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.     

Chitin and cellulose in the cell walls of the oomycete,Apodachlya sp.

Summary Hyphal walls of Apodachlya sp. (Leptomitales) gave a positive reaction when tested cytochemically for chitin. The color reaction indicative of the presence of chitin developed uniformly throughout the walls, but did not appear in the numerous cellulin granules found in this fungus. Chitin and cellulose fractions were prepared from chemically isolated walls and identified by X-ray diffraction.     

Genomic comparison of chitinolytic enzyme systems from terrestrial and aquatic bacteria

Chitin degradation ability is known for many aquatic and terrestrial bacterial species. However, differences in the composition of chitin resources between aquatic (mainly exoskeletons of crustaceans) and terrestrial (mainly fungal cell walls) habitats may have resulted in adaptation of chitinolytic enzyme systems to the prevalent resources. We screened publicly available terrestrial and aquatic chitinase‐containing bacterial genomes for possible differences in the composition of their chitinolytic enzyme systems. The results show significant differences between terrestrial and aquatic bacterial genomes in the modular composition of chitinases (i.e. presence of different types of carbohydrate binding modules). Terrestrial Actinobacteria appear to be best adapted to use a wide variety of chitin resources as they have the highest number of chitinase genes, the highest diversity of associated carbohydrate‐binding modules and the highest number of CBM33‐type lytic polysaccharide monooxygenases. A ctinobacteria do also have the highest fraction of genomes containing β‐1, 3‐glucanases, enzymes that may reinforce the potential for degrading fungal cell walls. The fraction of bacterial chitinase‐containing genomes encoding polyketide synthases was much higher for terrestrial bacteria than for aquatic ones supporting the idea that the combined production of antibiotics and cell‐wall degrading chitinases can be an important strategy in antagonistic interactions with fungi.     

Hyphal wall composition inApodachlyella completa

Mechanically isolated hyphal walls of the oomyceteApodachlyella completa (Humphrey) Indoh. (Leptomitales) were investigated by means of biochemical, cytochemical, and X-ray analyses. Microscopic examination of the cell wall preparations revealed them to be free of cytoplasmic contaminants β-Glucans account for 88% of wall weight and contain predominantly I→3 and I→6 linkages. Cellulose was demonstrated cytochemically and by X-ray diffraction and accounts for approximately 6% of wall dry weight. Additionally, walls contain 5% insoluble hexosamine, 4.8% protein, 1.1% lipid, and 0.5% ash. Chitin was qualitatively detected by means of cytochemical and X-ray analysis. The cell wall composition ofA. completa is similar to that reported for other oomycetes, in that β-glucans are the primary wall constituents. However, this fungus shows the unusual feature of chitin occurring simultaneously with cellulose, as do the closely related speciesApodachlya sp. andLeptomitus lacteus. *** DIRECT SUPPORT *** A01R4022 00007     

HYPHAL WALL COMPOSITION OF MINDENIELLA SPINOSPORA AND ARAIOSPORA SP.

Mechanically isolated hyphal walls of the rhipidiacean fungi Mindeniella spinospora Kanouse and Araiospora sp. (Oomycetes) were examined by biochemical, cytochemical and x-ray diffraction analyses. In both fungi, the most abundant wall constituents were 1 → 3- and 1 → 6-linked β-glucans accounting for 91% of wall dry weight in M. spinospora and 87% in Araiospora sp. In addition, hyphal walls of M. spinospora contained 1.7% mannose, 4.3% protein, 2.0% ash and 1.0% lipid. The quantities of these components in Araiospora sp. were 1.9%, 1.8%, 1.5%, and 1.3%, respectively. Both species had cellulose contents ranging from one-fifth to one-fourth of wall dry weight and chitin was apparently absent. In general, wall composition of both fungi is quite similar to that of the related species Sapromyces elongatus, lending support to the assertion that a biochemical dichotomy exists with respect to hyphal wall composition between Rhipidiaceae and Leptomitaceae, the two families comprising the order Leptomitales.     

Digestive enzymes of the saltmarsh periwinkleLittorina irrorata (Mollusca: Gastropoda)

Summary The saltmarsh periwinkleLittorina irrorata is well adapted for the digestion of a wide range of polysaccharides. Enzyme extracts attacked cellulose, pectin, xylan, bean gum and mannan (common in cell walls of higher plants), as well as starch and laminarin (representative of major polysaccharide classes in fungal, algal, and animal tissues). Activities were generally highes at a ph of 5 or 6. There was no evidence that chitin was digested, but 19 other enzymes, active toward various carbohydrates, lipids and peptides, were demonstrated. Enzymatic activity toward Azocoll, a general substrate for proteinase activity, was weak compared to that of other aquatic detritivores. The maximum was reached at a pH of 8. Enzymatic activities were generally measured with extracts of the entire visceral hump. Separate stomach or intestine extracts also gave strong activities. The stomach was the most acidic section of the digestive system with an average pH of 5.8; the intestine had an average pH of 7.3.     

