Production and seeding of protoplasts of <Emphasis Type="Italic">Porphyra okhaensis</Emphasis> (Bangiales,Rhodophyta) in laboratory culture

High yields of viable protoplasts were produced from Porphyra okhaensis H. Joshi, Oza & Tewari following two-step enzymatic digestion (protease pretreatment and cell wall polysaccharides-degrading enzyme treatment) of the thallus. Pretreatment of the tissues with 1% Protease P6 at 20± 1 ^°C for 30 min prior to digestion with cell wall polysaccharide-degrading enzymes increased the protoplast yield two fold compared to tissues that were digested with polysaccharide-degrading enzyme mixture. The polysaccharide-degrading enzymes employed for protoplast isolation from P. okhaensis were Cellulase Onozuka R-10, Macerozyme R-10, abalone acetone powder and agarase. Suitable pH, temperature and duration of enzyme treatment for optimal production of viable protoplasts were pH 6, 20± 1 ^°C and 3 h, respectively. Mannitol (0.8 M) was found to be an excellent osmotic stabilizer. When the tissue of P. okhaensis pretreated with 1% protease solution was digested with commercial enzyme mixture consisting of 2% Cellulase Onozuka R-10, 2% Macerozyme R-10, 1% abalone acetone powder, 50 units of agarase and 0.8 M mannitol in 1% NaCl (adjusted to pH 6.0 with 25 mM MES buffer) with gentle agitation for 3 h at 20± 1 ^°C, 23.2± 0.24× 10⁶ protoplasts g⁻¹ fresh wt. were obtained. The regeneration rate of protoplasts isolated in the present study was found to be 79%. Protoplasts that regenerated cell walls underwent regular cell divisions and developed into leafy gametophytic thallus in the laboratory cultures. Further, the seeding of nylon threads with partially developed protoplasts of P. okhaensis was successful in the laboratory conditions and germlings as long as 3–4 cm were obtained from such seeded threads in one month period in aerated cultures.     

Studies of cotyledon protoplast cultures from Brassica napus,B. campestris and B. oleracea. I: Cell wall regeneration and cell division

Protoplasts isolated from cotyledons of a number of cultivars of Brassica napus, B. campestris and B. oleracea were cultured in different media to study the characteristics of cell wall regeneration and cell division at early stages of culture. Time course analysis using Calcolfluor White staining indicated that cell wall regeneration began in some protoplasts 2–4 h following isolation in all cultivars. 30–70% of cultured cotyledon protoplasts exhibited cell wall regeneration at 24 h and about 60–90% at 72 h after the initiation of culture. Results also indicated that a low percentage (0.4–5.4%) of cultured cotyledon protoplasts entered their first cell division one day after initial culture in all twelve cultivars. The percentage of dividing cells increased linearly up to 40% from 1 to 7 day, indicating that cotyledon protoplasts of Brassica had a high capacity for cell division. Factors that influence the level of cell wall regeneration and cell division during cotyledon protoplast culture have been investigated in this study. Cotyledons from seedlings germinated in a dark/dim light regime provided a satisfactory tissue source for protoplast isolation and culture for all Brassica cultivars used. The percentages of protoplasts exhibiting cell wall regeneration and division were significantly influenced by cultivar and species examined, with protoplasts from all five cultivars of B. campestris showing much lower rates of cell wall regeneration than those of B. napus and B. oleracea over 24–120 h, and with the levels of cell division in B. napus cultivars being much higher than those in B. campestris and B. oleracea over 1–9 days. The capacity of cell wall regeneration and cell division in cotyledon protoplast culture of the Brassica species appears under strong genetic control. Cell wall regeneration in protoplast culture was not affected by the culture medium used. In contrast, the composition of the culture medium played an important role in determining the level of cell division, and the interaction between medium type and cultivars was very significant.Abbreviations BA benzylaminopurine - CPW Composition of Protoplast Washing-solution - CW Calcolfluor White - EDTA ethylenediamine-tetraacetic acid - KT Kinetin - Md MS modified Murashige and Skoog medium - 2,4-d 2,4-dichlorophenoxyacetic acid - NAA -naphthaleneacetic acid - IAA indole-3-acetic acid - PAR photosynthetically active radiation - SDS sodium dodecyl sulfate     

Protoplast isolation in the marine brown alga Dictyopteris prolifera (Dictyotales)

Protoplasts were isolated from thalli of Dictyopteris prolifera using a mixture of crude enzymes from vicera of live oysters (Crassostrea gigas) and the following commercial enzymes: an abalone enzyme, cellulase, polygalacturonase and hemicellulase. The enzyme mixtures produced up to 3.3 × 10⁷ cells per l g of tissue fresh weight. The conversion to protoplasts of the cells was about 100% using the oyster enzyme or the abalone enzyme alone. The optimum pH for protoplast isolation was 6.0 and 20 hours were required for conversion to protoplasts.     

