Plant protoplasts immobilized in calcium alginate: a simple method of preparing fragile cells for transmission electron microscopy

A simple method for electron microscopic preparation of plant protoplasts is described. The main problems in preparing these fragile protoplasts for electron microscopy have been cell collapse due to steep gradients between protoplasts and fixatives and unacceptable loss of material during the many steps of the procedure. These problems may be solved by immobilization of the protoplasts in calcium alginate beads. The free diffusion properties of this gel prevent steep gradients. The beads also simplify handling and prevent loss of material. Protoplasts isolated from hypocotyls of rape, Brassica napus (var. Niklas), have been used as a model system. Transmission electron microscopy of the immobilized protoplasts osmotically stabilized with glucose demonstrated adequate structural and ultrastructural preservation.     

Isolation of anucleated yeast protoplasts by means of density gradient centrifugation

An improved method for the preparation in high yield of anucleated Saccharomyces cerevisiae has been developed. This method is based on a two-stage centrifugation of the original protoplast mixture in linear density gradients (1–10%, w/v) of Ficoll 400. The yield of anucleated protoplasts was 5–9%, its value depended on the frequency of the nucleus-free protoplasts in the original mixture.The anucleated protoplasts were characterized by RNA, DNA and protein content, and by light and electron microscopy. The protoplasts lacking nuclei had about one third the diameter of the nucleated ones, and reduced of DNA, RNA and protein in comparison to normal protoplasts. Electron microscopy showed a typical yeast ultrastructure in anucleated protoplasts except that they lacked nuclei and exhibited a higher frequency of lipid granules and exocytotic electron-dense vesicles located close to the plasmalemma.     

Real and pseudo oxygen gradients in Ca-alginate beads monitored during polarographic Po2-measurements using Pt-needle microelectrodes

Polarographic microcoaxial needle electrodes were used to measure internal profiles of dissolved oxygen tension (Po(2)) within single Ca-alginate beads of different diameter containing entrapped cells of Saccharomyces cerevisiae. For the investigations, single beads coming from variable growing conditions and distinct cultivation stages were fixed in a special holding device. In dependence on microbial growth steep oxygen gradients were observed. The Oxygen penetration depth at steady state lay between 50 and 100 mum. After 8 h of cultivation time, the anaerobic space within the beads (phi 2 mm; cultivation in a packed bed reactor) is beginning at approximately 130 mum, whereas the anaerobic space within the beads (phi 2 mm) coming from the shaker flask culture is located approximately 440 mum below the bead surface. Surprisingly, steep gradients were also observed, when recording profiles from cell-free Ca-alginate beads of different diameter and alginate concentrations. The steep oxygen gradients apparently had to be interpreted as pseudo-Po(2)-gradients. These results were borne by several effects, such as formation of artifacts and diffusion barriers in front of the electrode tip or oxygen "availability" at the tip and consumption of oxygen by the electrode itself. These phenomena could be documented by microscopic observation and photography. Thus, to obtain real Po(2)-profiles it is important to be exactly informed about the physical, chemical, and biological properties of the material to be investigated. Furthermore, it is necessary to apply a special stepwise puncture technique with distinct step-in/step-out movements of the electrode: e.g., unidirectional or contradirectional puncture techniques. (c) 1994 John Wiley & Sons, Inc.     

Structure and association of wall fibrils produced by regenerating tobacco protoplasts

A study has been made of the wall fibrils produced by tobacco protoplasts, using scanning electron microscopy in conjunction with negative staining. It has been shown that the fibres seen in scanning electron microscopy correspond to aggregates of microfibrils. These aggregates are only visible where they are lifted clear of the protoplast surface. Negative staining of fixed protoplasts shows that the aggregation of microfibrils into the fibres visible in scanning electron microscopy is probably produced by air-drying. Gentle disruption of microfibrils produces both random broken fragments and bundles of short pieces of fibrillar material about 60 nm in length. This material is present in undisrupted young walls, but not in undisrupted older walls. The microfibrils in young walls seem much more fragile and liable to breakage than those in older walls. These results are discussed in terms of the interpretation of scanning electron microscope images and the mechanism of cellulose microfibril formation by higher plants.Abbreviations SEM Scanning electron microscopy     

