Changes in the rate of synthesis of wall polysaccharides during the cell cycle of yeast

Reevaluation and comparison of seemingly contradictory literature data on the mode of synthesis of wall polysaccharides during the cell cycle ofSaccharomyces cerevisiae explained the source of discrepancies and demonstrated their general consonance in the following points: 1. The rate of synthesis of glucan and mannan is not constant and does not increase continuously throughout the entire cell cycle. 2. The rate of synthesis of both polysaccharides is considerably reduced at the time of cell division and in the prebudding phase.     

An enzymic method for the determination of chitin and chitosan in fungal cell walls

The free and N-acetyl glucosamine contents, serving as a measure of the amounts of chitosan and chitin respectively, were determined in the chitinase hydrolysates of the cell wall of a wild strain ofNeurospora crassa. Chitinase, obtained from cultures ofSerratia marcescens, could hydrolyse the cell wall completely apart from being capable of hydrolysing preparations of chitin and chitosan. The free and N-acetyl glucosamines, released by chitinase hydrolysis, were determined by a modified Morgan-Elson reaction carried out in the presence and absence of acetic anhydride. The method is capable of estimating chitin and chitosan contents in as little as 100 μg of cell wall material.     

Regulation of chitin synthesis during germ-tube formation in Candida albicans

The synthesis of chitin during germ-tube formation in Candida albicans may be regulated by the first and last steps in the chitin pathway: namely l-glutamine-d-fructose-6-phosphate aminotransferase and chitin synthase. Induction of germ-tube formation with either glucose and glutamine or serum was accompanied by a 4-fold increase in the specific activity of the aminotransferase. Chitin synthase in C. albicans is synthesized as a proenzyme. N-acetyl glucosamine increased the enzymic activity of the activated enzyme 3-fold and the enzyme exhibited positive co-operativity with the substrate, UDP-N-acetylglucosamine. Although chitin synthase was inhibited by polyoxin D (K _i =1.2M) this antibiotic did not affect germination. During germ-tube formation the total chitin synthase activity increased 1.4-fold and the expressed activity (in vivo activated proenzyme) increased 5-fold. These results could account for the reported 5-fold increase in chitin content observed during the yeast to mycelial transformation.Non-Standard Abbreviations GlcNac N-acetyl glucosamine - UDP-GlcNac UDP-N-acetyl glucosamine - PMSF phenylmethylsulphonylfluoride     

Regeneration of the cell wall in protoplasts of Candida albicans

To assess the dynamics of synthesis of the wall by regenerating Candida albicans protoplasts deposition of chitin and mannoproteins were investigated ultrastructurally using wheat germ agglutinin conjugated with either horseradish peroxidase or colloidal gold, and Concanavalin A coupled to ferritin respectively.Freshly prepared protoplasts lacked wheat germ agglutinin receptor sites but after 1–2 h of regeneration, they were detected. After 4–5 h of regeneration, the cell wall showed a discrete structure which was only labelled with wheat germ agglutinin in thin sections. At this stage of regeneration the outermost layer of the wall was labelled with clusters of Concanavalin A-ferritin particles.After 8 h regeneration, the cell wall appeared compact, and homogenously marked with wheat germ agglutinin whereas only the surface layers appeared consistently labelled with Concanavalin A-ferritin.From these observations we conclude that C. albicans protoplasts are able to regenerate in liquid medium a cell wall consisting of a network of chitin fibrils and mannoproteins at least (glucan polymers were not determined in the present cytological study). The former are the fundamental component of the inner layers at early stages of regeneration, whereas the latter molecules are predominant in the outer layers of the wall.Abbreviations WGA-HRP wheat germ agglutinin conjugated with horseradish peroxidase - WGA-Au wheat germ agglutinin conjugated with colloidal gold - Con A-ferritin Concanavalin A coupled to ferritin     

Aspergillus fumigatus exoβ(1‐3)glucanases family GH55 are essential for conidial cell wall morphogenesis

The cell wall of Aspergillus fumigatus is predominantly composed of polysaccharides. The central fibrillar core of the cell wall is composed of a branched β(1‐3)glucan, to which the chitin and the galactomannan are covalently bound. Softening of the cell wall is an essential event during fungal morphogenesis, wherein rigid cell wall structures are cleaved by glycosyl hydrolases. In this study, we characterised the role of the glycosyl hydrolase GH55 members in A. fumigatus fungal morphogenesis. We showed that deletion of the six genes of the GH55 family stopped conidial cell wall maturation at the beginning of the development process, leading to abrogation of conidial separation: the shape of conidia became ovoid, and germination was delayed. In conclusion, the reorganisation and structuring of the conidial cell wall mediated by members of the GH55 family is essential for their maturation, normal dissemination, and germination.     

