Electron microscopy of the transitional conversion cell of Histoplasma capsulatum

Aspects of the fine structure of the transitional conversion cell formed during the early stages of the yeast to mold morphogenesis ofHistoplasma capsulatum as seen in ultrathin sections are described and illustrated by electron micrographs. Formation of the transitional cell was observed to occur with the highest degree of frequency between the 18th and 24th hr following induction of the conversional stimulus, although many yeastlike cells were observed to undergo degeneration or to initiate conversion only to abort the process. Cytoplasmic streaming and organelle migration from the parent yeast to the transitional cell was observed to occur prior to septation. The cell wall of the transitional form is thinner than that of the yeast and appears to arise from the inner portion of the laminated cell wall adjacent to the plasma membrane of the converting yeastlike cell. Interseptal or Woronin bodies were observed in association with the septal pore of the completed septum and were observed in the cytoplasm of both the yeastlike and transitional cell. The presence of these structures support strongly the pre-hyphal character of the converting cell complex.     

Yeastlike to mycelial phase transformation of Histoplasma capsulatum as observed by scanning electron microscopy

Details of the sequential events occurring during the critical phases of yeast to mold morphogenesis of the dimorphic fungal pathogenHistoplasma capsulatum as seen by the new technique of scanning electron microscopy are described and illustrated by electron micrographs.No conspicuous surface sculpturing was observed for the normal yeastlike cell immediately before or the newly formed hyphal cell after the critical period of transformation. However, both the parent yeastlike cell as well as the intermediate conversional cell shows a furrowing of the external cell surface which is due possibly to changes in internal cell pressure resulting from the migration of cell contents into the newly forming hyphal cell.     

Paracoccidioides brasiliensis: Conversion of Yeastlike Forms into Mycelia in Submerged Culture

Details of the sequential morphological changes occurring during yeastlike to mycelial-form conversion of the dimorphic pathogen Paracoccidioides brasiliensis are described and illustrated by photomicrographs. Conversion of yeastlike to hyphal morphology was initiated by changing the temperature of incubation from 37 to 23 C. Production by the parent yeastlike cells of elongated buds developing into hyphae started to be conspicuous after 24 hr of incubation at 23 C. After 120 hr of incubation, growth was almost exclusively filamentous. Direct transformation of parent yeastlike cells into hyphae was not observed. Dry weight increased continuously during the conversion process in spite of the gradual disappearance of the parent yeastlike cells. Concurrent studies showed that changes in ribonucleic acid and deoxyribonucleic acid content per unit dry weight are about the same whether the yeastlike cells are undergoing conversion at 23 C or growing normally at 37 C, and that deoxyribonucleic acid synthesis is apparently required for bud formation in both cases.     

Drug—induced alterations in the ultrastructural organization of Histoplasma capsulatum and Blastomyces dermatitidis

Aspects of the fine structure as seen in thin section of yeastlike cells ofHistoplasma capsulatum andBlastomyces dermatitidis exposed to polyenic antibiotics are described and illustrated by electron micrographs. The exposure of log phase yeastlike cells to minimal fungicidal concentrations of both amphotericin B (Fungizone) and hamycin resulted in detectable alterations of the plasma membrane, and, to a lesser extent, the mitochondria. WithH. capsulatum, ultrastructural changes were observed to occur within 1 h exposure to amphotericin B. Marked degenerative changes and plasmolysis were observed to occur within 6 hrs exposure of the yeastlike cells to both polyenes. The observed changes in ultrastructural appearance are compatible with the concept of binding of the polyene with membrane sterol and subsequent damage due to alterations of permeability.     

Electron microscopy of yeastlike cell development from the microconidium of Histoplasma capsulatum.