Protoplasts of Gelidium robustum (Rhodophyta)

Viable protoplasts were isolated from apices of the agarophyte Gelidium robustum (Gardn.) Hollenb. & Abb. using a combination of commercial cell-wall degrading enzymes and extracellular wall-degrading enzymes isolated from a marine bacterium. The protoplasts were approximately 8–15 µm in diameter, liberated mainly from the surface cell layers and from cells at the distal ends of medullary filaments. The bacterial enzyme alone was not sufficient to liberate significant numbers of protoplasts. Maximum yield was 9 × 10⁵ protoplasts/g tissue (wet wt.). Optimum osmolality occurred between 1750–1950 mOs kg^–1; yield and viability were severely diminished at osmolalities less than 1350 mOs kg^–1. Viability, as determined by flurorescein diacetate staining and Evans Blue exclusion 1 hr after removal from the enzyme solution, was approximately 80–95%. Roughly 80% of the cells did not show Calcofluor fluorescence, while 40% stained positively for the presence of sulfated polysaccharides. Cell wall regeneration was observed with inconsistent reproducibility, and no cell division was observed when the protoplasts were placed in culture medium.Dedicated to the memory of Professor Michael Neushul.     

Isolation of protoplasts from tissue fragments of Philippine cultivars of <Emphasis Type="Italic">Kappaphycus alvarezii</Emphasis> (Solieriaceae,Rhodophyta)

Protoplasts were isolated from tissue fragments (<1 mm²) of three Philippine cultivars of Kappaphycus alvarezii: the giant cultivar, cultivar L and Bohol wild type, by enzymatic dissolution of cell walls. Yields of viable protoplasts from young and old thalli (apical, middle, basal segments) were compared at various temperatures, duration of treatment and pH using eight combinations of commercial enzymes (abalone acetone powder and cellulase), and prepared extracts from fresh viscera of abalone (Haliotis asinina) and a terrestrial garden snail. Isolated protoplasts were grown in various culture media, temperatures, photoperiods and irradiance values to determine the conditions that favor germination and growth.Protoplast yields in tissues treated with commercial enzymes and the garden snail extract were lower than those obtained in tissues treated with fresh abalone extracts. Generally, the number of viable protoplasts increased with duration of enzyme treatment at 25 °C with a maximum yield of 8.2 × 10³ g⁻¹ tissue at 48 h. Yields were consistently higher in all cultivars at pH 6.1. The yields were also high from the middle segments of the giant cultivar (3.7 × 10³ g⁻¹ tissue) and Bohol wild type (4.5 × 10³ g⁻¹ tissue) treated with fresh abalone extract, and from basal segments of cultivar L and tissues treated with garden snail extract. The germination rate of protoplasts was highest (39.8%) at 25 °C and 20 μmol photon m⁻² s⁻¹, using a 12:12 light dark photoperiod. The filament was 3.7 mm long by Day 5. These findings are relevant to developing cultures from protoplasts for genetic or strain improvement of K. alvarezii cultivars.     

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.     

An efficient protocol for plant regeneration from protoplasts of the moss <Emphasis Type="Italic">Atrichum undulatum P. Beauv in vitro</Emphasis>

A system for plant regeneration from protoplasts of the moss, Atrichum undulatum (Hedw.) P. Beauv. in vitro, is first reported. Viable protoplasts were isolated at about 9 × 10⁵ protoplasts g⁻¹ fresh weight from 10 to 18 days protonemata. For regeneration of protoplasts, viable protoplasts were cultured in liquid–solid medium containing surface liquid medium MS (0.4 M mannitol) and subnatant solid medium Benecke (0.3 M mannitol) at 20 °C under a 16-h photoperiod white light after 12 h preculture in darkness at 20 °C. The great majority of protoplasts follow a regenerative sequence: formation of asymmetric cells in 2–3 days; division of the asymmetric cells to 2–3 cells in 4–5 days, and further develop to produce a new chloronemal filament in 15 days. Juvenile gametophyte can be visible in 20 days. The plating ratio of cell cluster regenerated from protoplasts reaches up to 45%. Transient expression experiments indicate the electroporation uptake of DNA is possible.     

