Fine Structure of Listeria monocytogenes in Relation to Protoplast Formation

Among the eight strains of Listeria monocytogenes tested for lysozyme sensitivity, two were resistant to lysozyme but became sensitive after lipase pretreatment. Among the other six, one was very sensitive to lipase and another one was extremely susceptible to lysozyme. Stable protoplasts were formed from the lysozyme-resistant strain (42) by lipase and lysozyme treatment, which completely digested the cell wall. The cell wall (uranyl acetate-lead stained) was of a thick triple-layered profile, with the intermediate layer of low density. Lipase treatment for a short time (60 min) did not cause any alteration in structure, but prolonged treatment (180 min) caused extensive digestion of the plasma membrane and the cell wall, liberating cytoplasmic material. When the cells were treated with either lipase or lysozyme, a small number of protoplasts were extruded through the partly digested or weakened transverse cell wall, leaving an almost intact cell wall ghost. There were small vesicular structures in the interspace between cell wall and plasma membrane. Mesosomes of varied organization were prominent in electron micrographs, both in sections and in negatively stained preparations. These were largely everted during protoplasting in the form of tubules and as small peripheral buds; a few small vesicles also remained as intrusive structures, some of which were very unusual because they appeared to be enclosed by the inner layer of plasma membrane alone. Lysis of the protoplasts by dilution of the sucrose, while maintaining a constant ionic environment, liberated many small vesicular structures and fibrillar nuclear material.     

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.     

Electron microscopy of infection of nematodes byDactylaria haptotyla

Infection of nematodes byDactylaria haptotyla, a nematode-trapping hyphomycete, was studied by electron microscopy. The cytoplasm of the adhesive knob in the fungus contained a number of electron-dense, membrane-bound vesicles, 0.2–0.5 µm in diam. The vesicles were rarely seen in the stalk cell or vegetative cell cytoplasm. When the adhesive knob came into contact with the nematode's cuticle, it secreted an adhesive which was seen in ultrathin sections between the knob and the cuticle as an amorphous mass. At the same time, electron-dense vesicles in the cytoplasm were reduced in number and many small vacuoles developed. Soon after capture of a nematode, the cell wall of the adhesive knob became obscure at the prospective site of penetration, where a vesicle, 0.7 µm in diam, was found in serial thin sections of the knob's cytoplasm. At the site facing the vesicle, the peripheral part of the nematode's cell exhibited a high electron density. The vesicle, which appeared to be derived from smaller electron-dense vesicles coalesced with each other, released its enzymic contents toward the captured nematodes before penetration by the fungus.     

Accumulation of noncrystalline cellulose in Physarum microplasmodia

Physarum plasmodium lives as a slimy mass of protoplast in the dark fragments into small multinucleated microplasmodia (mPL) in a liquid medium. When mPL are exposed to several unfavorable environments, they transform into “spherules” with a cell wall. Using a synchronous spherule-induction system for mPL, we examined the effect of 2,6-dichlorobenzonitrile on the synthesis of cellulose in mPL, by observing mPL under a fluorescence microscope, and isolated cellulose from mPL to identify them morphologically under scanning electron microscopy. Moreover, we examined in vivo labeling to determine when cellulose synthesis is activated in step 2. We found that the nourishment medium in step 2 was essential for mPL prior to spherulation and that the conversion starts at 48 h in step 2 of our system. From the experiments using Updegraff reagent for the sedimentation of cellulose in the cell wall fraction from mPL, we propose that cellulose produced in mPL is likely noncrystalline cellulose. We conclude that mPL of multinucleated protoplasts without the cell wall structure synthesize cellulose under constitutive condition and accumulate abundantly noncrystalline cellulose, in preparation for unfavorable environments that may occur in the future in which mPL must initiate the program to form the cell wall of spherules.     

Ultrastructural Changes Associated with Spore Formation in Sporangia and Sporangiola of Thamnidium elegans Link