Fine details of the sequential morphological events occurring during transition of microconidia (spores less than 5 micrometer in diameter) to the yeastlike phase of Histoplasma capsulatum as seen in ultrathin section are described and illustrated by electron micrographs. Masses of microconidia were obtained when the fungas was grown on a garden soil extract medium. Spores were incubated under in vitro environmental conditions conducive for phase transition (an enriched medium at 37 degrees C). Within 48 h of incubation, the microconidia either germinated to give rise to a short mycelium or the germ tube process became a yeast mother cell without further extension. The wall of the yeast mother cell was thin and smooth, and its cytoplasmic content was ultrastructurally complex, consisting of numerous lipid bodies, vacuoles, glycogen-like deposits, and membrane systems. Within 96 h, the mother cell underwent multipolar budding to form simultaneously linear hyphal and/or ovate yeastlike daughter cells. During the transition, new cell wall materials of the germ tube, the mother cell, and yeastlike daughter cells arose by blastic action from the innermost layer(s) of the wall of the precursor form. Lomasome-like vesicles were often seen in association with areas of new cell wall formation. After organellar migration into and septation of the daughter cells, the yeast mother cell's cytoplasmic content underwent marked degenerative changes.     

Spontaneous feline sporotrichosis: A fine structural study

Fine structural details of the parasitic yeastlike phase of Sporothrix schenckii contained in biopsy tissue from a naturally-occurring case of disseminated feline sporotrichosis are described and illustrated by electron microscopy. Both free and phagocytosed fungal cells were observed. The fungal cells were contained within an extracellular, electron transparent vacuolar area which was bounded by a limiting membrane of probable host origin. The yeastlike cells were characterized by a conspicuous layer of osmiophilic microfilaments which occurred along the outermost surface of the cell wall. In many yeastlike cells, scattered, membranebound vacuoles containing electron opaque material were observed in the cytoplasm. Asteroid bodies were not observed.     

Ultrastructure of Acrasis rosea,a Cellular Slime Mold,During Development*

SYNOPSIS. An ultrastructural study of the myxamoebae of Acrasis rosea in the vegetative, aggregative and culminative stages was made. An intracytoplasmic system of microfibrillar bundles develops as the cells enter the aggregative stage and commence the morphogenetic sequence leading to the construction of a fruiting body. The fibrillar bundles disappear in the cells of the mature fruiting body. No relevant ultrastructural differences were observed between spores, stalk cells and microcysts. Each of these cells is surrounded by a single-layered coat of fibrillar material that is oriented parallel to the cell surface. Tubular structures were observed between the plasma membrane and the cell coat. The tubules may be layered along the cell periphery or they may be recessed in pockets formed by the plasma membrane. They resemble lomasomes typical of fungal cells. The myxamoebae of A. rosea clearly differ from the Dictyostelium-type myxamoebae in mitochondrial structure, the presence of lamellate structures in the nucleolus and the absence of prespore vacuoles.     

Immunocytochemical ultrastructural analysis of chromatophore membrane formation in Rhodospirillum rubrum.

An immunocytochemical ultrastructural study of Rhodospirillum rubrum cultured under semiaerobic conditions was conducted to correlate the localization of functional components with membrane formation. R. rubrum is a facultatively phototrophic organism. Under reduced oxygen, this bacterium forms an intracytoplasmic chromatophore membrane that is the site of the photosynthetic apparatus. Immunogold techniques were used to localize intracellular protein antigens associated with the photosynthetic apparatus. Antibody, demonstrated by immunoblotting to be specific for the reaction center and light-harvesting photochemical components, was conjugated to colloidal gold particles and used for direct immunolabeling of fixed, sectioned specimens. Membrane invaginations appeared by 4 h after transition to induction conditions, and mature chromatophore membrane was abundant by 22 h. The occurrence of chromatophore membrane was correlated with bacteriochlorophyll a content and the density of the immunolabel. In uninduced (aerobic) cells and those obtained from cultures 0.5 h posttransition, the immunogold preferentially labeled the peripheral area of the cell. In contrast, in cells obtained after 22 h of induction, the central region of the cell was preferentially immunolabeled. These findings provided immunocytochemical evidence supporting the hypothesis that the chromatophore membrane is formed by invagination of the cytoplasmic membrane.     