Chitin in the cell wall of yeasts

Summary According to literature a glucan is the main cell wall constituent of baker's yeast and probably of all yeasts. Chitin is reported in some filamentousEndomycetaceae, but is said to be absent in all other yeasts tested.A modified chitosan sulphate crystallization test for detecting chitin in yeasts and the relevant characteristics of these crystals were described. It was applied to 29 yeast species in addition to baker's and brewer's yeast. ExceptSchizosaccharomyces octosporus all were found to contain chitin as a cell wall constituent. However, the amount was very small, varied in different species and seemed to increase in older cultures.Chitin has also been demonstrated as glucosamine on paper chromatograms of concentrated hydrolysates of the cell wall residue, obtained after treating baker's yeast with boiling dilute alkali and acid.     

Chitosan-mediated changes in cell wall composition, morphology and ultrastructure in two wood-inhabiting fungi

The effect of chitosan on cell wall deposition was investigated in the two wood-inhabiting fungal species Trichoderma harzianum (CBS 597.91) and Sphaeropsis sapinea (NZFS 2725). The study used three independent analytical techniques to quantify chitin in the fungal mycelium. A colorimetric method for the detection of d-glucosamine was compared with two gas chromatography–mass spectroscopy (GC-MS) methods employing alditol acetates analysis and pyrolysis. The latter used a stable-isotope-labelled internal standard, d₃-N-acetyl glucosamine. At least in the case of S. sapinea, the study provided evidence of an increase in the chitin content in the mycelium due to chitosan treatment, indicating that chitosan treatment affected cell wall deposition. Electron microscopy techniques showed alteration in surface morphology and cell wall texture due to chitosan treatment. The implications of these results are discussed with a view to analysing possible mechanisms for growth inhibitory effects of chitosan on fungal hyphae.     

AsSlt2基因对茄链格孢细胞壁完整性的调控

【背景】由茄链格孢(Alternaria solani)引起的马铃薯早疫病被普遍认为是马铃薯生产上的第二大叶部病害,在马铃薯各产区普遍发生,给马铃薯生产造成了巨大的经济损失。【目的】明确AsSlt2基因对茄链格孢细胞壁完整性的影响。【方法】在含有刚果红、细胞壁降解酶和十二烷基硫酸钠(sodiumdodecylsulfate,SDS)等细胞壁胁迫的培养基上观察ΔAsSlt2缺失突变株的生长情况,计算相对生长抑制率;通过实时荧光定量PCR (RT-qPCR)方法检测ΔAsSlt2菌株中细胞壁合成相关基因的表达情况;进一步检测ΔAsSlt2细胞壁中几丁质的含量及胞外酶活性。【结果】ΔAsSlt2缺失突变株对SDS、刚果红、细胞壁降解酶等细胞壁胁迫的敏感性增强,在加入细胞壁降解酶后突变株原生质体释放量显著增多;ΔAsSlt2对外源氧胁迫更敏感,突变株胞外过氧化物酶和漆酶活性均显著降低;进一步研究发现,ΔAsSlt2细胞壁中几丁质含量减少,几丁质合成相关基因与漆酶合成相关基因的表达量均明显降低。【结论】AsSlt2基因在茄链格孢细胞壁的完整性及抵御外界胁迫方面发挥重要作用。     

Mode of increase in cell wall polysaccharides in synchronously growing Saccharomyces cerevisiae

The mode of increase in cell wall polysaccharides of yeast (glucan and mannan) during cell cycle was analyzed using cell wall samples obtained from a synchronous culture. The increase in mannan and total glucan proceeded almost linearly throughout the cell cycle except for a short period of their leveling off at the time of cell division. However, the constituents of glucan behaved characteristically: Alkalisoluble glucan and insoluble glucan increased mainly in the former and the latter half of the cell cycle, respectively.     

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.     

The Cell Wall of Fusarium oxysporum

Sugar analysis of isolated cell walls from three formae speciales of Fusarium oxysporum showed that they contained not only glucose and (N-acetyl)-glucosamine, but also mannose, galactose, and uronic acids, presumably originating from cell wall glycoproteins. Cell wall glycoproteins accounted for 50–60% of the total mass of the wall. X-ray diffraction studies showed the presence of α-1,3-glucan in the alkali-soluble cell wall fraction and of β-1,3-glucan and chitin in the alkali-insoluble fraction. Electron microscopy and lectin binding studies indicated that glycoproteins form an external layer covering an inner layer composed of chitin and glucan.     

