Plant donor tissue and isolation procedure effect on early formation of embryoids from protoplasts of Helianthus annuus L.

The effects of factors influencing sunflower protoplast isolation yield, plating efficiency (PE) and the early differentiation into embryoids (embryogenic capacity, EC) have been studied. Only hypocotyl-derived protoplasts divided. The variations of PE and EC in the various treatments did not seem to be linked to the protoplast yields. From statistical analysis of the data, we concluded that, the sunflower genotype, the age and height of seedlings, the part of hypocotyl used, the incubation time (from 6 to 16 hours) in enzymes of explants or of protoplasts alone, influenced PE but large variations were detected for EC. A comparison of the factors effecting EC suggested an origin, inside the hypocotyl, of cells able to give rise, after induction, to embryogenic protoplasts.     

Isolation and culture of soybean hypocotyl protoplasts

Summary Protoplasts were isolated seedling hypocotyls of soybean (Glycine max), and cultured in both liquid and agarose-solidified, modified K8P medium. Nuclear staining revealed that only 2% of protoplasts lacked a nucleus, 93% contained a single nucleus, and 5% contained more than one. Maximum protoplast yields and subsequent division frequencies, in liquid medium, were obtained from 5 days-old seedlings. Maximum division frequencies (54%) were obtained from hypocotyl protoplasts plated at a density of 5×10⁴ ml⁻¹. Using different osmolality reduction régimes for liquid cultures, hypocotyl protoplasts developed into green, nodular callus, similar to that which has previously given rise to shoot buds in perennialGlycine species. This tissue, however, did not produce shoot buds in soybean. N. H. was supported by a SERC CASE studentship and a postdoctoral fellowship from Shell Research Ltd., Sittingbourne, Kent, UK.     

An investigation of the intracellular site of anthocyanoplasts using isolated protoplasts and vacuoles

Microscopic observations made during preparation of protoplasts and vacuoles from red radish seedling hypocotyl (Raphanus sativus L.) show that anthocyanoplasts, the strongly pigmented bodies present in the pigmented cells of the hypodermis, begin as apparently membranous vesicles in the cytoplasm made visible by the deposition and accumulation of anthocyanins, but only rarely appear in the isolated vacuole. Isolation of protoplasts and vacuoles was also achieved from mung bean seedling hypocotyl (Vigna radiata L Wilczek), red cabbage leaf (Brassica oleracea L.) and Prunus x yedoensis Matsum callus. Anthocyanoplasts were usually in the vacuole, although sometimes in the cytoplasm, of the mung bean and cabbage, but were never seen in vacuoles of Prunus callus.     

High growth rate and regeneration capacity of hypocotyl protoplasts in some Brassicaceae

Protoplasts isolated from 4-day-old hypocotyls of various species of Brassica (Brassica napus, B. campestris and B. oleracea ) produced callus with high efficiency in media containing casein hydrolysate and high concentrations of the auxin 2,4-D (4.5 μM). Cell division began after 24 h and 60% of the cells had divided after 48 h. In contrast, protoplasts isolated from stem and mesophyll of plants grown in vitro or in the greenhouse began to divide after a delay of 3–5 days. In these cases 40–50% of the cells had divided after 5 days as compared to 70% for hypocotyl protoplasts. To obtain a high frequency of regeneration, rapidly growing calli were transferred to media having a high cytokinin:auxin ratio as early as possible, usually 3 weeks after protoplast isolation. The average regeneration frequency for calli obtained from mesophyll protoplasts was 50%, while as many as 70% of the calli derived from hypocotyl protoplasts of B. napus regenerated plantlets on a medium containing zeatin (9.1 μM) and IAA (0.6 μM). On the same medium regeneration of Brassica oleracea was obtained. A low percentage of calli (1%) from Brassica campestris formed shoots when cultured on a combination of zeatin (4.6 μM), BA (4.4 μM) and IAA (0.6 μM).     

Isolation and culture of sunflower protoplasts (Helianthus annuus L.): Factors influencing the viability of cell colonies derived from protoplasts

Sunflower protoplasts from various sources (mesophyll, stems, cotyledons anhypocotyls) have been tested for their capacity to divide in culture. Only hypocotyl protoplasts divided in our media at a high and repeatable percentage (60%). Culture at low density in a medium containing glutamine or ammonium succinate as sole sources of nitrogen and a reduced amount of naphthalene acetic acid (NAA) (0.1 mg/l) were the most important conditions for obtaining calli from sunflower protoplasts. On such media, 6% of the initially plated protoplasts reached the stage of calli.     

