Ultracytochemical characterization of non-specific acid phosphatase activities in Saccharomyces cerevisiae.

Glutaraldehyde prefixation causes a considerable inactivation of the acid phosphatase of yeast protoplasts in dependence on the duration of aldehyde influence. Lead ions necessary for ultracytochemical demonstration effect a still stronger inhibition of enzymatic activity. Prefixation, however, protects the enzyme from further inhibition by lead. At pH 4.4 in intact cells acid phosphatase activities are mainly localized in the periplasmic space and in vesicles fused with the plasma membrane. The cell wall and cytoplasm usually remain free of reaction products. On the cell surface activities are found in form of globular lead deposits. At pH 5.2 and 6.3 the periplasmic activity appears decreased compared to that at lower pH values and the intracellular activity is increased. The plasma membrane of protoplasts is completely free of precipitates. The intracellular activity sites of protoplasts (cisternae of endoplasmic reticulum and/or Golgi-like system, small vesicles, central vacuole, nuclear envelope) are the same as for intact cells. The occurrence of at least two forms of acid phosphatase in S. cerevisiae id deduced.     

Modulation of a Cell Surface Glycoprotein in Yeast: Acid Phosphatase

Upon inorganic phosphate starvation the cell wall glycoprotein acid phosphatase of yeast Saccharomyces cerevisiae is derepressed. Purified acid phosphatase isolated from early log phase cells differs in reactivity and stability from acid phosphatase from late log phase cells indicating that the two enzymes are structurally different. This demonstrates that the yeast cell has not only the capacity to regulate the amount of acid phosphatase but also the ability to vary (modulate) the structure of the secreted enzyme. Modulation of acid phosphatase may be a mechanism which is involved in morphogenetic and behavioral differentiation of the yeast cell.     

Localization of acid phosphatase in Saccharomyces cerevisiae: a clue to cell wall formation.

Acid phosphatase is present in two layers of the cell envelope of Saccharomyces cerevisiae. These are separated by another layer, which is free of acid phosphatase. We have evidence that the cell wall is built up in two stages, which are independent. In the first stage, the cell wall is built up during the formation of the bud. Glucanase vesicles are involved in this process. In the second stage, a thick layer is deposited at the inside against the new cell wall. This results in the thick, rigid wall of the mature yeast cell. This latter layer is probably assembled on the outer surface of the plasmalemma.     

Expression of human T-cell leukemia virus type I envelope protein in Saccharomyces cerevisiae

The entire envelope gene of human T-cell leukemia virus type I (HTLV-I) was inserted into an expression vector and expressed under the control of the repressible acid phosphatase promoter in yeast (Saccharomyces cerevisiae). The product in yeast cells was glycosylated into heterodisperse proteins.     

Permeability of yeast cell envelope to fluorescent galactosylated telomers derived from THAM

The work reported herein deals with the study of cellular recognition and permeability phenomena in yeasts. Various galactosylated organic telomers derived from trishydroxymethyl-aminomethane (THAM) and bearing fluorescent moieties were synthesized in order to measure their ability to cross the yeast cell envelope. Grafting fluorescent probes on the organic telomer backbone allowed us to study their specific behaviors toward the yeasts by fluorescence microscopy. Yeasts belonging to the genera Kluyveromyces and Saccharomyces were used for this study. With Saccharomyces yeast cells bearing mannose-specific lectins or lectin-like proteins, on their outer surface, all the galactosylated or nongalactosylated organic telomers passed through the cell envelope and invaded the cytoplasm. With Kluyveromyces yeast cells bearing galactose-specific lectins, the galactosylated organic telomers were blocked at the outer surface while the nongalactosylated derivatives crossed the cell envelope. Moreover, preincubation of Kluyveromyces yeasts with galactose or methylgalactose inhibited the cell surface anchorage of the organic telomers and allowed their penetration into the cytoplasm. When assays were performed on spheroplasts of both Kluyveromyces and Saccharomyces yeasts, no fixation on the surface could be observed, and all the derivatives went through the membrane and invaded the cytoplasm.     

Analysis of the BiP gene and identification of an ER retention signal in Schizosaccharomyces pombe.