2,3-Butanedione monoxime increases sensitivity to Nikkomycin Z in the budding yeast Saccharomyces cerevisiae

Summary Nikkomycin Z (NZ) is a competitive inhibitor of chitin synthase III in the yeast Saccharomyces cerevisiae. Myosin type II-deficient yeast strains (myo1) display a dramatic reduction in growth when chitin synthase III activity is inhibited by NZ, supporting the contention that actomyosin motility plays an important role in maintaining cell wall integrity. A proposed inhibitor of cortical actin polymerization in vitro, 2,3-butanedione monoxime (BDM), also inhibits growth of wild-type yeast strains at a concentration of 20 mM. In this study, we assayed for potential in vivo interplay between BDM-sensitive cell functions and cell wall chitin synthesis by testing for increased sensitivity to NZ during co-treatment with BDM at sub-inhibitory concentrations. Our results show that BDM can increase the sensitivity of yeast cells to Nikkomycin Z.     

Mannan transglycosylase: a novel enzyme activity in cell walls of higher plants

Mannan transglycosylase is a novel cell wall enzyme activity acting on mannan-based plant polysaccharides in primary cell walls of monocotyledons and dicotyledons. The enzyme activity was detected by its ability to transfer galactoglucomannan (GGM) polysaccharides to tritium-labelled GGM-derived oligosaccharides generating tritium-labelled GGM polysaccharides. Mannan transglycosylase was found in a range of plant species and tissues. High levels of the enzyme activity were present in flowers of some kiwifruit (Actinidia) species and in ripe tomato (Solanum lycopersicum L.) fruit. Low levels were detected in mature green tomato fruit and activity increased during tomato fruit ripening up to the red ripe stage. Essentially all activity was found in the tomato skin and outermost 2 mm of tissue. Mannan transglycosylase activity in tomato skin and outer pericarp is specific for mannan-based plant polysaccharides, including GGM, galactomannan, glucomannan and mannan. The exact structural requirements for valid acceptors remain to be defined. Nevertheless, a mannose residue at the second position of the sugar chain and the absence of a galactose substituent on the fourth residue (counting from the non-reducing end) appear to be minimal requirements. Mannan-based polysaccharides in the plant cell wall may have a role analogous to that of xyloglucans, introducing flexibility and forming growth-restraining networks with cellulose. Thus mannan transglycosylase and xyloglucan endotransglycosylase, the only other known transglycosylase activity in plant cell walls, may both be involved in remodelling and refining the cellulose framework in developmental processes throughout the life of a plant.Abbreviations EBM Endo--mannanase - GGM galactoglucomannan - GGMO Galactoglucomannan-derived oligosaccharide - G₂M₅ Di-galactosyl mannopentaitol - M₂–M₅ Mannobiitol to mannopentaitol oligosaccharides - SK+OP Skin plus outer pericarp - XET Xyloglucan endotransglucosylase - XG Xyloglucan     

Comparative subcellular immunolocation of polypeptides associated with xylan and callose synthases in French bean (Phaseolus vulgaris) during secondary wall formation

The Golgi apparatus of plant cells is thought to be the main site of synthesis of cell wall matrix polysaccharides and the terminal glycosylation of glycoproteins. Much of this evidence still depends on earlier biochemical studies employing subcellular fractionation. However acquiring pure Golgi membranes is still difficult and the question of spatial organisation of glycosyl transferases can be addressed by immunolocation of the enzymes. An antibody to a xylan synthase-associated polypeptide from French bean, the enzyme which synthesises the core polysaccharide for secondary wall xylan, has been raised and shown to inhibit its activity. Xylan is deposited in secondary thickenings and the xylan synthase was only detected in appreciable amounts in developing xylem cells. The location within the Golgi stack was observed throughout the dictyosomes. Some enzyme subunits were also detected in post-Golgi vesicles. A second antibody to a non-catalytic M(r) 65000 subunit of beta 1,3- glucan (callose) synthase was used for a comparative study. Although the bulk of this enzyme has been detected in previous studies at plasmamembrane-wall interfaces in sieve plates and stressed tissue, a Golgi-location can be observed in root tip meristematic cells during cell plate formation. The enzyme was present throughout the stacks. Callose was also immunolocated in a similar manner to xylan in secondary walls and thickenings and in pits in developing xylem. In these cells, the callose synthase was detected at the surface of the growing thickenings and the plasmamembrane within the pits.     

