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.     

The influence of cold acclimation on the behavior of the plasma membrane following osmotic contraction of isolated protoplasts

Summary Osmotic contraction of protoplasts isolated from cold acclimated leaves ofSecale cereale L. cv. Puma results in the formation of exocytotic extrusions of the plasma membrane. Numerous knobs or polyps were observed on the surface of the protoplasts with scanning electron microscopy. In thin sections, the extrusions were bounded by the plasma membrane with a densely osmiophilic interior. Cross-fracturing of the extrusions revealed aparticulate bodies within, a further indication that the interior of the extrusions was predominantly lipid material. Freeze-fracture of the plasma membrane suggests a possible source of this lipid material. Following osmotic contraction, the particle density on the plasma membrane protoplasmic face (PFp) increased, being reflected in both a substantial increase in paracrystalline arrays and an increase in the particle density in non-crystalline regions. This increase in particle density indicates that lipid material is preferentially lost from the plasma membrane during contraction. The density on the exoplasmic face (EFp) did not change. Together, these findings suggest that during hypertonic contraction of acclimated protoplasts, lipid material is preferentially subducted from the plasma membrane and sequestered into lipid bodies (the osmiophilic regions). The formation of lipid bodies and extrusions was readily reversible. Following osmotic expansion of acclimated protoplasts, the extrusions were retracted back into the plane of the plasma membrane.Department of Agronomy Series Paper no. 1497.     

Osmotically evoked shrinking of guard-cell protoplasts causes vesicular retrieval of plasma membrane into the cytoplasm

The dye FM1-43 was used alone or in combination with measurements of the membrane capacitance (C_m) to monitor membrane changes in protoplasts from Viciafaba L. guard cells. Confocal images of protoplasts incubated with FM1-43 (10 μM) at constant ambient osmotic pressure (π_o) revealed in confocal images a slow internalisation of FM1-43-labelled membrane into the cytoplasm. As a result of this process the relative fluorescence intensity of the cell interior (f_FM,i) increased with reference to the total fluorescence (f_FM,t) by 7.4 × 10⁻⁴ min⁻¹. This steady internalisation of dye suggests the occurrence of constitutive endocytosis under constant osmotic pressure. Steady internalisation of FM1-43 labelled membrane caused a prominent staining of a ring-like structure located beneath the plasma membrane. Abrupt elevation of π_o by 200 mosmol kg⁻¹ caused, over the first minutes of incubation, a rapid internalisation of FM1-43 fluorescence into the cytoplasm concomitant with a decrease in cell perimeter. Within the first 5 min the cell perimeter decreased by 7.9%. Over the same time f_FM,i/f_FM,t increased by 0.13, reflecting internalisation of fluorescent label into the cytoplasm. Combined measurements of C_m and total fluorescence of a protoplast (f_FM,p) showed that an increase in π_o evoked a decrease in C_m but no change in f_FM,p. This means that surface contraction of the protoplast is due to retrieval of excess membrane from the plasma membrane and internalisation into the cytoplasm. Further inspection of confocal images revealed that protoplast shrinking was only occasionally associated with internalisation of giant vesicles (median diameter 2.7 μm) with FM1-43-labelled membrane. But, in all cases, osmotic contraction was correlated with a diffuse distribution of FM1-43 label throughout the cytoplasm. From this, we conclude that endocytosis of small vesicles into the cytoplasm is the obligatory process by which cells accommodate an osmotically driven decrease in membrane surface area. Received: 4 May 1999 / Accepted: 19 August 1999     

Osmotically induced fluid-phase uptake of fluorescent markers by protoplasts ofChenopodium album

Summary Protoplasts fromChenopodium album suspension culture show large, up to 5-fold, changes in surface area upon hypertonic or hypotonie treatment. These surface area variations cannot be explained by elastic stretching of the plasmalemma. An exchange of membrane material between the plasmalemma and an internal membrane source takes place. Fluid-phase uptake experiments with the fluorescence dyes 5, 6-carboxyfluorescein and Lucifer yellow CH demonstrated that osmotic shrinkage of protoplasts is accompanied by vesicular uptake of the external medium into protoplast cytoplasm. Confocal laser scanning microscopy, as well as conventional fluorescence microscopy, revealed the number, diameter and distribution of the osmocytotic vesicles at different osmotic levels. The rate of osmocytotic vesicle uptake was higher in the presence of calcium chloride than in the presence of EDTA in the external medium. At 6.9 mM calcium chloride we observed a loss of vesicular fluorescence upon returning protoplasts to 0.4 M from 0.8 M sorbitol.     

