Masako Osumi

THE ULTRASTRUCTURE OF YEAST : CELL WALL STRUCTURE AND FORMATION

Yeasts are unicellular eukaryotes, and are used widely as a model system in basic and applied fields of life science, medicine, and biotechnology. The ultrastructure of yeast cells was first studied in 1957 and the techniques used have advanced greatly in the 40 years since then; an overview of these methods is first presented in this review. The ultrastructure of budding and dimorphic yeast cells observed with a scanning electron microscope (SEM) and a transmission electron microscope (TEM) after thin sectioning and freeze-etching are then described, followed by discussion of the regeneration of the cell wall of Candida albicans protoplasts detected by cryosectioning. C. albicans protoplasts are regenerated to synthesize microfibrils on their surface. They are aggregated into thicker bundles which are intermeshed, forming a wide-meshed network of long fibrils. These microfibrillar structures are chains of beta-1,3-glucan which are broken down after treatment with beta-1,3-glucanase. Morphologically identical microfibrils are synthesized in vitro by a cell-free system in which the active cell membrane fraction as a source of beta-1,3-glucan synthetase and UDP glucose as the sole substrate are used. The diameter of an elemental fibril of beta-glucan is estimated to be 2.8 nm from the pattern of autocorrelation of the image obtained by computer processing. In contrast, in the presence of aculeacin A the formation of normal fibrillar nets or bundles is significantly inhibited, resulting in the occurrence of short fibrils. These electron microscopic data suggest that aculeacin A inhibits not only the synthesis of beta-1,3-glucan but the aggregation of microfibrils of this polysaccharide, allowing formation of the crystalline structure. On the basis of the cumulative data obtained from the electron microscopic studies, we are led to the assumption that de novo synthesized beta-glucan chains might initially form fine particles which are then transformed into thin fibrils with single to multiple strands which appear to be oriented parallel to each other so that they develop into fibrillar structures. This process of assembly of beta-glucan molecules leads to the development of a fibrous network within the regenerating Candida cell wall. Third, the mechanism of cell wall formation is shown by low-voltage (LV) SEM and TEM, using various techniques and computer graphics, of the regeneration system of Schizosaccharomyces pombe protoplasts: after 10 min of regeneration, the protoplasts begin to grow fibrillar substances of a beta-glucan nature, and a fibrillar network covers the surface of all protoplasts. The network is originally formed as fine particles on the protoplast surface and these are subsequently lengthened to microfibrils 2 nm thick. The microfibrils twist around each other and develop into 8 nm thick fibrils forming flat bundles 16 nm thick. Interfibrillar spaces are gradually filled with amorphous particles of an alpha-galactomannan nature and, finally, the complete cell wall is formed after 12 h. Treatment of reverting protoplasts with RuO4 provided clear TEM images of glucan fibrils with high electron density. The relationship between cell wall regeneration and intracellular organelles was examined by using serial thin sections stained with PATAg and computer-aided three-dimensional reconstruction. The secretory vesicles in a protoplast had increased markedly by 1.4, 3.4, and 5.8 times at 1.5, 3.0, and 5 h, respectively. Three-dimensional analysis indicates that Golgi apparatuses are located close together in the nucleus of the protoplast and are dispersed into the cytoplasm during the progress of cell wall formation.

Three-dimensional arrangement of F-actin in the contractile ring of fission yeast

The contractile ring, which is required for cytokinesis in animal and yeast cells, consists mainly of actin filaments. Here, we investigate the directionality of the filaments in fission yeast using myosin S1 decoration and electron microscopy. The contractile ring is composed of around 1,000 to 2,000 filaments each around 0.6 μm in length. During the early stages of cytokinesis, the ring consists of two semicircular populations of parallel filaments of opposite directionality. At later stages, before contraction, the ring filaments show mixed directionality. We consider that the ring is initially assembled from a single site in the division plane and that filaments subsequently rearrange before contraction initiates.