Ultrastructural Studies on the Yeastlike and Mycelial Phases of Sporotrichum schenckii

Fine details of the internal and external morphology of the yeastlike and mycelial phases of the dimorphic fungal pathogen Sporotrichum schenckii as seen in ultrathin sections are described and illustrated by electronphotomicrography. Comparisons of yeastlike phase ultrastructure were made using two different methods of fixation and embedding. The internal morphology of the two forms of yeastlike S. schenckii was in many ways similar to that of similarly dimorphic fungi and yeasts studied by other authors. However, the use of the glutaraldehyde-osmium in agar fixation technique suggests the presence of an electron transparent capsular or slime layer with associated electron dense microfibrils to be present external to the cell wall of the yeastlike phase but not the mycelial phase. Mycelial phase S. schenckii was found to contain many of the internal microstructures reported for other filamentous dimorphic fungi. Conidia production in agitated liquid culture was found to be restricted since only rare sessile conidia were observed.     

Deviated formation of intestinal glycocalyx in human stomach cancer cells. Another type of signet ring cell.

The process of glycocalyx formation by the trilaminar membrane was investigated at the subcellular level by use of cultivated cancer cells derived from a human stomach adenocarcinoma. Glycocalyx was apparently synthesized on the characteristic trilaminar membrane of Golgi-derived vesicles which gave rise to cytoplasmic vacuoles which, in turn, fused to form an intracytoplasmic cyst. Characteristic microvilli similar to those of intestinal epithelium extended from the membrane lining the intracytoplasmic cyst. These ultrastructural features agree with earlier histochemical findings in suggesting intestinal metaplasia in the origin of the gastric tumor. The morphologic features of the cancer cells clearly indicated that glycoprotein is first synthesized in the Golgi complex and fully formed mucoprotein then emerges as membrane-bound glycocalyx in the vesicles budding from the Golgi stacks. The glycocalyx layer is an integral part of the external leaflet of the characteristic trilaminar membrane. Abundant deposits of glycocalyx in the intracytoplasmic cyst constituted the ultrastructural basis for a distinctive type of signet ring cell that differed from mucous signet ring cells derived from goblet cells.     

Ultrastructural localization of glycoproteins in rabbit fibroblasts altered by Herpes simplex virus type 1 infection

The periodic acid-thiocarbohydrazide (SO2)--OsO4 method was used to examine the distribution of glycoproteins in rabbit fibroblast cells infected with Herpes simplex virus type 1. In non-infected cells, a low level of staining was seen over the plasma membrane and the membranes of the Golgi apparatus. At 17 hr post-infection, the intensity of reaction was increased to include not only a relatively heavy staining of the plasma membrane, including the numerous microvilli characteristic of infected cells, and of the newly proliferated Golgi membranes, but also the envelopes of intracytoplasmic and extracellular virions. A very faint but only occasional staining also was associated with the virus-induced reduplications of the inner nuclear membrane and the envelopes of associated enveloping nucleocapsids. We suggest that such differences in the intensity of staining may be related either to the amount of glycoproteins or to the sequential maturation of the viral glycoproteins. We also observed that the structurally modified portions of the Golgi membranes at the position where intracytoplasmic naked nucleocapsids bud into the Golgi cisternae usually exhibit a more intense reaction for glycoproteins than do the adjacent portions of the Golgi membranes. This supports the evidence for an envelopment of nucleocapsids in the cytoplasm, but it does not indicate whether this event obligatorily follows or only occasionally takes the place of the envelopment of nucleocapsids at the inner nuclear membrane. In either event, the envelopes of all mature virions exhibit a prominent reaction to glycoproteins.     