The Mechanics of Injury to Isolated Protoplasts following Osmotic Contraction and Expansion

Micro-osmotic manipulation was used to determine the influence of osmotic contraction on the expansion potential of individual protoplasts isolated from rye (Secale cereale L. cv Puma) leaves. For protoplasts isolated from leaves of nonacclimated plants (NA protoplasts), osmotic contraction in sufficiently hypertonic solutions (>1.53 osmolal) predisposed the protoplasts to lysis during osmotic expansion when they were returned to isotonic conditions (0.53 osmolal). In contrast, for protoplasts isolated from leaves of cold acclimated plants (ACC protoplasts), osmotic contraction in either 2.6 or 4.0 osmolal solutions was readily reversible. Following osmotic contraction, the resting tension (γ_r) of NA protoplasts was similar to that determined for protoplasts in isotonic solutions (i.e. 110 ± 22 micronewtons per meter). In contrast, γ_r of ACC protoplasts decreased from 164 ± 27 micronewtons per meter in isotonic solutions to values close to zero in hypertonic solutions. Following expansion in hypotonic solutions, γ_r's of both NA and ACC protoplasts were similar for area expansions over the range of 1.3 to 1.6. Following osmotic contraction and reexpansion of NA protoplasts, hysteresis was observed in the relationship between γ_r and surface area—with higher values of γ_r at a given surface area. In contrast, no hysteresis was observed in this relationship for ACC protoplasts. Direct measurements of plasma membrane tension (γ) during osmotic expansion of NA protoplasts from hypertonic solutions (1.53 osmolal) revealed that γ increased rapidly after small increments in surface area, and lysis occurred over a range of 1.2 to 8 millinewtons per meter. During osmotic expansion of ACC protoplasts from hypertonic solutions (2.6 osmolal), there was little increase in γ until after the isotonic surface area was exceeded. These results are discussed in relation to the differences in the behavior of the plasma membrane of NA and ACC protoplasts during osmotic contraction (i.e. endocytotic vesiculation versus exocytotic extrusion) and provide a mechanistic interpretation to account for the differential sensitivity of NA and ACC protoplasts to osmotic expansion from hypertonic solutions.     

Purification of Functionally Sealed Cytoplasmic Side-out Plasma Membrane Vesicles from Saccharomyces cerevisiae

Highly purified plasma membrane vesicles were prepared from yeast protoplasts by a combination of osmotic lysis, differential centrifugation, and separation in an aqueous dextran/polyethylene glycol two-phase system. The vesicles were predominantly (85-90%) of cytoplasmic side-out orientation and displayed large ATP-dependent proton pumping activity which was inhibited by vanadate (100 μM) but not by bafilomycin or nitrate. The preparation presented a distinct polypeptide profile with respect to the total membrane fraction and was enriched in the 110-kDa polypeptide corresponding to the plasma membrane H⁺-ATPase. This preparation of native plasma membranes vesicles is especially suitable for functional studies in vitro.     

Mechanical study of the deformation and rupture of the plasma membranes of protoplasts during osmotic expansions

Summary The stress and strain (surface tension and fractional change in area) in the plasma membrane of protoplasts isolated from rye leaves (Secale cereale L. cv Puma) were measured during osmotic expansions from isotonic into a range of more dilute solutions. The membrane surface tension increases rapidly to a maximum and then decreases slowly with some protoplasts lysing in all phases of the expansion. The maximum surface tension is greater for rapid expansions, and protoplasts lyse earlier during rapid expansion. Over the range of expansion rates investigated, the area at which lysis occurs is not strongly dependent on expansion rate. The value of the maximum tension is determined by the expansion rate and the rate at which new material is incorporated into the membrane. During osmotic expansion, protoplasts isolated from cold-acclimated plants incorporate material faster than do those from nonacclimated plants and thus incur lower membrane tensions.     

