Karyokinesis in growing and reverting protoplasts ofSchizosaccharomyces pombe

Division of nuclei without cytokinesis proceeds in growing protoplasts ofSchizosaccharomyces pombe. Prior to regeneration of the complete cell wall and reversion the protoplasts contain 1–7 nuclei, protoplasts with 1–2 nuclei are most frequent. When regeneration of the wall is postponed by adding snail enzymes to the growth medium, protoplasts with a higher number of nuclei (2–4) occur. Multinuclear protoplasts can revert to cells. During the first cytokinesis the protoplast with the regenerated cell wall is divided into two cells by a septum, distribution of nuclei between the two cells being probably incidental. More than only a single nucleus can pass to the revertants even during the second cytokinesis. Septation of protoplasts occurs also during a partial blockage of the wall formation by the snail enzyme preparation, however, reversion to cells can never be observed here (it occurs only after transfer of protoplasts to the medium without the enzyme preparation). The growing and reverting protoplasts represent a very good model system for studying relations among individual processes of the cell cycle, primarily growth of the cell, nuclear cycle and cytokinesis. Yeast protoplasts are often utilized as models for studying morphogenic processes, relations among regeneration of the cell wall, including division of the nucleus (karyokinesis) and cytokinesis.     

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.     

The ultrastructure of cellular division (autosporogenesis) in the coccoid green alga,Trebouxia aggregata,revealed by rapid freeze fixation and freeze substitution

Summary Adequate ultrastructural preservation of cells of the green algaTrebouxia aggregata is achieved by immersion freeze fixation using liquid propane followed by freeze substitution and resin embedding at ambient temperature. Despite differential staining of membranes, using this method we have been able to study plasma membrane biogenesis during cellular division. Daughter protoplasts are separated by an ingrowing septum of plasma membrane that extends into the cell from a particular site at the peripheral plasma membrane marked by centrioles. Septum development involves tip growth followed by lateral growth. This growth seems to involve transfer of membrane from an adjacent partially coated reticulum to the septum plasma membrane. The reticulum which extends from nearby Golgi stacks to the area of septum growth is associated with an extensive array of microtubules. After daughter protoplasts are completely separated, each one becomes surrounded by a cell wall which is distinct from the persisting mother wall. The ultrastructural evidence suggests that cells ofT. aggregata are autospores rather than vegetative cells.Abbreviations C centriole - ER endoplasmic reticulum - G Golgi body - MTOC microtubule organizing center - Mt(s) microtubule(s) - N nucleus - P primary septum - PCR partially coated reticulum - PM plasma membrane - Py pyrenoid - S septum     

Experimental inhibition of cell wall formation and of reversion inNadsonia elongata andSchizosaccharomyces pombe protoplasts

Summary The growth, cell wall regeneration, and the reversion of the protoplasts ofNadsonia elongata andSchizosaccbaromyces pombe cultivated in nutrient media containing snail enzyme was studied by light and electron microscopy. The protoplasts grew in the presence of snail enzyme and an incomplete cell wall composed of fibrils was formed on their surface. Thus, the presence of snail enzyme inhibited the completion of cell wall structure and, consequently, the reversion of the protoplasts to normal cells. The transfer of these protoplasts to medium free from snail enzyme led first to the completion of the cell wall and then to the reversion of the protoplasts to normal cells. The reported experiments confirmed that the regeneration of the complete cell wall preceded the protoplast reversion.     

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.     

Efficient protoplast regeneration ofBacillus thuringiensis andAgrobacterium tumefaciens

Summary Treatment ofBacillus thuringiensis andAgrobacterium tumefaciens taken from the early growth phase (8 h) with lysozyme at 1 mg/ml gave 90–99% protoplast formation and 10–12% protoplast regeneration on the minimal medium in absence of plasma expander (Bovine serum albumin). Enhanced fusion frequency was obtained when protoplasts from 8 h grown cells were used for fusion experiments.     

Growth of Streptococcus mutans protoplasts is not inhibited by penicillin.