Production of an Antifungal Chitinase from Enterobacter sp. NRG4 and its Application in Protoplast Production

Summary In this study flake chitin, crab shell chitin, mushroom stalk, fungal cell wall, wheat bran and rice bran were used as substrate for chitinase production by Enterobacter sp. NRG4 under submerged and solid state fermentation (SSF) conditions. Enterobacter sp. NRG4 produced 72 and 49.7 U/ml of chitinase in presence of cell walls of Candida albicans and Fusarium moniliforme in submerged fermentation. Under SSF, maximum chitinase production was 965 U/g solid substrate with flake chitin and wheat bran (1:3 ratio) at 75% moisture level after 144 h. The purified chitinase inhibited hyphal extension of Fusarium moniliforme, Aspergillus niger, Mucor rouxi and Rhizopus nigricans. The chitinase was effective in release of protoplasts from Trichoderma ressei, Pleurotus florida, Agaricus bisporus and Aspergillus niger. Protoplasts yield was maximum with 60 mg of 24 h old fungal mycelium incubated with 60 U of chitinase and 60 U of cellulase.     

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.     

Growth of bacteria on chitin, fungal cell walls and fungal biomass, and the effect of extracellular enzymes produced by these cultures on the antifungal activity of amphotericin B

Vibrio alginolyticus, Streptomyces griseus, Arthrobacter G12, Bacillus sp. and Cytophaga sp. were grown on solid and liquid media containing soluble and insoluble carbon sources. Arthrobacter G12, Bacillus sp. and Cytophaga sp. grew well on media which contained fungal cell walls or fungal biomass as the main carbon source. All bacteria produced extracellular proteases and all bacteria except Arthrobacter G12 produced extracellular chitinases. Growth of Cytophaga sp. on colloidal chitin was paralleled by the accumulated chitinase activity in the culture filtrate, and growth of Cytophaga sp. and Arthrobacter G12 on cell walls of Geotrichum candidum and cell walls of Candida pseudotropicalis was paralleled by the accumulation of laminarinase activity in the culture filtrate, but little or no extracellular chitinase activity was observed in these cultures. Mycolases purified from the culture filtrates of Cytophaga sp. grown on colloidal chitin on cell walls of C. pseudotropicalis potentiated the antifungal activity of amphotericin B.     

哈氏木霉分生孢子发育的超微结构和细胞化学

通过电子显微镜和细胞化学标记研究了哈氏木霉分生孢子发育的超微结构和细胞化学。分生孢子发育的超微结构研究表明,分生孢子壁的发育是有个由薄而光滑到厚而有疣的过程;期间脂肪体在分生孢子和产孢细胞中不断累积,最后脂肪体沿着内壁排列成一层。免疫金标记结果显示,幼嫩的分生孢子壁中缺乏几丁质和纤维素,只有在成熟的分生孢子壁中含有几丁质;出乎意料的是在成熟分生孢子中发现有少量纤维素的存在。     

THE COMPOSITION AND PHYLOGENETIC SIGNIFICANCE OF THE MOUGEOTIA (CHAROPHYCEAE) CELL WALL1

The two-layered, fibrillar cell wall of Mougeotia C. Agardh sp. consisted of 63.6% non-cellulosic carbohydrates and 13.4% cellulose. The orientation of cellulose microfibrils in the native cell wall agrees with the multinet growth hypothesis, which has been employed to explain the shift in microfibril orientation from transverse (inner wall) toward axial (outer wall). Monosaccharide analysis of isolated cell walls revealed the presence of ten sugars with glucose, xylose and galactose most abundant. Methylation analysis of the acid-modified, 1 N NaOH insoluble residue fraction showed that it was composed almost exclusively of 4-linked glucose, confirming the presence of cellulose. The major hemicellulosic carbohydrate was semi-purified by DEAE Sephacel (Cl^?) anion-exchange chromatography of the hot 1 N NaOH soluble fraction. This hemicellulose was a xylan consisting of a 4-xylosyl backbone and 2,4-xylosyl branch points. The major hot water soluble neutral polysaccharide was identified as a 3-linked galactan. Mougeotia cell wall composition is similar to that of (Charophyceae) and has homologies with vascular plant cell walls. Our observations support transtructural evidence which suggests that members of the Charophyceae represent the phylogenetic line that gave rise to vascular plants. Therefore, the primary cell walls of vascular plants many have evolved directly from structures typical of the filamentous green algal cell walls found in the Charophyceae.     

