A New Method for Embryo Sac Isolation and In Situ Fusion of Egg and Synergid Protoplasts in Nicotiana tabacurn

A new method combining enzymatic maceration with osmotic shock was developed for isolation of living embryo sac and its protoplasts in Nicotiana tabacum L. The principle of this method was that the ovules submitted to enzymatic treatment and osmotic shock could release embryo sacs along with some internal ovular cells through either the funicle cut end or the micropyle. Factors affecting embryo sac isolation were investigated, including concentration of mannitol as a shock osmoticum and in enzymesolution ,duration of enzymatic maceration,and duration of osmotic shock. As a result a procedure was established: Ovules at mature embryo sac stage were macerated for 2. S h in 1 %–1.5% cellulase R-10 and 0. 5% macerozyme R-10 (or 1% Pectinase,Serva) dissolved in 13% mannitol solution using microshaker,followed by osmotic shock for 15–30 min with enzyme free 8% mannitol solution and gentle agitation using a pipette. Using a capillary,50–70 embryo sacs could be collected manually in one hour. The embryo sacs thus isolated could be kept viable from which protoplasts of egg cell and other componcnt cells could be further isolated. An additional interesting phenomenon was that osmotic shock often caused in situ fusion the protoplasts of egg cell and synergids. The rate of fusion ranging 9%—71.9% could be controlled by modification of the procedure. This phenomenon merits further attention both from basic and practical point of view. The present method gives the advantages of faciliting isolation and promoting good harvest of viable embryo sacs/female protoplasts within a relative short time.     

Extensor and flexor protoplasts from samanea pulvini : I. Isolation and initial characterization

Protoplasts were isolated from extensor and flexor regions of open pulvini of the nyctinastic tree Samanea saman. Both types of protoplasts undergo many changes during isolation. Extensor protoplasts are univacuolate in vivo, but some become multivacuolate. All flexor protoplasts are univacuolate. In an open pulvinus, extensor cells have a higher osmotic pressure than flexor cells. However, both types of protoplasts can be isolated with optimal yield using the same osmoticum (0.5 molar sorbitol) in the digestion medium. This suggests that some leakage of osmoticum occurs during harvest or digestion, especially from extensor tissue. Despite these changes, both types of protoplasts extrude protons in response to 10 micromolar fusicoccin (1.6-1.8 nanoequivalent/10⁶ protoplasts/minute), demonstrating that the protoplasts are metabolically active and that proton transport mechanisms must be at least partially functional. The changes in vacuolar structure and osmotic pressure are what one might expect if the protoplasts, which are isolated from open pulvini, take on characteristics of cells in a closed pulvinus.     

Observations on the time course of wall development at the surface of isolated protoplasts

The formation of cell wall fibres at the surface of isolated leaf protoplasts has been studied by scanning electron microscopy. Fibres are not formed on incubated protoplasts until a lag period has elapsed. This period is about 8 h for leaf protoplasts of Nicotiana tabacum and about 45 h for leaf protoplasts of Antirrhinum majus. In the case of Antirrhinum protoplasts the length of the lag period is dependent on the concentration of osmoticum present during the incubation period. If regenerating protoplasts are briefly treated with dilute cellulase, the newly formed wall is completely digested. Such protoplasts are capable of producing new fibres at the surface within minutes of their return to a nutrient medium. These results are discussed in terms of the likely source of the lag period and its significance in wall regeneration studies.Abbreviations MS culture medium used at full strength - 0.1 MS culture medium used at one tenth full strength     

Extensor and Flexor Protoplasts from Samanea Pulvini : II. X-Ray Analysis of Potassium, Chlorine, Sulfur, Phosphorus, and Calcium

Concentrations of K, Cl, P, S, and Ca in extensor and flexor protoplasts from open pulvini of the nyctinastic tree Samanea saman were estimated using x-ray microanalysis. This technique is particularly suitable when absolute numbers of protoplasts are low, because less than 100 protoplasts are required to obtain statistically significant data. Flexor protoplasts contain similar concentrations of P and S but almost twice as much K and Cl as extensor protoplasts. Low levels of total measurable osmoticum suggest that extensive leakage has occurred during protoplast isolation. Both extensor and flexor protoplasts appear to contain some unidentified osmoticum not detectable by x-ray analysis. Extensor protoplasts must have more unidentified osmoticum to compensate for their lower levels of K and Cl.     

