Sugar beet guard cell protoplasts demonstrate a remarkable capacity for cell division enabling applications in stomatal physiology and molecular breeding

A highly-efficient protocol for the large-scale isolation ofguard cell protoplasts from sugar beet (Beta vulgaris L.) hasbeen developed. Optimization of conditions for culturing theseprotoplasts resulted in extensive cell division and colony formation,at frequencies exceeding 50%. Plants can subsequently be regeneratedfrom these guard cell-derived colonies. This provides definitiveconfirmation that, in sugar beet leaf protoplast populations,only guard cells are the source of totipotent protoplasts. Thesefindings are the outcome of a directed, non-empirical approachto overcoming plant cell recalcitrance which was initiated byexploiting computer-assisted microscopy to couple in vitro responseto cell origin. The results reaffirm the conclusion that, inplants, extreme degrees of cytodifferentiation need not entailterminal specialization. The responsive nature of this systemcan be ascribed to the unique use of cultures essentially comprisinga single in vivo cell type. A uniform model system has thusbeen created with potential for widespread application. Theirdistinct morphological (and mechanical) features make guardcells a valuable choice for studying various fundamental aspects,not only of stomatal physiology, but also of plant cell (de)differentiation,differential gene expression etc. Furthermore, an applied valuefor such a system can also be envisaged. Results indicate thatthese cells are highly amenable to genetic manipulation techniques.The importance of these observations to our understanding ofplant cell function and behaviour is discussed. Key words: Beta, guard cells, stomatal physiology, totipotency, transformation     

Cell-wall antigens in mesophyll cells and mesophyll-derived protoplasts of sugar beet: possible implication in protoplast recalcitrance?

We have investigated the possible relation between plant cell-wall constituents and the recalcitrance of the cell to regenerate organs and whole plants in vitro. A temporal and spatial expression of several carbohydrate epitopes was observed both within leaf tissue used for protoplast isolation and within new walls reformed by recalcitrant mesophyll protoplasts of sugar beet ( Beta vulgaris L.); these include four pectic epitopes, one xyloglucan (rhamnogalacturonan I) epitope, two carbohydrate motifs of arabinogalactan proteins (AGPs) and callose. The walls of mesophyll cells and newly formed walls of protoplasts were similar with respect to the presence of large amounts of pectins recognized by JIM7 antibodies, the scarcity of JIM5-pectins and the complete absence of LM5-responding pectin molecules. Their main differences were the significantly higher accumulation of LM6-recognizing pectins and the very conspicuous greater accumulation of AGPs and callose in walls deposited by protoplasts than in those synthesized by donor cells.     

Iron deficiency decreases the Fe(III)-chelate reducing activity of leaf protoplasts

The ferric-chelate reductase (FC-R) activity of mesophyll protoplasts isolated from Fe-sufficient (control) and Fe-deficient sugar beet (Beta vulgaris L.) leaves has been characterized. Measurements were made in an ionic environment similar to that in the apoplastic space of the sugar beet mesophyll cells. The FC-R activity of Fe-sufficient and Fe-deficient protoplasts was dependent on light. Fe deficiency decreased markedly the FC-R activity per protoplast surface unit. The optimal pH for the activity of the FC-R in mesophyll protoplasts was in the range 5.5 to 6.0, typical of the apoplastic space. Beyond pH 6.0, the activity of the FC-R in mesophyll protoplasts decreased markedly in both Fe-sufficient and Fe-deficient protoplasts. These data suggest that both the intrinsic decrease in FC-R activity per protoplast surface and a possible shift in the pH of the apoplastic space could lead to the accumulation of physiologically inactive Fe pools in chlorotic leaves.     

Plant regeneration from leaf-derived protoplasts within the Daucus genus: effect of different conditions in alginate embedding and phytosulfokine application

