Somatic hybridization in higher plants

Summary Somatic hybridization in higher plants has come into focus since methods have been established for protoplast fusion and uptake of foreign DNA and organelles by protoplasts. Polyethylene glycol (PEG) was an effective agent for inducing fusion. Treatment of protoplasts with PEG resulted in 5 to 30% heterospecific fusion products. Protoplasts of different species, genera and even families were compatible when fused. A number of protoplast combinations (soybean + corn, soybean + pea, soybean + tobacco, carrot + barley, etc.) provided fusion products which underwent cell division and callus formation. Fusion products initially were heterokaryocytes. In dividing heterokaryocytes, random distribution of mitotic nuclei was observed to be accompanied by multiple wall formation and to result in chimeral callus. Juxtaposition of mitotic nuclei suggested nuclear fusion and hybrid formation. Fusion of heterospecific interphase nuclei was demonstrated in soybean + pea and carrot + barley heterokaryons. Provided parental protoplasts carry suitable markers, the fusion products can be recognized. For the isolation and cloning of hybrid cells, fusion experiments must be supplemented with a selective system. Complementation of two nonallelic genes that prevent or inhibit growth under special culture conditions appears as the principle on which to base the selection of somatic hybrids. As protoplasts of some species have been induced to regenerate entire plants, the development of hybrid plants from protoplast fusion products is feasible and has already been demonstrated for tobacco. Presented in the formal symposium on Somatic Cell Genetics at the 27th Annual Meeting of the Tissue Culture Association, Philadelphia, Pennsylvania, June 7–10, 1976.     

A comparative study on the ultrastructure of cultured cells and protoplasts of soybean during cell division

Summary Cultured soybean cells recovered from a marked decrease in cell division 20 hours after removal of their cell walls with enzymes and exhibited sustained mitotic activity. Mitosis was essentially similar in both cultured cells and protoplasts. At prophase microtubules aggregated in a clear zone surrounding the nucleus prior to forming the spindle. During metaphase and anaphase chromosomal microtubules were attached to diffuse kinetochores and extended to broad spindle poles; few interzonal microtubules were evident. Considerable endoplasmic reticulum was present at the spindle poles throughout division and may contribute to the new nuclear envelope at telophase. A typical phragmoplast consisting of vesicles, overlapping microtubules and associated electron-dense material appeared earlier in the protoplasts and developed into a thicker cell plate than found in the cultured cells.Supported by the National Research Council of Canada, Grant A6304.     

Somatic hybridization in higher plants.

Somatic hybridization in higher plants has come into focus since methods have been established for protoplast fusion and uptake of foreign DNA and organelles by protoplasts. Polyethylene glycol (PEG) was an effective agent for inducing fusion. Treatment of protoplasts with PEG resulted in 5 to 30% heterospecific fusion products. Protoplasts of different species, genera and even families were compatible when fused. A number of protoplast combinations (soybean + corn, soybean + pea, soybean + tobacco, carrot + barley, etc.) provided fusion products which underwent cell division and callus formation. Fusion products initially were heterokaryocytes. In dividing heterokaryocytes, random distribution of mitotic nuclei was observed to be accompanied by multiple wall formation and to result in chimeral callus. Juxtaposition of mitotic nuclei suggested nuclear fusion and hybrid formation. Fusion of heterospecific interphase nuclei was demonstrated in soybean + pea and carrot + barley heterokaryons. Provided parental protoplasts carry suitable markers, the fusion products can be recognized. For the isolation and cloning of hybrid cells, fusion experiments must be supplemented with a selective system. Complementation of two non-allelic genes that prevent or inhibit growth under special culture conditions appears as the principle on which to base the selection of somatic hybrids. As protoplasts of some species have been induced to regenerate entire plants, the development of hybrid plants from protoplast fusion products is feasible and has already been demonstrated for tobacco.     