Fully formed pre-cleavage sporangia and sporangiola of Thamnidiumelegans Link were bounded by a primary wall plus a thick, internalsecondary wall layer. In sporangia in late pre-cleavage, Golgi-likecisternae were associated with groups of cytoplasmic vesiclesof characteristic size and appearance which were not found insporangia containing large cleavage vesicles. In both sporangia and sporangiola, protoplast cleavage was effectedby enlargement of endogenous cleavage vesicles each containinga lining layer of variable appearance, mutual fusion of cleavagevesicle membranes and fusion of cleavage vesicle membranes withthe plasmalemma. Golgi-like cisternae and small vesicular profileswere present in sporangium protoplasts at all stages of cleavagevesicle enlargement. In sporangia, the columella zone was delimitedby cleavage vesicles and separated from the sporogenous zoneby a fibrillar wall. A similar wall, which sometimes protrudedto form a small columella, was formed in sporangiola. Recently delimited spore protoplasts were bounded by plasmalemmamembrane derived from cleavage vesicle bounding membrane andsporangium or sporangiolum plasmalemma and surrounded by aninvesting layer derived from cleavage vesicle lining material.The investing layer at first appeared single, but later twoelectron opaque profiles were discernible. The spore wall wasformed between the investing layer and the plasmalemma. Wallsof sporangia and sporangiola which contained fully formed sporesconsisted of the primary layers only.     

Electron microscopic observations of cell regeneration from cultured protoplasts ofAmmi visnaga

Summary Protoplasts ofAmmi visnaga initiated cell wall formation within 2 days in culture; after 13 days the new cells were enclosed by a cell wall similar to the walls on the original cultured cells. Budding occurred in protoplasts with little or no detectable cell wall. No evidence was obtained for direct participation of any organelle in cell wall formation. The cytoplasm of regenerating cells contained numerous organelles and appeared typical of actively growing plant cells; they were easily distinguished from degenerate cells and protoplasts. While coated vesicles were common, spiny vesicles occurred in only a few cells. Sustained cell division yielded multicellular aggregates. Multinucleate protoplasts, formed by spontaneous fusion, did not divide; some of them contained annulate lamellae with few pore complexes.Supported by the National Research Council of Canada, Grant A6304.     

Isolation by preparative free-flow electrophoresis and aqueous two-phase partition from rat adipocytes of an insulin-responsive small vesicle fraction with glucose transport activity

Preparative free-flow electrophoresis and aqueous two-phase polymer partition were used to obtain a plasma membrane-enriched fraction of adipocytes isolated from epididymal fat pads of the rat together with a fraction enriched in small vesicles with plasma membrane characteristics (thick membranes, clear dark-light-dark pattern). The electrophoretic mobility of the small vesicles was much less than that of the plasma membrane consistent with an inside-out orientation whereby charged molecules normally directed to the cell surface were on the inside. When plasma membranes and the small vesicle fraction were isolated from fat cells treated or not treated with 100 μU/ml insulin and the resident proteins of the two fractions analyzed by SDS-PAGE, the two fractions exhibited characteristics responses involving specific protein bands. Insulin treatment for 2 min resulted in the loss of a 90 kDa band from the plasma membrane. At the same time, a ca. 55-kDa peptide band that was enhanced in the plasma membrane was lost from the small vesicle fraction. The latter corresponded on Western blots to the GLUT-4 glucose transporter. Thus, we suggest that the small vesicle fraction with characteristics of inside-out plasma membrane vesicles may represent the internal vesicular pool of plasma membrane subject to modulation by treatment of adipocytes with insulin.     

Methane production by the membranous fraction of Methanobacterium thermoautotrophicum.

Intact membrane vesicles are required to synthesize methane from CO2 and H2 by disrupted preparations of Methanobacterium thermoautotrophicum cells. When membrane vesicles were removed by high-speed centrifugation at 226 600 g, the remaining supernatant fraction no longer synthesized methane. Alternatively, if vesicle structure was disrupted by passage through a Ribi cell fractionator at very high pressures (345 MPa), the bacterial cell extract, with all the particulate fraction in it, did not synthesize methane. Methyl-coenzyme M, a new coenzyme first described by McBride & Wolfe [(1971) Biochemistry 10, 2317--2324], was shown to stimulate methane production from CO2 and H2, as previously reported, but the methyl group of the coenzyme did not appear to be a precursor of methane in this reaction. No methyl-coenzyme M reductase activity was detected in the cytoplasmic fraction of M. thermoautotrophicum cells.     

Electron microscopy study of cell structures and their changes during growth and regeneration ofSchizosaccharomyces pombe protoplasts

The submicroscopic structure of growing and regeneratingSchizosaccharomyces pombe protoplasts cultivated in solid and liquid medium was studied by means of ultrathin sectioning. The protoplasts regenerate within 24 hours. Shortly before growth commences, rudiments of the new cell wall can be identified on the protoplast surface. Simultaneously, a large number of dictyosomes appears in the cytoplasm and decreases as synthesis of the new wall progresses. An increase occurs in the number of endoplasmic reticulum membranes some of which are arranged parallel with the cytoplasm membrane of the protoplast. Throughout the whole time of regeneration the protoplasts contain only one nucleus. The nucleo-cytoplasm ratio of growing and regenerating protoplasts is lower than in intact cells. The number of mitochondria falls at the outset of regeneration and does not rise again until towards the end.     