We have cloned the gene for the resident luminal ER protein BiP from the fission yeast, Schizosaccharomyces pombe. The predicted protein product is equally divergent from the budding yeast and mammalian homologues. Disruption of the BiP gene in S. pombe is lethal and BiP mRNA levels are regulated by a variety of stresses including heat shock. Immunofluorescence of cells expressing an epitope-tagged BiP protein show it to be localized to the nuclear envelope, around the cell periphery and in a reticular structure through the cytoplasm. Unexpectedly, we find the BiP protein contains an N-linked glycosylation site which can be utilized. The C-terminal four amino acids of BiP are Ala-Asp-Glu-Leu, a new variant of the XDEL sequence found at the C-termini of luminal endoplasmic reticulum proteins. To determine whether this sequence acts as a sorting signal in S.pombe we expressed an acid phosphatase fusion protein extended at its C-terminus with the amino acids ADEL. Analysis of the sorting of this fusion protein indicates that the ADEL sequence is sufficient to cause the retention of proteins in the endoplasmic reticulum. The sequences DDEL, HDEL and KDEL can also direct ER-retention of acid phosphatase in S.pombe.     

Effect of endocytosis upon acid phosphatase activity ofTetrahymena pyriformis

Summary Increased endocytosis inTetrahymena pyriformis, produced by presenting starved cells with either peptone-yeast extract medium or killed yeast cell suspension, results in increased cellular acid phosphatase activity.Tetrahymena, grown in peptone-yeast extract medium, showed increased acid phosphatase activity after phagocytosis of yeast cells. This increase was not apparent until about one hour after presentation and was maximal at about 2.5 hours.Tetrahymena, grown on yeast suspension, showed little increase in acid phosphatase activity on presentation with peptone-yeast extract medium. These results may indicate that endocytosis, of either particles or solutes, produces an adaptive increase in acid phosphatase activity (presumably lysosomal in nature) which is related to feeding.Histochemical examination failed to localise the increase in acid phosphatase activity cellularly, but small particles, of about 1 diameter, which showed acid phosphatase activity and were presumably lysosomes were noted. Closely orientated yeast cells showed varying intensities of lead deposition, from absence to intense staining. This suggests that newly ingested yeast cells may be ingested initially in a single phagosome and that thereafter one or more lysosomes may fuse with them.     

A rapid method for determination of acid phosphatase activity of whole yeast cells

A simple and rapid procedure for determination of intracellular acid phosphatase activity without the need for disruption of cells is described. Candida lipolytica cell suspension was treated with 0.1% Triton X-100 for 30 min at room temperature and with intermittent shaking. The enzyme assay is carried out directly with the permeabilized cell suspension. Permeabilization of the yeast cells to p -nitrophenylphosphate by Triton X-100 provides almost 100% efficiency in determining the total acid phosphatase activity compared to results obtained with disrupted yeast cells.     

Localized secretion of acid phosphatase reflects the pattern of cell surface growth in saccharomyces cerevisiae

Secretion of cell wall-bound acid phosphatase by Saccharomyces cerevisiae occurs along a restricted portion of the cell surface. Acid phosphatase activity produced during derepressed synthesis on a phosphate-limited growth medium is detected with an enzyme-specific stain and is localized initially to the bud portion of a dividing cell. After two to three generations of phosphate-limited growth, most of the cells can be stained; if further phosphatase synthesis is repressed by growth in excess phosphate, dividing cells are produced in which the parent but not the bud can be stained. Budding growth is interrupted in α-mating-type cells by a pheromone (α-factor) secreted by the opposite mating type; cell surface growth continues in the presence of α-factor and produces a characteristic cell tip. When acid phosphatase synthesis is initiated during α-factor treatment, only the cell tip can br stained; when phosphate synthesis is repressed during α-factor treatment, the cell body but not the tip can be stained. A mixture of derepressed α cells and phosphatase-negative α cells form zygotes in which mainly one parent cell surface can be stained. The cell cycle mutant, cdc 24 (Hartwell, L.H. 1971. Exp. Cell Res. 69:265-276), fails to bud and, instead, expands symmetrically as a sphere at a nonpermissive temperature (37 degrees C). This mutant does not form a cell tip during α-factor treatment at 37 degrees C, and although acid phosphatade secretion occurs at this temperature, it is not localized. These results suggest that secretion reflects a polar mode of yeast cell- surface growth, and that this organization requires the cdc 24 gene product.     

