Evidence that Blastocladiella emersonii zoospore chitin synthetase is located at the plasma membrane

Blastocladiella emersonii zoospores are not encased by a cell wall and do not detectably synthesize or contain chitin; accompanying de novo cell wall formation during zoospore encystment, chitin rapidly accumulates and is incorporated into the cell wall. Essential for understanding this abrupt change in chitin synthesis is the location of zoospore chitin synthetase. The enzyme has previously been reported to the sequestered with distinctive cytoplasmic organelles (gamma particles) characteristic for the zoospore cell type. Using similar differential and equilibrium density centrifugation procedures to those reported previously, we have observed the vast majority of zoospore homogenate chitin synthetase activity in fractions distinct from the gamma particle-enriched fractions. Over 90% of the homogenate enzyme activity could be recovered in a sucrose buoyant density region (1.14–1.18 g/ml) containing membranous elements and well separated from the region enriched for gamma particles (1.30–1.34 g/ml). When zoospores were surface-labelled with [³H]concanavalin A prior to homogenization, the buoyant density regions of radioactivity and of chitin synthetase activity exhibited nearly complete coincidence. At least the bulk of zoospore chitin synthetase appears to be located at the plasma membrane, rather than in gamma particles.     

Serratia marcescens chitinase: One-step purification and use for the determination of chitin

The extracellular chitinase produced by Serratia marcescens was obtained in highly purified form by adsorption-digestion on chitin. After gel electrophoresis in a nondenaturing system, the purified preparation exhibited two major protein bands that coincided with enzymatic activity. A study of the enzyme properties showed its suitability for the analysis of chitin. Thus, the chitinase exhibited excellent stability, a wide pH optimum, and linear kinetics over a much greater range than similar enzymes from other sources. The major product of chitin hydrolysis was chitobiose, which was slowly converted into free N-acetylglucosamine by traces of β-N-acetylglucosaminidase present in the purified preparation. The preparation was free from other polysaccharide hydrolases. Experiments with radiolabeled yeast cell walls showed that the chitinase was able to degrade wall chitin completely and specifically.     

The control of chitin deposition by ecdysterone in larvae of Bombyx mori

The effect of ecdysterone on the deposition of chitin in Bombyx larvae was examined. The chitin content in the abdomen decreased following hormone treatment to a value half that of the controls. Studies with ¹⁴C-glucose revealed that whereas controls exhibited a gradual decrease in the rate of ¹⁴C-glucose incorporation into chitin, the administration of ecdysterone resulted in a rapid fall in the rate of incorporation followed by a rise until ecdysis occurred. Chitin catabolism was estimated at 0·11 mg chitin/hr, based on the chitin content and incorporation rates. A dual rôle is indicated for ecdysterone in chitin metabolism, namely the activation of both synthetic and lytic systems.     

Development and use of quantitative competitive PCR assays for relative quantifying rumen anaerobic fungal populations in both in vitro and in vivo systems

This paper describes the use of a quantitative competitive polymerase chain reaction (QC-PCR) assay; using PCR primers to the rRNA locus of rumen fungi and a standard-control DNA including design and validation. In order to test the efficiency of this method for quantifying anaerobic rumen fungi, it has been attempted to evaluate this method in in vitro conditions by comparing with an assay based on measuring cell wall chitin. The changes in fungal growth have been studied when they are grown in in vitro on either untreated (US) or sodium hydroxide treated wheat straw (TS). Results showed that rumen fungi growth was significantly higher in treated samples compared with untreated during the 12 d incubation (P < 0.05) and plotting the chitin assay's results against the competitive PCR's showed high positive correlation (R² ≥ 0.87). The low mean values of the coefficients of variance in repeatability in the QC-PCR method against the chitin assay demonstrated more reliability of this new approach. And finally, the efficiency of this method was investigated in in vivo conditions. Samples of rumen fluid were collected from four fistulated Holstein steers which were fed four different diets (basal diet, high starch, high sucrose and starch plus sucrose) in rotation. The results of QC-PCR showed that addition of these non-structural carbohydrates to the basal diets caused a significant decrease in rumen anaerobic fungi biomass. The QC-PCR method appears to be a reliable and can be used for rumen samples.     

