Microtubule organization during the development of the mitotic apparatus in cultured mesophyll protoplasts of higher plants – an immunofluorescence microscopic study

Microtubule organization in the course of the interphase-mitosis transition, karyokinesis and cytokinesis in cultured mesophyll protoplasts of Medicago sativa L. cv. Regen S and Nicotiana tabacum L. cv. Wisconsin 38 was investigated during the early culture stages. A prominent circular band of microtubules, the prophase band of microtubules (PB) was seen in the cell cortex during prophase in most cells. The band appeared during very early prophase and disappeared during late prophase. Other prophase microtubule arrays were nuclear-envelope associated microtubule fluorescence (perinuclear fluorescence, PNF) and groups of microtubules radiating from the nuclear envelope into the cytoplasm. These radiating microtubutes (perinuclear radiating microtubules, PNR) were particularly long and prominent in the PB plane appearing to link the PNF with the PB network. The possible functions of the PNR are discussed. The role of the PB is discussed in the light of the unorganized nature of these cells.     

Differences in Protein Synthesis and Peroxidase isoenzymes between recalcitrant and regenerating ProtoPlasts

The reasons for the inability of recalcitrant mesophyll protoplasts to divide and re-enter the cell cycle are unknown. Changes in protein profile, indole-3-acetic acid (IAA)-oxidase and peroxidase activities, and isoenzymes were compared in protoplasts of recalcitrant grapcvine ( Vitis vinifera ) L. cv. Sultanina) and regenerating tobacco ( Nicotiana tabacum ) L. cv. Xanthi). Using [³⁵S]-methionine. SDS-PAGE and two-dimensional separation of proteins, differences in protein profile during protoplast culture were assessed. The changes in the de novo synthesized proteins were both qualitative and quantitative between the two species. The number of proteins which changed was double in tobacco compared to grapevine protoplasts. Peroxidase and IAA-oxidase activities increased significantly in tobacco protoplasts during culture whereas in grapevine they remained low. In tobacco protoplasts. 3 and 7 basic and acidic peroxidases, respectively, were induced during protoplast culture. which were not detected in the intact leaf, whereas in grapevine no new peroxidases were induced during protoplast culture.     

High yield isolation of mesophyll protoplasts from wheat, barley and rye

Efficient procedures are described for high-yield isolation of mesophyll protoplasts from spring wheat ( Triticum aestivum L. cv. Glenlea), winter wheat ( Triticum aestivum L. cv. Frederick), barley ( Hordeum vulgare L. cv. Bruce) and rye ( Secale cereale L. cv. Puma). Factors such as plant age, composition of the incubation medium during isolation, purification procedures and culture medium affect protoplast yield, viability and metabolic competence, as measured by light-dependent CO₂ fixation. Optimal osmolarity of the isolation medium was equivalent to 1.8 times that measured in the leaves of all plant material used. The presence of 2 m M ascorbic acid in the preincubation and isolation medium increased the yield by 50% and conserved viability and metabolic competence. The protoplasts were stable for up to 48 h without loss of either viability or of original activity of CO₂ fixation, which was in the order of 100 μmol CO₂ (mg chl)⁻¹h⁻¹.
In our MC-56 liquid medium these protoplasts regenerated cell walls within 72 h and a few divided.     

Studies on Plant Regeneration from Mesophyll Protoplasts of Solanum tuberosum L.

Protoplasts from potato mesophyll of two strains (Solannum tuberosum L. cv. Xiao Yie Zi x Duo Zi Bia and Solanum tuberosum L. cv. Wu Meng 601) were induced to callus in culture medium of protoplasts. The callus derived from mesophyll protoplasts were transferred to MS medium with 2 mg/l ZT+0.1 mg/L IAA. Shoots regenerated from the callus were detected after 70 days of culture.The shoots which had grown to a height of 2–3 cm were transferred to MS medium with 0.05 mg/L NAA. Roots were coming out in a few days.Complete plantlets were achieved. Stern segments with 1–2 leaves were then transferred to a mixture of sterilized soil and grown, and produced tuber.     