Effects of Selected Herbicides on Plant Protoplasts

Plant protoplasts were released from immature tomato fruits by incubation with a 20% solution of polygalacturonase (Pectinol R-10, Rhom & Haas) dissolved in 0.1 M KCl + 0.1 M MgCl₂. In this salt solution the protoplasts remained stabilized for up to 8 h and were used as a source of exposed plasma membrane. Gross responses of protoplasts to selected chemicals and herbicides were recorded photomicroscopically. Paraquat (1,1′-dimethyl-4,4′-bipyridinium ion) treatments resulted in a characteristic response which was different from that of general denaturants (trichloroacetic acid, ethanol, and detergents) and of osmotic shock. Initial phases of the paraquat response were characterized by a segregation of the cytoplasm into isolated areas on the inner membrane surface. The final phase was a rupture of the plasma membrane and collapse of the cell. The herbicides, 2,4′-dinitro-4-trifluoromethyl-diphenylether (preforan); 1,1-dimethyl-3-(α,α,α-trifluoro-m-tolyl)urea (fluometuron); 3-(3-chloro-4-bromophenyl)-1-methoxy-1-methylurea (chlorbromuron); and α,α,α-trifluoro-2,6-dinitro-N-N-dipropyl-p-toluidine (trifluralin) produced no apparent structural effect on the protoplasts.     

Calcium-Dependent Freezing Tolerance in Arabidopsis Involves Membrane Resealing via Synaptotagmin SYT1

Plant freezing tolerance involves the prevention of lethal freeze-induced damage to the plasma membrane. We hypothesized that plant freezing tolerance involves membrane resealing, which, in animal cells, is accomplished by calcium-dependent exocytosis following mechanical disruption of the plasma membrane. In Arabidopsis thaliana protoplasts, extracellular calcium enhanced not only freezing tolerance but also tolerance to electroporation, which typically punctures the plasma membrane. However, calcium did not enhance survival when protoplasts were exposed to osmotic stress that mimicked freeze-induced dehydration. Calcium-dependent freezing tolerance was also detected with leaf sections in which ice crystals intruded into tissues. Interestingly, calcium-dependent freezing tolerance was inhibited by extracellular addition of an antibody against the cytosolic region of SYT1, a homolog of synaptotagmin known to be a calcium sensor that initiates exocytosis. This inhibition indicates that the puncture allowing the antibody to flow into the cytoplasm occurs during freeze/thawing. Thus, we propose that calcium-dependent freezing tolerance results from resealing of the punctured site. Protoplasts or leaf sections isolated from Arabidopsis SYT1-RNA interference (RNAi) plants lost calcium-dependent freezing tolerance, and intact SYT1-RNAi plants had lower freezing tolerance than control plants. Taken together, these findings suggest that calcium-dependent freezing tolerance results from membrane resealing and that this mechanism involves SYT1 function.     