A method is described in which cells of Streptococcus mutans BHT can be converted to spherical, osmotically fragile protoplasts. Exponential-phase cells were suspended in a solution containing 0.5 M melezitose, and their cell walls were hydrolyzed with mutanolysin (M-1 enzyme). When the resultant protoplasts were incubated in a chemically defined growth medium containing 0.5 M NH4Cl, the protoplast suspensions increased in turbidity, protein, ribonucleic acid, and deoxyribonucleic acid in a balanced fashion. In the presence of benzylpenicillin (5 microgram/ml), balanced growth of protoplasts was indistinguishable from untreated controls. This absence of inhibition of protoplast growth in the presence of benzylpenicillin was apparently not due to inactivation of the antibiotic. When exponential-phase cells of S. mutans BHT were first exposed to 5 microgram of benzyl-penicillin per ml for 1 h and then converted to protoplasts, these protoplasts were also able to grow in chemically defined, osmotically stabilized medium. The ability of wall-free protoplasts to grow and to synthesize ribonucleic acid and protein in the presence of a relatively high concentration of benzylpenicillin contrasts with the previously reported rapid inhibition of ribonucleic acid and protein synthesis in intact streptococci. These data suggest that this secondary inhibition of ribonucleic acid and protein synthesis in whole cells is due to factors involved with the continued assembly of an intact, insoluble cell wall rather than with earlier stages of peptidoglycan synthesis.     

Functional sieve element protoplasts

Sieve element (SE) protoplasts were liberated by exposing excised phloem strands of Vicia faba to cell wall-degrading enzyme mixtures. Two types of SE protoplasts were found: simple protoplasts with forisome inclusions and composite twin protoplasts-two protoplasts intermitted by a sieve plate-of which one protoplast often includes a forisome. Forisomes are giant protein inclusions of SEs in Fabaceae. Membrane integrity of SE protoplasts was tested by application of CFDA, which was sequestered in the form of carboxyfluorescein. Further evidence for membrane intactness was provided by swelling of SE protoplasts and forisome dispersion in reaction to abrupt lowering of medium osmolarity. The absence of cell wall remnants as demonstrated by negative Calcofluor White staining allowed patch-clamp studies. At negative membrane voltages, the current-voltage relations of the SE protoplasts were dominated by a weak inward-rectifying potassium channel that was active at physiological membrane voltages of the SE plasma membrane. This channel had electrical properties that are reminiscent of those of the AKT2/3 channel family, localized in phloem cells of Arabidopsis (Arabidopsis thaliana). All in all, SE protoplasts promise to be a powerful tool in studying the membrane biology of SEs with inherent implications for the understanding of long-distance transport and signaling.     

Plasma Membrane Ghosts Form Differently When Produced from Microtubule-Free Tobacco BY-2 Cells

When lysed in an actin stabilizing buffer, protoplasts madefrom tobacco BY-2 suspension culture cells formed plasma membraneghosts that retained both cortical actin and microtubules. Distinctcytoskeletal arrays occurred: the most common ghost array (typeI) derived from protoplasts in interphase and had random actinand microtubules, although the alignment of the actin was dependent,at least partially, on microtubule organization. Type II ghostswere larger and more irregular in shape than type I ghosts,and were characterized by a lack of microtubules and the presenceof distinctive arrays of actin bundles in concentric arcs. Theseghosts derived from protoplasts lacking cortical microtubulesproduced when wall digestion occurred while the cells were incell division, or from protoplasts isolated in the presenceof 100 µM propyzamide. Because type II ghosts derivedfrom protoplasts of similar size to those that give rise totype I ghosts, and because type II ghosts retained ordered actinarrays while the parent protoplasts had random cortical actin,type II ghosts apparently form differently to type I ghosts.We speculate that instead of the protoplast being sheared offto produce a round ghost, the plasma membrane tears and collapsesonto the slide, ordering the actin bundles in the process. Oneimplication of this model would be that cortical microtubulesprovide structural support to the plasma membrane of the protoplastso that only in their absence do the type II ghosts form. (Received May 26, 1998; Accepted October 26, 1998)     

