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  • Carbohydrates  (3)
  • Cytochemistry  (1)
  • 1
    Electronic Resource
    Electronic Resource
    Ultrastructural cytochemistry of the diaminobenzidine reaction in the aquatic fungus Entophlyctis variabilis (1977)
    Springer
    Archives of microbiology 114 (1977), S. 123-136 
    Details
    ISSN: 1432-072X
    Keywords: Fungus ; Cytochemistry ; Microbodies ; Development ; Entophlyctis
    Source: Springer Online Journal Archives 1860-2000
    Topics: Biology
    Notes: Abstract Ultrastructural localization of peroxidatic activity was investigated in the chytrid Entophlyctis variabilis with the 3,3′-diaminobenzidine (DAB) cytochemical prodedure. The subcellular distribution of reaction product varied with changes in pH of the DAB medium and with the developmental stage of the fungus. Incubations in the DAB reaction medium at pH 9.2 produced an electron dense reaction product within single membrane bounded organelles which resembled microbodies but which varied in shapes from elongate to oval. At this pH the cell wall also stained darkly. When the pH of the DAB medium was lowered to pH 8.2 or 7.0, DAB oxidation product was localized within mitochondrial cristae as well as in microbodies and zoosporangial walls. As soon as zoospores were completely cleaved out of the zoosporangial cytoplasm, endoplasmic reticulum (ER) also stained. When the wall appeared around the encysted zoospore, ER staining was no longer found. The influence of the catalase inhibitor, aminotriazole, and the inhibitors of heme enzymes, sodium azide and sodium cyanide, on the staining patterns within cells incubated in the DAB media indicates that microbody staining is due to both catalase and peroxidase, mitochondrial staining is due to cytochrome c, and ER staining is due to peroxidase.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF00410773
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  • 2
    Electronic Resource
    Electronic Resource
    The role of kinetosome-associated organelles in the attachment of encysting secondary zoospores ofSaprolegnia ferax to substrates (1989)
    Springer
    Protoplasma 149 (1989), S. 163-174 
    Details
    ISSN: 1615-6102
    Keywords: Adhesion ; Carbohydrates ; Exocytosis ; K-bodies ; Lectins ; Saprolegnia ; Ultrastructure
    Source: Springer Online Journal Archives 1860-2000
    Topics: Biology
    Notes: Summary Electron and fluorescence microscopy were used to identify organelles involved in attachment of secondary zoospores ofSaprolegnia ferax as they were transformed into secondary cysts. When secondary zoospores were exposed to 1.0% peptone in the absence or presence of a substrate, they began to encyst. If substrates were present when encystment was induced, the groove surface of the secondary zoospores adhered to them. The first event in attachment was secretion of contents of the kinetosome-associated organelle (K-body), which was typically oriented with the tubule-filled cavity positioned toward the cell surface of the groove region in the zoospore. The tubules which contained carbohydrates became coarsely granular, the matrix became more fibrous, and the shell remained along the membrane concavity that was formed as the K-body fused with the plasma membrane. Five minutes later, a cyst coat appeared, and cysts were not readily dislodged from a substrate. The concavity was no longer found, presumably because it had evaginated; but a layered pad of adhesion material was between the cyst coat and substrate. The layers of the adhesion pad corresponded to the structure of the matrix of K-bodies. As with the tubules of the K-body, the coarsely granular portion at the edge of the pad stained for carbohydrates. Similarly, the lectins WGA and GS-II labeled with fluorescein stained the rim of the adhesion pad on cysts, indicating the presence of glycoconjugates containing N-acetylglucosamines. Because globular areas near the kinetosomes and groove of zoospores (where K-bodies were located) also bound WGA and GS-II, K-bodies contained the same carbohydrates as the adhesion pad. We conclude that K-bodies function in the attachment of encysting zoospores to substrates as the cell differentiates. The tubular portion of the K-body matrix contains carbohydrates which might assist in the adhesion process.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01322988
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  • 3
    Electronic Resource
    Electronic Resource
    Characterization of cell surface carbohydrates on asexual spores of the water moldSaprolegnia ferax (1993)
    Springer
    Protoplasma 175 (1993), S. 161-172 
    Details
    ISSN: 1615-6102
    Keywords: Carbohydrates ; Cell surface ; Lectins ; Oomycetes ; Saprolegnia ; Spores
    Source: Springer Online Journal Archives 1860-2000
    Topics: Biology