Cytoplasmic deletion processes during spermatogenesis in mosses

Comparative ultrastructural observations reveal that cytoplasmic deletion during spermatogenesis in Sphagnum and other mosses (Bryopsida) has two distinct phases. In young spermatids, Golgi-derived vesicles produce the mucopolysaccharide sheaths in which the gametes are liberated. Golgi bodies, however, play no part in removal of cytoplasm during gamete maturation. Rounding off of the cells during this process results in a 50% reduction in volume. Mid-spermatid stages in Sphagnum are characterised by the sequential loss of Golgi bodies and endoplasmic reticulum (ER) but no further diminution of the cytoplasm. The final stages of nuclear metamorphosis and chromatin condensation, in late spermatids, are marked by the sudden appearance, in the otherwise featureless central cytoplasm, of a membrane vesicle complex (MVC) comprising cisternae, tubules, and smooth and coated vesicles. Following repositioning of the MVC beneath the plasma membrane, rapid shrinkage of the cytoplasm is associated with the presence of vesicle fusion profiles at the cell surface. The MVC is considered to be intimately involved in cytoplasmic breakdown and loss. Acid phosphatase activity can be detected throughout spermatogenesis. Spermatogenous cells and young spermatids possess relatively low levels of the enzyme, restricted to the ER and perinuclear space, but particularly high levels occur in the MVC region of late spermatids of Sphagnum. The deletion process in Bryopsida is much more gradual than that of Sphagnum. Mid-spermatids contain sheets of ER, Golgi with small vesicles, and irregular cisternae associated with coated vesicles. Vacuoles derived either from dilation of the ER or the coated vesicle complexes gradually increase in size and number at the expense of the cytoplasm. During the early stages of chromatin condensation, a large central vacuole opens onto the anterior face of the gametes. Further discharge of vesicles continues throughout gamete maturation. A comparative survey of spermatogenesis in land plants indicates that cytoplasmic deletion is achieved in different ways in different groups. We speculate that the spermatozoids of the common ancestor of archegoniate plants probably possessed large amounts of cytoplasm. The deletion mechanisms may have originated from a contractile vacuole apparatus.     

Subcellular localization of enzymes inStreptomyces aureofaciens and its alteration by benzyl thiocyanate

Mycelia of a low- and a high production strain ofStreptomyces aureofaciens were converted into protoplasts and divided into five subcellular fractions in order to localize exopolyphosphatases (EC 3.6.1.11), triphosphatase (EC 3.6.1.25), inorganic diphosphatase (EC 3.6.1.1), apyrase (EC 3.6.1.5) and glucokinase (EC 2.7.1.2). The highest specific activity of enzymes hydrolyzing polyphosphates was found in cytoplasmic vesicles and membranes. Triphosphatase was detected in the periplasmic fraction. Periplasmic vesicles and cytoplasm exhibited a high activity of diphosphatase. Apyrase was found mainly in the fractions of membranes and cytoplasmic vesicles. Glucokinase was a cytoplasmic enzyme. The enzymes were released from membrane structures into cytoplasm or periplasmic space if benzyl thiocyanate (10 μm) was present in the growth medium.     

Death of<Emphasis Type="Italic"> Escherichia coli</Emphasis> during rapid and s<Emphasis>e</Emphasis>vere dehydration is related to lipid phase transition

This study reports the effects of exposure to increasing osmotic pressure on the viability and membrane structure of Escherichia coli. Changes in membrane structure after osmotic stress were investigated by electron transmission microscopy, measurement of the anisotropy of the membrane fluorescent probe DPH (1,6-diphenyl-1,3,5-hexatriene) inserted in E. coli, and Fourier infrared spectroscopy (FTIR). The results show that, above a critical osmotic pressure of 35 MPa, the viability of the bacterium is drastically reduced (2 log decrease in survivors). Electron micrographs revealed a severe contraction of the cytoplasm and the formation of membrane vesicles at 40 MPa. Changes in DPH anisotropy showed that osmotic dehydration to 40 MPa promoted a decrease in the membrane fluidity of integral cells of E. coli. FTIR measurements showed that at 10–40 MPa a transition from lamellar liquid crystal to lamellar gel among the phospholipids extracted from E. coli occurred. Bacterial death resulting from dehydration can be attributed to the conjunction between membrane deformation, caused by the volumetric contraction, and structural changes of the membrane lipids. The influence of the latter on the formation of membrane vesicles and on membrane permeabilization at lethal osmotic pressure is discussed, since vesiculation is hypothetically responsible for cell death.     

