Isolation and Fusion of Sperm Cells in Several Bicellular Pollen Species

Living sperm cells were isolated in large quantities from the pollen tubes, grown by the in vivo-in vitro technique in 8 bicellular pollen species belonging to 5 families. An “osmotic shook weak enzyme treatment” method could effectively release sperms from pollen tubes and favor sub sequent purification. The viable sperm yields were up to 82.9% in Zephyranthes candida and 78.2% in Hemerocallis minor. Fusions were successfully induced by polyethylene glycol (PEG) according to the "small-scale fusion" procedure in various combinations, viz., between the same sperm cells in 5 species, between sperm cells of Gladiolus gandavensis and Hippeastrum vitta turn, between sperm cells and microspore protoplasts in Hemerocallis minor, and between sperm cells of H. vittatum and microspore protoplasts of Hemerocallis fulva. Test with fluorochrome reaction, more than 85% of the fusion products of sperm cells in Z. candida were viable. The yieid of viable fusion products between sperm cells and microspore protoplasts in Hemerocallis minor was about 75% and half of them could survive after culture for 24h. The induction of fusion between sperm cells and petal protoplasts in G. gandavensis by a combined PEG-dimethyl sulfoxide (DMSO) treatment was investigated in detail. About 90% of the fusion products thus obtamed were viable. Several critical factors affecting the fusion efficiency were studied. These included the ratio of sperm cell number to petal protoplast number in the mixture, concentrations of PEG and DMSO, and duration of incubation in the inducing solution. It appeared that addition of DMSO could significantly increase the fusion frequency, and that there may be a synergistic effect between PEG and DMSO. This is the first attempt to use isolated sperm cells for fusion studies in bicellular pollen species.     

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.     

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.     

Protoplast fusion and the cell cycle

Protoplasts isolated from rapidly dividing cell suspension cultures of either Nicotiana sylvestris or tumor derived cultures of Crepis capillaris were fused by PEG or liposome treatments to form homokaryons. Analysis of binucleates by Feulgen microspectrophotometry, and autoradiography, has revealed that whereas fusion products of all cell cycle combinations occur, protoplasts of certain cycle phases participate in fusions more frequently than expected, and there is a slight predominance of like-with-like cycle combinations. It is argued that this tendency towards specificity of fusion may be explained by cycle related variation in surface charge on protoplasts, and the mechanisms of action of the fusogens used.Abbreviations PEG polyethylene glycol - CAPT tumorous cell culture of Crepis capillaris - NS-1 cell culture of Nicotiana sylvestris     

Single-Pair Fusion of Various Combinations Between Female Gametoplasts and Other Protoplasts in Nicotiana tabacum

This paper reports an enzymatic maceration-osmotic shock method for isolation of tobacco embryo sac and its component cell protoplasts, and also a new method for fusion between single pairs of selected mesophyll protoplasts using polyethylene glycol (PEG) as on inducing agent. An integration of these two methods has led to the successful fusion of female gametoplasts with other kinds of protoplasts. The female gametoplasts described here, in a broad sense, include the egg cell (E), central cell (C) and synergid (S). One of the female gametoplasts was selected and fused with another female, male (generative cell, G) or somatic (mesophyll, M)protoplast. Various combinations were involved: E+S, E+C, E +G, E+M, C+C, C+S, C+G, C+M, S+S, S+G, S+M, etc. Briefly, the authors were able to choose any desired combination to realize single-pair fusion by the new PEG method. For the purpose of culturing such fusion products that were limited in number, the authors had done some preliminary experimets using mesophyll protoplasts as feeder cells. Two methods were adopted: the microdrop culture, and the millicell culture with feeder cells. The mesophyll protoplasts were precultured for 2—3 days in large for population expansion before they were used as feeder cells. One or several protoplasts were cultured in a microdrop or a millicell and were induced formation of small cell clusters. This result indicated that the culture methods might also be suitable for culturing the products from fusion of female gametoplasts and other protoplasts in this plant species.     