    Notes: Summary In asexual reproduction of the water mold,Saprolegnia ferax, four distinct and sequentially produced spores are involved in dispersal, two of which are motile and two of which are nonmotile. Composition of cell surface glycoproteins may be important in dispersal strategies for each of these stages. Binding patterns of fluorescently labelled lectins were investigated to identify differences in glycoproteins of asexually produced dispersal stages. The pattern of lectin binding to zoospores was diverse. FITC-Con A bound to surfaces of zoospores and membranes of the water expulsion vacuole system, indicating the prescence of mannosyl and glucosyl residues. In zoospores incubated for more than 30 min in FITC-WGA and FITC-GS II. which bind N-acetyl glucosamine, fluorescence was sometimes localized in peripheral, intracellular patches. In shorter incubations, secondary zoospores bound these lectins along the groove region where K-bodies were located. Surfaces of cystospores typically bound FITC-WGA, but not FITC-GS II. FITC-GS II, however, bound to empty cystospore walls, probably because reactive sugars were available at the inner surface of the wall. Germ tubes emerging from cystospores bound labelled WGA and GS II, but not Con A. The same lectin binding pattern was found along discharge papilla of primary cystospores, indicating that modifications in cystospore walls associated with direct germination and zoospore discharge were similar. Thus, glycoproteins involved in early establishment of the hyphal system differ from those forming the cell surface of cystospores. Differences in the binding pattern of lectins to zoospores and cystospores highlight differences between cell surface carbohydrates of motile and nonmotile asexual stages.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01385015
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  • 4
    Electronic Resource
    Electronic Resource
    Production and modifications of extracellular structures during development of chytridiomycetes (1994)
    Springer
    Protoplasma 181 (1994), S. 123-141 
    Details
    ISSN: 1615-6102
    Keywords: Carbohydrates ; Chytridiomycetes ; Extracellular material ; Membranes ; Ultrastructure ; Zoospores
    Source: Springer Online Journal Archives 1860-2000
    Topics: Biology
    Notes: Summary In development of the primitive fungi, chytridiomycetes, unwalled zoospores bearing single, posterior flagella are transformed into walled, round-cells which elaborate the thallus. Production, structural modification, or release of extracellular material are involved with each transition of developmental stage. This article reviews the variety and developmental changes of extracellular materials found at the cell surface of chytridiomycetes. A cell coat, produced from Golgi-derived vesicles during zoosporogenesis, is visible around free swimming zoospores of some chytridiomycetes. How the zoospore surface receives and transduces signals is not widely explored, but it is known that fenestrated cisternae and simple cisternae, which are integrated into the microbody-lipid globule complex, are spatially and structurally associated with the plasma membrane and flagellar apparatus. This spatial association, as well as the cytochemical localization of calcium in fenestrated cisternae, suggest a mechanism for signal transduction and for regulation of zoospore motility. Zoospores become encased in a new layer of extracellular material as the zoospore encysts. Among some chytrids the source of this material is preexisting vesicles which fuse with the plasma membrane. Among other zoospores, a readily identifiable population of encystment vesicles is not apparent, demonstrating that there is no single pattern or mechanism for zoospore encystment in chytridiomycetes. Encysted zoospores developing into thalli, typically produce cell walls with a microfibrillar substructure. Ultrastructural analysis of walls reveals distinctive architecture and remarkable sculpturing which have been used in systematics of some members of chytridiomycetes. Nothing is known as to underlying controls of cytoskeletal elements and plasma membrane enzyme complexes in wall biogenesis. Many changes in cell surface structures accompany thallus maturation. Septa, many traversed with plasmodesmata, are produced in most chytrid thallus types. As sporangia and resting spores prepare for the production and release of zoospores, additional extracellular layers of material are frequently produced. Polarized deposits of extracellular material become discharge plugs, discharge vesicles, or endoopercula. Interstitial material is also released into cleavage furrows. Circumscissile or localized digestion of walls produce operculate or inoperculate exit ports for zoospore release. Cryofixation preserves more extensive extracellular material than does conventional chemical fixation, and broader application of cryofixation may radically alter our current view of cell surface structure. Thus chytridiomycetes exhibit a range in patterns for the occurrence and subsequent modifications of extracellular materials, even for members within the same order. The most universally recognized role for these extracellular materials is protection. Although there is a reasonable view of the types of extracellular material involved in chytridiomycete development, we have only limited understandings of their biogenesis or roles in regulation and communication, areas awaiting more investigations.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1007/BF01666392
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