Carbohydrate-labeled fluorescent microparticles and their binding to lectins

The preparation of micrometer-sized, cross-linked poly(p-phenyleneethynylene) (PPE) beads to which simple monosaccharides are attached is reported. Mannose, glucose, and galactose derivatives have been synthesized. The fluorescence properties, size distribution, and morphology of these microparticles have been elucidated through fluorimetry, fluorescence confocal microscopy, and scanning electron microscopy. Protein binding assays were carried out using Concanavalin A tagged with the fluorophore Texas Red, and the resultant bioconjugates were imaged using confocal microscopy. The microparticles are shown to exhibit efficient binding to lectins and may have potential application as fluorescent probes, biocapture agents, or column packing material for affinity chromatography.     

Wall ultrastructure in regenerating protoplasts ofAspergillus nidulans

Summary The ultrastructure of the wall formed by regenerating protoplasts ofAspergillus nidulans was investigated by electron microscopy using shadowing and freeze-etching techniques. The first evidence of wall formation by the protoplasts was seen in the development of a microfibrillar network composed of chitin. As the protoplasts develop further amorphous material was deposited on the outer surface of the skeletal net.     

Production of asymmetric hybrids between Arabidopsis thaliana and Brassica napus utilizing an efficient protoplast culture system

Application of the protoplast culture method developed for Brassica protoplasts to protoplasts of Arabidopsis thaliana has increased the opportunities for interspecific hybridizations involving Arabidopsis. A more-efficient and much-simpler method was established compared to the earlier-reported protocol developed for A. thaliana protoplasts in which alginate beads were utilized. Mesophyll protoplasts of A. thaliana (ecotypes 'Landsberg erecta' and 'Wassilewskija') were cultured in the modified 8p liquid medium, which had been developed for Brassica protoplasts. For comparison, protoplasts were cultured in sodium alginate beads supplied with B5 medium according to the protocol for A. thaliana. The protoplasts divided with high frequencies in the 8p medium, and calli proliferated more rapidly than in the sodium alginate beads. High frequencies of shoot differentiation and regeneration were observed in calli of both ecotypes, from about 30% in the ecotype 'Wassilewskija' to about 60% for 'Landsberg erecta'. The more-rapidly the calli developed, the higher the regeneration frequencies were. Asymmetric hybrids between A. thaliana and Brassica napus were obtained by treating the protoplasts of A. thaliana with iodoacetamide (IOA) and B. napus protoplasts with UV-irradiation before fusion with polyethylene glycol (PEG). By using the culture procedure developed for Brassica protoplasts, calli developed and plants were regenerated. Although most of the plants regenerated after cell fusion were A. thaliana-like and were judged to be escapes from IOA treatment, more than ten plants showed hybrid features of both morphological and molecular characters. Among the hybrids that have flowered so far, both male-fertile and male-sterile plants have been obtained. Back-crossings to A. thaliana are now in progress as is morphological and molecular characterization of the plants.     

Ultrastructural characterization and three-dimensional reconstruction of isolated maize (Zea mays L.) egg cell protoplasts

Summary Isolated egg cell protoplasts ofZea mays L., inbred line A 188, have been studied at the transmission electron microscope level. Their preparation for electron microscopy has been performed by embedding in ultra-low gelling agarose as a preliminary step. Five isolated egg cell protoplasts were serially ultrathin sectioned and studied in detail. One of these protoplasts was reconstructed in three dimensions to provide additional information on its structure. After enzymatic digestion and microdissection, isolated egg cells are true, highly vacuolized protoplasts. The structure of their organelles agrees with in situ observations, indicating an ultrastructural intactness after isolation: the mitochondria are polymorphic, form reticulate networks, and have well developed cristae; the plastids contain starch grains; and the spherical nucleus is euchromatic. As in situ, the organelles of the isolated egg cell protoplasts are aggregated near the nucleus. The complete picture provided by this work should serve as a comparative base for studies on in vitro fertilization products.     