Plasma membrane-cell wall adhesion is required for expression of plant defense responses during fungal penetration

Fungal pathogens almost invariably trigger cell wall-associated defense responses, such as extracellular hydrogen peroxide generation and callose deposition, when they attempt to penetrate either resistant or susceptible plant cells. In the current study, we provide evidence that the expression of these defenses is dependent on adhesion between the plant cell wall and the plasma membrane. Peptides containing an Arg-Gly-Asp (RGD) motif, which interfered with plasma membrane-cell wall adhesion as shown by the loss of the thin plasma membrane-cell wall connections known as Hechtian strands, reduced the expression of cell wall-associated defense responses during the penetration of nonhost plants by biotrophic fungal pathogens. This reduction was associated with increased fungal penetration efficiency. Neither of these effects was seen after treatment with similar peptides lacking the RGD motif. Disruption of plant microfilaments had no effect on Hechtian strands but mimicked the effect of RGD peptides on wall defenses, suggesting that the expression of cell wall-associated defenses involves communication between the plant cell wall and the cytosol across the plasma membrane. To visualize the state of the plasma membrane-cell wall interaction during fungal penetration, we observed living cells during sucrose-induced plasmolysis. In interactions that were characterized by the early expression of cell wall-associated defenses, there was no change, or an increase, in plasma membrane-cell wall adhesion under the penetration point as the fungus grew through the plant cell wall. In contrast, for rust fungus interactions with host plants, there was a strong correlation between a lack of cell wall-associated defenses and a localized decrease in plasma membrane-cell wall adhesion under the penetration point. Abolition of this localized decreased adhesion by previous inoculation with a fungus that increased plasma membrane-cell wall adhesion resulted in reduced penetration by the rust fungus and induction of cell wall-associated defenses. These results suggest that rust fungi may induce a decrease in plasma membrane-cell wall adhesion as a means of disrupting the expression of nonspecific defense responses during penetration of host cells.     

CHANGES OF THE PRESPORE SPECIFIC STRUCTURE DURING DEDIFFERENTIATION AND CELL TYPE CONVERSION OF A SLIME MOLD CELL

In the slug of the cellular slime mold, Dictyostelium discoideum , are differentiated the anterior prestalk cells and the posterior prespore cells, whose differentiation is characterized by formation of the prespore specific vacuole (PSV). The ultrastructural changes of the PSV were investigated during dedifferentiation of a prespore cell disaggregated from a slug and also during conversion of the cell type, caused by fragmentation of a slug, between the prespore and the prestalk cells.
During the dedifferentiation, the PSV first lost its lining membrane which subsequently congregated, together with the inner filamentous material, to form some electron dense granules. Finally, the vacuole membrane was punctured, and the granules were released into cytoplasm. During conversion of the prespore to the prestalk cell, the PSV was degraded through the same process as in dedifferentiation, but the degradation proceeded much more synchronously in a converting cell. When a prestalk fragment was isolated from a slug, formation of the PSV was detected in no cell until 2 hr of incubation. After a lag, the PSV was formed in a converting cell through the process which is not a simple reversal of its degrading process.     

Ultrastructure of the epithelial cells of the ventral prostate from the hopping mouse Notomys alexis

The large ventral prostate of the hopping mouse has abundant secretory units whose epithelial cells vary in height and which often have nuclei in the apical region of the cell. TEM observations indicated two epithelial cell types in which some unusual features occurred. Type A cells had granular endoplasmetic reticulum (GER) whose membranes often formed intracytoplasmic confronting cisternae. Type B cells had more fragmented and vesiculated GER with sparse ribosomes and less frequently also intracytoplasmic confronting confronting cisternae. In the latter cells, two types of granules were found, one of which was derived from the Golgi and the other possibly directly from the GER. Type A cells only had one type of granule present. A highly convoluted membrane was also found at the basal region in many of the cells. The significance of these unusual ultrastructural features has yet to be ascertained.     

Intracytoplasmic membrane formation and increased oxidation of glycerol growth of Gluconobacter oxydans.