Isolation of plasma membrane fractions from green wheat leaves by free-flow electrophoresis or two-phase partition alone or in combination

Plasma membrane vesicles were isolated from shoots of light-grown wheat seedlings by preparative free-flow electrophoresis, aqueous polymer two-phase partition or both. Plasma membrane vesicles were identified from staining of thin sections prepared for electron microscopy with phosphotungstic acid at low pH. The orientation of the plasma membrane vesicles was determined from latency and trypsin sensitivity of K⁺ Mg²⁺ATPase and of glucan synthase II, and concanavalin A-peroxidase binding and membrane asymmetry visualized by electron microscopy. The K⁺Mg²⁺ATPase and of glucan synthase II activities of plasma membrane fractions isolated by two-phase partition were latent and trypsin resistant. The vesicles bound concanavalin A-peroxidase strongly and exhibited a cytoplasmic side-in morphology. These fractions of cytoplasmic side-in vesicles were less than 10% contaminated by cytoplasmic side-out vesicles. By free-flow electrophoresis, two populations of vesicles which stained with phosphotungstic acid at low pH, designated D and E, were obtained. The vesicle population with the lower electrophoretic mobility, fraction E, contained plasma membrane vesicles with properties similar to those of the plasma membrane vesicles obtained after two-phase partition. The phosphotungstic-reactive vesicles with greater electrophoretic mobility, fraction D, were concanavalin A unreactive with the cytoplasmic membrane leaflet outwards. Less than 50% of the K⁺Mg²⁺-ATPase activity of this fraction was latent and trypsin sensitive. The vesicles of fraction D appeared to be preferentially cytoplasmic side-out. The electrophoretic mobilities of cytoplasmic side-out (non-latent glucan synthase II activity) and cytoplasmic side-in (latent glncan synthase II activity) plasma membrane vesicles isolated from a frozen and thawed wheat plasma membrane fraction, corresponded with the mobilities of fraction D and E, respectively, again showing that the plasma membrane vesicles with the lesser electrophoretic mobility were cytoplasmic side-in. The cytoplasmic side-in and cytoplasmic side-out vesicles therefore showed opposite eletrophoretic mobilities compared with a previous free-flow electrophoretic separation of soybean plasma membranes. The majorities of the plasma membrane vesicles of both fractions D and E entered the upper phase upon two-phase partition with the phase composition used for purification of wheat plasma membranes. Thus, neither electrophoretic mobility nor phase partitioning characteristics can be used as the only criteria for assignment of vesicle orientation.     

Uptake of protoplasts from the filamentous fungiAspergillus nidulans andFusarium oxysporum into protoplasts from celery (Apium graveolens L.)

Summary Protoplasts isolated from celery cell suspension cultures, were mixed with fungal protoplasts, from either the saprophytic speciesAspergillus nidulans or the pathogenic speciesFusarium oxysporum. The incubation of protoplast mixtures with PEG caused close adhesion between plant and fungal protoplasts. Subsequent dilution of PEG resulted in the uptake of protoplasts from either fungal species into the plant protoplast cytoplasm. A range of PEG concentrations, incubation times and dilution rates were tested to maximise adhesion and uptake frequencies. Identification of uptake was achieved either by fluorescent staining of nuclei or by electron-microscopy. A maximum of 10% celery protoplasts had taken upA. nidulans protoplasts after PEG treatment. Fungal protoplasts were taken up into celery protoplast cytoplasm by endocytosis, and were maintained within vesicles; two bounding membranes were observed by electron microscopy. Plant protoplast viability was determined during prolonged incubation following fungal protoplast uptake. The presence ofA. nidulans protoplasts tended to maintain celery protoplast viability and although some morphological disintegration occurred intact celery protoplasts remained for at least 92 h after uptake. The uptake ofF. oxysporum protoplasts markedly depressed celery protoplast viability after 24 h incubation and greater celery protoplast disintegration occurred.Abbreviations PEG Polyethylene glycol - DAPI 4,6-diaminido-2-phenylindole - 2,4-D 2,4-dichlorophenoxyacetic acid     

Short-term effects of Al3+ on the osmotic behavior of red beet (Beta vulgaris L.) protoplasts

