Changes in fatty acid and lipid content in callus and protoplasts of Parthenocissus tricuspidata and Petunia hybrida during culture

Protoplasts isolated from callus cells of Petunia hybrida L. and Parthenocissus tricuspidata L. crown gall were used in order to correlate the fatty acid and lipid contents and composition during culture with the ability or unability of the cells to divide. Freshly isolated protoplasts were characterized by a decrease in fatty acids, galactoli-pids and phospholipids, an increased saturation of the fatty acids of the phospholipids and higher weight percentages of neutral lipids and phosphatidic acid. During culture, fatty acids and phospholipid increased in dividing protoplast of Petunia but not in non-dividing protoplasts of Parthenocissus. The findings may imply a two-stage response to isolation stresses: the first step being lipid degradation and the second lipid biosynthesis.     

Comparative study of RNA metabolism in freshly isolated protoplasts and callus cultures of Parthenocissus tricuspidata crown gall

RNA metabolism was compared in protoplasts and cells of Parthenocissus tricuspidata crown gall callus. A rapid increase in the permeability to precursors during the first three hours following the termination of protoplast isolation was observed. Consequently, RNA synthesis occurred at a higher rate in protoplasts than in whole cells. On the other hand, protoplasts and callus tissues showed similar kinetics of incorporation of precursors into mature rRNA's. Pulse-chase experiments showed the maturation rate to be nearly the same in both cases.     

Induction of efficient cell division in alfalfa protoplasts

Alfalfa (Medicago sativa L.) protoplasts derived from cell suspension cultures divided inefficiently in liquid culture. The onset of cell division activity occurred synchronously among the protoplasts; however, many were blocked at cytokinesis and therefore did not complete first division. Very few of the cells that began to divide continued to do so. Immobilization of protoplasts in agarose after 1 to 4 days in liquid culture overcame this inhibition of division. Continuous growth in agarose was restricted and therefore microcolonies were transferred to agar medium to complete callus development. Plating efficiencies of 2–10% were achieved within 30 days of protoplast isolation. The agarose treatment was responsible for a 5- to 30-fold improvement in plating efficiency.Contribution No. 774 Ottawa Research Station     

Soybean protoplast culture and direct gene uptake and expression by cultured soybean protoplasts

A method was developed for culturing protoplasts freshly isolated from developing soybean (Glycine max L.) cotyledons. First cell divisions were observed within 5 days after protoplast isolation and microcalli, consisting of about 20 cells, were formed within 10 days. Thirty days after protoplast isolation, callus tissues were observed without the aid of a microscope. A 30 to 50% plating efficiency was consistently obtained. Using a polyethylene glycol-electroporation technique, DNA was introduced into these protoplasts. The protoplasts were then cultured to form callus. Chloramphenicol acetyltransferase (CAT) activity was detected in protoplast cultures 6 hours after introduction of a 35S-CAT-nopaline synthase 3′ chimeric gene. The highest CAT activity was detected in 3-day-old electroporated protoplast cultures, indicating transient expression of the introduced gene. Some CAT activity was detected in 40-day-old callus cultures and in geneticin (G418) selected callus tissues which also received a chimeric neomycin phosphotransferase II gene, indicating the presence of stable transformants. A control chimeric gene with an inverted 35S promoter failed to produce any CAT activity in this system.     

mRNAs newly synthesized by tobacco mesophyll protoplasts are wound-inducible

We have used 2-dimensional (2D) non-equilibrium pH gradient gel electrophoresis (NEPHGE) of in vitro synthesized proteins and northern hybridization with labelled cDNAs coding for three pathogenesis related (P.R.) proteins, to analyze the shift in mRNA content induced by the isolation and culture of tobacco mesophyll protoplasts. The in vitro protein pattern of mRNAs from freshly isolated protoplasts is characterized by the absence of most leaf spots and the appearance of 19 new spots. After 6 hours of culture, the mRNAs coding for the P.R. proteins become detectable and after 12 hours the protoplasts contain an mRNA population almost typical of callus cells.The different steps involved in the isolation and culture of protoplasts were analysed. Cutting off the leaf and sterilization do not change the mRNA set. In contrast, the mechanical injury applied to the leaf in order to facilitate the penetration of the enzymatic mixture induces a modification of the mRNA content identical to that resulting from protoplast isolation. Wounding is the essential event inducing dedifferentiation. Varying the culture medium and conditions leads to only limited modifications of the mRNA pattern. These results are discussed on the basis of present knowledge of the reaction of the plant to wounding and we suggest that wound healing callus and in vitro callus correspond to the same differentiation state.     