Structural and immunological studies on the protoplast membrane of the yeast Candida utilis

Cell membranes of the yeast Candida utilis isolated by lysis of protoplasts have been shown to be lipoprotein in nature. Electron microscopy shows that Mg⁺⁺ is responsible for maintaining the integrity of the membrane. A close serological relationship was found between membranes and cell walls isolated from the yeast. This relationship was exhibited not only by membranes obtained by strepzyme treatment but also by those obtained from the action of helicase enzyme. No such relationship existed between membranes and whole cells. Related data have been obtained by treatment of yeasts with different digestive enzymes. All of the results suggest that the protoplast membrane possesses traces of structural cell wall material. This material is detectable by serological tests, but not by electron microscopy.     

Lipase production by free and immobilized protoplasts of Sporotrichum (Chrysosporium) thermophile Apinis

Summary Production of lipase by free and alginate-entrapped protoplasts was studied in batch culture. Cell-wall-degrading enzymes Novozym 234 and cellulase CP improved lipase secretion of normal mycelium by 25%–100%. The protoplast-regenerated mycelium exhibited several-fold higher lipase activity in batch replacements in TRIS buffer over normal spore-derived mycelium. The specific lipase activity of immobilized protoplasts was about four times higher than normal mycelial beads. Protoplasts beads were stable and retained high enzyme activity even after three buffer replacements lasting 120 h; TRIS buffer was better than acetate or normal glucose medium. A minimum of 8 h regeneration period was necessary for lipase synthesis. Triolein, olive oil, tributyrin and oleic acid butylester were able to induce lipase in immobilized protoplasts. Tween 80 enhanced lipase activity of the immobilized protoplasts. Partially degraded immobilized mycelium was nearly as effective as normal immobilized protoplasts for lipase secretion. Both free and immobilized protoplasts could be reused for up to 200 h with some loss in enzyme activity.     

Stability and comparative transport capacity of cells, mureinoplasts, and true protoplasts of a gram-negative bacterium

The outer layers of the cell envelope of a pseudomonad of marine origin were removed by washing the cells in 0.5 m NaCl followed by suspension in 0.5 m sucrose. The term mureinoplast has been suggested for the rod-shaped forms which resulted from this treatment. As previously established, these forms lacked the outer cell wall layers but still retained a rigid peptidoglycan structure. Mureinoplasts remained stable if suspended in a balanced salt solution containing 0.3 m NaCl, 0.05 m MgSO(4), and 0.01 m KCl but, unlike whole cells, lost ultraviolet (UV)-absorbing material if suspended in 0.5 m NaCl or 0.05 m MgCl(2). Sucrose added to the balanced salt solution also enhanced the loss of UV-absorbing material. Addition of lysozyme to suspensions of mureinoplasts in the balanced salt solution produced spherical forms which, by electron microscopy and the analysis of residual cell wall material, appeared to be true protoplasts. Only undamaged mureinoplasts, as judged by their capacity to fully retain alpha-aminoisobutyric acid, were capable of being converted to protoplasts. Protoplasts and undamaged mureinoplasts retained 100% transport capacity when compared to an equal number of whole cells. The Na(+) requirement for transport of alpha-aminoisobutyric acid and the sparing action of Li(+) on this Na(+) requirement were the same for both protoplasts and whole cells. These observations indicate that, in this gram-negative bacterium, the cell wall does not participate in the transport process though it does stabilize the cytoplasmic membrane against changes in porosity produced by unbalanced salt solutions. The results also indicate that the requirements for Na(+) for transport and for the retention of intracellular solutes are manifested at the level of the cytoplasmic membrane.     

Application of protoplast fusion technique to genetic recombination of Micromonospora rosaria

The optimum conditions for efficient formation and regeneration of Micromonospora rosaria protoplasts have been determined. The state of inoculum culture and stage of growth in a medium containing partially growth-inhibiting concentrations of glycine had significant effects on protoplasting. A high frequency of regeneration was accomplished with a hypertonic regeneration agar medium. A slight difference was found in the optimum culture age for formation and regeneration of protoplasts. Protoplast fusion was carried out using these optimum conditions. The recombinant frequency varied from 0.7 to 5.9% in the intraspecific crosses employing single and multiple auxotrophic markers. Electron microscopy showed stable and intact protoplasts when they were prepared with a hypertonic buffer. However, many protoplasts were shown to be damaged and many membraneous vesicles were observed when prepared in buffer without sucrose. The fusion process of protoplasts of Micromonospora was observed with the aid of electron microscopy.     