Behavior of the Plasma Membrane of Isolated Protoplasts during a Freeze-Thaw Cycle

Cryomicroscopy of protoplasts isolated from nonacclimated (NA) rye leaves (Secale cereale L. cv Puma) revealed that the predominant form of injury following cooling to the minimum temperature for 50% survival (LT₅₀) (−5°C) was expansion-induced lysis of the plasma membrane during warming and thawing of the suspending medium when the decreasing osmolality resulted in osmotic expansion of the protoplasts. When cooled to temperatures below the LT₅₀, the predominant form of injury was loss of osmotic responsiveness following cooling so that the protoplasts were osmotically inactive during warming. Only a low incidence (<10%) of expansion-induced lysis was observed in protoplasts isolated from acclimated (ACC) leaves, and the predominant form of injury following cooling to the LT₅₀ (−25°C) was loss of osmotic responsiveness. The tolerable surface area increment (TSAI) which resulted in lysis of 50% of a population (TSAI₅₀) of NA protoplasts osmotically expanded from isotonic solutions was 1122 ± 172 square micrometers. Similar values were obtained when the protoplasts were osmotically expanded from hypertonic solutions. The TSAI determined from cryomicroscopic measurements of individual NA protoplasts was similar to the TSAI₅₀ values obtained from osmotic manipulation. The TSAI₅₀ of ACC protoplasts expanded from isotonic solutions (2145 ± 235 square micrometers) was approximately double that of NA protoplasts and increased following osmotic contraction. Osmotic contractions were readily reversible upon return to isotonic solutions. During freeze-induced dehydration, endocytotic vesicles formed in NA protoplasts whereas exocytotic extrusions formed on the surface of ACC protoplasts. During osmotic expansion following thawing of the suspending medium, the endocytotic vesicles remained in the cytoplasm of NA protoplasts and the protoplasts lysed before their original volume and surface area were regained. In contrast, the exocytotic extrusions were drawn back into the surface of ACC protoplasts as the protoplasts regained their original volume and surface area.     

Cytological study on wheat (Triticum timopheevi Zhuk.) protoplasts

Protoplasts were obtained from tetraploid wheat (Triticum timopheevi Zhuk.) suspension culture by incubation in solution of 1 % pectinase 500, 1 % driselase and 1 % cellulase and cultivated in Schenk and Hildebrandt medium. Freshly isolated protoplasts contained dense cytoplasm and constricted organellae exhibited negative contrast of their membranes. Together with normal protoplasts huge multinucleate protoplasts were present in the population. 3 h after plating, the cytoplasm showed normal appearance, the negative contrast of membranes was not evident any longer. Cisternae of endoplasmic reticulum and Golgi apparatus were numerous. There were some vesicles and fibres on the protoplast surface. 8 d after plating, many dividing cells were found out and cell clumps arosen in this way were present in the culture. Some of the protoplasts particularly those originally multinucleate ones were upset.     

Plasmalemma fine structure in isolated tobacco mesophyll protoplasts

Summary Tobacco mesophyll protoplasts have been examined by electron microscopy during isolation procedures and after 24 hours culture in a medium known to support cell wall regeneration. During isolation the plasmalemma shows little structural differentiation apart from the formation of small vacuoles in the cytoplasm. After 24 hours of culture, several types of activity are seen at the plasmalemma surface. Microtubules, profiles of endoplasmic reticulum, electron dense granules and coated vesicles are associated with the inner surface of the membrane. External to the plasmalemma fibrillar structures occur, both as extensive networks and as individual fibrils apparently associated with the membrane itself. Techniques and criteria for electron microscopy are presented, and the results discussed in terms of plasmalemma function and the regeneration of the cell wall.     

The release of secretory vesicle in encysting Giardia lamblia

Giardia is an intestinal parasite that undergoes adaptation for survival outside the host. It secretes an extracellular cyst wall using a poorly understood process. An encystation-specific secretory vesicle (ESV) was previously described containing cyst wall proteins. The process of release of these vesicles has been suggested to occur after fragmentation of large ESV in small secretory vesicles, followed by exocytosis, but it was not demonstrated. The release of the ESV was studied by transmission electron microscopy. It was observed: (1) the moment of vesicle release; (2) that a large vesicle is exocytosed and does not fragment into small vesicles; (3) membrane fusion is distinct from traditional exocytosis since it is incomplete; (4) the occurrence of membrane fragmentation and that those membranes reseal to form ghosts; (5) these membrane ghosts may be endocytosed, adhered to flagellar surface or/and form empty vesicles in the extracellular medium.     