Protoplast isolation and culture from carob (Ceratonia siliqua) hypocotyls: ability of regenerated protoplasts to produce mannose-containing polysaccharides

The aim of this study was to isolate protoplasts from carob (Ceratonia siliqua L.) embryonic tissues with the ability to regenerate cell walls, divide and synthesize galactomannan, a valuable polysaccharide for industry. Protoplasts isolated from carob hypocotyl hooks regenerated cell walls within 24 h. The first divisions of the regenerated cells were observed after 2 days of culture. The highest percentage that successfully divided was achieved when the seedlings were grown under diffuse light, the hypocotyl hooks were plasmolysed for 1 h before incubation in the protoplast isolation solution and the protoplasts were cultured under diffuse light. After 9 days of culture, cell clusters, consisting of eight cells, had been produced, which underwent further mitotic divisions and which were expected to lead to callus formation. Polysaccharide and oligosaccharide synthesis during protoplast regeneration was studied by radiolabelling with exogenous d ‐[U‐¹⁴C]glucose, d ‐[U‐¹⁴C]mannose or d ‐[2‐³H]mannose, which gave rise to uniform, moderately specific and highly specific labelling, respectively. As revealed by the radioactivity distribution in cell wall monosaccharides, the regenerants deposited new wall polymers that differed markedly from those being synthesized by the hypocotyls from which the protoplasts had been isolated. The regenerants deposited large amounts of callose and smaller amounts of galactose‐, arabinose‐ and mannose‐containing polymers. The latter included glucuronomannan, as demonstrated by a new method involving partial acid hydrolysis followed by β‐glucuronidase (EC 3.2.1.31) digestion. The regenerating protoplasts also released soluble extracellular carbohydrates: polysaccharides which appeared to be mainly acidic arabinogalactans, and oligosaccharides which were mainly neutral and contained glucose, galactose and mannose. We conclude that regenerating carob protoplasts are a useful system for studying carbohydrate secretion, including mannose‐rich poly‐ and oligosaccharides.     

Production of hybrid cells from single protoplasts of sunflower hypocotyl and broad bean guard cells by electrical fusion

The C4-directed enzymatic apparatus in guard cells is known to be coupled with a reduction in photorespiration resulting in a higher survival rate and yield potential of crops. This has led to searches for guard-cell-specific genes and promoters and methods for transferring them into C3-plants. To explore this possibility we performed somatic fusions between guard cell protoplasts from Vicia faba and hypocotyl protoplasts from Helianthus annuus, using a technique which allows fusion of a single pair of individually selected protoplasts. We obtained fusions in 30–70% of attempts. Culture of the hybrid fusion products in a liquid nutrient medium, without conditioning or feeder cells, produced microcolonies consisting of 8–9 cells within 9 days of culture. This revised version was published online in June 2006 with corrections to the Cover Date.     

Callus formation from isolated sunflower (Helianthus annuus) mesophyll protoplasts

Mesophyll protoplasts of the cultivated sunflower,Helianthus annuus, have been consistently found not to divide or regenerate calli, despite the efforts of several groups. In the present report, we describe the conditions for donor plant culture, protoplast isolation, and their culture that were suitable for repeated regeneration of green, nodular, vigorously growing calli from isolated sunflower mesophyll protoplasts. The best conditions for protoplast isolation employed the use of both CAYLA cellulase and CAYLA pectinase. Culture conditions were not much different from those established earlier for sunflower hypocotyl protoplasts. The most startling observation was the great variability of division frequencies between experiments even under strictly controlled, identical experimental conditions. This finding points to an important influence of a variable in the physiological state of the donor plant which is difficult to control.     

Plant regeneration from leaf protoplasts of Brassica oleracea var. italica CV Green Comet broccoli

A procedure is described for regeneration of plants from leaf protoplasts of the hybrid broccoli cultivar, Green Comet (Brassica oleracea var italica). The totipotency of protoplasts isolated from plants regenerated from hypocotyl explants (GCR) was greater than that of protoplasts from plants grown directly from seed (GC). Using medium B developed by Pelletier et al (1983), division efficiencies greater than 70% were obtained in leaf protoplasts isolated from GCR. Approximately 1% of these protoplasts formed calli on solidified medium; 77% of the calli regenerated shoots. In contrast, protoplasts from seed-grown material showed a lower division efficiency (15–22%) and fewer protoplast-derived calli produced shoots. Some of the 178 protoplast-derived plants grown to maturity had variant phenotypes.Abbreviations NAA napthalene acetic acid - BA 6-benzylaminopurine - MES 1-morpholino-ethane sulfonate This work has been submitted by D. R. in partial fulfillment of the requirement for the Ph.D. degree     