FUS1 regulates the opening and expansion of fusion pores between mating yeast

Mating yeast cells provide a genetically accessible system for the study of cell fusion. The dynamics of fusion pores between yeast cells were analyzed by following the exchange of fluorescent markers between fusion partners. Upon plasma membrane fusion, cytoplasmic GFP and DsRed diffuse between cells at rates proportional to the size of the fusion pore. GFP permeance measurements reveal that a typical fusion pore opens with a burst and then gradually expands. In some mating pairs, a sudden increase in GFP permeance was found, consistent with the opening of a second pore. In contrast, other fusion pores closed after permitting a limited amount of cytoplasmic exchange. Deletion of FUS1 from both mating partners caused a >10-fold reduction in the initial permeance and expansion rate of the fusion pore. Although fus1 mating pairs also have a defect in degrading the cell wall that separates mating partners before plasma membrane fusion, other cell fusion mutants with cell wall remodeling defects had more modest effects on fusion pore permeance. Karyogamy is delayed by >1 h in fus1 mating pairs, possibly as a consequence of retarded fusion pore expansion.     

Morphological Changes during Conversion of Clostridium saccharoperbutylacetonicum to Protoplasts by Sucrose-Induced Autolysis

When exponentially growing cells of Clostridium saccharoperbutylacetonicum (ATCC 13564) were exposed to hypertonic concentrations of sucrose (0.3–0.5 M), rapid degradation of the cell wall occurred (sucrose-induced autolysis). The morphological changes from the original rod-shaped cells to protoplasts during the sucrose-induced autolysis were investigated by phase contrast and electron microscopy. When the cells were autolysed in the sucrose solution (0.35 M), each cell began to swell at the middle or at one pole and then formed a small bulb at the swollen part. The bulb consisted of the cytoplasm which was enveloped by the plasma membrane and extruded from the small gap produced by the degradation of the cell wall. The bulb gradually enlarged as lysis progressed, and finally became a protoplast which had no cell wall. The large pre-division cell frequently formed the bulb at the middle (septal site), while the small post-division cell formed the bulb at the pole.     

Spatial determinants in morphogenesis: recovery from plasmolysis in the diatom Ditylum

Ditylum cells are enclosed in a rigid wall consisting of two "valves" (end walls) connected by "girdle bands." A hollow spine, the Labiate Process (LP), extends from each valve and a stable cytoplasmic strand connects its base with the nucleus. We investigated whether cells might possess "spatial determinants" for controlling their internal organization and wall morphogenesis. Upon plasmolysis, cells contracted into a spherical protoplast detached from the wall. Recovery was initiated by growing filopodia that "searched" the inside of the wall. Some attached to the inside corners, generating tension that could temporarily displace the protoplast. Others consolidated into the strand connecting nucleus with the LP. The protoplasts soon expanded and cells recovered: some divided immediately, the rest within 24 h. When recently divided cells were plasmolysed, their nascent valves were exocytosed. These were ignored by the filopodia during recovery. Later, protoplasts secreted a new valve, while the nascent valves were discarded. The interphase microtubule (MT) cytoskeleton radiates from a central Microtubule Center. A thicker bundle connects the nucleus to each LP. Plasmolysis destroyed the MT cytoskeleton; its re-establishment matched growth of the filopodia. The anti-MT drug oryzalin prevented filopodial extension while existing filopodia retracted, except those stabilized by attachment to the corners of the cell and the LP. Several anti-actin agents had relatively little effect. However, one, mycalolide B, caused the nucleus to be extruded from the protoplast by a bundle of MTs. We conclude that the geometry of the wall could provide spatial information to which the MT-cytoskeleton/filopodia respond.     

The Effects of Cell Cycle Parameters on Cell Wall Regeneration and Cell Division of Cotton Protoplasts (Gossypium hirsutum L.)