Secretion of an active nonglycosylated form of the repressible acid phosphatase of Saccharomyces cerevisiae in the presence of tunicamycin at low temperatures

The role of mannan chains in the formation and secretion of active acid phosphatase of yeast (Saccharomyces cerevisiae), a repressible cell surface mannoprotein, was studied in yeast protoplast systems by using tunicamycin at various temperatures. At 30 degrees C, tunicamycin-treated protoplasts did not produce active acid phosphatase; however, at 25 or 20 degrees C they formed and secreted active enzyme. This form of acid phosphatase gave 59-, 57-, and 55-kDa bands on SDS-PAGE which neither bound to concanavalin A Sepharose, nor changed in molecular weight upon treatment with endoglycosidase H, indicating that the peptides are nonglycosylated. The nonglycosylated form, like its glycosylated counterpart, is a dimer on the basis of gel permeation chromatography. The Km for para-nitrophenyl-phosphate and Ki for inorganic phosphate of both glycosylated and nonglycosylated acid phosphatases were almost the same. These results suggested that 1) the conformation of the nonglycosylated acid phosphatase secreted at low temperatures is probably identical with that of the glycosylated one, and 2) the conformation of acid phosphatase is very important for its secretion. The rate of intracellular transport of nonglycosylated acid phosphatase is about one-fourth that of the glycosylated enzyme, indicating that glycosylation facilitates the transport of acid phosphatase proteins.     

A cytochemical study of the localization of acid phosphatase in Saccharomyces cerevisiae at different growth phases.

Synopsis The localization of acid phosphatase in the yeastSaccharomyces cerevisiae at different growth phases has been studied. It was shown to be crucial for authentic location of acid phosphatase that the cytochemical reaction be performed on whole cells. Dimethylsulphoxide was used to alleviate the effects of fixation of the yeast cells with glutaraldehyde; the sulphoxide did not affect the distribution of acid phosphatase in the cells. It has been established that in exponentially-growing cells acid phosphatase is localized mostly in small vacuolar compartments. In mature cells, the bulk of acid phosphatase is found in the central vacuole, although a significant amount of the enzyme is detectable in the plasma membrane and the adjacent vesicles.     

The ultrastructure of the cell surface and plasma membrane of exponential and stationary phase cells of Schizosaccharomyces pombe,grown in different media

In order to study the ultrastructure of the cell surface and plasma membrane of Schizosaccharomyces pombe as a function of growth conditions we investigated exponential and stationary phase cells grown in rich and minimal medium.Electron microscopic preparation techniques based on rapid cryofixation (without cryoprotectants) were used. The intramembraneous aspects of the plasma membrane were described by freeze fracturing. For the first time the dynamic surface structures could be directly analyzed by freeze drying in the scanning electron microscope and in thin section of freeze substituted samples. This preparation techniques reveal hair-like structures on the surface of yeast cells. The hairs of cells grown in the rich medium are longer than those grown in the minimal medium. A mutant defective in the structure of a cell surface galactomannoprotein (acid phosphatase) reveals (under conditions of maximal acid phosphatase expression) a cell surface structure that differs from the wild type. It is likely that the hairs represent the peripheral galactomannan layer or part of it.On the membrane fracture faces the number, shape, distribution and state of aggregation of the intramembraneous particles are different between membranes of growing and non-growing cells and between cells grown under different physiological conditions. In the minimal medium corresponding periodical structures on the plasmic and exoplasmic fracture faces were observed, which clearly differ between exponential and stationary phase cells. The number, length and depth of plasma membrane invaginations increase as the cells go from the exponential phase to the stationary phase. Short and flattened invaginations are filled with thin periodic structures.     

Okadaic acid inhibits a protein phosphatase activity involved in formation of the mitotic spindle of GH4 rat pituitary cells.

Okadaic acid, a selective inhibitor of serine/threonine protein phosphatases, was utilized to investigate the requirement for phosphatases in cell cycle progression of GH4 rat pituitary cells. Okadaic acid inhibited GH4 cell proliferation in a concentration-dependent manner with a half-maximal inhibition (IC50) of approximately 5 nM. Treatment of GH4 cells with 10 nM okadaic acid resulted in a 40-60% decrease in phosphatase activity and an increase in the proportion of phosphorylated retinoblastoma (RB) protein. Cell cycle analysis indicated that okadaic acid increased the percentage of cells in G2-M, decreased proportionally the percentage of cells in G1 phase, and had little effect on the percentage of cells in S-phase. The absence of a change in the proportion of S-phase cells indicates that G1-specific phosphatases responsible for dephosphorylation of RB protein were not inhibited by 10 mM okadaic acid. Mitotic index revealed that 10 nM okadaic acid decreased proliferation of GH4 cells specifically by slowing the progression through mitosis. Immunostaining with anti-tubulin demonstrated that 10 nM okadaic acid-treated mitotic cells contained mitotic spindles; however, the spindle apparatus in these cells frequently contained multiple poles. These results suggest that the organization of spindle microtubules during prometaphase requires a protein phosphatase that is sensitive to nanomolar concentrations of okadaic acid. Chromosomes in 10 nM okadaic acid-treated cells appear to be attached to spindle microtubules and the nuclear envelope is absent. The effects of okadaic acid on the spindle differ from those elicited by the calcium channel blocker, nimodipine, indicating that this okadaic acid sensitive phosphatase is not part of the calcium signalling events which participate in mitotic progression.     