Multiple forms of phosphoenolpyruvate carboxylase in mesophyll, epidermal and guard cells of Vicia faba

The distribution of phosphoenolpyruvate carboxylase (PEPCase, EC 4.1.1.31) in different leaf‐cell‐types and tissues of Vicia faba L. cv. 3‐fach Weiße was studied. The highest specific PEPCase activity was found in guard cell protoplasts (16.3 µmol mg⁻¹ protein h⁻¹) whereas for epidermal and mesophyll protoplasts remarkably lower specific activities were found (1.6 and 1.0 µmol mg⁻¹ protein h⁻¹, respectively). On chlorophyll and protoplast basis, a similar distribution of enzyme activity was observed. Compared with epidermal extracts, the specific PEPCase activity of mesophyll tissue was 17‐fold lower. Immunological studies with polyclonal antibodies to PEPCase indicated 3 immunoreactive proteins in epidermal tissue and guard cell protoplasts with molecular masses of 107 000, 110 000, and 112 000. Only the M_r 107 000 protein was found in extracts of mesophyll and epidermis protoplasts. Western immunoblots after native electrophoresis of epidermal and mesophyll proteins showed a significant difference in PEPCase mobility. It is assumed, that the immunostained proteins of M_r 110 000 and 112 000 represent isoforms or subunits of the PEPCase and that they are involved in stomatal movements.     

Isolation and Regeneration of Tobacco Mesophyll Cell Protoplasts under Low Osmotic Conditions

A method is described for the isolation of large numbers of tobacco (Nicotiana tabacum L. cv. Xanthi-nc) mesophyll cell protoplasts under relatively low external osmotic conditions. The procedure utilized 0.2 m sucrose as the primary osmoticum and a mixture of 0.5% macerozyme, 4% cellulase, and 2% polyvinylpyrrolidone, pH 5.4. The viability of resultant protoplasts was confirmed through regeneration of fertile plants. Plating and regeneration studies revealed, however, that qualitative and quantitative modifications in plating and differentiation media were necessary for protoplasts prepared in this manner. Over-all, the procedure was found to be a simplified alternative to those previously described for tobacco protoplast regeneration. In addition, the system should permit studies related to the influence of differing osmoticum levels on a variety of cell functions.     

Effect of cellulase fractionation on the viability of cultured barley (Hordeum vulgare) protoplasts

The age of the stock plants was important for the barley ( Hordeum vulgare L. cv. Perth) protoplast viability. Light conditions under which the stock plants were grown also affected the viability of the protoplasts. Greenhouse-grown plants yielded much higher number of protoplasts than dark-grown plants, but protoplast viability was better when protoplasts were isolated from etiolated plants. Light supplied during protoplast culture affected protoplast viability within the first 24 h of culture. Cellulase R-10 (Onozuka) was better than Cellulysin (Calbiochem) and Cellulase ⁺ Macerozyme R-10 (Onozuka) for barley mesophyll protoplast isolation. Cellulase R-10 (Onozuka) was fractionated on a G-75 Sephadex column. The eluted fractions were tested for their ability to release barley mesophyll protoplasts and for their toxicity towards the protoplasts. Only a small part of the Cellulase R-10 was necessary for protoplast isolation from barley leaves. When the fractionated cellulase was analysed by isoelectric focusing, this part of the cellolase appeared as a single band.     

Mass electrofusion and mass selection of functional hybrids from vacuolate × evacuolate protoplasts

Vacuolate mesophyll protoplasts of Nicotiana tabacum L. (cv. Samsun) were electrically fused with evacuolate protoplasts of the same species. For this purpose a mass fusion chamber was constructed. Due to distinct differences in the specific density of the respective protoplast populations, interspecific hybrids could be separated from intraspecific ones as well as from unfused parental protoplasts on an isoosmotic density gradient. The interspecific hybrids appeared to be viable to about 60% as assayed by a bacterial test for photosynthetic oxygen evolution.     

A Revised Medium for Growth of Pea Mesophyll Protoplasts

The nutrient requirements of mesophyll protoplasts from Pisum sativum L. cv. Timo have been investigated and a synthetic and completely defined medium has been designed. A high calcium concentration (12 mM) stimulated both protoplast survival and cell division. The content of iron and zinc was also critical. Additions of nicotinic acid, pyridoxine and thiamine were necessary. The protoplast growth was enhanced when some amino acids were included in the medium. An absolute requirement for auxin and cytokinin was shown. In the revised medium about 90% of the isolated protoplasts survived and formed a cell wall. The first divisions were observed after 5 days and after 1 week 10–20% of the cells had divided at least once.     