2,4-Dichlorophenoxyacetic acid affects mode and frequency of regeneration from hypocotyl protoplasts ofBrassica oleracea

Summary The effect of 2,4-dichlorophenoxyacetic acid (2,4-D) on the regeneration from hypocotyl protoplasts ofBrassica oleracea was studied by varying the 2,4-D concentration in the protoplast culture medium, 8 p, and the callus proliferation medium, K3. When hypocotyl protoplasts of the inbred line BL12 were cultured in the complete absence of 2,4-D, they divided and produced embryogenic calli. Moreover, these calli generated somatic embryos which were easily recognized by red cotyledons due to the presence of anthocyanin. When 2,4-D was present either in 8p medium or K3 medium the formation of somatic embryos was reduced. On the other hand, the number of shoot-forming calli increased considerably. We therefore conclude that 2,4-D directs the mode of regeneration by suppressing somatic embryogenesis in favour of shoot regeneration. Secondly, 2,4-D increases the regeneration efficiency. Furthermore, the callus proliferation phase on K3 medium is most important with respect to the determination of either somatic embryogenesis or shoot regeneration.Abbreviations BA benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - IAA indole acetic acid - NAA naphthalene acetic acid - PE plating efficiency     

Agarose embedding affects cell wall regeneration and microtubule organization in sunflower hypocotyl protoplasts

Sunflower hypocotyl protoplasts ( Helianthus annuus L. cv. Emil) divide symmetrically to form loosely associated microcolonies when cultured in liquid medium, whereas when embedded in agarose beads they divide asymmetrically to give rise to embryo-like structures. To understand the relationship between protoplast embedding and cell division patterns, we studied the deposition of β-linked glucan and the dynamics of microtubules during early phases of culture. After one day in culture, under both culture conditions, a small proportion of the protoplasts had already begun to rebuild a β-glucan cell wall and the process reached completion in all protoplasts after 10 days. Callose deposition was faster in agarose than in liquid medium but it concerned only 30–40% of the protoplasts and was not related to either division type. No marked differences were observed in cortical arrays of microtubules. However, in embedded protoplasts perinuclear microtubules formed a well-defined basket around the nucleus; these microtubules were never observed in liquid-cultured protoplasts. A narrow preprophase band was present only in dividing protoplasts cultured in liquid medium. The results suggest that asymmetric division could be related to the lack of a narrow preprophase band and that protoplast embedding enhances nucleation or stabilization of microtubules.     

Fractional protein makeup of Candida utilis yeast protoplasts in the process of their growth and development

Candida utilis IBFMY-405 was grown in a synthetic medium with glucose. Cells taken at the logarithmic phase of growth were studied. The cells were treated with the enzyme from Helix pomatia to prepare protoplasts which were separated by differential centrifugation into groups according to their size. Three protein fractions were isolated from each group and the amino acid composition of the proteins was determined. Proteins of the first fraction (cytoplasmic) prevailed in all of the protoplast groups while the content of proteins of the second fraction (intermediate or myosin-like) was the lowest. As the size of protoplasts increased, difference in the quantitative content of proteins from the first and second fractions became less pronounced. The content of proteins of the third fraction was 3.6 and 2.4 times higher in the protoplasts of the medium size than in the largest protoplasts. The amino acid composition of each protein fraction differed quantitatively and qualitatively in all of the protoplast groups.     

An improved protocol for plant regeneration from leaf- and hypocotyl-derived protoplasts of carrot

An easy and effective regeneration system from leaf- and hypocotyl-derived protoplasts was established for carrot. The protoplast isolation efficiency after preplasmolytic treatment and digestion of source material in enzyme mixture consisted of 1% cellulase Onozuka R-10 and 0.1% pectolyase Y-23 reached on average 3 × 10⁶ and 10⁶ protoplasts per g of leaf and hypocotyl tissue, respectively. A modified thin alginate layer technique was applied for the protoplast culture. Direct somatic embryogenesis on a simplified Kao and Michayluk medium in the presence of 2,4-D and zeatin occurred during cultivation of both leaf- and hypocotyl-derived protoplasts for all accessions used. Morphologically normal plants were produced at very high efficiency within two months after initiation of the protoplast culture. Ninety three percent of in vitro derived plants were diploids. Pollen viability and seed set after self-pollination were similar to those of plants obtained from seeds.     