Chemical composition of the gastric shield of a bivalve, Zyrphea crispata, and of the teeth of the gizzard of a gastropod opisthobranch, Aplysia punctata

The chemical composition of the gastric shield of the bivalve Zyrphea crispata is very similar to that of the teeth of the gizzard of the gastropod opisthobranch Aplysia punctata. Both structures are indeed mainly made up of proteins and chitin. Their protein fractions, although heterogeneous, have almost the same amino acid composition. The proportion of free chitin is remarkably high, amounting to 74–78% of the total chitin. These cuticular structures certainly play a similar function in the gastric digestion, according to the presence of some hydrolases mainly laminarinase, the activity of which is much higher than in the crystalline style. Despite their morphological dissimilarity and specialization in two distinct classes of mollusca, the gastric shield and the teeth of the gizzard thus appear to be homologous structures on the basis of their chemical composition.     

Changes in composition of harvested mushrooms (Agaricus bisporus)

Post-harvest changes in the biochemical composition of the mushroom were studied. Non-structural polysaccharide was found at levels greater than 10% dry wt in the fresh mushroom. After 4 days storage, the level had decreased to below 5% dry weight. The polysaccharide appeared to contain only glucose residues joined by α-1,4 and α-1,6 linkages. The chitin content of cell walls increased by ca 50% during 4 days storage, while cell wall glucan decreased. There was a large increase in urea content.     

Etude des paraios de levures du genre rhodotorula IV. variation de la teneur en chitine

A study of the chitin contents in Rhodotorula yeast walls indicates that the contents of this amino polysaccaharide may vary from 0.58 to 12% according to the yeast and depending on the culture conditions.The variations of the glucosamine concentrations, estimated by direct determinations on the cell walls, do not reflect the modifications of the chitin contents.Depending on the culture conditions, the yeast cell walls possess structures which are differently degraded by enzyme actions. Cell walls with high glucosamine content, but low amino-acids content, are the more easily degraded.     

Evaluation of different yeast cell wall mutants and microalgae strains as feed for gnotobiotically grown brine shrimp Artemia franciscana

The nutritional value of isogenic yeast strains and two microalgal species for gnotobiotically grown Artemia was examined. Yeast cell wall mutants were always better feed for Artemia than their respective wild type. Yeast cells harbouring null mutants for enzymes involved early in the biochemical pathway for cell wall mannoproteins synthesis performed best as feed for Artemia. Yeast cells defective in chitin or β-glucan production were scored in second order. The mnn6 isogenic yeast mutant, harbouring a null mutation for mannoprotein phosphorylation, performed poorly as feed for Artemia, although with good growth. These results suggest that any mutation affecting the yeast cell wall scaffolding by reducing the amount of covalent links between the major components of yeast cell wall, namely mannoproteins, β-glucans and chitin, is sufficient to improve the digestibility for Artemia. The results with microalgae indicated that within one species, strains can have different nutritional value under gnotobiotic conditions. The growth phase was another parameter influencing feed quality, although here it was not possible to reveal the exact cause. It is anticipated that the standard Artemia gnotobiotic growth test is an excellent tool to study the mode of action of bacteria, with a probiotic as well as with a pathogenic character.     

Characterization of the Neurospora crassa DHN melanin biosynthetic pathway in developing ascospores and peridium cells

Neurospora crassa contains all four enzymes for the synthesis of DHN (dihydroxynaphthalene), the substrate for melanin formation. We show that the DHN melanin pathway functions during N. crassa female development to generate melanized peridium and ascospore cell walls. N. crassa contains one polyketide synthase (PER-1), two polyketide hydrolases (PKH-1 and PKH-2), two THN (tetrahydroxynaphthalene) reductases (PKR-1 and PKR-2), and one scytalone dehydratase (SCY-1). We show that the PER-1, PKH-1, PKR-1 and SCY-1 are required for ascospoer melanization. We also identified the laccase that functions in the conversion of DHN into melanin via a free radical oxidative polymerization reaction, and have named the gene lacm-1 (laccase for melanin formation-1). In maturing perithecia, we show that LACM-1 is localized to the peridium cell wall space while the DHN pathway enzymes are localized to intracellular vesicles. We present a model for melanin formation in which melanin is formed within the cell wall space and the cell wall structure is similar to “reinforced concrete” with the cell wall glucan, chitin, and glycoproteins encased within the melanin polymer. This arrangement provides for a very strong and resilient cell wall and protects the glucan/chitin/glycoprotein matrix from digestion from enzymes and damage from free radicals.     