Enzymatic isolation of viable nucelli at the megaspore mother cell stage and in developing embryo sacs in Nicotiana tabacum

Summary Nucelli and developing embryo sacs were enzymatically isolated from ovules of Nicotiana tabacum. Megaspore mother cells, tetrads, uninucleate, binucleate, four-nucleate, eight-nucleate and mature embryo sacs were obtained. The isolated embryo sacs were intact and living, and maintained their original shape and organization. Cytoplasmic streaming was clearly observed. Prolonged incubation of ovules or reincubation of isolated embryo sacs in the maceration mixture resulted in the liberation of the gametophytic cells as individual, living protoplasts.     

Freeze-thaw injury to isolated spinach protoplasts and its simulation at above freezing temperatures

Possibilities to account for the mechanism of freeze-thaw injury to isolated protoplasts of Spinacia oleracea L. cv. Winter Bloomsdale were investigated. A freeze-thaw cycle to −3.9 C resulted in 80% lysis of the protoplasts. At −3.9 C, protoplasts are exposed to the equivalent of a 2.1 osmolal solution. Isolated protoplasts behave as ideal osmometers in the range of concentrations tested (0.35 to 2.75 osmolal), arguing against a minimum critical volume as a mechanism of injury. Average protoplast volume after a freeze-thaw cycle was not greatly different than the volume before freezing, arguing against an irreversible influx of solutes while frozen. A wide variety of sugars and sugar alcohols, none of which was freely permeant, were capable of protecting against injury which occurred when protoplasts were frozen in salt solutions. The extent of injury was also dependent upon the type of monovalent ions present, with Li = Na > K = Rb = Cs and Cl ≥ Br > I, in order of decreasing protoplast survival. Osmotic conditions encountered during a freeze-thaw cycle were established at room temperature by exposing protoplasts to high salt concentrations and then diluting the osmoticum. Injury occurred only after dilution of the osmoticum and was correlated with the expansion of the plasma membrane. Injury observed in frozen-thawed protoplasts was correlated with the increase in surface area the plasma membrane should have undergone during thawing, supporting the contention that contraction of the plasma membrane during freezing and its expansion during thawing are two interacting lesions which cause protoplast lysis during a freezethaw cycle.     

Isolation and preservation of the living embryo sac ofCrinum asiaticum L. var.japonicum baker

The enzymatic maceration method was used to isolate an intact embryo sac ofCrinum asiaticum and its component cells. Best results were obtained when using enzyme solutions that contained pectinase hemicellulase, cellulase and pectolyase. Aseptic ovules were incubated in the enzyme solution for 1.5 hr at 25 C. This allowed the isolation of embryo sacs to yield up to 20% of the amount present. An isolated embryo sac usually consists of an egg cell, synergids, antipodals and a central cell. Some embryo sacs can be digested as gametophytic protoplast. The size, shape and position of the isolated embryo sac seemingly possessed similarities with those of the fixed embryo sac in the ovary. An isolated embryo sac can be in a living state when the result of the fluorochromatic reaction (FCR) and protoplasmic streaming is positive. When cultured in proper media, 68% of the isolated gametophytic protoplasts were observed to have sustained their positive FCR for more than 1 month.     