Formation and regeneration of Frankia protoplasts

A technique for forming protoplasts from Frankia cells and regenerating them to the normal hyphal mode of growth is described. Electron microscopy proved that protoplasts were studied and not spores or small hyphae. Regenerated colonies were investigated for genetic markers. One ArI3 colony had been cured of its plasmids without being affected in its symbiotic properties.     

Preparatory studies for the use of plant protoplasts in space research

An experiment using plant protoplasts has been accepted for the IML-1 mission to be flown on a space shuttle in 1991. Preparatory experiments include studies of cell wall formation, cell division, the effect of simulated weightlessness using fast and slow rotating clinostats, and the development and testing of hardware for the IML-1 mission. After 24 h at 25°C, protoplasts isolated from hypocotyls or leaves of rapeseed seedlings, or from carrot suspension cells, show 60, 20 and 15% cell wall formation, respectively. The time course of formation of the cell wall and cell division could be delayed by treatment at low temperatures or immobilization in alginate or agarose. This aspect is of importance in connection with problems of late access to the space shuttle before launch. At 4°C only 18% of the rapeseed hypocotyl protoplasts had formed cell walls after 24 h. Protoplasts immobilised in agarose or alginate gradually regain their cell division capacity and after 72 h the frequencies are 51 and 26%, respectively, compared to non-immobilised control protoplasts. A significant decrease in cell division activity is observed after rotation for 6 h on the slow clinostat. A similar effect is not observed on the fast clinostat. Protoplasts, cultured in the specially designed plant chamber for up to 14 days established cell aggregates which have further developed into plants.     

Callus and embryoid formation from protoplasts of Helianthus annuus

Sunflower hypocotyl protoplasts have been isolated and cultured. Optimum plating density for cell division and colony formation was in the range of 5 to 7×10⁴ cells/mi in an agarose medium supplemented with BAP (1 mg/l) and NAA (1 mg/l). Plating efficiency was 60% after 21 days of culture. In the resultant culture a mixed population of calli and embryoids was observed. Thirty seven percent of the cell clusters exhibited a developmental pattern similar to an embryoid. Many stages of embryogenesis were observed in the same cultures.Abbreviations 2,4-D 2,4 dichlorophenoxyacetic acid - NAA 1-naphtaleneacetic acid - IAA Indole-3-acetic - BAP 6-benzylamino purine - GA₃ Gibberellic acid     

Lactobacillus lactis protoplasts at different stages of cell cultivation

Abstract Protein profiles of both protoplasts and cell homogenates of Lactobacillus lactis prepared in the course of cell multiplication were compared. The sodium dodecyl sulfate acrylamide gel electrophoretograms of whole cell homogenates and protoplasts show almost the same complexity. Protoplast protein profiles after 4 hours of growth exhibit new bands in both the low and high molecular mass region of the gel. The changes in protein composition during conversion of the cells into protoplasts are predominantly quantitative in nature.     

Seawater-resistant, non-spherical protoplasts from seagrass leaves

Two distinct types occurred among enzymatically isolated protoplasts from leaves of eelgrasses ( Zostera marina L., Z. japonica Ascherson and Phyllospadix iwatensis Makino). Spherical protoplasts with a smooth cell membrane were obtained only from young leaf tissues at the basal portions of blades protected from seawater by tightly enclosing sheaths. Non-spherical protoplasts had a highly invaginated cell membrane and were obtained from mature leaf blades, where the cells also in situ have this type of membrane. The protoplasts from mature leaves were rather rigid in shape and resistant to wide ranges of osmotic potential and salinity without change in their non-spherical shape, while the spherical protoplasts were rapidly destroyed in seawater. Detergents lysed the spherical protoplasts but not the non-spherical ones, suggesting that the highly invaginated enclosing structures of the non-spherical protoplasts contained detergent-resistant materials. Thus, the seagrass leaf cells develop seawater resistance, and this change alters the nature of the enclosing structures during the growth of the leaf blades. The non-membranous enclosing structures and their characteristic materials in the mature leaf cells remain to be defined.     

Isolation of protoplasts from somatic embryos of carrot

Protoplasts were isolated enzymatically from synchronously induced globular somatic embryos from a carrot suspension culture. Among the macerating enzymes tested, Driselase was the most effective for release of protoplasts from embryos. A higher medium osmolarity was required for the isolation of protoplasts from embryos than from undifferentiated cells. Protoplasts from embryos were smaller than protoplasts from undifferentiated cells. On step gradients of Ficoll, protoplasts from embryos gave one major band. Protoplasts from undifferentiated cells gave two major bands, one lighter and the other heavier than the protoplasts from embryos.