Protoplasts of four Daucus carota subspecies and three wild Daucus species were isolated from 2-week-old shoot cultures during overnight incubation in an enzyme mixture composed of 1 % (w/v) cellulase Onozuka R-10 and 0.1 % (w/v) pectolyase Y-23. Before the culture, they were embedded in autoclave- or filter-sterilized alginate solution. Modified thin alginate layer (TAL) and extra thin alginate film (ETAF) techniques were applied for protoplast immobilization. A rich mineral-organic medium based on the formulation of Kao and Michayluk supplemented with 0.1 mg l^?1 2,4-dichlorophenoxyacetic acid, 0.2 mg l^?1 zeatin, and optionally 100 nM phytosulfokine (PSK), a peptidyl plant growth factor, was used for protoplast culture. Plating efficiency was genotype-dependent and in 40-day-old cultures, it varied from 10 % for Daucus pusillus to 73 % for D. carota subsp. sativus. A considerably higher ability in colony formation was observed in the modified TAL culture system using filter-sterilized alginate and in the presence of PSK in the protoplast culture medium. Plant regeneration through somatic embryogenesis stimulated by PSK application occurred for five out of the seven Daucus accessions used in the present study. We believe our data may facilitate the use of wild Daucus in somatic hybridization with cultivated carrot.     

Computer-Assisted Identification of Protoplasts Responsible for Rare Division Events Reveals Guard-Cell Totipotency

With the use of a computer-controlled microscope system to assist in the positioning and rapid relocation of large numbers of cultured cells, we were able to identify those protoplasts with the capacity to divide within a highly recalcitrant culture in which only a tiny fraction of the total population proceeds to produce viable microcalli. In the cultures used, comprising Beta vulgaris L. (sugar beet) leaf protoplasts, it was confirmed that these cells can be recognized solely on the basis of morphological characters. Therefore, a direct link exists between competence for cell division in vitro and cell type. Divergent callus morphologies and totipotent potential could also be ascribed to distinct protoplast types and hence to cells with a specific origin. The progenitors of the totipotent protoplasts in these cultures have been confirmed as being stomatal guard cells. Consequently, in plants even the most highly adapted living cells clearly retain and can reactivate all of the functional genetic information necessary to recreate the whole organism; an extreme degree of cytodifferentiation is, therefore, no hindrance to expressing totipotent potential. In addition to the considerable practical value of these findings, their implications concerning our understanding of both the control of gene expression and plant cell differentiation and its reversibility are of fundamental significance.     

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.     

Involvement of JIM13- and JIM8-Responsive Carbohydrate Epitopes in Early Stages of Cell Wall Formation

Beta vulgaris L.). The spatial and temporal expression of both antigens was studied in suspension cells used as the source-tissue for protoplast isolation, in suspension- and mesophyll-derived protoplasts, and in cells which developed from both types of protoplast. Immunofluorescence and immunocytochemical-electron microscopic methods revealed that labeling was present in the cell walls of most suspension cells and also in the incipients of cell walls synthesized around the protoplasts. This signal became much more intense as rebuilding of the cell wall progressed during culture. Relatively weaker labeling was observed in the cytoplasm, where it was frequently associated with the vacuolar compartment. Signal intensity varied between individual cells of the same population and in successive stages of development, but was always stronger with JIM13 than with JIM8. The role of JIM13-responsive epitope in the development of suspension-derived protoplasts was further studied by its ability to bind antibody added to cultures of different ages. Both JIM8- and JIM13-responsive epitopes were widespread in sugar beet cells of different origin and stage of cell wall synthesis. These epitopes may play an important role in cell wall formation and growth under in vitro conditions. Received 17 August 1998/ Accepted in revised form 13 January 1999     

Protoplast regeneration from gametophytes and sporophytes of some species in the order Laminariales (Phaeophyceae)

Summary Protoplasts were isolated from sporophytes and from gametophyte cultures of several species in the order Laminariales. For each example, the isolation and culture procedures were investigated systematically, to identify conditions leading to plant regeneration. After dedifferentiation through a filamentous stage, protoplasts isolated from adultLaminaria saccharina sporophytes regenerated polystichous bladelets. In contrast, cells isolated fromLaminaria digitata sporophytes proved recalcitrant in culture, except when the donor plants were undifferentiated sporelings. The most critical factors for protoplast development were the origin of explants, the osmoticum used for cell isolation, cultivation in plain seawater, and the absence of stress during the first two weeks of culture. We also found that protoplast isolation from the sporophytes of members of the Laminariales results in the release of hydrogen peroxide, up to 5–120 μM final concentration in the macerating medium, a characteristic which may be related to protoplast recalcitrance. Protoplasts isolated from the gametophytic phase readily regenerated into normal gametophytes, capable of gametogenesis and producing sporophytes by fertilization.     