Conifer somatic embryogenesis for studies of plant cell biology

Summary Embryogenic cultures have been produced for a wide range of conifers and current methods developed for spruce permit the maturation of high quality embryos that can be desiccated and then germinated to form plantlets. Embryogenic suspensions consisting of immature embryos are an excellent source of regenerable protoplasts. This review considers examples of applications of embryogenic suspension cultures for basic studies in three areas of plant cell biology. a) Immunofluorescence studies of microtubules in mitotic spruce cells reveal focused spindle poles at prophase and anphase, suggesting the presence of microtubule organizing centers (MTOCs). Antibodies known to recognize animal MTOCs do not stain the polar regions but do stain developing kinetochores. b) Embryo-derived protoplasts regenerate directly to somatic embryos. Fluorescence studies of the cytoskeleton in freshly derived protoplasts reveal random cortical microtubules and a fine network of actin filaments. During culture, protoplasts change shape and develop transverse cortical microtubule arrays. Embryonal cells of newly formed embryos possess distinctive arrays of cortical microtubules and networks of fine actin filaments while suspensor cells are characterized by transverse cortical microtubules and longitudinal actin cables. c) Transmission electron microscope studies of endocytosis in spruce protoplasts reveal an endocytotic pathway similar to that described previously for soybean. Uptake results are confirmed using high pressure freeze fixation instead of conventional chemical fixation. Presented in the Session-in-Depth Morphogenesis: Plant Cell and Tissue Differentiation at the 1994 Congress on Cell and Tissue Culture, Research Triangle Park, NC, June 4–7, 1994.     

Immunological methods for the agglutination of protoplasts from cell suspension cultures of different genera

Summary Protoplasts from cell suspension cultures of Vicia hajastana Grossh., soybean (Glycine max L.) and brome grass (Bromus inermis Leyss.) were tightly agglutinated by immune sera prepared against them in rabbits. After incubation, the aggregated protoplasts became adpressed over a considerable area of their surface. Antibody prepared against Vicia protoplasts agglutinated both Vicia and soybean protoplasts alone, as well as a mixture of the two. Soybean and bromegrass antibody likewise cross-reacted with and agglutinated Vicia protoplasts. The heterologous reactions were nearly as strong as, and in some cases stronger than, the homologous. When sheep anti-rabbit globulin was reacted with a mixture of the protoplasts previously coated with homologous antibody, agglutination occurred much more quickly and the aggregates could not be dispersed without physical damage. Carbol-fuchsin staining of nuclei showed that Vicia and soybean protoplasts were randomly mixed in the aggregate. The protoplasts were viable and underwent division after the antibody treatment. The immune serum, which presumably contained complement, lysed the protoplasts unless it was heat-treated prior to use.Issued as NRCC No. 13168.     

Activation of glyoxalase I during the cell division cycle and its homology with auxin regulated genes

In several plant systems increase in glyoxalase I activity has been correlated with cell proliferation. Cell cycle studies of tobacco protoplasts indicate a rise in glyoxalase I activity prior to G₂/M phase. Further, synthetic auxin, NAA, induced glyoxalase I activity and cell division significantly. This induction was specific in response to auxin only. Cytokinins alone do not induce cell division or increase enzyme activity. Analysis of glyoxalase I cDNA sequence from soybean shows significant homology with auxin inducible genes particularly Nt107 and limited but strong similarity with identified plant mitotic cyclins, implicating glyoxalase I in possible relationship with certain cell division regulating factors.     

Evaluation of parameters affecting the yield, viability and cell division of Pinus pinaster protoplasts

Various factors affecting the yield and viability of Pinus pinaster Ait. cotyledon protoplasts and the mitotic activity of or regenerated cells are described. A study of the effect of sterilization procedures of the plant material showed that whereas the organs collected from disinfested seedlings allow for good yield and viability of isolated protoplasts, germination under non-sterile conditions favours a greater germinating capacity and stronger mitotic activity. Numerous clusters of from 10 to 15 cells were formed after 20 days of culture when a 5% aqueous solution of calcium hypochlorite was used as a sterilizing agent.
The effects of an additional purification of the enzymes showed that although yield and viability of the protoplasts are only slightly improved, the more highly purified enzymes on the other hand enhanced the mitotic activity markedly. Between the two total enzyme concentrations used (0.2 and 0.4%, and in which the relative ratio of each element was unchanged), only the lowest level supplied a debris-free protoplast suspension; mitotic activity occurred only in that case.
Comparison of the populations of cotyledon protoplasts collected from seedlings at two different growth stages (not fully-developed or fully-expanded cotyledons) did not reveal any appreciable difference in their size distribution. Neither was the extent of cellular viability affected by the degree of cell differentiation at the time of collecting. On the other hand, the yield of protoplasts and the mitotic activity of the regenerated cells were greater when partially-developed organs were used. Moreover a pretreatment of the elongating cotyledons with a mineral (half-strength MS macronutrients and full-strength micronutrients) and hormonal (15 μ M BAP, 0.5 μ M NAA) solution improved cell division frequency.     