Early death at medium acidification and survival after low pH adaptation inCryptococcus neoformans

WhenCryptococcus neoformans was grown in yeast nitrogen base (YNB) supplemented with 0.5% glucose, the medium was acidified to below pH 3 during the exponential growth phase, which caused early growth-phase death in susceptible strains. Even in resistant strains, 30–70% cells died if incubated for 2 d in YNB supplemented with 1.5% glucose, whereas the remaining cells survived long. Two types of fatal alterations have been observed in dead cells. In the first type, release of cytoplasm occurred through weakened parts of the cell wall; structures attached to cell walls of dead cells were shown to be rich in proteins by FITC staining, indicating their cytoplasmic origin. In the second type, cells shrank distinctly with no sign of wall rupture. The shrinkage may be due to dysfunction of the plasma membrane at low pH. The mechanism of cell survival in medium below pH 3 was also examined. Aniline blue alone, or calcofluor together with methylene blue, allowed cell wall glucan or chitin and dead cell cytoplasm to be stained simultaneously. In the later stages of incubation, cells showing bright staining for cell wall glucan and chitin emerged. These changes in cell wall synthesis could be considered as an adaptation mechanism to acidification of the medium, because such cells survived longer than cells showing no change in the cell wall staining pattern.     

Chitin synthesis in Saccharomyces cerevisiae in response to supplementation of growth medium with glucosamine and cell wall stress

In Saccharomyces cerevisiae most chitin is synthesized by Chs3p, which deposits chitin in the lateral cell wall and in the bud-neck region during cell division. We have recently found that addition of glucosamine (GlcN) to the growth medium leads to a three- to fourfold increase in cell wall chitin levels. We compared this result to the increases in cellular chitin levels associated with cell wall stress and with treatment of yeast with mating pheromone. Since all three phenomena lead to increases in precursors of chitin, we hypothesized that chitin synthesis is at least in part directly regulated by the size of this pool. This hypothesis was strengthened by our finding that addition of GlcN to the growth medium causes a rapid increase in chitin synthesis without any pronounced change in the expression of more than 6,000 genes monitored with Affymetrix gene expression chips. In other studies we found that the specific activity of Chs3p is higher in the total membrane fractions from cells grown in GlcN and from mutants with weakened cell walls. Sucrose gradient analysis shows that Chs3p is present in an inactive form in what may be Golgi compartments but as an active enzyme in other intracellular membrane-bound vesicles, as well as in the plasma membrane. We conclude that Chs3p-dependent chitin synthesis in S. cerevisiae is regulated both by the levels of intermediates of the UDP-GlcNAc biosynthetic pathway and by an increase in the activity of the enzyme in the plasma membrane.     

Hyphal growth ofHypomyces chlorinus Tul.: An autoradiographic study

Summary The incorporation of the chitin precursor N-acetyl-D-(1-³H) glucosamine byH. chlorinus has been studied by light and electron microscopic autoradiography. Light microscopic autoradiography showed that the incorporation occured preferentially at the hyphal apex. Autoradiograms from electron microscopy were quantitatively evaluated to determine the relative radioactivity incorporation between the cell wall and cytoplasm: this showed that (³H) incorporation took place mainly in the plasmalemma-wall complex. However a small amount of N-acetyl glucosamine can enter into the cytoplasmic space and is then transported by endomembranes (Golgi apparatus-vesicles) to the plasmalemma-cell wall interface before polymerization.Abbreviations PATAg Periodic acid-thiocarbohydrazide-silver proteinate - PTA phosphotungstic acid     

N-Glycyl-glucosamine: A novel constituent in the cell wall of Halococcus morrhuae

The dinitrophenyl-derivative of N-glycylglucosamine was isolated from partially hydrolyzed dinitrophenylated cell walls of Halococcus morrhuae CCM 859. To increase the yield of amino-terminal glycine residues, halococcal cell walls were treated with alkali or acid prior to dinitrophenylation. Authentic N-glycyl-glucosamine was used as a reference substance. A substitution of the amino group of glucosamine by an amino acid has so far not been found in any other wall of a pro- or eucaryotic cell. Since only 5% of the glycine residues reveal an unsubstituted carboxyl group within intact cell walls, glycine may play a role in connecting glycan strands through peptidic linkages between the amino group of glucosamine and the carboxyl group of an uronic acid or gulosaminuronic acid.Abbreviations DNP dinitrophenyl     

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.