Isolation and culture of protoplasts from high anthocyanin-producing callus of sweet potato

Optimum conditions for the isolation and culture of protoplasts from high anthocyanin-producing callus of sweet potato (Ipomoea batatas) were investigated. Growth phase of callus and the ratio of callus-enzyme solution affected the yield of protoplasts. Composition of the medium and protoplast density were examined for protoplast culture.Small colonies were regenerated from the protoplasts. Upon transfer to light a high amount of anthocyanin was accumulated in these colonies.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - MES 2-(N-morpholino)-ethanesulfonic acid     

Independent synthesis of phospholipid and the intrinsic proteins of the sarcoplasmic reticulum

The relationship between the synthesis of phospholipids and the intrinsic proteins of the sarcoplasmic reticulum was investigated in differentiating L6 cells in culture. The rates of lipid synthesis and turnover in L6 showed no large variations over the course of differentiation from myoblasts to myotubes while the rate of synthesis of the sarcoplasmic reticulum Ca2+-ATPase steadily increased. Removal of choline from the culture medium after the onset of fusion resulted in a 2-fold inhibition of phosphatidylcholine (PC) synthesis and a 40-50% reduction in total cellular PC content within 36 h. The synthesis and content of phosphatidylethanolamine also declined subsequent to the effect on PC. The amount of newly synthesized phospholipid in the microsomal fraction also decreased 50% in choline-deprived cells. Choline deprivation of myotubes for up to 4 days had no effect on the rates of synthesis of the Ca2+-ATPase or two intrinsic glycoproteins of 53,000 and 160,000 daltons. The newly synthesized proteins were incorporated into PC-deficient microsomal membranes. The synthesis of total cellular protein and total membrane protein was not altered, thus phospholipid:protein ratios declined 2-fold. These observations suggest that the assembly of the sarcoplasmic reticulum is not tightly coordinated with the rate of phospholipid synthesis.     

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.     

Division frequency of pea protoplasts in relation to starch accumulation

Division frequency of alginate-embedded pea (Pisum sativum var. Belman) protoplasts derived from embryonic shoot tips was studied quantitatively by image analysis in relation to starch accumulation and protoplast size. Protoplast divisions were observed from day 4 on and the number of protoplasts undergoing division increased in a stepwise manner to 70% the following days. The starch content increased rapidly during the first 3 days of culture prior to the onset of division and resulted a 4.2-fold increase in the intracellular starch area and a 3.0-fold increase (from 27% to 80%) in the number of protoplasts containing starch. Subsequent periods with rapid increases the number of dividing protoplasts were preceded by further starch accumulation. Dividing protoplasts were 33–60% smaller and contained 8–42% less starch than non-dividing protoplasts. However, calculations showed that, in the dividing protoplasts, the relative area covered by starch was 6–12% higher than in non-dividing protoplasts. These data suggest that starch accumulation precedes division of pea protoplasts.     

Action of Phospholipase A2 and Phospholipase C on Bacillus subtilis Protoplasts

Protoplasts prepared from Bacillus subtilis by lysozyme digestion lysed in the presence of pure pancreatic phospholipase A(2). The phospholipids cardiolipin, phosphatidylethanolamine, phosphatidylglycerol and lysylphosphatidylglycerol, which are present in the membrane, are degraded by phospholipase A(2) only after removal of the cell wall, giving free fatty acids and lyso derivatives. The four phospholipids are hydrolyzed equally well at a given enzyme concentration. Differences in the phospholipid composition of the protoplasts were obtained by variations in the growth medium, time of harvesting, and preincubation time with lysozyme. The extent of hydrolysis appeared to depend on the initial phospholipid composition. A relative increase in acidic phospholipids in the membrane facilitated the action of phospholipase A(2), whereas the rate of hydrolysis was diminished when protoplasts were tested which contained a relatively high amount of positively charged phospholipid. Pure phospholipase C from B. cereus preferentially hydrolyzed phosphatidyl-ethanolamine in the B. subtilis membrane. More than 80% of this phospholipid was converted into diglyceride, whereas only 30% of the cardiolipin was hydrolyzed. Such a loss of phospholipids, however, was not followed by lysis of the protoplasts. Liposomes were prepared from the lipid extracts of B. subtilis and incubated with both phospholipases. The hydrolysis pattern of the phospholipids in these model membrane systems was identical to the hydrolysis pattern of the phospholipids in the protoplast membrane. Phospholipase A(2) hydrolyzed all the phospholipids in the liposomes equally well, whereas phospholipase C preferentially degraded phosphatidylethanolamine.     