Protoplasts as tools in cell biology

Studies of plant protoplasts using both fluorescent dyes and electron dense probes have demonstrated endocytosis in plants. Ultrastructural work with soybean protoplasts using cationized ferritin (CF) revealed an endocytotic pathway from coated pits at the plasma membrane to coated vesicles, the partially coated reticulum, Golgi bodies, multivesicular bodies and finally the vacuole. Endocytosis may be responsible for membrane retrieval from the cell surface or degradation of elicitors or toxins during host-pathogen interactions. Immunofluorescence studies of dividing plant protoplasts have provided new information about the preprophase band (PPB) of microtubules and the shape of spindles. Studies of PPBs in soybean protoplast cultures permitted detailed examination of PPB development and an assessment of the usefulness of the PPB index for identifying morphogenic cultures. In multinucleate protoplasts the size and number of PPBs were apparently not controlled by nuclear number. Research with conifer protoplasts resulted in the discovery of new features of gymnosperm spindles.     

Callus production from photoautotrophic soybean cell culture protoplasts

Summary Protoplasts were prepared from a photoautotrophic (PA) cell line of Glycine max (soybean). A yield of 75 to 90% after two to three hours digestion in a mixture of 1% Cellulase R10, 0.2% Pectolyase Y23 and 2% Driselase was obtained. Cell division and colony formation occurred from approximately 18% of the plated protoplasts. The cultured protoplasts were as sensitive to the herbicide atrazine, a photosynthetic inhibitor, as the original PA cells under the same conditions. Protoplasts and cells of a heterotrophic (HT) soybean culture were not as sensitive to atrazine. The isolated protoplasts retained the PA characteristics of the parental culture in the callus and cell suspension cultures obtained from the protoplasts. The chromosome numbers in the parental cell line and in cells derived from the isolated protoplasts (both PA and HT) were found to be largely (99%) the normal diploid number of 40.Abbreviations BA Benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid - HT Heterotrophic - MES 2-(morpholino) ethane sulfonic acid - NAA Naphthaleneacetic acid - PA Photoautotrophic - PCM Protoplast culture medium     

Cell division and differentiation in protoplasts from cell cultures of Glycine species and leaf tissue of soybean

Protoplasts were isolated from cell cultures of G. soja and G. tabacina, respectively. The isolation procedure employed Percoll for the separation and concentration of protoplasts. The cultured protoplasts formed cells which developed into embryo-like structures. Protoplasts also were isolated from leaf tissue of soybean cv. Williams 82. Upon culture, the protoplasts regenerated cell walls and divided to form cell cultures.Abbreviations 2,4-D 2,4-Dichlorophenoxyacetic acid BA|Benzyladenine - BA Benzyladenine     

Fusion between interphase and mitotic plant protoplasts : Induction of premature chromosome condensation

Morphological changes in interphase nuclei were cytologically studied in heterophasic dinucleate cells formed by the fusion of mitotic and interphase plant protoplasts. Mitotic protoplasts were isolated from a partially synchronized suspension culture of wheat (Triticum monococcum). The mitotic cells were accumulated by colchicine after release of hydroxyurea block. Treatment of protoplast populations with polyethylene glycol-dimethyl sulphoxide solution resulted in metaphase-interphase fusion. Three hours after fusion, the appearance of chromosomes with single chromatid as well as of fragmented, pulverized chromatin in heterophasic cells indicated the induction of premature chromosome condensation (PCC) in somatic wheat cells. Condensation in interphase nuclei of mitotically inactive rice protoplasts was also detected after fusion with mitotic wheat protoplasts.     