Regeneration from Laminaria japonica Areschoug (Laminariales, Phaeophyceae) protoplasts isolated with bacterial alginase

Summary The conditions for effective isolation of viable protoplasts from Laminaria japonica with an alginase produced by marine bacterium Alteromonas sp. and a commercially available cellulase were investigated. The highest yields of viable protoplasts (7.910.4x10⁶ cells g^–1 FW) were obtained with a hypertonic solution containing 50 % seawater, 25 mM MgCl₂, 5 mM HEPES buffer system, and 0.5 M mannitol. Protoplasts were not obtained from thalli of L. japonica when an abalone alginase (abalone acetone powder; AAP: Sigma) was used instead of the bacterial alginase. The isolated protoplasts were cultured in an PESI medium at 5 °C. Complete cell wall formation was observed within 7 days, and dividing cells were first observed in a 9-day-old culture. Some protoplasts regenerated into sheet-shaped thalli and rhizoid structures were also observed on some thalli after 30 to 40 days in culture. This is the first report of protoplast regeneration into plantlets of L. japonica Areschoug (Laminariales, Phaeophyceae).Abbreviations FW Flesh weight - AAP Abalone acetone powder - HEPES N-2-hydroxy-ethylpiperazine-N-2-ethanesulfonic acid - Tris Tris(hyrdoxymethyl)aminomethane - PESI Provasoli's enriched seawater with iodine     

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

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

Karyokinesis in growing and reverting protoplasts ofSchizosaccharomyces pombe

Division of nuclei without cytokinesis proceeds in growing protoplasts ofSchizosaccharomyces pombe. Prior to regeneration of the complete cell wall and reversion the protoplasts contain 1–7 nuclei, protoplasts with 1–2 nuclei are most frequent. When regeneration of the wall is postponed by adding snail enzymes to the growth medium, protoplasts with a higher number of nuclei (2–4) occur. Multinuclear protoplasts can revert to cells. During the first cytokinesis the protoplast with the regenerated cell wall is divided into two cells by a septum, distribution of nuclei between the two cells being probably incidental. More than only a single nucleus can pass to the revertants even during the second cytokinesis. Septation of protoplasts occurs also during a partial blockage of the wall formation by the snail enzyme preparation, however, reversion to cells can never be observed here (it occurs only after transfer of protoplasts to the medium without the enzyme preparation). The growing and reverting protoplasts represent a very good model system for studying relations among individual processes of the cell cycle, primarily growth of the cell, nuclear cycle and cytokinesis. Yeast protoplasts are often utilized as models for studying morphogenic processes, relations among regeneration of the cell wall, including division of the nucleus (karyokinesis) and cytokinesis.     

Callus production from willow (Salix viminalis L.) protoplasts

Protoplasts were isolated from cell suspensions of Salix viminalis (basket willow) clone 78-0-90 and S. schwerinii clone 77-0-77, using cellulysin and macerase in modified Woody Plant medium. For clone 78-0-90, 6.3 · 10⁶ ± 1.9 · 10⁶ protoplasts were obtained per gram fresh weight. Cell divisions started two days after protoplast isolation and gave rise to callus which has been maintained in culture for up to four years. Protoplast yield from the clone 77-0-77 was lower (less than 10⁶ protoplasts per gram cells), cell division was infrequent and no callus was obtained. Protoplasts were also isolated from the leaves of willow shoot cultures using cellulysin and pectolyase, but these did not show cell divisions.Abbreviations BA benzyladenine - 2,4-D 2,4-dichlorophenoxyacetic acid - MS medium Murashige & Skoog (1962) medium - WP medium Woody Plant medium (Lloyd & McCown 1981)     

Protoplast isolation and regeneration in the marine red alga Porphyra nereocystis

We have developed a method for isolating viable protoplasts from the blade phase of the epiphytic marine red alga Porphyra nereocystis Anderson, using a two-step enzymatic digestion with commercially available enzymes. The first step uses papain, the second step uses abalone acetone powder. The method is rapid and gives a high yield of viable protoplasts. In liquid culture in enriched seawater medium, the protoplasts can undergo regeneration along three pathways: they directly form filaments resembling the conchocelis phase of Porphyra; they form calli with relatively thick-walled, pigmented cells; and they indirectly form blades from the edges of these calli. Porphyra nereocystis protoplasts also may serve as an alternative propagation method in aquaculture and be useful for studies of cell-wall formation, cell division, and thallus differentiation. They may also be used in somatic selection, somatic hybridization and gene-transfection experiments.Abbreviations AAP abalone acetone powder - PAP papain - FDA fluorescein diacetate This paper is dedicated to the memory of the late Dr. Munenao Kurogi (1921–1988), Professor Emeritus of Hokkaido UniversityThis research was supported by the Washington Sea Grant Program (National Oceanic and Atmospheric Administration). We thank Professor Y. Fujita (Nagasaki University, Japan), Professor S.-J. Wang (Shanghai University of Fisheries, P.R. China) and Dr. H. Kito (Seikai Regional Fisheries Research Laboratory, Nagasaki, Japan) for sharing their experience with Porphyra protoplast production with us. We thank J.S. Charleston for expert technical assistance in preparation of the electron-microscopy specimens. We also thank Dr. S.K. Herbert and John Carrier (Friday Harbor Laboratories) and Dr. John Merrill and D. Gillingham (American Sea Vegetable Co. and Applied Algal Research, Seattle) for collections of P. nereocystis.     