Interspecies protoplast fusion inLarix: Comparison of electric and chemical methods

Summary Larix was chosen for the study on interspecies protoplast fusion due to its ability to regenerate plants from protoplasts derived from embryogenic cultures.L. laricina line L2 was used in fusion experiments with eitherL. × eurolepis line L6 orL. × leptoeuropaea line L5. A method of unambiguous labeling of parental protoplasts prior to fusion was developed using vital fluorescent dyes. Of a number of dyes tested, only rhodamine B hexyl ester chloride (R6) and 3,3′-dihexylox-carbocyanine iodide (DiOC₆) stained the protoplasts in a consistent and uniform fashion. The fusion of mixed parental protoplasts that were internally labeled was carried out either in the presence of a 20% polyethylene glycol (PEG) solution or in an electric field. The progress of fusion was readily observed, taking only minutes under the experimental conditions. The fusion products could be identified by dual fluorescence several h after the onset of fusion. Heterofusion frequencies of approximately 18% and 6% in the presence of PEG and an electric field, respectively, were attained. Postfusion cultures betweenL. × laricina protoplasts and protoplasts ofL. × leptoeuropaea gave rise to cell colonies and betweenL. laricina andL. × eurolepis, to mature somatic embryos.     

Regeneration of Hybrid Plantlets Via Pollen-Hypocotyl Protoplast Fusion in Brassica spp.

It has been reported that "gameto-somatic hybridization" was induced by fusion of microspore tetrad protoplasts with somatic protoplasts in Nicotiana and Petunia. However, since the success of isolation of pollen protoplasts in recent years, the use of protoplasts at pollen stage as one of the fusion partners in such hybridization is a novel experimentation. Young pollen protoplasts were isolated from the pollen grains of Brassica chinensis at mid-late unicellular to early bicellular stage the pollens for 1.5--2.5 h at 25℃ in a CPW solution containing 0.8 % of eellulase, 0.5 % pectinase, 0.1% pectolyase, 1 3 % mannitol, 1 0 % glucose, 0. 3% potassium dextran sulphate and 3 mmol/L MES. The purified pollen protoplasts were then fused with the hypocotyl protoplasts of B. napus by PEG method. Heterokaryons were identified by means of visualization of the fluorescence from FITC-prela-beled pollen protoplasts. In order to increase heterokaryons and reduce hypocotyls homokaryons, the denstity of hypocotyl protoplasts were lowered and the ratio of the number of hypocotyl vs. pollen protoplasts were adjusted from 1 : 3 to 1 : 6. The fusion products were cultured in a liquid KM8p medium supplemented with 0.4 mol/L glucose, 0.8 mg/L 2, 4-D, 0.25 mg/L NAA. 0. 5 mg/L BA, 500 mg/L glutamine and 3 mmol/L MES where cell division and callus formation took place. The calli, after being transferred to a MS medium supplemented with 2.0 mg/L BA, 3 % sucrose and 0.4 % agarose, differentiated into a few shoots. The shoots were transferred onto a half-strength MS medium supplemented with 2% sucrose, 0.1--0. 2 mg/L NAA, 0.5 mg/L IBA and 20% potato juice for root formation. Finally, three plantlets were regenerated. Chromosome counts by roottip squash method revealed that one plantlet was 2n= 48, corresponding to an allotriploid resulted from a fusion between one pollen protoplast of B. chinensis (2n = 20) and one hypocotyl protoplast of B. napus (2n = 38), and the other two plantlets were 2n = 58, which might be an allotetraploid originated from a fusion between two pollen protoplasts and one hypocotyl protoplast. The isozyme patterns of leaf esterases showed that all the three plantlets had bands characteristic of both parents. This is the first case of success in "gameto-somatic hybridization" by using pollen protoplasts rather than tetrad protoplasts as the haploid partner.     