In situ localization of β-glucans in the cell wall of Schizosaccharomyces pombe

The chemical composition of the cell wall of Sz. pombe is known as β‐1,3‐glucan, β‐1,6‐glucan, α‐1,3‐glucan and α‐galactomannan; however, the three‐dimensional interactions of those macromolecules have not yet been clarified. Transmission electron microscopy reveals a three‐layered structure: the outer layer is electron‐dense, the adjacent layer is less dense, and the third layer bordering the cell membrane is dense. In intact cells of Sz. pombe, the high‐resolution scanning electron microscope reveals a surface completely filled with α‐galactomannan particles. To better understand the organization of the cell wall and to complement our previous studies, we set out to locate the three different types of β‐glucan by immuno‐electron microscopy. Our results suggest that the less dense layer of the cell wall contains mainly β‐1,6‐branched β‐1,3‐glucan. Occasionally a line of gold particles can be seen, labelling fine filaments radiating from the cell membrane to the α‐galactomannan layer, suggesting that some of the radial filaments contain β‐1,6‐branched β‐1,3‐glucan. β‐1,6‐glucan is preferentially located underneath the α‐galactomannan layer. Linear β‐1,3‐glucan is exclusively located in the primary septum of dividing cells. β‐1,6‐glucan only labels the secondary septum and does not co‐localize with linear β‐1,3‐glucan, while β‐1,6‐branched β‐1,3‐glucan is present in both septa. Linear β‐1,3‐glucan is present from early stages of septum formation and persists until the septum is completely formed; then just before cell division the label disappears. From these results we suggest that linear β‐1,3‐glucan is involved in septum formation and perhaps the separation of the two daughter cells. In addition, we frequently found β‐1,6‐glucan label on the Golgi apparatus, on small vesicles and underneath the cell membrane. These results give fresh evidence for the hypothesis that β‐1,6‐glucan is synthesized in the endoplasmic reticulum–Golgi system and exported to the cell membrane. Copyright

Effects of hydrostatic pressure on the ultrastructure and leakage of internal substances in the yeast Saccharomyces cerevisiae

The structural damage to and leakage of internal substances from Saccharomyces cerevisiae 0–39 cells induced by hydrostatic pressure were investigated. By scanning electron microscopy, yeast cells treated at room temperature with pressuresbellw 400 MPa for 10 min showed a slight alteration in outer shape. Transmission electron microscopy, however, showed that the inner structure of the cell began to be affected, especially the nuclear membrane, when treated with hydrostatic pressure around 100 MPa at room temperature for 10 min; at more than 400–600 MPa, further alterations appeared in the mitochondria and cytoplasm. Furthermore, when high pressure treatment was carried out at — 20° C, the inner structure of the cells was severely damaged even at 200 MPa, and almost all of the nuclear membrane disappeared, although the fluorescent nucleus in the cytoplasm was visible by 4,6-diamidino-2-phenylindole (DAPI) staining. The structural damage of pressure-treated cells was accompanied by the leakage of internal substances. The efflux of UV-absorbing substances including amino acid pools, peptides, and metal ions increased with increase in pressure up to 600 MPa. In particular, amounts of individual metal ion release varied with the magnitude of hydrostatic pressures over 300 MPa, which suggests that the ions can be removed from the yeast cells separately by hydrostatic pressure treatment.

Loss of cell wall alpha(1‐3) glucan affects Cryptococcus neoformans from ultrastructure to virulence

Yeast cell walls are critical for maintaining cell integrity, particularly in the face of challenges such as growth in mammalian hosts. The pathogenic fungus Cryptococcus neoformans additionally anchors its polysaccharide capsule to the cell surface via α(1‐3) glucan in the wall. Cryptococcal cells disrupted in their alpha glucan synthase gene were sensitive to stresses, including temperature, and showed difficulty dividing. These cells lacked surface capsule, although they continued to shed capsule material into the environment. Electron microscopy showed that the alpha glucan that is usually localized to the outer portion of the cell wall was absent, the outer region of the wall was highly disorganized, and the inner region was hypertrophic. Analysis of cell wall composition demonstrated complete loss of alpha glucan accompanied by a compensatory increase in chitin/chitosan and a redistribution of beta glucan between cell wall fractions. The mutants were unable to grow in a mouse model of infection, but caused death in nematodes. These studies integrate morphological and biochemical investigations of the role of alpha glucan in the cryptococcal cell wall.

Development of microbodies in Candida tropicalis during incubation in a n-alkane medium

Development of microbodies in Candida tropicalis pK 233 was studied mainly by electron microscopical observation. The yeast cells, precultured on malt extract, scarcely contained microbodies and showed very low catalase activity. When the precultured cells were transferred to a n-alkane medium and incubated with shaking, the number of microbodies increased and concomitantly the activity of catalase was enhanced. That is, both the area ratio of microbodies in the cell and the ratio of microbodies to cytoplasm in area increased significantly during the utilization of n-alkanes for 8 hrs. Localization of catalase in the microbodies was demonstrated cytochemically by use of 3,3′-diaminobenzidine, but other organella in the cell, except for vacuoles appearing in the early growth phase and mitochondria, were not stained with this reagent. Microbodies seemed to grow by division. Biogenesis of microbodies in the yeast cells is also discussed.

