membranaefaciens Lodder et Kreger-Van Rij belong to the speciesCandida guilliermondii, whileCandida guilliermondii var.nitratophila Diddens et Lodder is phenotypically closer toCandida pelliculosa. (2) Observation of native and hydrolysed cell walls in the electron microscope showed no differences between the test strains. (3) The results of X-ray phase analysis of cell walls differentiatedCandida guilliermondii var.nitratophila from the other two, however. (4) Electron microscopy photomicrographs and diffractograms of cell walls indicated that, after 2% HCl extraction at 100 C, the cell walls contain chitin, which is isolated by further extraction with 30% HCl. After 3% NaOH hydrolysis the chitin diffractogram is not clear.     

Characterization of fructose 6 phosphate phosphoketolases purified from Bifidobacterium species

An extracellular chitin deacetylase activity has been purified to homogeneity from autolyzed cultures of Aspergillus nidulans. This enzyme is an acidic glycoprotein with a pI of 2.75 and a 28% (wt/wt) carbohydrate content. The apparent M _r of the enzyme estimated by SDS/PAGE and Superose 12 (f.p.l.c.) was around 27,000. The enzyme had an optimum pH at 7.0 and was stable in the pH range 4.0–7.5. Its optimum temperature of reaction was 50°C, and it was stable from 30° to 100°C after 1 h of preincubation. The enzyme hydrolyzed glycol chitin and oligomers of N-acetylgucosamine and to a lesser extent chitin, colloidal chitin, carboxymethylchitin, and an -1 3,1 6-N-acetylgalactosamine-galactan among other substances with amido groups, but the enzyme did not hydrolyze peptide bonds. The role of this enzyme could be deacetylation of chitin oligosaccharides during autolysis, after action of endochitinase on cell walls.     

Lysis of cell walls ofMucor ramannianus möller by aStreptomyces sp.

A study has been made of some chemical and ultrastructural changes that occur in the hyphal, arthrospore and sporangiospore walls ofMucor ramannianus during lysis by a soil streptomycete.Arthrospore and hyphal walls, which were shown to contain chitin, chitosan, other polysaccharides and phosphate (principally as polyphosphate), were lysed by culture fluid of the streptomycete after this organism had been grown on the same material. Alcohol-insoluble material found in the supernatants of the incubation mixtures gave on hydrolysis glucosamine, galactose, mannose and fucose. No laminarinase activity was detected in these culture fluids. Culture fluids of the streptomycete after growth on chitin and chitosan were also found to lyse the walls of arthrospores and hyphae.Despite the chemical similarities the walls were very different in thin section.A major component in the sporangiospore walls was glucan and an active laminarinase was shown to be present in the culture fluids of the streptomycete after growth on them. Further, ultrathin sections showed that an inner fibrillar layer of the sporangiospore wall was lysed leaving an outer electron-dense layer.     

Characterization of chitin and chitin synthase from the cellulosic cell wall fungusSaprolegnia monoi¨ca

The presence of chitin in hyphal cell walls and regenerating protoplast walls ofSaprolegnia monoi¨ca was demonstrated by biochemical and biophysical analyses. α-Chitin was characterized by X-ray diffraction, electron diffraction, and infrared spectroscopy. In hyphal cell walls, chitin appeared as small globular particles while cellulose, the other crystalline cell wall component, had a microfibrillar structure. Chitin synthesis was demonstrated in regenerating protoplasts by the incorporation of radioactiveN-acetylglucosamine into a KOH-insoluble product. Chitin synthase activity of cell-free extracts was particulate. This activity was stimulated by trypsin and inhibited by the competitive inhibitor polyoxin D (K_i 20 μM). The reaction product was insoluble in 1M KOH or 1M acetic acid and was hydrolyzed by chitinase into diacetylchitobiose. Fungal growth and cell wall chitin content were reduced when mycelia were grown in the presence of polyoxin D. However, hyphal morphology was not altered by the presence of the antibiotic indicating that chitin does not seem to play an important role in the morphogenesis ofSaprolegnia.     

CHITIN AND CELLULOSE IN THE CELL WALLS OF RHIZIDIOMYCES SP

Fuller , Melvin S. (Brown U. Providence, R. I.), and Isaac Barshad . Chitin and cellulose in the cell walls of Rhizidiomyces sp. Amer. Jour. Bot. 47(2): 105-109. Illus. 1960.–Chemically isolated cell wall preparations of the aquatic Phycomycete, Rhizidiomyces sp., were analyzed by means of X-rays. The resulting diffraction patterns had maxima corresponding with known values for chitin and mercerized cellulose. The findings in this study are discussed with respect to Von Wettstein's hypothesis that the aquatic Phycomycetes can be separated into groups on the basis of whether their cell walls contain chitin or cellulose.     

Lectin Binding Studies on the Cell Walls of Soybean Rust (Phakopsora pachyrhizi Syd.)

Walls of uredospores, infection structures, intercellular hyphae and haustoria of the soybean rust fungus (Phakopsora pachyrhizi) were studied by electron microscopy using gold-labeled wheat germ lectin (WGL) and Concanavalin A (ConA) as cytochemical probes. Receptors for WGL (probably chitin) were detected in all fungal walls included in this study. WGL-binding occurred throughout the entire walls (uredospores, appressorial cone, penetration hyphae, haustorial mother cells) or only to the inner wall layers (germ tubes, appressoria, intercellular hyphae).     

Deletion of BGL2 results in an increased chitin level in the cell wall of Saccharomyces cerevisiae

It is shown that the deletion of BGL2 gene leads to increase in chitin content in the cell wall of Saccharomyces cerevisiae. A part of the additional chitin can be removed from the bgl2Δ cell wall by alkali or trypsin treatment. Chitin synthase 1 (Chs1) activity was increased by 60 % in bgl2Δ mutant. No increase in chitin synthase 3 (Chs3) activity in bgl2Δ cells was observed, while they became more sensitive to Nikkomycin Z. The chitin level in the cell walls of a strain lacking both BGL2 and CHS3 genes was higher than that in chs3Δ and lower than that in bgl2Δ strains. Together these data indicate that the deletion of BGL2 results in the accumulation and abnormal incorporation of chitin into the cell wall of S. cerevisiae, and both Chs1 and Chs3 take part in a response to BGL2 deletion in S. cerevisiae cells. This revised version was published online in August 2006 with corrections to the Cover Date.