Fine structure of fusion products from soybean cell culture and pea leaf protoplasts

Protoplasts from pea (Pisum sativum L.) leaves and cultured soybean (Glycine max L.) cells were fused by means of polyethylene glycol and subsequently cultured for one week. Both agglutinated protoplasts and cultured fusion products were examined by electron microscopy. Agglutination occurred over large areas of the plasma membranes. The membrane contanct was discontinuous and irregularly spaced. Many cultured fusion products regenerated cell walls and divided to form cell clusters. Fusion of pea and soybean interphase nuclei occurred in some cells. The detection of heterochromatin typical of pea in the synkaryon, even after division, suggests the cells were hybrids. The cytoplasm of the cells from the fusion products contained both soybean leucoplasts and pea chloroplasts. The chloroplasts had apparently ceased dividing and some showed signs of degenerating. Large multinucleate fusion products developed cell walls but failed to divide.Abbreviations PEG polyethylene glycol - SEM scanning electron microscopy - TEM transmission electron microscopy Supported by National Research Council of Canada, Grant A6304     

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.     

草木樨状黄芪和木本霸王的科间体细胞杂交

在成功培养原生质体的基础上,用改进的PEG-高pH高钙法诱导草木樨状黄（Astragalus melilotoides）和木本霸王（Zygophyllum xanthoxylum）原生质体融合,得到了科间体细胞杂种融合细胞。采用罗丹明-6G预处理草木樨状黄芪原生质体以及UV-B辐照霸王原生质体,使双亲原生质体及其同源融合产物均不能持续分裂而死亡,融合后的杂种细胞由于生理互补可恢复持续分裂能力而被筛选出来。融合产物经培养分裂获得了2个杂种细胞系,其中1个分化出芽。染色体计数和分子鉴定证明了杂种的真实性。初步比较了杂种细胞系及亲本对盐分和水分胁迫的耐受性,结果表明杂种细胞系对盐分和水分胁迫的耐受性介于两个亲本之间。     

草木樨状黄芪和木本霸王的科间体细胞杂交

在成功培养原生质体的基础上, 用改进的PEG-高pH高钙法诱导草木樨状黄芪(Astragalus melilotoides)和木本霸王(Zygophyllum xanthoxylum)原生质体融合, 得到了科间体细胞杂种融合细胞。采用罗丹明-6G预处理草木樨状黄芪原生质体以及UV-B辐照霸王原生质体, 使双亲原生质体及其同源融合产物均不能持续分裂而死亡, 融合后的杂种细胞由于生理互补可恢复持续分裂能力而被筛选出来。融合产物经培养分裂获得了2个杂种细胞系, 其中1个分化出芽。染色体计数和分子鉴定证明了杂种的真实性。初步比较了杂种细胞系及亲本对盐分和水分胁迫的耐受性, 结果表明杂种细胞系对盐分和水分胁迫的耐受性介于两个亲本之间。     

Polyethylene Glycol-induced Uptake of Bacteria into Yeast Protoplasts

Cells of the nitrogen-fixing bacterium Azotobacter vinelandii and the unicellular cyanobacterium Anacystis nidulans were introduced into protoplasts of Saccharomyces cerevisiae by the polyethylene glycol (PEG) method. Factors influencing the uptake frequency were examined, and experimental conditions were established for maximizing the uptake frequency. Under optimal conditions, each protoplast took-up a few bacterial cells. Electron-microscopic studies showed the localization of integrated bacterial cells in membrane-bound vesicles of the cytoplasm or large vacuoles. The protoplasts at the intermediate stages of uptake revealed two major mechanisms of uptake: (a) “endocytosis” by a single protoplast and (b) “cell fusion” between two or more protoplasts. Some bacterial cells disintegrated during the subsequent incubation period through a heterophagy-like process.     