The influence of culture conditions on mitotic activity in protoplasts derived fromPisum root cortical explants

Summary Protoplast cultures were prepared from explants of the roots of seedling peas. In defined, synthetic media these cultures were mitotically active. A variety of culture conditions were investigated and the influences of these conditions on the mitotic activity of the protoplasts were observed. Marked inhibition of mitoses were observed after exposure to high light intensities, and in the absence of a proper exogenous supply of hormones. The protoplasts showed extreme sensitivity to the nature and concentration of the exogenous hormone supply. The protoplasts were mitotically active at low population densities (6,000–8,000 protoplasts/ ml of medium). They did not divide in cultures in which glucose was supplied as a carbohydrate source, but divided actively in cultures in which sucrose (2%) was supplied. The responses to temperature and pH were similar to most protoplast systems which have been reported. The definition of a wide variety of optimal culture conditions resulted in high mitotic activity in protoplast cultures with low population densities.     

Direct gene transfer to plant protoplasts by mild sonication

Summary A novel procedure employing mild sonication for transformation of plant protoplasts is described. Transient expression of a chloramphenicol acetyltransferase (CAT) gene in protoplasts of sugar beet (Beta vulgaris L.) and tobacco (Nicotiana tabacum L.) was obtained by a brief exposure of the protoplasts to 20 kHz ultrasound in the presence of plasmid DNA. Maximum levels of CAT activity were achieved by sonication for 500–900 ms at 30–70 W electric power (0.65–1.6 W/cm2 acoustic power). This reduced the viability to 15–20 % and 60 % for sugar beet and tobacco protoplasts, respectively. Up to 12 % (sugar beet) and 81 % (tobacco) of maximum transient expression could be achieved with no significant loss of viability. Protoplasts surviving exposure to ultrasound were found to have a similar long-term viability and to regenerate to micro-calli as untreated protoplasts. Plasmid DNA concentrations of 80–110 g/ml and sucrose concentrations of 21–28 % in the sonication medium were found to be optimal for transient expression.Abbreviations CAT chloramphenicol acetyltransferase     

Effects of fusicoccin and abscisic acid on glucose uptake into isolated beetroot protoplasts

Uptake of glucose, 3-O-methylglucose and sucrose into beetroot protoplasts is considerably stimulated by 10^–6M fusicoccin. This effect is decreased in the presence of 10mM Na⁺ or K⁺, 2 mM Mg²⁺ or Ca²⁺. Whereas fusicoccin causes no change in the pH-optimum of the sugar uptake (pH 5.0), the apparent K_m of this uptake which obeys a biphasic kinetics is decreased by the action of fusicoccin. In the protoplast suspension, fusicoccin induces an acidification which is suppressed by uncoupling agents. Correspondingly, uncouplers as well as vanadate and diethylstilbestrol markedly inhibit the effect of fusicoccin on sugar uptake. The present data support the view that glucose uptake into beetroot protoplasts depend on the proton-pumping activity of the plasmalemma-ATPase. cis–Abscisic acid diminishes significantly the fusicoccin-enhanced glucose uptake. By using a radioimmunoassay, the internal abscisic acid content of the protoplast was estimated to be in the range of 10^–6 M. Protoplasts isolated from bundle tissue contain twice as much abscisic acid as those derived from storage parenchyma. Because protoplasts from the bundle tissue were shown to take up sugars much faster than those from the storage cells, the observed effect of abscisic acid might reflect an involvement of this hormone in the regulation of carbohydrate partitioning in the beet.Abbreviations ABA cis–abscisic acid - bundle protoplast protoplasts isolated from the conducting tissue of beetroots - DES diethylstilbestrol - FC fusicoccin - 3-OMG 3-O-methylglucopyranose - PCMBS p–chloromercuribenzenesulfonic acid - storage protoplasts protoplasts isolated from storage parenchyma     

Isolation of protoplasts and regeneration of callus from suspension cultures of cultivated beets

Conditions necessary for the isolation and culture of protoplasts from suspension cultures of sugar, fodder and garden beets were investigated. Good yields of protoplasts were obtained by treating cells with a mixture of cellulase, Macerozyme and Driselase enzymes. Nutritional requirements of beet protoplasts were found to be quite simple: protoplasts could be cultured in MS, B₅ or PGo based media with 0.4 M glucose with the optimum result being produced on KM8p medium. Plating efficiency (P.E) was genotype-dependent with the sugar beet giving better P.E. than the fodder or garden beets used, and higher values being achieved with the use of desalted Driselase for isolation followed by culture on KMBp medium.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - BAP N⁶ benzylaminopurine - NAA naphthaleneacetic acid - P.E. plating efficiency - * University of Birmingham beet germplasm accession number     

Uptake of protoplasts from the filamentous fungiAspergillus nidulans andFusarium oxysporum into protoplasts from celery (Apium graveolens L.)