The short-term (less than 10 min) effects of Al³⁺ on the biophysical properties of plasma membranes were investigated by time-series image analysis of osmotically-induced volumetric and morphologic changes of red beet (Beta vulgaris L.) protoplasts. Exposure to Al³⁺ under hypotonic conditions reduced the volumetric expansion of protoplasts and their resultant burst: i.e. lysis of protoplasts in a concentration-dependent manner. Under hypertonic conditions, protoplasts exposed to Al³⁺ underwent an enhanced volumetric contraction in cross-sectional area, while maintaining higher protoplast roundness. The residual effects of Al³⁺ pre-treatment on subsequent osmotic behavior were also examined, and protoplasts pre-treated with Al³⁺ also exhibited less lysis during subsequent exposure to hypotonic conditions and enhanced volumetric contractions and higher roundness under subsequent hypertonic conditions. Under our experimental conditions, Al³⁺ consistently minimized protoplast surface area by inhibiting osmotic expansion or by enhancing osmotic contraction, as well as by maintaining higher protoplast roundness. These results suggested that the electrostatic property of Al³⁺ might have induced the binding and possible cross-linking of negatively-charged sites on the plasma membrane surface. This may be an important factor in understanding the mechanism of Al³⁺ phytotoxicity.     

The relationship between cell injury and osmotic volume reduction: III. Freezing injury and frost resistance in winter wheat

In order to distinguish between several possible mechanisms of frost hardening in winter wheat (Triticum aestivum L.) cells from two hardy and two tender cultivars were plasmolyzed in CaCl₂ solution at room temperature and cell volumes estimated by microscopic examination. Analyses of Boyle-van't Hoff plots of these data reveal that all cells from cultivars progressively increase their intracellular solute concentration up to 20 days hardening. This increase, which we had predicted from published calorimetric data to be the sole mechanism of hardening explained less than half of the increase in hardening seen in the most hardy cultivar, Kharkov. Hardening also increased the osmotically inactive volume.At CaCl₂ concentrations greater than 5%, plasmolyzed protoplasts departed further from the Boyle-van't Hoff prediction, remaining larger than expected until some higher concentration of CaCl₂, where protoplast volume again sharply decreased. In all cultivars except hardened Kharkov, the concentration of CaCl₂ producing this abrupt volume decrease had a freezing point corresponding to the killing temperature. If this concentration was exceeded during plasmolysis, then the protoplasts burst during deplasmolysis at some volume less than their original volume.We interpret these data to mean that, in addition to the often described hardening mechanism of increased cell solute and water binding, winter wheat shows a third mechanism, a mechanical resistance to protoplast shrinkage which produces volumes larger than those predicted during osmotic stress. The resisting element appears to be the plasma membrane itself. Shrinkage brings the membrane under compressive stress, developing tangential pressure within it. Cell injury occurs when the cell membrane area has been reduced to the point at which irreversible loss of membrane material is inevitable. Cell death occurs during deplasmolysis when the protoplast bursts because its membrane contains insufficient material to subtend the area of the cell wall.Of the cultivars tested, hardened Kharkov was unique in avoiding injury. Hardened Kharkov was injured only after the volume inflection had been greatly exceeded. Refractile droplets of lipid appeared in the cytoplasm of hardened Kharkov protoplasts during plasmolysis but disappeared during deplasmolysis suggesting that hardy Kharkov was able reversibly to store membrane lipids in cytoplasmic vesicles and return them to the membrane on deplasmolysis.     