Efficient plant regeneration from protoplasts isolated from embryogenic suspension cultures of Cyclamen persicum Mill.

A protocol for plant regeneration from protoplasts has been developed, and then successfully applied to different genotypes of Cyclamen persicum Mill. Protoplasts were isolated from embryogenic suspension cultures by enzymatic digestion in 2% cellulase R10 and 0.5% macerozyme R10. Yields obtained varied between 1 and 5 × 10⁵ protoplasts per gram fresh mass depending on the genotype. Protoplasts were immobilized in alginate films, which promoted proper cell wall regeneration. The highest cell division frequencies were found in modified Kao and Michayluk (1975, Planta 126:105–110) medium containing the same types and concentrations of plant growth regulators that were applied for suspension culture (2.0 mg l⁻¹ 2,4-dichlorophenoxyacetic acid and 0.8 mg l⁻¹ 6-(γ,γ-dimethylallylamino)purine). Cell division was recorded for all 11 tested genotypes in frequencies of up to 12% and 18% after 7 and 14 days, respectively. However, cell division frequency varied strongly between different genotypes. After 4–6 weeks calluses were released from the alginate films and further cultured on hormone-containing medium for continued growth or transferred to hormone-free medium for regeneration of somatic embryos. Plant regeneration via somatic embryogenesis succeeded in 9 out of the 11 genotypes under investigation. Up to now protoplast-derived plants from four genotypes have been successfully transferred to soil.     

Sucrose biosynthesis in Dunaliella

Four independent kinds of observations indicate that the cell wall regenerated by oat (Avena sativa L.) and corn (Zea mays L.) protoplasts in culture is less well developed than that regenerated by tobacco (Nicotiana tabacum L.) protoplasts. Following wall regeneration the cereal protoplasts remained susceptible to osmotic shock upon transfer to water, showed great enlargement, stained poorly with calcofluor white, and maintained a positive internal electrical potential. The development of a negative membrane potential by tobacco protoplasts in culture often occurred simultaneously with the onset of cell division. Since division was observed only in protoplasts which had regenerated good cell walls and had re-established negative membrane potentials it is suggested that culture conditions which favor these two processes should improve protoplast viability.     

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     

Transformation of <Emphasis Type="Italic">Platymonas</Emphasis> (<Emphasis Type="Italic">Tetraselmis</Emphasis>) <Emphasis Type="Italic">subcordiformis</Emphasis> (Prasinophyceae,Chlorophyta) by agitation with glass beads

A transient transformation system for the unicellular marine green alga, Platymonas subcordiformis, was established in this study. We introduced the pEGFP-N1 vector into P. subcordiformis with a glass bead method. P. subcordiformis was incubated in cell wall lytic enzymes (abalone acetone powder and cellulase solutions) to degrade the cell wall. The applicable conditions for production of viable protoplasts were pH 6.5, 25°C, and 3 h of enzyme treatment. The protoplast yield was 61.2% when P. subcordiformis cells were added to the enzyme solution at a concentration of 10⁷ cell ml⁻¹. The protoplasts were immediately transformed with the pEGFP-N1 vector using glass-bead method. The transformation frequency was about 10⁻⁵, and there was no GFP activity observed in either the negative or the blank controls. This study indicated that GFP was a sensitively transgenic reporter for P. subcordiformis, and the method of cell wall enzymolysis followed by glass bead agitation was applicable for the transformation of P. subcordiformis.     