Colony formation and plant regeneration from mesophyll protoplasts of Solanum etuberosum

A procedure for the culture of Solanum etuberosum mesophyll protoplasts with subsequent shoot regeneration is described. Several factors affected protoplast yield, colony formation, and shoot regeneration from in vitro plants. A protoplast isolation medium with 0.6 M sucrose produced twice the yield as one with 0.3 M sucrose. uowever, a higher concentration of osmoticum was inhibitory to colony development unless it was diluted into a lower osmoticum medium in a bilayer system. A 16 hour light/8 hour dark photoperiod for stock plants allowed twice the protoplast yield compared to plants grown under continuous light but no effect was found on subsequent colony formation or shoot regeneration. The concentrations of four major salts in the protoplast plating medium were critical for a high frequency of colony formation from protoplasts. Levels of 0.25 × or 1 × were considerably better than 4 ×. Fast colony formation, but at a lower efficiency, was obtained with a monolayer plating method. A bilayer plating system allowed a higher efficiency but colonies developed more slowly. For the best treatments, the frequency of colony formation from protoplasts ranged from 2.4 to 3.6 × 10^-3 with 37% to 66% of the colonies producing shoots ten weeks after protoplast isolation.Cooperative investigation of the USDA-ARS and the Wisconsin Agric. Exp. Stn.     

Efficient plantlet regeneration from protoplasts isolated from suspension cultures of poplar (Populus alba L.)

We developed an efficient plant regeneration system from protoplasts for poplar (Populus alba L.). Protoplasts were isolated from 4-day-old suspension cultures derived from seed-induced calli with a yield of 6.96× 10⁶ cells/g fresh weight cells and then cultured at a concentration of 2.5×10⁵ cells/ml in NH₄NO₃-free Murashige and Skoog (MS) medium supplemented with 5 μM 2,4-dichlorophenoxyacetic acid (2,4-D), 0.05 μM thidiazuron (TDZ) and 0.5 M glucose as a osmoticum. The plating efficiency of the cultured protoplasts was calculated at 26.5% at day 7 and 31.7% at day 14. Cell colonies were observed after culturing for 4 weeks. Regenerated colonies were propagated through subculture in liquid MS medium supplemented with 5 μM 2,4-D. Buds were induced from regenerated calli on MS medium containing 10 μM kinetin or 1 μM TDZ. Regenerated shoots were rooted on half-strength MS medium, and the plantlets were transplanted in soil. Randomly amplified polymorphic DNA analysis did not detect any DNA polymorphism among the regenerated plants. Received: 7 March 1997 / Revision received: 16 June 1997 / Accepted: 5 July 1997     

Changes in osmotic pressure and structure at the initial stages of zygote formation inClosterium ehrenbergii

Summary The behavior of gamete cells ofClosterium ehrenbergii in hypertonic solutions was observed and the significance of changes in osmotic pressure of the protoplasts is discussed in relation to zygote formation. The osmotic pressure of fusing gamete protoplasts was calculated to be 0.063 Osm at the original cell volume. The osmotic pressure of immature gamete protoplasts was 0.24 Osm at incipient plasmolysis. This lowering of cell osmotic pressure may serve to protect the rupture of the plasma membrane during migration of protoplasts in the conjugation tube after dissolution of cell walls. During maturation of gamete cells, chloroplasts and dictyosomes differed greatly in their ultrastructure from those of vegetative cells. These structural changes may be induced by changes of the physiological condition including osmotic pressure in the cells.     

Sensitivity to Abscisic Acid and Osmoticum Changes During Embryogenesis of Alfalfa (Medicago sativa)