Improvement of plasmid stability of recombinant Bacillus-subtilis cells in continuous immobilized cultures

Abstract: The immobilization of recombinant Bacillus subtilis in K-carrageenan gel beads has been performed in order to study the growth conditions inside the gel beads and to improve plasmid stability. Bacterial colonies showing high cell density were studied using scanning electron microscopy. A series of continuous cultures of free and immobilized B. subtilis MT119 (pHV1431, pIL252 and pIL252 Kpn) have been developed without selection pressure. In the free-cell systems, it was found that a loss of plasmid vectors occurred after a short period. In contrast, in the immobilized cell systems, plasmid-free segregants were not detected in any of the cases during the first 80 h of the culture.     

Patch clamping corn protoplasts

Summary Cell wall regeneration around protoplasts from Black Mexican Sweet corn suspension cells has been observed using scanning electron microscopy. A coherent array of cellulose microfibrils can be seen around protoplasts two hours after they have been isolated. This array does not form in the presence of 15 mg/l Congo Red. The frequency and electrical resistance of seals made between patch clamp pipettes and the plasmalemma around corn protoplasts is not significantly affected by the presence or absence of these fibrils (p₀=0.75); it remains relatively low. Some single channel records from BMS corn protoplasts are shown.     

Atomic force microscopy of pollen grains,cellulose microfibrils,and protoplasts

Summary Atomic force microscopy (AFM) holds unique prospects for biological microscopy, such as nanometer resolution and the possibility of measuring samples in (physiological) solutions. This article reports the results of an examination of various types of plant material with the AFM. AFM images of the surface of pollen grains ofKalanchoe blossfeldiana andZea mays were compared with field emission scanning electron microscope (FESEM) images. AFM reached the same resolutions as FESEM but did not provide an overall view of the pollen grains. Using AFM in torsion mode, however, it was possible to reveal differences in friction forces of the surface of the pollen grains. Cellulose microfibrils in the cell wall of root hairs ofRaphanus sativus andZ. mays were imaged using AFM and transmission electron microscopy (TEM). Imaging was performed on specimens from which the wall matrix had been extracted. The cell wall texture of the root hairs was depicted clearly with AFM and was similar to the texture known from TEM. It was not possible to resolve substructures in a single microfibril. Because the scanning tip damaged the fragile cells, it was not possible to obtain images of living protoplasts ofZ. mays, but images of fixed and dried protoplasts are shown. We demonstrate that AFM of plant cells reaches resolutions as obtained with FESEM and TEM, but obstacles still have to be overcome before imaging of living protoplasts in physiological conditions can be realized.Abbreviations AFM atomic force microscope - FESEM field emission scanning electron microscope - PyMS pyrolysis mass spectrometry - TEM transmission electron microscope     

Nurse culture of low numbers of Medicago and Nicotiana protoplasts using calcium alginate beads

Protoplasts of two species, lucerne and tobacco, were cultured in semi-solid droplets of calcium alginate as a means of nurse culturing very low numbers of protoplasts. It was shown that increasing autoclave times decreased the gelling capacity of the alginic acid. A convenient measure of viscosity is described to allow appropriate adjustment of the alginate solution. Tobacco protoplasts are shown to be more sensitive to higher alginate concentrations than lucerne, however beads with a final alginate concentration of approximately 1.5% were suitable for both species. Agitation of the beads in liquid medium was needed for optimum division frequencies. The volume of liquid medium affected the culture response. Interestingly, the local cell density (bead cell density) was shown to be more influential than the total cell density. Nurse beads with higher densities of protoplasts of the same species were visually marked with activated charcoal. Experiments were performed to determine whether nursing was effective with calcium alginate encapsulation and to what extent the cell densities could be lowered. When there were no nurse beads, divisions effectively ceased at 10⁴ per ml with lucerne and 10³ per ml with tobacco. In the presence of nurse beads, protoplasts in the test beads grew at high frequency down to the lowest densities tested, namely 50 per ml for tobacco. With these methods transformed lucerne protoplasts from electroporation experiments and somatic hybrids have been recovered and plants regenerated with much greater efficiency that was hitherto possible.     