Summary Protoplasts isolated from celery cell suspension cultures, were mixed with fungal protoplasts, from either the saprophytic speciesAspergillus nidulans or the pathogenic speciesFusarium oxysporum. The incubation of protoplast mixtures with PEG caused close adhesion between plant and fungal protoplasts. Subsequent dilution of PEG resulted in the uptake of protoplasts from either fungal species into the plant protoplast cytoplasm. A range of PEG concentrations, incubation times and dilution rates were tested to maximise adhesion and uptake frequencies. Identification of uptake was achieved either by fluorescent staining of nuclei or by electron-microscopy. A maximum of 10% celery protoplasts had taken upA. nidulans protoplasts after PEG treatment. Fungal protoplasts were taken up into celery protoplast cytoplasm by endocytosis, and were maintained within vesicles; two bounding membranes were observed by electron microscopy. Plant protoplast viability was determined during prolonged incubation following fungal protoplast uptake. The presence ofA. nidulans protoplasts tended to maintain celery protoplast viability and although some morphological disintegration occurred intact celery protoplasts remained for at least 92 h after uptake. The uptake ofF. oxysporum protoplasts markedly depressed celery protoplast viability after 24 h incubation and greater celery protoplast disintegration occurred.Abbreviations PEG Polyethylene glycol - DAPI 4,6-diaminido-2-phenylindole - 2,4-D 2,4-dichlorophenoxyacetic acid     

Improvement of protoplast culture protocols for Beta vulgaris L. (sugar beet)

Summary The effects of NaCl, feeder cells and the embedding of protoplasts in calcium alginate have been investigated in an attempt to improve culture conditions of recalcitrant sugar beet (Beta vulgaris L.) mesophyll protoplasts. While the use of NaCl in all instances proved detrimental to protoplast development, the other two treatments had clear beneficial effects. Minimum plating densities, necessary to sustain cell division, could be reduced to <5% (<4000 protoplasts / ml) of the control levels and plating efficiencies could be significantly enhanced by approx. 10 fold. Plants could still be regenerated from soft calli derived from mesophyll protoplasts cultured under the modified conditions at a frequency of 20–30 %. In particular, the use of alginate is considered of potentially great importance for the further application of beet protoplasts for other aims e.g. asymmetric hybridization.     

Plant regeneration from highly embryogenic callus,cell suspension and protoplast cultures of Trifolium fragiferum

Using various media, tissue and protoplast cultures plant regeneration systems were developed for Trifolium fragiferum (2n=16). (L.). The best media for induction of embryogenic cultures were based on Kao (1977) or Kao and Michayluk (1975). Somatic embryogenesis was observed in cultures derived from green leaf mesophyll protoplasts of branching plants, somatic embryo protoplasts and cell suspension protoplasts, leaflets and various explants of immature zygotic embryos. The process of somatic embryogenesis was maintained for over two years on Murashige and Skoog's (1962) medium supplemented with 0.5 mg l^-1 benzyladenine and 0.05 mg l^-1 naphthaleneacetic acid. These long term cultures were capable of regenerating plants that were fertile and produced seeds. These results were compared with those from protoplast, tissue and organ culture of other species of the Trifolium genus. This revised version was published online in June 2006 with corrections to the Cover Date.     

Progress in plant protoplast research

During the past years plant regeneration from protoplasts was achieved for a number of important crops (maize, sorghum, rice, wheat, sugar beet). The use of embryogenic tissue for protoplast isolation greatly contributed to this success. There was also some progress in woody plant species and ornamentals. Fusion of protoplasts resulted in may fertile hybrid plants, especially in the Brassicaceae and Solanaceae. These somatic hybridization studies led to introduction of new agronomical traits from sexually incompatible species into the cultivar gene pool and to new nucleus-organelle compositions. The limitations of somatic hybridization, mainly imposed by the taxonomic distance of the parents, and expressed as chromosome loss and reduced fertility, are more clearly recognized now. Asymmetric hybridization with irradiated donor protoplasts resulted in cybrids with new cytoplasmic traits (e. g. intraspecific fusions in Brassica ), as well as in the transfer of only a few donor choromosomes (e. g. intrageneric fusions in Nicotiana ). Most intrageneric fusions, however, resulted only in a limited elimination of donor chromosomes (e. g. in Lycopersicon ), and polyploidization occurred (e. g. in Nicotiana ). Also some success on protoplast transformation was obtained in both monocots and dicots. Fertile transgenic rice plants (Japonica, Indica) were produced after direct gene transfer into protoplasts derived from embryogenic cell suspensions. Particle gun experiments using embryogenic cell suspension of maize resulted in fertile transgenic plants. Transformation of citrus and lettuce by direct gene transfer was also reported.     