Action of chitinase on spines of the diatom Thalassiosira fluviatilis

An electron microscopic study of the degradation of the chitin spines of the diatom Thalassiosira fluviatilis by Streptomyces chitinase revealed that only the apices of fibrils are broken down. The result suggests that the enzymolysis of crystalline chitinous structures may be rate-limited by the area of microfibril apices available, which varies with chitin source. A suspension of spines can be used as an assay for chitinase activity by monitoring the rate of loss of turbidity, and although this is not a sensitive assay, it does allow assessment of activity on a crystalline substrate.     

The mycelial cell wall of Penicillium charlesii G. Smith NRRL 1887

Mycelial cell wall preparations of Penicillium charlesii G. Smith have been shown to have a total neutral carbohydrate content of 69%. Glucosamine which comprises 12% of the wall is present principally as chitin. Lipids comprise 37.5% of the wall while polypeptides comprise 19.5%. No galactofuranose units are present in the wall of this organism which is known to produce an extracellular β-1,5-galactofuranose containing polymer.     

Induced production of chitinase to enhance entomotoxicity of Bacillus thuringiensis employing starch industry wastewater as a substrate

Induced production of chitinase during bioconversion of starch industry wastewater (SIW) to Bacillus thuringiensis var. kurstaki HD-1 (Btk) based biopesticides was studied in shake flask as well as in computer-controlled fermentors. SIW was fortified with different concentrations (0%; 0.05%; 0.1%; 0.2%; 0.3% w/v) of colloidal chitin and its consequences were ascertained in terms of Btk growth (total cell count and viable spore count), chitinase, protease and amylase activities and entomotoxicity. At optimum concentration of 0.2% w/v colloidal chitin, the entomotoxicity of fermented broth and suspended pellet was enhanced from 12.4 × 10⁹ (without chitin) to 14.4 × 10⁹ SBU/L and from 18.2 × 10⁹ (without chitin) to 25.1 × 10⁹ SBU/L, respectively. Further, experiments were conducted for Btk growth in a computer-controlled 15 L bioreactor using SIW as a raw material with (0.2% w/v chitin, to induce chitinase) and without fortification of colloidal chitin. It was found that the total cell count, spore count, delta-endotoxin concentration (alkaline solubilised insecticidal crystal proteins), amylase and protease activities were reduced whereas the entomotoxicity and chitinase activity was increased with chitin fortification. The chitinase activity attained a maximum value at 24 h (15 mU/ml) and entomotoxicity of suspended pellet reached highest (26.7 × 10⁹ SBU/L) at 36 h of fermentation with chitin supplementation of SIW. In control (without chitin), the highest value of entomotoxicity of suspended pellet (20.5 × 10⁹ SBU/L) reached at 48 h of fermentation. A quantitative synergistic action of delta-endotoxin concentration, spore concentration and chitinase activity on the entomotoxicity against spruce budworm larvae was observed.     

Cooperation between ER stress and calcineurin signaling contributes to the maintenance of cell wall integrity in Candida glabrata

Candida glabrata is the second most common source of Candida infections in humans. In this pathogen, the maintenance of cell wall integrity (CWI) frequently precludes effective pharmacological treatment by antifungal agents. In numerous fungi, cell wall modulation is reported to be controlled by endoplasmic reticulum (ER) stress, but how the latter affects CWI maintenance in C. glabrata is not clearly understood. Here, we characterized a C. glabrata strain harboring a mutation in the CNE1 gene, which encodes a molecular chaperone associated with nascent glycoprotein maturation in the ER. Disruption of cne1 induced ER stress and caused changes in the normal cell wall structure, specifically a reduction in the β-1,6-glucan content and accumulation of chitin. Conversely, a treatment with the typical ER stress inducer tunicamycin up-regulated the production of cell wall chitin but did not affect β-1,6-glucan content. Our results also indicated that C. glabrata features a uniquely evolved ER stress-mediated CWI pathway, which differs from that in the closely related species Saccharomyces cerevisiae. Furthermore, we demonstrated that ER stress-mediated CWI pathway in C. glabrata is also induced by the disruption of other genes encoding proteins that function in a correlated manner in the quality control of N-linked glycoproteins in the ER. These results suggest that calcineurin and ER quality control system act as a platform for maintaining CWI in C. glabrata.     