Structural and ultrastructural analysis of Solanum lycopersicoides protoplasts during diploid plant regeneration

Light, fluorescence and electron microscopy were used to analyse the structural properties of protoplasts obtained from established suspension culture of Solanum lycopersicoides Dun, composed of meristematic cell aggregates. Four types of protoplasts were distinguished immediately after isolation: (1) mononuclear; (2) polynuclear, (3) anuclear and (4) homogeneous protoplasts. Only mononuclear protoplasts were capable of complete cell wall regeneration and mitotic division. Other types of protoplasts were eliminated during culture. Three phases were distinguished in the developing protoplast culture: (1) the elimination phase during which protoplasts damaged during isolation underwent complete degradation; (2) a phase of intense division during which both mitotic cell division and amitotic nuclear division took place; and (3) a stabilization phase leading to the formation of suspension culture. The cell suspension culture obtained from protoplasts was capable of regenerating diploid plants.     

Temporary inhibition of cell wall synthesis improves the transient expression of the GUS gene in Brassica napus mesophyll protoplasts

Transformation of Brassica napus mesophyll protoplasts was performed with the ß-glucuronidase gene fusion system. After electroporation, transient expression in protoplasts transformed directly after isolation was about 1 to 2 per million. By the use of 2,6-dichloro-benzonitrile, a non-toxic inhibitor of cell wall synthesis, and in the presence of 5% polyethyleneglycol, transformation of the cell material was performed three days after isolation. At that time, about 25–30% of the protoplasts had reached the first S-phase of the mitotic cycle. A 1000 fold increase of protoplasts expressing the ß-glucoronisidase gene transiently was obtained, in the partly synchronized protoplasts, compared to those transformed directly after isolation.Abbreviations CAT Chloroamphenicol acyltransferase - 2,6-DB 2,6-Dichlorobenzonitrile - EP-buffer electroporation buffer - GUS ßglucoronisidase - PEG Polyethylene glycol - PJ propidium iodide - Xgluc 5-bromo-4-chloro-3-indolyl glucoronide     

Controlled cell wall regeneration for efficient microinjections of Nicotiana tabacum var. Carlson protoplasts

Nicotiana tabacum var. Carlson protoplast culture conditions were modified to contain a cell wall inhibitor, 2,6-dichlorobenzonitrile, in order to delay cell wall regeneration and to allow efficient nuclear and cytoplasmic microinjections. Under modified conditions, the protoplast preparations appeared healthier as compared to the control protoplasts and showed no resistance at all during microinjection. Furthermore, the duration of protoplast microinjection was extended for up to 3–4 days. In order to set up nuclear microinjections, the nuclei of these protoplasts were stained either before or after immobilization without any adverse effect on their mitotic activity. Successful cytoplasmic microinjections were demonstrated by injecting Alfalfa mosaic virus (AMV) RNA, which resulted in viral infection of 14% of the injected protoplasts.Abbreviations AMV Alfalfa Mosaic virus - BAP 6-benzylaminopurine - 2,4-D 2,4-dichlorophenoxy-acetic acid - DB 2,6-dichlorobenzonitrile - LR lissamine rhodamine - NAA 1-naphthalene-acetic acid     

The isolation and culture of protoplasts from an embryogenic cell suspension culture of Picea glauca (moench) voss

Conditions were standardized for the isolation and culture of protoplasts from an embryogenic cell suspension culture of Picea glauca. A combination of 0.5% Cellulase R-10, 0.25% Macerozyme, 0.25% Driselase, 0.25% Rhozyme HP-150 with 0.5M mannitol and 5 mM CaCl₂.2H₂O produced an average of 4.5 × 10⁶ protoplasts per gram fresh weight of cells. Of the several protoplast culture media tested, von Arnold and Eriksson and Kao and Michayluk (KM8P) media best supported mitotic divisions of protoplasts. A density of 10⁵ protoplasts per ml and the addition of 5 mM glutamine to the culture medium was necessary to induce sustained divisions and microcallus formation. Microcalli grew into subculturable callus using a nurse culture technique.Abbreviations BAP benzylaminopurine - 2,4-D 2,4-dichlorophenoxy-acetic acid - FDA fluorescein diacetate NRCC No. 27937     

An ultrastructural investigation on the polyethylene glycol-induced adhesion of tobacco nuclei and uptake of micronuclei by soybean protoplasts

Nuclei isolated from tobacco protoplasts were induced to be taken up by soybean protoplasts using a protocol involving polyethylene glycol (PEG), osmotic shock and pH shift. Transmission electron microscopy revealed that PEG treatment condensed the chromatin of the isolated nuclei. Close adhesion of isolated nuclei to the plasma membrane of protoplasts following PEG treatment, was observed by both scanning and transmission electron microscopic methods. Ultrastructural observations were also made on the formation of micronuclei in tobacco cells following the treatment with amiprophosmethyl (APM). Nuclei and micronuclei isolated from APM-treated cells were induced to be taken up by soybean protoplasts. A single case of uptake of an isolated micronucleus was observed by transmission electron microscopy. The observations on the effects of PEG on the isolated nuclei, micronuclei and protoplasts are discussed in relation to the possible mechanism of uptake of nuclei by protoplasts using PEG.     