Vacuolar localization of ethylene-induced chitinase in bean leaves

The localization of ethylene-induced endochitinase was studied in bean (Phaseolus vulgaris L. cv Saxa) leaves. The specific activity of chitinase in mesophyll protoplasts isolated from the leaves was as high as in tissue homogenates, indicating that most of the enzyme was located intracellularly. Vacuoles isolated and purified from the protoplasts were found to contain most of the intracellular chitinase activity.     

Phenotypic Variation and Changes of Chromosome Number in Plantlets Regenerated from Potato Protoplasts

Morphological variation and change of chromosome number in the plantlets of potato (Solanum tuberosum L. cv. Xiao Yie Zi × Duo Zi Bai) regenerated from mesophyll protoplasts have been studied. The normal plantlets from protoplasts were similar to parent plants. Their chromosome numbers were 2n = 48±or 2n= 72 of euploid. The plantlets with distinctive phenotypic variation were likely to be aneuploid with increased chromosome numbers.     

Effects of apoplastic sucrose on carbohydrate pools and sucrose efflux of mesophyll protoplasts of pea (Pisum sativum)

The effects of the apoplastic, i.e. external, concentration of sucrose (0–30 m M ) on O₂ evolution, O₂ consumption, starch, sucrose, glucose and fructose content, and uptake and efflux of sucrose in mesophyll protoplasts of Pisum sativum L. cv. Fenomen were studied. Neither photosynthesis, dark respiration, sucrose nor starch content change with increased apoplastic sucrose concentration. The contents of glucose and fructose in the protoplasts increase with increased apoplastic sucrose concentration. The sucrose efflux increases with increased external sucrose concentrations between 1 and 5 m M , but above this range the efflux decreases with increased external sucrose concentrations. These findings indicate that although external sucrose does not enter the protoplasts, there is a relationship between the external sucrose pool and the internal pools of sugars in the mesophyll protoplasts. The results suggest an active sucrose efflux from the protoplasts at physiological concentrations of apoplastic sucrose (max 5 m M ) and a simple diffusion mechanism at higher concentrations.     

Synthesis and localization of pathogenesis-related proteins in tobacco.

The PR1 family of pathogenesis-related proteins from tobacco (Nicotiana tabacum L.) leaves is induced by a variety of pathogenic and chemical agents and is associated with resistance to tobacco mosaic virus. The majority of the PR1 proteins did not copurify with mesophyll protoplasts (the major cell type of the leaf) isolated from tobacco mosaic virus-infected N. tabacum cv. Xanthi-nc leaves. However, these isolated protoplasts were capable of synthesizing and selectively secreting the PR1 proteins. Using monoclonal antibodies for immunofluorescence microscopy, we localized these proteins to the extracellular spaces predominantly in regions adjacent to viral lesions as well as in xylem elements of infected leaves.     

Abscisic acid synthesis and metabolism in barley leaves and protoplasts

Protoplasts isolated from barley (Hordeum vulgare L. cv. Clipper) leaves contained abscisic acid (ABA). The ABA content of these protoplasts did not change when they were incubated for up to 6 h in media of decreasing osmotic potential. There was a substantial, but transient, increase in ABA in barley leaf segments during protoplast isolation. The magnitude of this increase was inversely dependent on the osmotic potential of the isolation medium. Maximum ABA content was recorded after 2 h of exposure to the sorbitol-containing medium. The subsequent decline was due to conversion of ABA to phaseic acid (PA) and to other metabolites.Barley mesophyll protoplasts were not able to metabolise ABA, PA or any of the other metabolites formed from ABA by intact leaf tissue.     