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.     

Direct observation of the structure of mycelial cell walls from the potato blight fungus Phytophthora infestans by solid-state 13C NMR

Mycelial cell walls from the potato blight fungus ( Phytophthora infestans ) (Mont.) de Bary were examined in the solid state by ¹³C nuclear magnetic resonance spectroscopy with cross-polarization and magic-angle spinning. The spectrum was free from interference by spinning sidebands. The main component of the cell walls had the spectral properties of a β -(1,3')-glucan. Protein appeared to be present also. The presence of β -(1,6')-linked glucose residues, cellulose or chitin was not ruled out, but there was no evidence for these as major components of the cell walls.     

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.     

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.     

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.     

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.     

Unexpected Effects of Chitin,Cellulose, and Lignin Addition on Soil Dynamics in a Wet Tropical Forest

Decades of studies on the role of decomposition in carbon (C) and nitrogen (N) cycling have focused on organic matter (OM) of plant origin. Despite potentially large inputs of belowground OM from fungal cell walls and invertebrate exoskeletons, studies of the decomposability of their major constituent, chitin, are scarce. To explore effects on soil C dynamics of chitin, in comparison with two plant-derived chemicals, cellulose and lignin, I conducted a field-based chemical-addition experiment. The design contained three chemical treatments plus a control, with four replicates in each of two species of tropical trees grown in plantations. The chemicals were added in reagent-grade form at a rate that doubled the natural detrital C inputs of 1000 g C m^?2 y^?1. Despite its purported recalcitrance, chitin was metabolized quickly, with soil respiration (R _soil) increasing by 64% above the control within days, coupled with a 32% increase in soil extractable ammonium. Cellulose, which was expected to be labile, was not readily decomposed, whereas lignin was rapidly metabolized at least partially in one of the forest types. I examined effects of stoichiometry by adding to all treatments ammonium nitrate in a quantity that adjusted the C:N of cellulose (166) to that of chitin (10), using both field and in vitro experiments. For cellulose, CO₂ release increased more than five- to eightfold after N addition in root-free soil incubated in vitro, but only 0–20% in situ where roots were intact. By the end of the 2-year-long field experiment, fine-root biomass tended to be higher in the chitin treatment, where R _soil was significantly higher. Together these findings suggest that soil N availability limited cellulose decomposition, even in this Neotropical forest with high soil N stocks, and also that trees successfully competed for N that became available as chitin decomposed. These results indicate that the major constituent of cell walls of soil fungi, chitin, can decompose rapidly and release substantial N that is available for plant and microbial growth. As a consequence, soil fungi can stimulate soil OM decomposition and N cycling, and thereby play a disproportionate role in ecosystem C and N dynamics.     

The chitinase system ofStreptomyces sp. ATCC 11238 and its significance for fungal cell wall degradation

Summary A crude preparation of extracellular proteins fromStreptomyces sp. ATCC 11238, containing chitin and laminarin degrading enzymes was active in lysing the cell walls of most of 50 viable filamentous ascomycetes tested, but was almost inactive with endomycetidae, zygomycetes and oomycetes. This mycolase preparation was fractionated by gel filtration and DEAE-ion exchange chromatography with special interest in chitin-degrading enzymes. N-Acetylglucosamine is liberated from crab shell chitin by the combined action of an exo-chitinase and -N-acetylglucosaminidase. Both purified enzymes lysed cell wall preparations singly or together only when supplemented by protein containing endochitinase activity recovered from the gel after gel electrophoresis. Furthermore, enzymes degrading chitosan and azocoll were detected and separated.     

Purification and Mode of Action of Chitosanolytic Enzyme from Enterobacter sp. G-1

A chitosanolytic enzyme was purified from Enterobacter sp. G-1 by fractionation of 30% saturation with ammonium sulfate, isoelectric focusing, and Sephadex G-100 gel chromatography. The purified enzyme. showed a single band on sodium dodecyl sulfate polyacrylamide gel electrophoresis, and the molecular mass was estimated to be 50 kDa. The enzyme degraded N-acetyl-chitooligosaccharides, glycol chitin, colloidal chitin, and colloidal chitosan (about 80% deacetylated), but did not degrade chitooligosaccharides, colloidal chitosan (100% deacetylated), or Micrococcus lysodeikticus cell walls. It hydrolyzed GlcNAc_4–6 and colloidal chitin to GlcNAc₂, finally. The main cleavage site with GlcNAc_3–6 was the second linkage from the non-reducing end, based on the pattern of pNp-GlcNAc_2–5. Colloidal chitosan was hydrolyzed to GlcNAc₂ and to similar partially N-acetylated chitooligosaccharides.