PROGRAMMED CELL DEATH IN THE HONEY-BEE (APIS MELLIFERA L.) LARVAE MIDGUT

The histochemical and cytochemical localization of acid phosphatase has been used in an attempt to map the sites of cellular lysis and death. Reaction product was found both in the brush border of the midgut epithelium and in the basal membrane. Vacuolar acid phosphatase activity was found in the regenerative epithelial cells. Extra-cisternal reaction product was associated with the endoplasmic reticulum which was dilated in lysed areas of the cytoplasm. Free acid and alkaline phosphatase activity was found in the basal area of the midgut epithelial cells and the former also occurred in the haemocoel. In the tracheoblastic cells only vacuolar acid phosphatase activity was seen. Chromatin aggregates were distributed throughout the nucleus and the nuclear envelope showed some infolding. Certain mature epithelial cells proved positive for anti-histone associated DNA fragmentation indicative of programmed cell death.     

Influence of fluconazole at subinhibitory concentrations on cell surface hydrophobicity and phagocytosis of Candida albicans

Cell surface hydrophobicity (CSH) status influences virulence of Candida albicans and decreases the susceptibility of yeast cells to phagocytic killing. We tested whether subinhibitory concentrations of fluconazole, which is widely used in the treatment and prophylaxis of candidiasis, affect CSH and the susceptibility of C. albicans to enzymatic digestion by glucanase and to phagocytic killing. Treatment of yeast cells with subinhibitory fluconazole concentrations resulted in greater phagocytosis. This effect was independent of CSH but may be related to increased cell wall porosity resulting from alterations in the cell envelope. The use of subinhibitory concentrations of fluconazole in patients with competent phagocytes may contribute to resistance to candidiasis regardless of yeast CSH status.     

Production of an exocellular acid phosphatase by the yeast Hansenula holstii NCYC 560

1. The yeast Hansenula holstii NCYC 560 produced invertase and an inducible acid phosphatase located betweent the cytoplasmic membrane and the yeast cell wall. 2. These enzymes were also found in the culture medium outside the cell boundaries. 3. The amount of cell wall mannan in cells grown in phosphate-limited medium decreased in comparison with that of cells grown in phospahte-rich medium. 4. It is proposed that the mannan in this yeast is a loose and highly permeable structure, allowing external enzymes to leave the cell boundaries.     

Biochemical and genetic evidence that yeast extracellular protein phosphatase activity is due to acid phosphatase

In this paper evidences are presented strongly confirming that an extracellular 32P-phosphopeptide phosphatase activity of yeast is accounted for by acid phosphatase. Dephosphorylation of 32P phosphoseryl peptides was achieved with whole yeast cells, thus demonstrating extracellular location of protein phosphatase activity. The acid phosphatase and protein phosphatase activity copurified throughout purification procedure. Purified enzyme showed the same pH-profile and had the same Km value with phosphopeptide substrate as intact cells. Protein phosphatase activity is repressed by phosphate in the same manner as acid phosphatase activity, showing that not only repressible but also constitutive acid phosphatase displays protein phosphatase activity. Using mutant strains defective in acid phosphatase activity it was confirmed that acid phosphatase and protein phosphatase activities are the products of the same gene(s).     

The enzyme cytochemistry of the intracellular organelles in the rat choroid plexus epithelial cell

Electron microscopic cytochemical studies on the rat choroid plexus epithelium have revealed enzymatic sites for the activities of acid phosphatase, glucose-6-phosphatase and thiamine pyrophosphatase on different organelles. Only the activity of acid phosphatase has been previously described. Acid phosphatase, glucose-6-phosphatase and thiamine pyrophosphatase were respectively situated mainly in the lysosomes, in the endoplasmic reticulum an nuclear envelope, and in the Golgi complex. These three enzymes can thus be considered as marker enzymes for their respective organelles in the choroid plexus epithelial cells as well as in other tissue cells. The possible function of these enzymes in the choroid plexus epithelial cells is also briefly discussed.