Structural features of isolated generative cells and their protoplasts from pollen of some liliaceous plants

Large quantities of intact generative cells and their protoplasts were isolated from pollen protoplasts of four liliaceous plants, and their structural features were investigated. The generative cells, liberated from the vegetative cell cytoplasm of the pollen protoplasts, were initially spindle-shaped with two long, oppositely oriented extensions, and were surrounded by two cell membranes, one on each side of a wall of uniform thickness. The generative nuclei, stained with 4′,6-diamidino-2-phenylindole (DAPI), showed ellipsoidal and highly condensed chromatin, whereas the generative cell cytoplasm, whose quantity was widely different from species to species, showed no fluorescence, suggesting the absence of plastid and mitochondria! DNA, although many mitochondria were present. The isolated generative cells, which were spindle-shaped at first, became spherical in shape in vitro. Immunocytochemistry and transmission electron microscopy revealed that this change was associated with the depolymerization of an axial array of microtubules present in generative cells in situ. These results are discussed in relation to the function of the generative cell within the bicellular pollen of angiosperms.     

Electron microscopic study of plant-animal cell fusion

Summary Avian erythrocytes and protoplasts isolated from mesophyll cells of tobacco plants were suspended in 1% protease, agglutinated with polyethylene glycol (PEG) and subsequently fused upon elution of the PEG. The fusion reaction was monitored by scanning (SEM) and transmission (TEM) electron microscopy. SEM studies showed a marked difference in the topography of agglutinated cells. During, and subsequent to fusion, the markedly different surfaces of the two cell types became homogeneous and lines of demarcation between the cells were no longer visible. TEM revealed that adhesion occurred over the entire membrane area between agglutinated cells. Incipient fusion was evidenced by the appearance of vacuoles at the intermembrane surfaces. During initial elution of the PEG, cytoplasmic channels between erythrocytes and protoplasts were evident. With continued elution of the PEG, starch-containing plant chloroplasts and starch grains were seen within erythrocytes and homogenous erythrocyte cytoplasm was present inside plant protoplasts. Cytoplasmic mixing between the two cell types occurred within 3 hours of elution. The frequency of interkingdom fusion was estimated to be 0.5–1%.     

In Vitro Divisions of Unfertilized Central Cells and Other Embryo Sac Cells in Nicotiana tabacum var macrophylla

The embryo sacs and female cells could be isolated from the unfertilized ovules of Nicotiana tabacum L. var. macrophylla which were treated in a solution containing 1.5 % cellulase R- 1O, 1% macerozyme R-10, 10% mannitol, 10 mmol/L CaCI:, pH 5.8 for 3 h followed by given slight pressure with a micropipette. The central cells could be kept viable for 10 h and the egg cells for 3 h in 10% mannital. Sometimes, the in situ fusion products of egg cell and synergid protoplasts could be obtained and kept viable for at least 5 h. The high concentration (20 mg/L) of 2, 4-D was used in enzyme solution to induce the division of the unfertilized central cells and other megagametophytic cells in subsequent culture. Treatment of 2,4-D together with enzymatic maceration of ovules was proved to be better than its direct treatment of isolated embryo sac or its component cells. Isolated embryo sacs were cultured in microchambers (Millicell-CM PICM 012 50 MILLIPORE) feeded with divided mesophyll protoplasts of Nicotiana rustica L. The medium was KMSp medium supple- mented with 1% glucose, 0.1 mol/L mannitol, 0.1 mol/L sorbitol, 0.25 mol/L sucrose, 1 mg/L BA, 6% to 10% coconut water, and 0.15% low gelling agarose. Division of central cells, antipodal cells and the in situ fusion products of egg cell and synergid protoplasts were induced. The unfertilized central cell was for the first time to be induced in vitro to develop into small cell clusters.     

烟草未受精中央细胞及其它胚囊细胞的离体分裂

自70年代中期以来,未传粉子房和胚珠的离体培养已在多种植物中取得成功,得到的单倍体植株来源于胶囊中的卵细胞、助细胞以及反足细胞。而分离的未受精胚囊及其成员细胞的离体培养虽屡经尝试,迄今只有Kranz等诱导了玉米未受精卵细胞分裂形成小愈伤组织,至于中央细胞与其它雌配子体细胞则无离体分裂的报道。本文报道大叶烟草未受精中央细胞首次培养成细胞团及其它胚囊细胞启动离体分裂的实验结果。     