Specific association of the proto-oncogene product pp60c-src with an intracellular organelle, the PC12 synaptic vesicle

The protein product of the proto-oncogene c-src is a membrane-associated tyrosine kinase of unknown function. Identification of pp60c-src target membranes may elucidate the function of the c-src protein. The available evidence indicates that pp60c-src associates with distinct membranes within single cell types and has different distributions in different cell types. Our experiments demonstrate targeting of pp60c-src to an isolatable and biochemically identified membrane fraction in the neuroendocrine cell line PC12. The c-src protein was found to be specifically associated with synaptic vesicles since: (a) the pp60c-src immunofluorescent pattern overlapped with a synaptic vesicle marker, synaptophysin; (b) a significant proportion (44%) of the pp60c-src from PC12 but not fibroblast postnuclear supernatants was recovered in a small vesicle fraction; (c) an anti-synaptophysin cytoplasmic domain antibody immunodepleted all of the pp60c-src vesicles in this fraction, and (d) pp60c-src copurified during a 100-fold purification of PC12 synaptic vesicles. These results suggest a role for the c-src protein in the regulation of synaptic vesicle function.     

Interaction of Cryptococcus neoformans Extracellular Vesicles with the Cell Wall

Cryptococcus neoformans produces extracellular vesicles containing a variety of cargo, including virulence factors. To become extracellular, these vesicles not only must be released from the plasma membrane but also must pass through the dense matrix of the cell wall. The greatest unknown in the area of fungal vesicles is the mechanism by which these vesicles are released to the extracellular space given the presence of the fungal cell wall. Here we used electron microscopy techniques to image the interactions of vesicles with the cell wall. Our goal was to define the ultrastructural morphology of the process to gain insights into the mechanisms involved. We describe single and multiple vesicle-leaving events, which we hypothesized were due to plasma membrane and multivesicular body vesicle origins, respectively. We further utilized melanized cells to “trap” vesicles and visualize those passing through the cell wall. Vesicle size differed depending on whether vesicles left the cytoplasm in single versus multiple release events. Furthermore, we analyzed different vesicle populations for vesicle dimensions and protein composition. Proteomic analysis tripled the number of proteins known to be associated with vesicles. Despite separation of vesicles into batches differing in size, we did not identify major differences in protein composition. In summary, our results indicate that vesicles are generated by more than one mechanism, that vesicles exit the cell by traversing the cell wall, and that vesicle populations exist as a continuum with regard to size and protein composition.     

Gas vesicle assembly in Microcyclus aquaticus.

When observed in the electron microscope intact gas vesicles appeared as transparent areas in whole cells of Microcylus aquaticus, whereas vesicles collapsed by centrifugation were not discernible. Within 5 min of suspending cells containing collapsed vesicles in growth medium, small transparent vesicles were detected. By 15 min the average number of vesicles per cell was 15. This number remained relatively constant while the size of the vesicles increased until they attained their maximum diamtere of 100 nm. At this time the vesicles, interpreted as biconical structures, began to elongate presumably due to the synthesis of the cylindrical midsection. Closely correlated with the time at which vesicles began to elongate was the initiation of smaller vesicles which resulted in a doubling of the number of vesicles per cell by 90 min. This evidence coupled with the isolation of a mutant which assembles only the conical portions of the vesicle suggests that assembly occurs in two distinct stages subject to genetic mutation. Protein and ribonucleic acid synthesis, and presumably adenosine triphosphate formation, were required for gas vesicle assembly. In addition, inhibition of protein or ribonucleic acid synthesis resulted in a loss of extant gas vesicles. Over the time course of our study, deoxyribonucleic acid synthesis was not required for gas vesicle assembly or stability.     