LIGHT AND ELECTRON MICROSCOPIC STUDIES OF THE FUSION CELL IN ASTEROCOLAX GARDNERI SETCH. (RHODOPHYTA,CERAMIALES)12

The fusion cell in Asterocolax gardneri Setch, is a large, multinucleate, irregularly-shaped cell resulting from cytoplasmic fusions of haploid and diploid cells. Subsequent enlargement takes place by incorporating adjacent gonimoblast cells. The resultant cell consists of two parts—a central portion of isolated cytoplasm, surrounded by an electron dense cytoplasmic barrier, and the main component of the fusion cell cytoplasm surrounding the isolated cytoplasm. The fusion cell contains many nuclei, large quantities of floridean starch, endoplasmic reticulum, and vesicles, but few mitochondria, plastids and dictyosomes. The endoplasmic reticulum forms vesicles that apparently secrete large quantities of extracellular mucilage which surrounds the entire carposporophyte. The isolated cytoplasm also is multinucleate but lacks starch and a plasma membrane. Few plastids, ribosomes and mitochondria are found in this cytoplasm. However, numerous endoplasmic reticulum cisternae occur near the cytoplasmic barrier and they appear to secrete material for the barrier. In mature carposporophytes, all organelles in the isolated cytoplasm have degenerated.     

An ultrastructural investigation on the polyethylene glycol-induced adhesion of tobacco nuclei and uptake of micronuclei by soybean protoplasts

Nuclei isolated from tobacco protoplasts were induced to be taken up by soybean protoplasts using a protocol involving polyethylene glycol (PEG), osmotic shock and pH shift. Transmission electron microscopy revealed that PEG treatment condensed the chromatin of the isolated nuclei. Close adhesion of isolated nuclei to the plasma membrane of protoplasts following PEG treatment, was observed by both scanning and transmission electron microscopic methods. Ultrastructural observations were also made on the formation of micronuclei in tobacco cells following the treatment with amiprophosmethyl (APM). Nuclei and micronuclei isolated from APM-treated cells were induced to be taken up by soybean protoplasts. A single case of uptake of an isolated micronucleus was observed by transmission electron microscopy. The observations on the effects of PEG on the isolated nuclei, micronuclei and protoplasts are discussed in relation to the possible mechanism of uptake of nuclei by protoplasts using PEG.     

Formation of the plasma membrane during regeneration ofParamecium caudatum

Summary Fragments ofParamecium caudatum cells obtained by merotomy were fixed in 1% OsO₄ within 5 seconds after cutting. The ultrastructure of the damaged area of the fragment was studied in oriented ultrathin sections and by scanning electron microscopy. The cytoplasm exposed by merotomy was covered during a few seconds with a new membrane. This was a typical trilaminar membrane continuous with the plasma membrane covering the undamaged surface of the cell. The surface over the wound was wrinkled into irregular grooves and ridges. The cytoplasm, mitochondria and trichocysts in the injured region were electron translucent. The cytoplasm under the new membrane contained an unusually high amount of small membrane vesicles, 20–90 nm in diameter. These were probably the remnants of subpellicular alveoli and the plasma membrane destroyed by microsectioning. The possibility that the exposed cytoplasm would be covered by mere shifting of the existing plasma membrane can be excluded. The complex structure of the cortex with its subpellicular alveoli and regularly distributed cilia provide a strong argument against this notion. It seems probable that the new membrane was built up from the available molecular material,e.g., phospholipids and proteins present in the cytoplasm. Fragments of the membrane and alveolar membranes in the form of small vesicles may have also been included into the new membrane.     

Visualization of vacuoplasts in isolated vacuole preparations from mesophyll protoplasts of periwinkle [Catharanthus roseus (L.) G. Don]

A procedure was developed for the rapid detection of vacuoplasts in vacuole preparations isolated from mesophyll protoplasts of Catharanthus roseus (L.) G. Don (periwinkle). The procedure relies on the staining of surface carbohydrates on the plasma membrane surrounding vacuoplasts with fluorescein-labeled lectins. When isolated under conditions of constant osmotic strength, approximately 15–20% of the vacuoles isolated showed surface labeling with FITC-agglutinin from Abrus precatorius. Isolation of vacuoles after an initial osmotic shock showed much lower (<5%) surface labeling. This lower level of surface labeling correlated well with a lower level of other non-vacuolar marker enzyme activities. A thin layer of cytoplasm was visible in a small number of these stained structures, indicating that they were vacuoplasts.Abbreviations FITC fluorescein isothiocyanate