Gluconobacter oxydans is well known for the limited oxidation of compounds and rapid excretion of industrially important oxidation products. The dehydrogenases responsible for these oxidations are reportedly bound to the cell's plasma membrane. This report demonstrates that fully viable G. oxydans differentiates at the end of exponential growth by forming dense regions at the end of each cell observed with the light microscope. When these cells were thin sectioned, their polar regions contained accumulations of intracytoplasmic membranes and ribosomes not found in undifferentiated exponentially growing cells. Both freeze-fracture-etched whole cells and thin sections through broken-cell envelopes of differentiated cells demonstrate that intracytoplasmic membranes occur as a polar accumulation of vesicles that are attached to the plasma membrane. When cells were tested for the activity of the plasma membrane-associated glycerol dehydrogenase, those containing intracytoplasmic membranes were 100% more active than cells lacking these membranes. These results suggest that intracytoplasmic membranes are formed by continued plasma membrane synthesis at the end of active cell division.     

Ultrastructure of the intra-erythrocytic stage of Theileria species from cattle and waterbuck

A transmission electron microscopic study of the intra-erythrocytic stages of a pathogenic Theileria parva from cattle and a previously uncharacterized Theileria sp. from waterbuck (Kobus defassa) in Kenya revealed several novel ultrastructural features, associated with feeding and multiplication, in these parasites. In trophozoites a connecting channel was observed between the parasite's cytostome and its intracytoplasmic food vacuole. In some cases the limiting membrane of the food vacuole was seen to be continuous with a close-meshed network of membrane-bounded, anastomosing tubules. This labyrinthine structure, which has not been described previously, may function as a digestive organelle in theilerial trophozoites. Electron micrographs also revealed the mode of intra-erythrocytic multiplication of these parasites in vivo. Prior to division, electron-dense cisternae and rhoptries appeared beneath the parasite's plasmalemmal membrane, marking the sites of merozoite formation. From a single parasite, a maximum of four merozoites were formed by schizogonous division and subsequently separated from a residual body by constriction at the base of each merozoite. In addition, observations on two double-membraned organelles seen in trophozoites and the intra-erythrocytic crystalline structures associated with Theileria sp. in waterbuck are reported.     

The role of sterols in morphogenetic processes and dimorphism in fungi

The review considers the fundamental biological problem of fungal dimorphism as an adaptive reaction to adverse impacts. Primary attention is paid to sterols, phospholipids, storage lipids, and fatty acids. The structural and biological functions of sterols are considered, as well as their role in membrane stabilization under stress and their relation to morphogenetic processes in mycelial fungi, of which many are pathogenic. Data on the biosynthesis of the main fungal sterol, ergosterol, are presented, as well as data on the inhibitors of this process and on the mutants deficient in its particular stages. Ergosterol biosynthesis is also considered in terms of its relation to the composition of the fungal cell wall, which is the cell shape-determining structure, and to the intensity of chitin synthesis, a process in which azole derivatives play a role. Data obtained by the authors are presented that show the role of changes in the composition of sterols, phospholipids, storage lipids, and unsaturated fatty acids of resting cells in the induction of yeastlike growth in mucoraceous fungi.     

Freeze-fracture electron microscopic studies of age-related plasma membrane changes in Sporothrix schenckii

Characteristics of the plasma membrane of Sporothrix scheckii cells as revealed by freeze-fracture techniques have been classified into eight types (Y1, Y2a, Y2b, Y3a, Y3b, Y4a, Y4b, and Y5) in yeastlike cells grown under the following two conditions: brain heart infusion agar medium at 27 degrees C, and brain heart infusion agar medium at 37 degrees C. Type Y1 cells are yeastlike cells having smooth plasma membranes without any invagination. Typical characteristics of the other types are as follows: type Y2a, smooth plasma membranes with few trenchlike invaginations; type Y2b, wavy plasma membranes with few oval or irregularly formed invaginations; type Y3a, plasma membranes with many randomly distributed trenchlike invaginations; type Y3b, plasma membranes with many cocoonlike or irregularly formed invaginations; type Y4a, plasma membranes with longer trenchlike invaginations; type Y4b, plasma membranes with irregularly formed, enlarged invaginations; and type Y5, smooth or wavy plasma membranes with aggregations of intramembranous particles and with many vacuoles between cell walls and plasma membranes or in the cytoplasm in some cells. By counting the proportion of each type of yeastlike cell under the two conditions and with different cultivation periods, it appears that plasma membrane types change as aging progresses in the following order: type Y1, Y2a, Y3a, Y4a, and Y5 in conidia and type Y1, Y2b, Y3b, Y4b, and Y5 in yeastlike vegetative cells. These observations provide us with an important advantage when studying the effects of antifungal agents on the plasma membrane of Sporothrix scheckii, as it is important to know the natural course of changes in membrane structure during aging.     