Protoplasts of cotton cotyledons were isolated and culturedto undergo cell wall regeneration and cell division. DNA contentand cell cycle parameters of nuclei from cotyledons and/or protoplastswere determined by flow cytometry. The DNA content of cotton,Gossypium hirsutum L., was estimated to be 4·34±0·12pg DNA per nucleus. There was a strong positive correlation between G₂ or Sand G₂,and cell wall regeneration and cell division and a strong negativecorrelation between G₁, and cell wall regeneration and celldivision of cotton cotyledon protoplasts. The cell cycle statusof cotyledons changes during their development; as the cotyledonsenlarge, the proportion of cells in G₀ and G₁ phases of thecell cycle increases. The implication of these results in relationto protoplast growth and development is discussed. Key words: Cell cycle parameters, cell wall regeneration, cell division, flow cytometry, Gossypium     

Isolation of cytoplasts from Satsuma mandarin (Citrus unshiu Marc.) and production of alloplasmic hybrid calluses via cytoplast–protoplast fusion

Cytoplasm of Satsuma mandarin (Citrus unshiu Marc.) is known to influence seedlessness. Transfer of cytoplasm to a seedy cultivar could possibly lead to the production of seedless citrus fruits. In the present paper cytoplasts were isolated from cell suspension-derived protoplasts of Satsuma mandarin via ultra-centrifugation in a discontinuous gradient. No nucleus could be detected in the cytoplasts by DAPI (4′, 6-diamidino-2-phenylindole) staining compared with normal protoplasts. The cytoplasts, with high viability and small size, did not divide during solid embedding culture. Cytoplasts of Satsuma mandarin were electrically fused with embryogenic protoplasts of Murcott tangor (C. reticulata × C. sinensis), which led to regeneration of several cell lines. Flow cytometry (FCM) indicated that the cell lines were diploids. Simple sequence repeats (SSR) and cleaved amplified polymorphism sequence (CAPS) showed that the cell lines got their nuclear DNA from the protoplast parent, whereas the cytoplast parent donated the mtDNA, confirming transfer of mtDNA from Satsuma mandarin into Murcott tangor via cytoplast–protoplast fusion though no polymorphism was detected in chloroplast DNA between the fusion partners. This is the first report on isolation and characterization of cytoplasts, together with cytoplast–protoplast fusion in Citrus, which has a potential for citrus cultivar improvement involving cytoplasm transfer via cytoplast–protoplast fusion.     

Ultrastructure of protoplasts from mycelium and microconidia of Trichophyton mentagrophytes

Protoplast formation from mycelium and microconidia of Trichophyton mentagrophytes was achieved with Novozym 234. Pretreatment procedures with dithiothreitol or urea mercaptoethanol sodium lauryl sulphate before digestion with Novozym 234 greatly reduced protoplast yield from mycelium. Snail gut enzyme did not protoplasts in good yield. Scanning electron microscopy of mycelium protoplasts showed the acquired spherical shape. The plasma membrane appeared finely granular although remnants of cell wall could sometimes be observed. Transmission electron microscopy showed the cell interior of these protoplasts was plasmolysed. Microconidia treated with Novozym 234 displayed a range of cell wall digestion, with intact protoplasts showing distinct cytoplasmic organelles.     

Domain-specific mechanosensory transmission of osmotic and enzymatic cell wall disturbances to the actin cytoskeleton

Summary. Plant protoplasts are embedded within surrounding cell walls and the cell wall–plasma membrane–cytoskeleton (WMC) structural continuum seems to be crucial for the proper functioning of plant cells. We have utilised the protoplast preparation methodology to study the organisation and the putative components of the WMC continuum. Application of an osmotic agent evoked plasmolysis of the Zea mays root apex cells which appeared to be cell type- and growth stage-specific. Simultaneous use of wall polysaccharide-digesting enzymes selectively severed linkages between the components of the WMC continuum which changed the plasmolytic patterns in various cell types. This was followed by a reorganisation of filamentous actin aimed to reinforce protoplast boundaries and maintain the functioning of intercellular contact sites, especially at the cross walls. Particularly strong effects were evoked by pectin-degrading enzymes. Such treatments demonstrated directly the differentiated composition of various wall domains surrounding individual cells with the pectin-enriched cross walls (synapses), and the cellulose-hemicellulose network dominating the side walls. The same wall-degrading enzymes were used for in vitro digestion of isolated Lupinus albus cell walls followed by the extraction of wall proteins. Selective release of proteins suggested the importance of wall polysaccharide–protein interactions in the maintenance of the functioning and mechanical stability of root cell walls. Correspondence and reprints: Department of Molecular and Cellular Biology, Adam Mickiewicz University, Międzychodzka 5, 60-371 Poznań, Poland.     