Changes in the density of microtubular networks in mesophyll cells and mesophyll derived protoplasts of Nicotiana and Triticum during leaf development

Changes in the density of microtubular mesh-works were analysed in mesophyll cells and mesophyll derived protoplasts of Nicotiana tabacum L. and Triticum aestivum L. during leaf development. The main purpose of this study was to test whether the low density, if not lack, of microtubular networks recently described in protoplasts that had been isolated from fully differentiated mesophyll cells happened during protoplast isolation or whether the loss of microtubules actually occurred during differentiation of the leaf tissue. Immunofluorescence microscopy showed that the density of the microtubular cytoskeleton in the leaf tissue decreased steadily after cessation of cell growth in both species. Nevertheless, in Triticum microtubule disappearance was swifter and occurred along a gradient from the base to tip of the leaf, a phenomenon reflecting the differences in the ontogeny between the dicotyledonous Nicotiana and the mono-cotyledonous Triticum leaves. Protein extraction from leaf tissues and Western blot analysis indicated that in both species the disappearance of microtubules was the result of a degradation of tubulin and not only due to a depolymerisation into tubulin subunits. When the cell walls were removed from live cells and the protoplasts released, the original patterns of the microtubules became obscured and, particularly in differentiated cells, the integrity and density of the microtubule strands deteriorated. The potential application of the density of the microtubular cytoskeleton as a marker in studies on differentiation and dedifferentiation in mesophyll cells and protoplasts is discussed.We wish to thank Silke Heichel for excellent technical assistance. We also express our thanks to the group of A.M. Lambert at CNRS, Strasbourg, France, for advice during establishment of our Western blot system. The work was supported by a grant of the German Ministry of Science and Technology (BMFT).     

Sterols and sterylglycosides of oats (Avena sativa). Distribution in the leaf tissue and medium-induced glycosylation of sterols during protoplast isolation

Sterols, sterylglycosides (SG), acylated sterylglycosides (ASG) and steroidal saponins of primary leaves of oat ( Avena sativa L. cv. Flämingskrone) were analyzed by thin-layer chromatography, gas-liquid chromatography and high-performance liquid chromatography. Intact leaves, epidermis preparations, epidermis-stripped leaves, isolated protoplasts and chloroplasts were compared. The mesophyll contained 79% of the total leaf sterols, 80% of the SG and 78% of the ASG, but only 33–67% of the saponins. Free sterols, SG and ASG were mainly localized within the mesophyll, whereas steroidal saponins were localized in the epidermis to a significantly higher extent. The sterol parts consisted mainly of sitosterol, stigmasterol. cholesterol. Δ⁵-avenasterol, Δ⁷-avenasterol, campesterol and Δ⁷-cholestenol, and were quantitatively different in different sterol groups. A higher percentage of sitosterol at the expense of stigmasterol was typical for SG and ASG as compared to free sterols. Only minor differences in the sterol composition were found in a given sterol group when isolated from different tissues. Isolated protoplasts contained only 5–9% of the sterols present in mesophyll cells, indicating that the major part of the free sterols was lost during isolation. Exposure of radioactively labelled leaf segments to either buffer or digestion medium induced rapid transformation of sterols to SG and ASG as shown by the shift of radioactivity from free sterols to the glyeosides. This suggests that two sterol pools exist in the cell: one in the plasmalemma, which is accessible to medium-induced transformation, and a second non-accessible pool in the interior membranes (e.g. chloroplasts) of the cell.     

Differences in oxidative stress, antioxidant systems, and microscopic analysis between regenerating callus-derived protoplasts and recalcitrant leaf mesophyll-derived protoplasts of Citrus reticulata Blanco

It is known that protoplasts derived from either leaves or suspension cultures of a citrus genotype vary greatly in their regeneration capacities; however, the underlying physiological mechanisms are not well known. In this study, oxidative stress and antioxidant systems during in vitro culture of callus-derived protoplasts and leaf mesophyll-derived protoplasts of Ponkan (Citrus reticulata Blanco) were analyzed to gain insights into observed physiological differences. Morphological observations using light microscopy and scanning microscopy have shown that new cell wall materials appeared within 2–3 days, and the integrate cell walls were regenerated approximately after 6 days of culture of the callus protoplasts, whereas no cell wall formation was observed in the mesophyll protoplasts after culture. During the culture, higher levels of H₂O₂ and malondialdehyde were detected in the mesophyll protoplasts as compared with the callus ones. On the contrary, the callus protoplasts possessed higher activities of antioxidant enzymes (SOD, POD and CAT) and larger amount of glutathione and ascorbic acid (at one time point) than the mesophyll protoplasts during the culture process. The current data indicate that the mesophyll and callus protoplasts displayed remarkable difference in the degree of oxidative stress and the antioxidant systems, suggesting that high levels of antioxidant activities might play an important role in the regeneration of protoplasts.     