Developing embryos of alfalfa can be placed into nine stagesof development according to their morphological characteristics.The intact seeds do not germinate when removed from the podand placed on water until at least stage VI, and complete germinabilityis not achieved until the seeds are at the stage when they startto undergo maturation desiccation. Isolated embryos are germinableas early as stage III, and will germinate within 24 h on Murashigeand Skoog medium containing 3% sucrose. Osmoticum can inhibitembryo germination, but only proper osmotic conditions can maintaindevelopment in vitro; development does not occur at germination-inhibitingconcentrations of abscisic acid. The sensitivity to abscisicacid and osmoticum changes with stage of development. Early-stageembryos have the highest abscisic acid sensitivity and thisdeclines to the extent that mature dry embryos require a highconcentration (1?0 mol m^–3) to prevent their germination.Sensitivity of the embryos to osmoticum is maximum at stageVII of development. The combined inhibitory effect of abscisicacid and osmoticum on germination during development is greaterthan their individual effects. This combined effect is stage-dependent.Thus studies on the effects of abscisic acid and osmoticum onembryogenesis and associated synthetic events should be expectedto vary according to the sensitivity to these agents at differentstages of development. Key words: Medicago sativa, embryogenesis, abscisic acid, osmoticum, seed development     

Enzymatic isolation of living embryo sacs of Petunia

Summary A 20%–25% yield of isolated and living embryo sacs of Petunia hybrida L. was obtained using an enzymatic maceration mixture containing 3% driselase (soluble fraction only), 0.1% MES buffer, pH 5.5, and 8% mannitol. For each maceration ± 450 ovules were incubated in 1 ml enzyme solution for 2 h at 30° C in a shaking waterbath (150 rpm). Subsequently, the enzyme solution was replaced by Brewbaker and Kwack's medium, pH 6.5, supplemented with 10% mannitol (BKM). Gentle agitation of the suspension resulted in the liberation of embryo sacs, which were then collected with a micropipette using a dissecting microscope and transferred to fresh BKM. The embryo sacs isolated are intact and living, and have maintained their original shape and organization When stored in BKM at room temperature the isolated embryo sacs remain alive for 8 h. Storage at 4° C results in a prolongation of viability of up to 80 h. Prolonged incubation of ovules or reincubation of isolated embryo sacs in the maceration mixture results in the liberation of the gametophytic cells as individual, living protoplasts.     

Plant regeneration via somatic embryogenesis, and transient gene expression in sweet potato protoplasts

A method for regenerating plants from petiole protoplasts of the in vitro-raised sweet potato cultivar Jewel is described. Protoplast yields of 3.0–5.0×10⁶ were obtained following 4–6 h digestion of 1- to 2-cm petioles (1 g fresh weight) with 1% Cellulase-R10, 2% Macerozyme-R10, and 0.3% Pectolyase Y-23 in a washing solution with 9% mannitol. A plating density of 10⁵ protoplasts/ml was optimal for subsequent division. An initial division frequency of 12–15% was obtained in liquid or agarose-solidified KP8 culture medium supplemented with 2,4-dichlorophenoxyacetic acid (2,4-D) (0.9 μm), and zeatin (2.3 μm). Colonies consisting of 100–200 cells were formed after 4 weeks in the dark at 24±2°C. The frequency of colony formation was improved by the gradual addition of fresh liquid KP8 medium of lower osmoticum. Protocalli (1–2 mm in diameter) were formed after an additional 4–6 weeks under continuous illumination and regular dilution with fresh culture medium. Morphogenic callus formed globular and heart-shaped embryos that developed into cotyledon stage embryos, following transfer of calli onto medium containing 2,4-D (11.3 μm) and benzylaminopurine (2.2 μm). Subsequently, embryo conversion to plantlets was obtained on basal medium with 2% sucrose and 3.5 μm gibberellic acid. Regenerated plantlets were successfully transplanted in soil. Mature plants appeared phenotypically normal. The same petiole protoplast populations showed transient expression of the gusA gene introduced using electroporation. Received: 10 October 1997 / Revision received: 10 February 1998 / Accepted: 2 March 1998     