An Ultrastructural Study on Triggering of Cell Division in Young Pollen Protoplast Culture of Hemerocallis fulva L.

The ultrastructural changes of young pollen protoplasts under culture condition in Hemerocallis fulva were studied. In comparison with the original pollen grains, the pollen protoplasts had been completely deprived of pollen wall, but kept the internal structure intact, including a large vacuole, a thin layer of cytoplasm and a peripherally located nucleus. After 8 days of culture a few pollen protoplasts were triggered to cell division: some of them were just undergoing mitosis with clearly visible chromosomes and spindle fibers; the others already divided into 2-celled units. The two daughter cells were equal or unequal in size but with similar distribution of organelles inside. Besides cell division, there were also free nuclear division, amitosis and formation of micronuclei indicating a diversity of division modes in pollen protoplast culture, A series of changes occurred during the process of induction of cell division, such as locomotion of the nucleus toward the central position, disappearence of the large vacuole, increase of electron density of cytoplasm, increase and activation of organelles, diminishing of starch granules in plastids, etc. However, the regeneration of surface wall was not sufficient it contained mostly vesicles with only a few microfibrits. The wall separating the two daughter cells were either complete or incomplete. The weak capability of wall formation is supposed to be one of the major obstacles which has so far restricted sustained cell divisions of young pollen protoplasts under current culture condition.     

Effect of proteases,phospholipases and polysaccharide-splitting enzymes on plasma membrane particles and on the synthesis of the fibrillar cell wall component in yeast protoplasts

Plasma membrane particles demonstrable by the freeze-etching technique, play, according to some authors, a role in the cell wall synthesis. On a model of yeast protoplast capable of regenerating the cell wall we studied the morphology of plasma membrane particles and the synthesis of the fibrillar cell wall component following a treatment with various enzymes and with lysolecithin. The enzymes used included proteases (trypsin, papain, pronase), polysaccharide-splitting enzymes (snail enzyme complex, mannosidase), phospholipases (A, C, D) and lipase. Upon treating living protoplasts with these substances in no case did we observe any morphologically demonstrable change in the particle structure or in their distribution in the plasma membrane. The fibrillar cell wall component was synthetized even in the presence of proteases and phospholipases. If the plasma membrane particles are assumed to represent enzyme systems synthesizing the cell wall component then in living protoplasts they are not located on the outer plasma membrane face or else are protected by some mechanism against the action of the corresponding enzymes.     

Laser microsurgery: a versatile tool in plant (electro) physiology

Summary In plant cells the cell wall is a formidable obstacle in many physiological studies such as patch-clamp measurements and cell labelling with antibodies. Enzymatic digestion of the cell wall, in order to release a protoplast, has a number of disadvantages; therefore we worked out an alternative method to gain access to the plasma membrane. The wall of specialized cells from three higher plant species and one unicellular alga were perforated using the focussed UV light of a nitrogen laser. In order to enhance the absorption of the UV light by the walls, a dye was used that binds specifically to cell wall components. Extrusion of the protoplast or parts thereof was controlled by a regulated gradual decrease of the osmolarity of the solution surrounding the cells. Cytoplasmic streaming and chloroplast circulation were maintained in the protoplasts, demonstrating their viability after the wall perforation with the laser. Continuous deposition of new cell wall material by the polar tip of pollen tubes after surgical removal of the wall at the tip is another demonstration of the viability of the cells. Formation of high resistance seals between the plasma membrane and a patch pipet was surprisingly difficult. The role of Hechtian strands and continuing synthesis of cell wall material in seal formation is further investigated. Other applications for the surgical laser are: fusion of two cells or vacuoles, analysis of the composition of specific parts of the cell wall, and release of the vacuole from an identified cell type for patchclamp studies.Abbreviations CFW calcofluor white - PM plasma membrane