Protoplast fusion of Schizosaccharomyces pombe auxotrophic mutants of identical mating-type

Summary Protoplasts of methionine-and lysine-requiring h^- mutants isolated from the L972 h^- strain of Schizosaccharomyces pombe were fused. The protoplasts were obtained from the cells with enzymes produced by Trichoderma viride. When a mixture of the protoplasts was treated with 30% PEG 4000 solution containing 10 mM CaCl₂, cell fusion and complementation was attained with a frequency of 0.17%. Both fusion partners were recovered among the spores after crossing of the fusion products with the strain M210 ade6 h⁺. Cytological and haploidization examinations showed that the fusion cells are not heterokaryons, and that the increased amount of genetic material is situated in one nucleus.     

High frequency of fusion induced in freely suspended protoplast mixtures by polyethylene glycol and dimethylsulfoxide at high pH

Fusion of freely suspended protoplast mixtures (hypocotyl protoplasts of Brassica napus mixed with mesophyll protoplasts of either B. campestris or Nicotiana plumbaginifolia) was induced by a solution containing 10% polyethylene glycol, 10% dimethyl-sulfoxide and 0.1M glycine-NaOH buffer (pH 10.0). The fusion products represented 15 to 17 percent of the surviving cells. More than 50% of the fusion products divided within two days after fusion, indicating that the fusion procedure did not significantly affect the viability of fused cells. The fusion products were not bound to the surface of the fusion vessel, so they could be isolated with a micropipette immediately after fusion.Abbreviations PEG polyethylene glycol - DMSO dimethylsulfoxide     

Ultrastructure of fusion products from soybean cell culture and sweet clover leaf protoplasts

Summary Protoplasts from cultured cells of soybean (Glycine max L.) and from sweet clover (Melilotus officinalis L.) mesophyll cells were fused with polyethylene glycol and subsequently cultured for six days. The resulting fusion products as well as unfused protoplasts of each parental species regenerated cell walls and divided. The fusion products were characterized by the presence of soybean leucoplasts and sweet clover chloroplasts. The chloroplasts appeared to be degenerating but other cytoplasmic organelles were typical of actively growing plant cells. The fate of individual nuclei could not be determined.Supported by National Research Council of Canada, Grant A6304     

Recovery and development of parasexual fusion products inEnteromorpha linza (L.) J. Ag. (Ulvales,Chlorophyta)

Newly released zoospores fromEnteromorpha linza (L.) J. Ag. lack significant cellulose cell wall material and are suitable for treatment as protoplasts in a parasexual fusion process using high pH-Ca^{+ +}, PEG and centrifugation. Treated zoospores settled on glass cover slips within 3 h and were examined microscopically at 1000 ×. Presumptive fusion products were identified by their larger size and presence of twin chloroplasts and eyespots. Unfused zoospores adjacent to fusion cells were killed by 2–3 min exposure to blue light (410–490 nm) from a high pressure mercury illuminator. Unexposed fusion cells developed into uniseriate germlings within 10 days at which stage they could be readily identified at 60 × with a dissecting microscope and isolated by micropipette. Ten-day germlings from both unfused zoospores and fusion cells were stained with the DNA-localizing fluorochrome hydroethidine and relative nuclear DNA content determined with epi-(incident) UV illumination. All germlings were found to be uninucleate. Germlings from unfused zoospores had haploid nuclei with 1N = 10 and 1C and 2C levels of DNA, while germlings from fusion cells had diploid nuclei with 2N = 20 and 2C and 4C levels of DNA. These result are interpreted as evidence of karyogamy following parasexual zoospore fusions. Isolated diploid germlings, cultured for 10 weeks were found to conserve their 2N chromosome complements and elevated levels of nuclear DNA. Although most diploid germlings were morphologically similar to haploid control plants, some exhibited ‘gigas’ characteristics, including larger cells, chloroplasts, and nuclei. These results are discussed in terms of unique phenotypes that result when nuclear and organellar genes are combined in different ways.