Catalase Is Differentially Expressed in Dividing and Nondividing Protoplasts

Based on our previous results that peroxidase is induced in dividing tobacco protoplasts but it is not expressed in the nondividing grapevine (Vitis vinifera L.) protoplasts during culture (C.I. Siminis, A.K. Kanellis, K.A. Roubelakis-Angelakis [1993] Physiol Plant 87: 263-270), we further tested the hypothesis that oxidative stress may be implicated in the recalcitrance of plant protoplasts. The expression of catalase, a major defense enzyme against cell oxidation, was studied during isolation and culture of mesophyll protoplasts from the recalcitrant grapevine and regenerating tobacco (Nicotiana tabacum L.). Incubation of tobacco leaf strips with cell wall-degrading enzymes resulted in a burst of catalase activity and an increase in its immunoreactive protein; in contrast, no such increases were found in grapevine. The cathodic and anodic catalase isoforms consisted exclusively of subunits [alpha] and [beta], respectively, in tobacco, and of subunits [beta] and [alpha], respectively, in grapevine. The catalase specific activity increased only in grapevine protoplasts during culture. The ratio of the enzymatic activities to the catalase immunoreactive protein declined in dividing tobacco protoplasts and remained fairly constant in nondividing tobacco and grapevine protoplasts during culture. Also, in dividing tobacco protoplasts the de novo accumulation of the catalase [beta] subunit gave rise to the acidic isoenzymes, whereas in nondividing tobacco and grapevine protoplasts, after 8 d in culture, only the basic isoenzymes remained due to de novo accumulation of the [alpha] subunit. The pattern of catalase expression in proliferating tobacco leaf cells during callogenesis was similar to that in dividing protoplasts. The different responses of catalase expression in dividing and nondividing tobacco and grapevine mesophyll protoplasts may indicate a specificity of catalase related to induction of totipotency.     

The hydraulic conductivity as a criterion for the membrane integrity of protoplasts fused by an electric field pulse

The hydraulic conductivity of the membrane, Lp, of fused plant protoplasts was measured and compared to that for unfused cells, in order to identify possible changes in membrane properties resulting from the fusion process. Fusion was achieved by an electric field pulse which induced breakdown in the membranes of protoplasts in close contact. Close membrane contact was established by dielectrophoresis. In some experiments pronase was added during field application; pronase stabilizes protoplasts against high field pulses and long exposure times to the field. The Lp-values were obtained from the shrinking and swelling kinetics in response to osmotic stress. The Lp-values of fused mesophyll cell protoplasts of Avena sativa L. and of mesophyll and guard cell protoplasts of Vicia faba L. were found to be 1.9±0.9·10^-6, 3.2±2.2·10^-6, and 0.8±0.7·10^-6 cm·bar^-1·s^-1, respectively. Within the limits of error, no changes in the Lp-values of fused protoplasts could be detected in comparison to unfused protoplasts. The Lp-values are in the range of those reported for walled cells of higher plants, as revealed by the pressure probe.Abbreviations GCP guard cell protoplast - Lp hydraulic conductivity - MCP mesophyll cell protoplast     

The isolation, culture and regeneration of Petunia leaf protoplasts

Methods are described for the enzymatic release of protoplasts from leaves of Petunia hybrida and for the utilization of protoplasts in studies in plant developmental biology. As a result of spontaneous fusion during cell wall degradation of leaf material, fresh preparations can contain a high proportion of multinucleate protoplasts. This level can be dramatically reduced by a gradual plasmolysis of the material prior to enzyme incubation.Leaf protoplasts maintained in liquid media are seen to undergo cell wall synthesis, “budding,” and limited regenerated cell division sometimes associated with anthocyanin production. Under such conditions, multinucleate cells are formed as a result of mitosis without cytokinesis.Protoplasts, plated out in a fully defined medium, undergo cell wall synthesis followed by sustained progeny cell division with eventual cell colony production. Cell colonies, derived from individual mesophyll protoplasts, grow rapidly upon subculture, to produce callus capable of shoot differentiation and ultimately whole plant formation. Protoplasts isolated from varieties of P. hybrida were found to differ in their cultural requirements.