A simple method for the isolation of plant protoplasts

A simple protoplast isolation protocol that was designed to recover totipotent plant protoplasts with relative ease has been described. The key elements of the protocol are, tissue digestion at slightly elevated temperatures and use of protoplast-releasing enzymes that are stable and efficient at higher temperatures. Besides enzymes, the protoplast isolation cocktail consisted of an osmoticum (mannitol or MgSO₄), and a protectant (CaCl₂ 2H₂O), all dissolved in distilled water. The protocol has ensured reproducibility, higher yields and is gentle on protoplasts as the protoplasts obtained were amenable to cell wall regeneration and cell division. Plant regeneration was demonstrated forNicotiana tabacum cv. Thompson from protoplasts isolated by this method. Wall regeneration and cell division were obtained in other species. The merits of the protocol are, simple and easy-to-handle procedure, non-requirement of preconditioning of donor plant and explants, incubation without agitation, satisfactory yields, culturability of the protoplasts isolated and applicability of the protocol to a large number of species including mucilage-containing plants.     

Differential induction of enzyme in soybean cell cultures by elicitor or osmotic stress

Soybean cell cultures were challenged either by glucan elicitor from Phytophthora megasperma f.sp. glycinea or by osmotic stress (0.4 M glucose). Osmotic stress induced production of a microsomal NADPH-dependent flavone synthase (flavone synthase II) which catalyses conversion of (2S)-naringenin to apigenin. In one of our cell-lines this enzyme activity was not detected either in unchallenged cells or in cells treated with glucan elicitor. Inducibility of flavone synthase II by 0.4 M glucose was highest at the end of the linear growth phase. Changes in the activities of a number of other enzymes were determined after treatment of the cells with elicitor or 0.4 M glucose. The activities of phenylalanine ammonialyase, cinnamate 4-hydroxylase, chalcone synthase and dihydroxypterocarpan 6a-hydroxylase all increased with elicitor and with osmoticum, albeit to a different degree. The rise in enzyme activity occurred later with osmoticum than with elicitor. The prenyltransferase involved in glyceollin synthesis was induced strongly by elicitor but only very weakly by osmoticum, whereas isoflavone synthase and NADPH: cytochrome-c reductase were only induced by elicitor. The activity of glucose-6-phosphate dehydrogenase did not change with elicitor or with osmoticum. Different product patterns were also obtained: whereas with elicitor, glyceollin I was the major product, intermediates of the glyceollin pathway (7,4-dihydroxyflavanone, trihydroxypterocarpan) accumulated with osmoticum.     

Response to chilling of tomato mesophyll protoplasts

Freshly isolated protoplasts from tomato leaves show two completely different responses to a chilling treatment of 12 h at 7° C prior to culture at 29° C, depending on the presence or absence of glucose in the medium. In the culture medium with glucose as osmoticum, where the rate of cell divisions under optimal culture conditions is relatively high (about 20% plating efficiency), protoplasts were drastically injured by the chilling procedure and died. In the medium with mannitol as the osmoticum instead of glucose, where the plating efficiency even under optimal conditions is rather low (about 8%), protoplasts withstand the chilling procedure. More-over, after the chilling treatment when the protoplasts were transferred to the optimal culture temperature of 29° C, the plating efficiency was raised to about 20%, which is the same level as in the glucose-containing medium without chilling. This effect was not observed when the medium in which the protoplasts were suspended during the chilling period was replaced with fresh medium. This suggests that under these conditions tomato protoplasts produce and excrete a factor in the cold that improves the vitality of the cells or stimulates cell division. The possible relationship between chilling sensitivity of tomato protoplasts and their ability to divide will be discussed.     

Mesophyll cell protoplasts of potato: isolation, proliferation, and plant regeneration

Mesophyll cell protoplasts were isolated from potato (Solanum tuberosum L. cv. Russet Burbank) leaves and induced to proliferate in culture. Protoplast division was observed only among preparations isolated from plants previously conditioned under short periods of low intensity illumination. Sustained growth and development of protoplast-derived calli (p-calli) occurred when they were maintained on defined media at 24 C under 500 lux lighting. Shoot bud development within p-calli was controlled by a number of factors including light, temperature, basic medium composition, nature and source of phytohormones, the continued presence of an osmoticum, low concentrations of a utilizable carbohydrate, and the developmental stage of the p-callus.     