Fine Structure of Encephalitozoon cuniculi from Rabbits,Mice and Hamsters*

SYNOPSIS. Fine structure and development of Encephalitozoon cuniculi from rabbits were studied in rabbit choroid plexus (CP) cell cultures and were compared to hamster and mouse microsporida. Sporoplasms had a single limiting membrane and contained a large nucleus. Proliferative forms (schizonts) had double outer membranes, the outermost being associated with the formation of the limiting membrane of vacuoles formed within the host cell cytoplasm. These organisms were often binucleate and divided to form sporonts. Sporonts divided once to form 2 sporoblasts which developed into electron-dense spores. Spores had a thick, 3-layered wall and contained a polar filament. The developmental cycle of E. cuniculi in rabbit CP cultures progressed rapidly. Sporoplasms were observed in host cells at 3 hr postinoculation (PI). By 24 hr PI proliferative forms were associated with host cell cytoplasmic vacuoles which contained developing organisms. Mature spores were present in vacuoles by 2 days PI, indicating that the life cycle in the CP system is ∼ 48 hr. The fine structure and the sequential developmental cycle of the mouse and hamster isolates were observed to be identical to those of the rabbit isolate and different from those of the genus Nosema. It is proposed, therefore, that the 3 organisms represent the same species, Encephalitozoon cuniculi.     

Primary culture of skeletal muscle cells as a model for studies of Toxoplasma gondii cystogenesis

Toxoplasma gondii is a protozoan pathogen of birds and mammals, including humans. The infective stage, the bradyzoite, lives within cysts, which occur predominantly in cells of the central nervous system and skeletal and cardiac muscles, characterizing the chronic phase of toxoplasmosis. In the present study, we employed for the first time primary mouse culture of skeletal muscle cells (SkMC) infected with bradyzoites, as a cellular model for cystogenesis. The interconversion of bradyzoite and tachyzoite was analyzed by immunofluorescence using 2 stage-specific antibodies, i.e., anti-bradyzoite (anti-BAG1) and anti-tachyzoite (anti-SAG1). After 24 hr of interaction only bradyzoites were multiplying, as revealed by anti-BAG1 incubation; interconversion to tachyzoites was not observed. After 48 hr of infection, 2 types of vacuoles were seen, i.e., BAG1+ and SAG1+, indicating the presence of bradyzoites as well as their interconversion to tachyzoites. After 96 hr of infection, BAG1+ vacuoles presented a higher number of parasites when compared to 48 hr, indicating multiplication of bradyzoites without interconversion. Using ultrastructural analysis, bradyzoites were found to adhere to the cell membranes via both the apical and posterior regions or were associated with SkMC membrane expansions. During bradyzoite invasion of SkMC, migration of the rough endoplasmic reticulum (RER) profiles to the parasite invasion site was observed. Later, RER profiles were localized between the mitochondria and parasitophorous vacuole membrane (PVM) that contained the parasite. After 31 days of parasite-host cell infection, RER profiles and mitochondria were not observed in association with the cyst wall. Alterations of the PVM, including increased thickness and electrondensity gain on its inner membrane face, were observed 48 hr after infection. Cystogenesis was complete 96 hr after infection, resulting in the formation of the cyst wall, which displayed numerous membrane invaginations. In addition, an electron-dense granular region enriched with vesicles and tubules was present, as well as numerous intracystic bradyzoites. These results show that the in vitro T. gondii model and SkMC are potential tools for both the study of cystogenesis using molecular approaches and the drug screening action on tissue cysts and bradyzoites.