Isolation,culture and division of olive (Olea europaea L.) protoplasts

Protoplasts from Olea europaea L. have been compared in terms of their yield, viability, cell division and callus differentiation. Viable protoplasts were isolated from in vitro cultured leaves and cotyledons by an overnight incubation in an enzyme solution containing 1–1.5% driselase and 0.5M sucrose. This method allowed high yield of purified protoplasts, which floated and formed a dark green band at the meniscus, after centrifugation. Purified protoplasts were diluted to 3×10⁴ protoplasts·ml^–1 in culture medium. After cell wall regeneration, protoplasts gradually increased their volumes under appropriate conditions. The first divisions occurred during the second week in culture. Division efficiency ranged from 5.2 to 9.8% after 20 days in culture. Two weeks later visible microcolonies developed only from cotyledon protoplasts. After 6 weeks in culture, the microcalli were transferred to a solidified culture medium with 0.6% agarose, which induced active callus growth.Abbreviations OM olive proliferation medium, Rugini 1984 - Omg OM for the germination of olive embryos - OMr=OM for root induction - OMp=OM for protoplasts - OMc=OM for callus - BN Bourgin and Nitsch medium 1967 - IBA indol-3-butyric acid - NAA naphthalene acetic acid - 2,4-D dichlorophenoxyacetic acid.     

Preparation of protoplasts in tissues of <Emphasis Type="Italic">Ficus elastica</Emphasis> callus cultures differing in the endogenous cyrokinin activity. The role of cytokinins in formation of protoplasts

The rate of formation of protoplasts in Ficus elastica callus cultures differing on endogenous cytokinin activity was examined. This rate was shown to be determined by cytokinin synthesis leading to formation of cells whose walls exhibit a changed rate of protoplast formation. In contrast to a culture exhibiting a high cytokinin activity, the culture with a low cytokinin activity produces a greater amount of protoplasts having a smaller intact cell surface. As compared to this culture, the callus culture exhibiting a high cytokinin activity produces a small amount of protoplasts characterized by a high viability. This fact points to the functional role of endogenous cytokinins in plant cells.     

Microcallus formation from maize protoplasts prepared from embryogenic callus

Conditions have been developed that induce maize (Zea mays L.) protoplasts to re-synthesize cell walls and to initiate cell divisions. Two types of embryogenic maize callus were used as a source of protoplasts: a heterogeneous callus (Type I) derived from immature embryos after three weeks in culture, and a friable, rapidly growing callus (Type II) selected from portions of the Type I callus. Many variables in the growth conditions of the donor tissue (type of medium, transfer schedule, age of callus), protoplast isolation solutions (pH, osmolarity, type and concentration of cell wall hydrolyzing enzymes, addition of polyamines) and conditions (amount of time in enzyme, amount of tissue per volume of enzyme incubation medium, agitation, preplasmolysis of source tissue, type of callus), and purification procedures (filtration and-or flotation), were found to affect both yield and viability of protoplasts (based upon fluorescein-diacetate staining). Our isolation procedure yielded high numbers of viable, uninucleated maize callus protoplasts which were densely cytoplasmic and varied in size from 20 to 50 m in diameter. Protoplasts plated in solid medium formed walls and divided several times. Of several gelling agents tested for protoplast propagation, only agarose resulted in protoplasts capable of sustained divisions leading to the formation of microcalli. Plating efficiency was established over a wide range of protoplast densities (10³–10⁷ protoplasts/ml). Highest plating efficiency (25%) was obtained at 1·10⁶ protoplasts/ml). The resulting microcalli grew to be dense clusters of about 0.1–0.5 mm in diameter and then stopped growing. Nurse cultures of maize and carrot (Daucus carota L.), were used to establish that individual protoplasts (not contaminating cells or cell clusters) formed walls and divided. Nurse cultures also increased the efficiency of microcallus formation from protoplasts.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - MS Murashige and Skoog (1962) salts - MS 1D Murashige and Skoog salts with 1 mg/l 2,4-D - MS 2D Murashige and Skoog salts with 2 mg/l 2,4-D - N₆ medium of Chu et al. (1975) - NN67-mod medium of Nitsch and Nitsch (1967) as modified in the present paper - FDA fluorescein diacetate - LMP low melting point     

Embryogenic callus formation from maize protoplasts

Maize (Zea mays L.) protoplasts have been obtained which divide rapidly and produce a callus that differentiates to form somatic embryos. The somatic embryos can be induced to form roots and small leaf-like structures. The genotype was the hybrid A188xBlack Mexican Sweet. Protoplasts were prepared from an embryogenic suspension culture derived from a Type II callus which had been selected from Type I callus produced by immature zygotic embryos. The basal medium for the suspension culture was N6 (C.C. Chu et al., 1975, Scientia Sinica 18, 659–668). The 2,4-dichlorophenoxyacetic acid concentration of the suspension culture was critical for subsequent protoplast growth and was optimal at 4.0 mg.l. Protoplasts had to be cultured in a low-osmoticum medium (0.3 M mannitol) for subsequent cell divisions to occur. The protoplasts have been transformed transiently with the gene chloramphenicol acetyltransferase (CAT) containing the 35S promoter obtained from cauliflower mosaic virus (CaMV-35S).Abbreviations FDA fluorescein diacetate - ABA abscisic acid - 2,4-D 2,4-dichlorophenoxyacetic acid     