An Ultrastructural Study on Pollen Protoplasts and Pollen Tubes Germinated From Them in Gladiolus gandavensis

Large quantities of protoplasts were isolated enzymatically from the mature pollen grains in Gladiolus gandavensis. Regeneration of cell wall and germination of pollen tubes were performed during culture of purified pollen protoplasts in Ks medium supplemented with 32% sucrose, 0.1 mg/1 2,4-D, 1 mg/1 NAA and 0.2 mg/1 6-BA, with a germination rate up to 47.7%. The materials were fixed gently with gradually increasing concentration of glutaraldehyde, followed by osmium, then preembedded in a thin layer of agar and surveyed under an inverted microscope so as to select desired specimens for subsequent procedure. Small agar blocks containing specimens were dehydrated through ethanal-propylene oxide series, embedded in Araldite and ultratomed. Electron microscopic observations show that the pollen protoplasts are surrounded by a smooth plasma membrane and with ultrastructurally intact cytoplasm, a vegetative nucleus and a generative cell. After 8h of culture, wall regeneration commences resulting in a multilayered, fibrillar wall structure which is different from the intine. No exine is formed. Numerous vesicles participate actively in the wall formation. The wall is uneven in thickness around its periphery; a thickened area somewhat resembling to germ furrow is formed, from which pollen tube emerges. The tubes contain abundant plastids, mitochondria and dictyosomes. Vesicles are released out of the plasma membrane and involved in tube wall formation. After 18h of culture, the vegetative nucleus and generative cell have migrated into the tube. Technical points of preparing pollen protoplast specimens for ultastructural studies and the fearnres of wall regeneration in pollen protoplast culture are discussed.     

Monensin blocks the transport of diphtheria toxin to the cell cytoplasm

Lysosomotropic amines are believed to inhibit the transport of diphtheria toxin to the cell cytoplasm by raising the pH within intracellular vesicles. If so, then other drugs that dissipate intracellular proton gradients should have a similar effect on toxin transport. We found that monensin, a proton ionophore unrelated to lysosomotropic amines, is a potent inhibitor of the cytotoxic effect of diphtheria toxin. Monensin appears to block the escape of endocytosed toxin from a vesicle to the cytoplasm. Monensin fails to protect cells from the effects of diphtheria toxin that is bound to the cell surface and exposed to acidic medium, suggesting that the step normally blocked by the drug is circumvented under these conditions. The inhibition of toxin transport caused by monensin could not be relieved when monensin was replaced by ammonium chloride, nor when ammonium chloride was again replaced by monensin. This suggests that both drugs block the same step of toxin transport. The effect of monensin on the transport of diphtheria toxin to the cytoplasm is consistent with the proposal (Draper and Simon. 1980. J. Cell Biol. 87:849-854; Sandvig and Olsnes. 1980. J. Cell Biol. 87:828-832) that the toxin is endocytosed and then, in response to an acidic environment, penetrates through the membrane of an intracellular vesicle to reach the cytoplasm.     

Cell wall synthesis in Allomyces macrogynus

Scanning electron microscopy and freeze-etching/cleaving have been employed to examine events in the synchronized development of gametophytic germlings of the aquatic Phycomycete Allomyces macrogynus. Motile spores were induced to start synchronized development and the sequence of surface changes associated with the encystment process was studied. Time course studies show that small vesicles (apparently blebbed off from the gamma-particles) start to accumulate on the surface of the plasma membrane after 6 min of synchronized growth at the same time as the first cell wall material can be detected. The vesicles increase in number during encystment. After 15 min of synchronized growth the number of vesicles decrease and after 20 min of growth no vesicle can be observed on the cell surface. During this period the cell surface appears increasingly smooth, probably due to cell wall formation. In freeze-etching/cleaving electron micrographs from this period, both intact and what appear to be ruptured vesicles outside the cell surface, can be observed. The intact vesicle has a characteristic surface pattern presumably of membrane particles. This surface view of the encystment processes supports the hypothesis that the gamma-particles through gamma vesicle formation participate in the cell wall synthesis during encystment in Allomyces.     

Electron-microscope observations of mitosis and cytokinesis in multinucleate protoplasts of soybean.

Multinucleate soybean protoplasts produced by spontaneous fusion during enzyme digestion of the cell wall initiated cell division after approximately 40 h in culture. The structure of these protoplasts during mitosis and cytokinesis was studied with both light and electron microscopes. Most nuclei did not fuse but divided synchronously. Interphase nuclei was commonly connected by short narrow nuclear bridges. At prophase and metaphase the nuclei appeared typical of those in most higher plants; technical difficulties prevented an adequate examination of protoplasts at anaphase. Telophase was characterized by cytokinesis involving phragmoplast and cell plate formation; however, complete partitioning of the cytoplasm by cell plants was not observed. Numerous coated vesicles were present near to or continuous with the cell plate and plasmalemma. The presence of a few dividing protoplasts with at least double the normal chromosome number suggests that some nuclear fusion occurred prior to mitosis. Very little cell wall material was detected at the margin of the dividing protoplasts.