Cytoplasm-specific Effects of Helminthosporium maydis Race T Toxin on Survival of Corn Mesophyll Protoplasts

High yields of mesophyll protoplasts were obtained from leaves of corn (Zea mays L., inbred W64A). Many protoplasts survived a week in the dark in a simple osmoticum. Culture filtrate from Helminthosporium maydis race T at dilutions of 1:10,000 to 1:20,000 destroyed protoplasts with Texas male-sterile (T) cytoplasm. Substantial damage to protoplasts with nonmale-sterile (N) cytoplasm occurred only at a 1:20 dilution. High concentrations of partially purified H. maydis race T (HMT) toxin (32.5-130 μg dry weight/ml) did not reduce survival of protoplasts with N cytoplasm or C or S male-sterile cytoplasms after 6 days of exposure. Protoplasts with T or TRf (fertility restored) cytoplasm collapsed within 1 to 3 days after treatment with 0.13 μg of HMT toxin/ml, which was one-fifth the level causing 50% inhibition of T cytoplasm seedling root growth. Protoplasts with T cytoplasm which were washed after 30 minutes or more of exposure to HMT toxin also collapsed within a few days. Cultured W64A T protoplasts and freshly isolated protoplasts from inbreds C103 and Mo17 with T cytoplasm were less sensitive to HMT toxin than freshly isolated W64A T protoplasts. Toxin-treated protoplasts survived longer in the light than in the dark. The sensitivity and specificity of the system described will facilitate physiological, ultrastructural, and genetic studies of toxin action.     

Polyethylene glycol and maltose enhance somatic embryo maturation in loblolly pine (Pinus taeda L.)

Summary A culture medium that can efficiently produce mature somatic embryos was developed for loblolly pine (Pinus taeda L.). The medium contained maltose as a carbohydrate source and polyethylene glycol as an osmoticum. This medium formulation significantly enhanced embryo maturation efficiency compared to a medium with only maltose, or with sucrose combined with polyethylene glycol. Maltose at 4% and polyethylene glycol at 6% resulted in the highest embryo maturation efficiency; an average of around 100 cotyledonary embryos were produced from 1 g of embryogenic tissue. These results suggested that previous ineffective embryo maturation in loblolly pine may be due to the lack of the proper combination of osmoticum and carbohydrate source. This embryo maturation method also improved morphology of cotyledonary embryos of loblolly pine.     

Apoplasmic and Protoplasmic Water Transport through the Parenchyma of the Potato Storage Organ

Stationary volume fluxes through living and denatured parenchyma slices of the potato (Solanum tuberosum L.) storage organ were studied to estimate the hydraulic conductivity of the cell wall and to evaluate the significance of water transport through protoplasts, cell walls, and intercellular spaces. Slices were placed between liquid compartments, steady-state fluxes induced by pressure or concentration gradients of low- and high-molecular-mass osmotica were measured, and water transport pathways were distinguished on the basis of their difference in limiting pore size. The protoplasts were the dominating route for osmotically driven water transport through living slices, even in the case of a polymer osmoticum that is excluded from cell walls. The specific hydraulic conductivity of the cell wall matrix is too small to allow a significant contribution of the narrow cell wall bypass to water flow through the living tissue. This conclusion is based on (a) ultrafilter coefficients of denatured parenchyma slices, (b) the absence of a significant difference between ultrafilter coefficients of the living tissue slices for osmotica with low and high cell wall reflection coefficients, and (c) the absence of a significant interaction (solvent drag) between apoplasmic permeation of mannitol and the water flux caused by a concentration difference of excluded polyethylene glycol. Liquid-filled intercellular spaces were the dominating pathways for pressure-driven volume fluxes through the parenchyma tissue.