Transfer of cytoplasm from newBeta CMS sources to sugar beet by asymmetric fusion

Summary For our program on the transfer of cytoplasmic male sterility (CMS) by cybridization inBeta vulgaris L. (sugar beet), we have developed a procedure for the isolation and culture of mesophyll protoplasts of sugar beet followed by shoot regeneration. A prerequisite proved to be the presence in the media of n-propylgallate (nPG), a lipoxygenase inhibitor. Sustained divisions were found in all accessions that were tested. Plating efficiencies and regeneration ability varied greatly from one experiment to the other and appeared to be accession-dependent. Shoots could be easily transferred to soil. A majority of the regenerants (72%) retained the diploid chromosome number. Somaclonar variation in phenotype was low (4.9%). Mitochondrial DNA probes, capable of discriminating different cytoplasms ofBeta spp. showed no rearrangements due to the protoplast and in vitro culture phase, indicating that these probes can be used to identify cybrids after asymmetric fusions. The data presented here open up possibilities for genetic engineering using protoplasts in one of the world's most important arable crops.     

Gallus Regeneration from Protoplasts of Sugar Beet(Beta vulgaris)

Conditions appropriate for isolation and culture of protoplasts from cell suspension cultures of sugar beet (Beta vulgaris L. ) were investigated. Protoplasts with high yields and high quality were obtained by treating cells with a mixture of cellulase, macerozyme R-10 and driselase, or other enzyme combinations. Protoplasts were cultured in MS liquid medium or solid agar medium. Callus was obtained from the cultured protoplasts.     

几种植物原生质体的扫描电镜观察

扫描电镜观察表明,分离自马铃薯、萱草。甘蔗、木薯和落花生等不同植物和组织的原生质体表面呈现不同程度的凹凸不平。马铃薯叶肉原生质体表面较粗糙,其余四种植物叶肉、幼茎或子叶原生质体稍光滑。有的原生质体显现不同程度的凹陷现象。有的原生质体表面尚残留有未完全水解的胞壁碎片。在木薯幼茎原生质体制备物中见有呈“裂片”状的球形结构。原生质体表面扫描图象的差异似与不同种植物有关,与组织源不同更有密切关系。 原生质体镀膜前,涂布于已镀膜的盖玻片支持物上的原生质体很少或无凹陷现象,涂布于已镀膜的双面胶支持物上的原生质体凹陷严重。     

Plant regeneration via somatic embryogenesis from protoplasts of six explants in Coker 201 (<Emphasis Type="Italic">Gossypium hirsutum</Emphasis>)

Fertile regenerated plants were obtained from protoplasts via somatic embryogenesis in Coker 201 (Gossypium hirsutum L.). Protoplasts were isolated from six different explantsleaves, hypocotyls, young roots, embryogenic callus, immature somatic embryos and suspension cultures and cultured in liquid thin layer KM8P medium. Callus-forming percentage of 20–50% was obtained in protoplast cultures from embryogenic callus, immature embryos and suspension cultures, and visible callus formed within 2 months. Callus-forming percentage of 5–20% in protoplast cultures from young roots, hypocotyls and leaves, and visible callus formed in 3 months. NAA 5.371 μM/kinetin 0.929 μM was effective to stimulate protoplast division and callus formation from six explants. Percentage of callus formation in the medium with 2,4-D 0.452 μM/kinetin 0.465 μM was over 40% from suspension cultures and immature embryos, 25% from embryogenic callus and 10% from hypocotyls. Callus from protoplasts developed into plantlets via somatic embryogenesis. Over 100 plantlets were obtained from protoplasts derived from 6 explants. Ten plants have been transferred to the soil, where they all have set seeds.