Stipe wall extension of Flammulina velutipes could be induced by an expansin-like protein from Helix aspersa

Expansin proteins extend plant cell walls by a hydrolysis-free process that disrupts hydrogen bonding between cell wall polysaccharides. However, it is unknown if this mechanism is operative in mushrooms. Herein we report that the native wall extension activity was located exclusively in the 10 mm apical region of 30 mm Flammulina velutipes stipes. The elongation growth was restricted also to the 9 mm apical region of the stipes where the elongation growth of the 1st millimetre was 40-fold greater than that of the 5th millimetre. Therefore, the wall extension activity represents elongation growth of the stipe. The low concentration of expansin-like protein in F. velutipes stipes prevented its isolation. However, we purified an expansin-like protein from snail stomach juice which reconstituted heat-inactivated stipe wall extension without hydrolytic activity. So the previous hypotheses that stipe wall extension was resulted from hydrolysis of wall polymers by enzymes or disruption of hydrogen bonding of wall polymers exclusively by turgor pressure are challenged. We suggest that stipe wall extension may be mediated by endogenous expansin-like proteins that facilitate cell wall polymer slippage by disrupting noncovalent bonding between glucan chains or chitin chains.     

Carbohydrates from the hyphal walls of some Oomycetes

Chemically extracted walls of seven species of Oomycetes were found to contain glucosamine in small amounts, possibly originating from chitin. The species belonging to the order Peronosporales seem to contain less glucosamine than the Saprolegniales.     

Cell wall structure of secreted laccase-silenced strain in Lentinula edodes

Laccase1 (Lcc1) is abundantly secreted from vegetative mycelia into culture medium by Lentinula edodes. Down-regulation of lcc1 in L. edodes results in abnormal hyphal structure and thinner cell wall in mycelia. In this study, we observed the effects of Lcc1 on the hyphal morphology and cell wall structure of L. edodes. A thick cell wall and fibrous layer were clearly observed in the lcc1-silenced strain ivrL1#32, when purified Lcc1 (0.1 mU/mL) was added to the culture medium. The ratio of cell wall polysaccharide contents was compared between the ivrL1#32 strain and the wild-type (WT) strain SR-1, revealing that levels of the alkali soluble β-1,3-1,6-glucan were significantly lower in the lcc1-silenced strain than in the WT strain. Chronological analysis revealed that chitin content in the cell wall did not increase over time, but that the alkali soluble β-1,3-1,6-glucan content increased after Lcc1 secretion in the WT. Taken together, these data suggest that the increased level of β-1,3-1,6-glucan induced by Lcc1 in the mycelial cell wall contributes to increased cell wall thickness and strength.     

Glucosamine and chitin accumulation in cell walls of the yeast Rhodotorula glutinis CBS 3044. Influence of culture conditions

During culture of Rhodotorula glutinis the fall in pH from 4.5 to 2 stimulates the synthesis of chitin; alternatively keeping the pH at 4.5 causes the chitin content to fall largely.However there is no proportional value between the chitin content fall and that of total hexosamines.     

Cu,Zn-superoxide dismutase is required for cell wall structure and for tolerance to cell wall-perturbing agents in Saccharomyces cerevisiae

Here we report that deletion of SOD1, the Cu,Zn-superoxide dismutase in Saccharomyces cerevisiae is sensitive to cell wall-perturbing agents, such as Calcofluor white and Congo red. The sensitivity was restored by retransformation with wild type SOD1 or the addition of N-acetylcysteine or reduced glutathione to the medium. Additionally, the accumulation of reactive oxygen species was observed in sod1Δ mutant in the presence of Calcofluor white or Congo red. Cell wall analysis indicated an increase of cell wall chitin and cell wall thickness in sod1Δ mutant compared to wild type. These results indicate a novel direct connection between antioxidative functions and cell wall homeostasis.