Plant regeneration from protoplasts of Enteromorpha intestinalis (Chlorophyta, Ulvophyceae) as seedstock for macroagal culture

A continuous micropropagation was established from protoplasts of thegreen alga Enteromorpha intestinalis. The effects of two differentcrude enzymes and the osmolarity at different concentrations of the enzymesolution on algal protoplast yields were tested. The optimal enzymecomposition for cell wall digestion and protoplast viability was 2%cellulase R 10 Onozuka and 2% Aplysie with 0.5 m mannitol. Largenumbers of Enteromorpha protoplasts were released (10.0 × 10⁶protoplasts from 1 g fresh thalli) and settled on a rangeof substrata. Regeneration of the protoplasts followed the normal patternfor this species. Conditions for pure cultures and efficient systems offloating supports with nets were determined to optimise the product qualityof plantlets of Enteromorpha. A promising storage process has beendeveloped which involves including protoplasts in beads of alginic acid gel.Plants regenerated from protoplasts may also be used as seedstock tofacilitate propagation for macroalgal culture.     

An Improved Protocol for Microcallus Production and Whole Plant Regeneration from Recalcitrant Banana Protoplasts (Musa spp.)

One important limitation for routine production of somatic hybrids in banana (Musa spp.) is the difficulty in protoplast regeneration. To facilitate protoplast regeneration in banana, the crucial step of microcallus production was optimised for the following parameters: nurse culture medium, duration of microcalli on nurse culture, differing nurse cells, and filter composition. A comparative study between two nurse cell media, Ma₂ and PCM, significantly affected the number of microcalli produced, which was 90 × 10³ per Petri dish on Ma₂ with 0.5 μM zeatin and 9.0 μM 2,4 D, and 30 × 10³ per Petri dish on PCM. Moreover, continuous production of microcalli was achieved on Ma₂ and the frequency of embryogenic cell aggregates was higher among microcalli on Ma₂-medium. However, no cell division was observed in protoplasts cultured on Ma₂ in which nurse cells were maintained for 2 weeks suggesting a requirement of effective presence of nurse cells for cell division of banana protoplasts. Use of a filter in conjugation with nurse cells resulted in greater than 7-fold increase in the number of microcalli. Flow cytometry analysis of 124 protoplast-derived plants showed the presence of hexaploid plants (mother plant is triploid) at the frequency of 4%. Together, these data are indicative of the complex factors involved in the regulation of plant cell division and growth. Each individual aspect must be optimised for efficient protocol development.     

Nutritional requirements of protoplast-derived,haploid tobacco cells grown at low cell densities in liquid medium

Preliminary attempts to define a completely synthetic medium able to support divisions of haploid tobacco mesophyll protoplasts at low initial densities have failed. High protoplast concentrations together with large amounts of naphtaleneacetic acid in the medium (3 mg l^-1 NAA) were required for maximal induction of protoplast division. However, cell suspensions derived from haploid protoplasts after four days of preculture at high initial cell densities could be diluted to densities as low as 1–4 cells ml^-1, provided the concentration of NAA in the medium was lowered to below 0.3 mg l^-1. The optimal NAA supply for low cell density growth was affected by the nature of the nitrogen source.A simple minimal medium which supports the growth of these haploid cells with a plating efficiency of 30–40%, independent of the cell density in the range of 1–4 to 3·10⁴ cells ml^-1, has been established. In this medium inositol was the only vitamin stringently required for growth.Growth of cells at low densities was also possible in a medium initially containing 3 mg l^-1 NAA, provided it was conditioned by the growth of protoplasts at high densities. Preliminary experiments with [¹⁴C]NAA showed that the amount of free NAA remaining in the medium after preincubation at high densities was drastically reduced. Simultaneously, NAA conjugates accumulated in the medium. The implications of these results are discussed.Abbreviations BA 6-benzyladenine - EDTA ethylene diaminetetraacetic acid - NAA naphtaleneacetic acid     

Protoplast isolation and culture for somatic hybridization of <Emphasis Type="Italic">Lupinus angustifolius</Emphasis> and <Emphasis Type="Italic">L</Emphasis>. <Emphasis Type="Italic">subcarnosus</Emphasis>

A method for isolation and shoot regeneration from electrofused protoplasts of L. angustifolius and L. subcarnosus was developed. Viable protoplasts were isolated from leaves of in-vitro grown seedlings at an average yield of 6 × 10⁵ protoplasts g⁻¹ fresh weight. Liquid and agarose solidified B5 media were used for protoplast culture. In the liquid-culture system, all tested media, VKM, P1 and KM8p, were applicable for inducing cell division (84% of all tested petri dishes at four weeks) and colony formation. Media containing additional carbohydrates were suitable to produce compact calli with green and brown pigmentations in different combinations. Analysis of callus with molecular markers allowed to identify six somatic hybrids. However, none of the parental-protoplast derived cell colonies could develop shoots. This is the first report on protoplast fusion of L. angustifolius and L. subcarnosus with subsequent shoot regeneration.