Induction of callus formation from difficile date palm protoplasts by means of nurse culture

We report here for the first time callus formation from protoplasts in date palm (Phoenix dactylifera L.). Protoplasts were isolated from young leaves of offshoots and embryogenic calli in Deglet nour and Takerboucht genotypes. The protoplast yield depended on genotype, donor plant material, mixture of enzyme solution, and incubation time. With regard to the donor material, the best response was obtained with callus. Cell division was induced in both liquid culture and nurse culture. The best donor material for cell division was callus and the best response was obtained with the feeder layer, which induced a division rate of 30% in Deglet nour and 15% in Takerboucht genotypes. The dividing cells developed to microcalli on the feeder layer; the microcalli developed to calli on modified MS medium; however, the calli failed to regenerate into roots or shoots.     

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.     

In vitro culture of Cucumis sativus L. XVIII. Plants from protoplasts through direct somatic embryogenesis

A procedure is described for the isolation and culture of protoplasts from embryogenic callus (gel-like callus — GLC) and embryogenic suspension cultures (ESC) of Cucumis sativus c.v. Borszczagowski. Maximal protoplast yields from GLC and ESC were 5×10⁶ and 1×10⁷ protoplasts/g tissue respectively. They were obtained following 14–16 h digestion with 1.2% Cellulase Onozuka R-10, 1.2% Macerozyme R-10 and 0.3% Driselase. At a plating density of 2×10⁵ / ml, first divisions occurred in 4–5 days and 7–8 days in ESC-and GLC-derived protoplasts respectively. The highest percentage of direct embryogenesis (over 80%) was observed with ESC. It was possible to obtain approximately 5000 embryo structures / g tissue. Some embryos converted into plants after 6 weeks, but most of them after 2 months of culture. ESC-derived plants, when transferred into the glasshouse, bloomed normally, and set seeds.Abbreviations CMS Murashige & Skoog (1962) medium for cucumber - GLC gel-like callus - ESC established embryogenic suspension culture - 2,4-d 2,4-dichlorophenoxyacetic acid     

Fertile wheat (Triticum aestivum L.) regenerants from protoplasts of embryogenic suspension culture

We report regeneration of fertile, green plants from wheat (Triticum aestivum L. cv. Aura) protoplasts isolated from an embryogenic suspension initiated from somatic early-embryogenic callus. The present approach combines the optimization of protoplast culture conditions with screening for responsive genotypes. In addition to the dominant effect of the culture media, the increase in fresh mass and the embryogenic potential of somatic callus cultures varied considerably between the various genotypes tested. Establishment of suspension cultures with the required characters for protoplast isolation was improved by reduction of the ratio between cells and medium and by less frequent (monthly) transfer into fresh medium. A new washing solution was introduced to avoid the aggregation of protoplasts. However, the influence of the culture medium on cell division was variable in the different genotypes. We could identify cultures from cultivar Aura that showed approximately a 9% cell division frequency and morphogenic response. The protoplast-derived microcolonies formed both early and late-embryogenic callus on regeneration medium and green fertile plants were obtained through somatic embryogenesis. The reproducibility of plant regeneration from protoplast culture based on the cultivar Aura was demonstrated by several independent experiments. The maintenance of regeneration potential in Aura suspension cultures required establishment of new cultures within a 9-month period.     

Callus formation from protoplasts of culturedSpinacia oleracea cells

Cell suspensions were initiated from plumule derived calli ofSpinacia oleracea. Some of these cell lines could be maintained in culture for at least three years without a reduced growth rate. A high yield of protoplasts was obtained from the cell suspensions. When protoplasts were cultured in Murashige and Skoog medium with naphthaleneacetic acid and 6-benzyladenine, cell wall formation was observed after three days. The cultured protoplasts produced numerous cell-clusters within two weeks. However only protoplasts isolated from suspensions which were in a rapidly dividing phase were able to divide with a high frequency and give rise to callus colonies.     

The isolation and culture of lily pollen protoplasts

Methods for the enzymatic isolation of lily protoplasts and their successful culture are described. When pre-anthesis binucleate pollen (immature pollen grains) was treated in enzyme solution containing macerozyme and cellulase, up to 80% lost their exine and gave rise to intact protoplasts within 1 h. These pollen protoplasts were uniform in size and densely cytoplasmic with two prominent generative and vegetative nuclei. The isolated pollen protoplasts regenerated a cell wall within 1 day of culture and produced a structure resembling a pollen tube after 10–12 days of culture. During this culture period, dividing generative nuclei or 2 sperm nuclei were observed in many protoplasts with regenerated cell walls.