Plasmolysis of Pteridium protoplasts: A study using light and scanning-electron microscopy

A study was undertaken using gametophytes of the fern Pteridium aquilinum to examine the effects of plasmolysis on the topography of protoplasts. Methods are described whereby the surfaces of non-isolated protoplasts can be observed in the plasmolysed condition using scanning electron microscopy. Plasmolysed gametophytes were also examined in the light microscope using differential interference contrast and ultra-violet fluorescence microscopy after staining with fluorescein diacetate. With scanning electron microscopy, plasmolysed protoplast surfaces appeared smooth with no evidence of wrinkling or infolding of excess membrane. The formation of irregular-shaped protoplasts, protoplasmic threads, subprotoplasts, and protoplasmic networks covering internal wall surfaces all provided evidence for strong wall adhesion of the protoplasm. The availability of membrane for uptake into folds or vesicles is therefore thought to be minimal. Transmission electron microscopy showed some protoplasmic threads to be plasmodesmata, the remainder being cell-wall contact points. Remnants of these threads were occasionally observed on isolated protoplasts in both the light and electron microscopes.     

Comparison of cell wall regeneration on maize protoplasts isolated from leaf tissue and suspension cultured cells

Summary The cell wall regeneration on protoplasts derived from maize mesophyll cells was compared with wall regeneration on protoplasts derived from suspension cultured cells using light microscopy, transmission electron microscopy, and mass spectrometry. The time course of cell wall regeneration has shown that the mesophyll protoplasts regenerated walls much slower than the protoplasts derived from cultured cells. Moreover, cell wall materials on the mesophyll protoplasts were often unevenly distributed. Electron microscopy has further demonstrated that the mesophyll protoplasts have less organized and compact walls than the protoplasts from cultured cells. Chemical analysis revealed that the mesophyll protoplasts had a lower ratio ofβ-(1–3)-glucan toβ-(1–4)-glucan than protoplasts from cultured cells. The significance of these results for the viability and development of protoplasts in culture is discussed. National Research Council of Canada paper no. 32458.     

Ultrastructural properties of ciliary zonule microfibrils

Conventional electron microscopy and rotary shadowing techniques have provided conflicting interpretations of microfibril ultrastructure. To address this issue, we have used quick-freeze deep-etch (QFDE) microscopy to obtain 3-dimensional surface views of microfibrils that have not been fixed, dehydrated, or stained with heavy metals. By this approach, microfibrils appear as tightly packed rows of bead-like subunits that do not display the interbead filamentous links seen by other methods. At regular 50-nm intervals along the microfibril length, a larger bead is often recognized which tends to be aligned with those from adjacent microfibrils when the microfibrils are in bundles. This evidence of organized lateral associations of microfibrils is supported by the observation of small filaments that span between the adjacent microfibrils. When QFDE microscopy was used to examine microfibrils exposed to sonication, partially dissociated microfibrils with the more typical "beads on a string" appearance were observed. Beads are also seen alone, as monomers, often with an array of small thread-like filaments extending from the bead in a "crab-like" manner. Our results suggest that the beads on a string appearance of sonicated microfibrils may result from a partial loss of protein components from the interbead domains, thus leading to exposure of a filamentous substructure. It is possible, therefore, that this phenomenon might also contribute to the beads on a string appearance of microfibrils seen using other electron microscopy techniques.     

Immobilization of plant protoplasts: Viability studies

Protoplasts of Daucus carota Ca68 and Catharanthus roseus have been immobilized by entrapment in gelforming polysaccharides (kappa-carrageenan, agarose and alginate). Uniform spherical beads of carrageenan and agarose containing the protoplasts have been prepared by utilizing an inert hydrophobic phase (vegetable oil). The entrapped protoplasts are viable and stabilized towards osmotic shock by the polymeric backbone. Standard methods have been used to study the viability and integrity of the entrapped protoplasts. Upon incubation in a relatively simple medium the immobilized protoplasts show a much higher viability after 14 days as compared to free protoplasts under the same conditions. The viability of D. carota protoplasts has also been monitored by an enzyme activity present in the cells (digitoxigenin 58-hydroxylase).