Culture of soybean mesophyll protoplasts in alginate beads

Mesophyll protoplasts were isolated from leaves of 10 day old aseptically grown soybean seedlings, or from surface disinfested leaves of 3 week old plants grown in environmental chambers. The protoplasts were encapsulated in 2mm diameter Ca alginate beads. Immobilized protoplasts were induced to divide by culturing in shaker flasks containing an actively growing soybean cell suspension. The feeder cell suspension supported the division of protoplasts independent of the protoplast density in the Ca alginate beads. At day 18 after encapsulation, the alginate matrix was dissolved, releasing viable callus colonies. The feeder cell suspension obviated plating of protoplasts at high density which is usually required for subsequent cell division and colony development. Since the protoplasts were embedded at low density, the cell colonies were derived from single cells.     

cis-regulatory elements involved in ultraviolet light regulation and plant defense.

An elicitor-regulated transient expression system was established in soybean protoplasts that allowed the identification of cis-regulatory elements involved in plant defense. The 5' region of an ultraviolet (UV) light-inducible and elicitor-inducible chs gene (chs1) of soybean was subjected to deletion analysis with the help of chimeric chs-nptII/gus gene constructs. This analysis delimited the sequences necessary for elicitor inducibility to -175 and -134 of the chs1 promoter. The same soybean sequences were able to direct elicitor inducibility in parsley protoplasts, suggesting a conserved function of cis-acting elements involved in plant defense. In addition, this region of the soybean promoter also promotes UV light inducibility in parsley protoplasts. However, in contrast to the elicitor induction, correct regulation was not observed after UV light induction when sequences downstream of -75 were replaced by a heterologous minimal promoter. This result indicates that at least two cis-acting elements are involved in UV light induction.     

Visualization of elicitor-binding loci at the plant cell surface

We describe a method which allows the visualization of elicitor-binding loci at the surface of plant protoplasts. Prerequisites for this method are the preparation of protoplasts under conditions of minimal proteolysis, and the availability of antibodies against either the elicitor itself or against the fluorescein portion of elicitor-fluorescein conjugates. Silver enhancement is used to amplify the visibility of 5-nm gold particles which are attached to an appropriate secondary antibody. Bound elicitor can then be visualized by epipolarization microscopy. This method, designated SEIG-EPOM (for silver enhanced immunogold as viewed by epipolarization microscopy), has been applied to protoplasts of parsley (Petroselineum cirspum L.), using the Phytophthora megasperma elicitor, and soybean (Glycine max Merr.) using polygalacturonic acid elicitor isolated from citrus pectin. We have been able to estimate the number of specific binding loci as being less than 100 per protoplast. Such loci possibly represent clusters of individual elicitor-receptor complexes. Structurally related elicitors have been shown to compete effectively for binding sites. The latter are sensitive to proteolysis, as is the elicitation response of protoplasts.Dedicated to Professor Peter Sitte on the occasion of his 65th birthday     

The morphology of multivesicular bodies in soybean protoplasts and their role in endocytosis

Summary Multivesicular bodies (MVBs) in soybean protoplasts are distinct organelles (generally 250–500 nm in diameter) consisting of a limiting membrane and a number of smaller internal vesicles (generally 40–100 nm in diameter). MVBs of soybean protoplasts are morphologically similar to MVBs of animal cell systems. They can have tubular protuberances which extend from the main body of the organelle and a lamellar plaque on the cytoplasmic surface of their limiting membrane. In addition, the internal vesicles can be labeled by a zinc iodide-osmium tetroxide postfixation and may form via invagination of the limiting membrane.The MVBs of soybean protoplasts are a major compartment in the endocytotic pathway. They accumulate, over time, exogenously applied cationized ferritin and may deliver it to the major lysosomal or lytic compartment of the plant cell, namely, the vacuoles.