A New Strategy of High-Speed Screening and Quantitative Structure-Activity Relationship Analysis to Evaluate Human ATP-Binding Cassette Transporter ABCG2-Drug Interactions

The human ATP-binding cassette (ABC) transporter ABCG2 (BCRP/MXR1/ABCP) plays a critical role in cellular protection against xenobiotics as well as pharmacokinetics of drugs in our body. In the present study, we aimed to analyze the quantitative structure-activity relationship (QSAR) latently residing in ABCG2-drug interactions. We first established standard methods for expression of human ABCG2 in insect cells, quality control of plasma membrane samples by using electron microscopy techniques, and high-speed screening of ABCG2 inhibition with test compounds. Plasma membrane vesicles prepared from ABCG2-expressing Sf9 cells were used as a model system to measure the ATP-dependent transport of [3H]methotrexate (MTX). Forty-nine different therapeutic drugs and natural compounds were tested for their ability to inhibit ABCG2-mediated MTX transport. Based on their inhibition profiles, we performed QSAR analysis using chemical fragmentation codes deduced from the structures of test compounds. Multiple linear regression analysis delineated a relationship between the structural components and the extent of ABCG2 inhibition, allowing us to identify one set of structure-specific chemical fragmentation codes that are closely correlated with the inhibition of ABCG2 transport activity. Based on the QSAR analysis data, we predicted the potency of gefitinib to inhibit ABCG2. The validity of our QSAR-based prediction for gefitinib was examined by actual experiments. Our kinetic analysis experiments suggest that the ABCG2-ATP complex binds gefitinib. The present study provides a new strategy for analyzing ABCG2-drug interactions. This strategy is considered to be practical and useful for the molecular designing of new ABCG2 modulators.

Aberrant chloroplasts in transgenic rice plants expressing a high level of maize NADP-dependent malic enzyme

Abstract. NADP-dependent malic enzyme (NADP-ME) is a major decarboxylating enzyme in NADP-ME-type C4 species such as maize and Flaveria. In this study, chloroplastic NADP-ME was transferred to rice (Oryza sativa L.) using a chimeric gene composed of maize NADP-ME cDNA under the control of rice light-harvesting chlorophyll-a/b-binding protein (Cab) promoter. There was a 20- to 70-fold increase in the NADP-ME activity in leaves of transgenic rice compared to that in wild-type rice plants. Immunocytochemical studies by electron microscopy showed that maize NADP-ME was mostly localized in chloroplasts in transgenic rice plants, and that the chloroplasts were agranal without thylakoid stacking. Chlorophyll content and photosystem II activity were inversely correlated with the level of NADP-ME activity. These results suggest that aberrant chloroplasts in transgenic plants may be caused by excessive NADP-ME activity. Based on these results and the known fact that only bundle sheath cells of NADP-ME species, among all three C4 subgroups, have agranal chloroplasts, we postulate that a high level of chloroplastic NADP-ME activity could strongly affect the development of chloroplasts.

Quantitative evaluation of the enhanced green fluorescent protein displayed on the cell surface of Saccharomyces cerevisiae by fluorometric and confocal laser scanning microscopic analyses.

Abstract. The number of foreign protein molecules expressed on the cell surface of the budding yeast Saccharomyces cerevisiae by cell surface engineering was quantitatively evaluated using enhanced green fluorescent protein (EGFP). The emission from EGFP on the cell surface was affected by changes in pH. The amount of EGFP on the cell surface, displayed as α-agglutinin-fusion protein under control of the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) promoter, was determined at the optimum pH of 7.0. The fluorometric analysis and the image analysis by confocal laser scanning microscopy (CLSM) showed a similar number of molecules displayed on the cell surface, demonstrating that 104–105 molecules of α-agglutinin-fused molecules per cell were expressed. Furthermore, the amount of fluorescent protein expressed on cells harboring a multicopy plasmid was three to four times higher than that on cells harboring the gene integrated into the genome.

Development of an arming yeast strain for efficient utilization of starch by co-display of sequential amylolytic enzymes on the cell surface

Abstract The construction of a whole-cell biocatalyst with its sequential reaction has been performed by the genetic immobilization of two amylolytic enzymes on the yeast cell surface. A recombinant strain of Saccharomyces cerevisiae that displays glucoamylase and α-amylase on its cell surface was constructed and its starch-utilizing ability was evaluated. The gene encoding Rhizopus oryzae glucoamylase, with its own secretion signal peptide, and a truncated fragment of the α-amylase gene from Bacillus stearothermophilus with the prepro secretion signal sequence of the yeast α factor, respectively, were fused with the gene encoding the C-terminal half of the yeast α-agglutinin. The constructed fusion genes were introduced into the different loci of chromosomes of S. cerevisiae and expressed under the control of the glyceraldehyde-3-phosphate dehydrogenase promoter. The glucoamylase and α-amylase activities were not detected in the culture medium, but in the cell pellet fraction. The transformant strain co-displaying glucoamylase and α-amylase could grow faster on starch as the sole carbon source than the transformant strain displaying only glucoamylase.