通过“供体—受体”原生质体融合将裸燕麦部分核基因组转移给普通小麦

本文进行了小麦和裸燕麦悬浮细胞原生质体的电融合,并基于双亲失活（用ＩＯＡ处理受全小麦原生质体,用γ－射线照射供体裸燕细胞系）,获得可能的杂种愈伤组织。对７块愈伤组织进行了乙醇脱氢酶（Ａｄｈ）同工酶筛选,发现５块表现出双亲特征酶带。对３个杂种细胞系进行５种同工酶分析,证实它们均为稳定的不对称体细胞核杂种细胞系;它们表现出小麦的完整谱带和裸燕麦的部分谱带。对２个杂种细胞系及亲本的核糖体ＤＮＡ Ｓｏｕｔ     

通过“供体-受体”原生质体融合将裸燕麦部分核基因组转移给普通小麦(英文)

本文进行了小麦和裸燕麦悬浮细胞原生质体的电融合,并基于双亲失活(用IOA处理受体小麦原生质体,用γ-射线照射供体裸燕麦细胞系),获得可能的杂种愈伤组织。对7块愈伤组织进行了乙醇脱氢酶(Adh)同工酶筛选,发现5块表现出双亲特征酶带。对3个杂种细胞系进行5种同工酶分析,证实它们均为稳定的不对称体细胞核杂种细胞系;它们表现出小麦的完整谱带和裸燕麦的部分谱带。对2个杂种细胞系及亲本的核糖体DNA Southern分析结果表明只有一个杂种细胞系(HB 95)含有双亲的全部谱带。细胞学观察表明,2个杂种细胞系的染色体数目均显著高于双亲。从杂种细胞系HB 94中分化出叶原基等分化结构。Adh同工酶分析表明,这些分化结构具有和母体细胞系完全相同的杂种谱带。     

小麦与燕麦不对称体细胞杂交的研究

以小麦品种济南177的悬浮细胞系(长期继代培养已丧失分化能力)来源的原生质体混合同品种胚性愈伤组织(分化能力较强, 约70%)制备的原生质体为受体, 以经300 mW/cm²紫外线照射0.5, 1, 2, 3, 5 min的普通燕麦愈伤组织(分化频率很低, 约10%)原生质体作供体, 用PEG法诱导融合. 可高频率地获得体细胞杂种细胞系, 并分化获得绿色正常的再生植株, 经荧光原位杂交、 同工酶及5S rDNA间隔序列分析, 确认了它们为体细胞杂种. 单独使用小麦胚性悬浮系或愈伤组织为受体获得的杂种克隆均未能得到绿色植株.     

单个原生质体融合系中变异体的不断形成

亲缘品种间原生质体的融合可产生有用的体细胞杂种植株。然而,远缘品种间原生质体的融合常常导致遗传不亲和性,这可能引起亲本之一染色体的快速消失。日本京都大学和京都医科大学的T.Endo等人发现,单个族间融合产物产生的愈伤组织系可能是连续遗传不稳定性的一个来源。他们分离出了由Duboisia hopwoodii细胞悬浮培养原生质体与烟草叶肉原生质体之间融合产生的单个杂种细胞。从融合产物长出了愈伤组织,从这些愈伤组织产生了10个     

普通小麦与玉米不对称体细胞杂交的研究

以长期继代培养,经分化实验证明无分化能力的普通小麦（Triticum aestivum L.)济南177原生质体为受体,以经380uW/cm^2紫外线处理的继代第3－5天的墨西哥黑甜玉米（Zea mays L.cv.Sccharina F.Nigera)胚性悬浮组织原生质体为供体,使用PEG的方法诱导融合。融合再生的18个单细胞克隆的愈伤组织经形态学比较、染色体检查、同工酶分析、5S rRNA间隔序列分析,确认克隆1为杂种愈伤组织,杂种愈伤组织再生出来的白化苗未进行杂种鉴定。同时,初步探讨了紫外线对玉米原生质体的影响。     

混合小麦亲本与新麦草不对称体细胞杂交体系的建立

以小麦品种济南177悬浮细胞系来源的原生质体与同品系胚性愈伤组织制备的原生质体混合后作为受体;以经过380μＷ/ｃｍ²紫外线照射1min、2min的新麦草原生质体分别作为供体,用PEG法诱导融合。组合Ⅰ(176+cha9+新麦草UV 1min)获得16个再生克隆。经过形态学、同工酶、染色体和RAPD分析,确定其全部为属间体细胞杂种。其中的5个克隆再生杂种植株。用7对小麦SSR引物对杂种克隆的叶绿体基因组进行了分析;组合Ⅱ(176+cha9+新麦草UV 2min)只获得3个克隆,且逐渐褐化死亡。表明以小麦济南177的两种培养细胞混合作受体的融合体系有利于杂种的获得及再生;紫外线对融合产物的生长发育有明显的剂量效应。     

普通小麦与簇毛麦不对称体细胞杂交的研究

以不同浓度(0～2.5mmol/L)碘乙酰胺(IOA)处理的小麦(Triticum aestivum L.)原生质体为受体,以经6krad(130rad/min)⁶⁰Co-γ射线处理的继代后4～5d期簇毛麦(Haynaldia villosa)愈伤组织原生质体为供体,使用PEG法诱导细胞融合。融合细胞经培养形成细胞团、愈伤组织或植株。通过形态学比较、染色体检查及同工酶分析,确认了得到的愈伤组织和再生植株为体细胞杂种。     

烟草和枸杞属间原生质体电融合再生杂种植株

烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ Ｌ．）叶肉原生质体和枸杞（Ｌｙｃｉｕｍ ｂａｒｂａｒｕｍ Ｌ．）悬浮细胞原生质体在适宜电场条件下能以４％ —５％ 的频率发生异质融合。用过氧化物酶和超氧歧化酶同工酶方法对随机选取的１００ 个细胞系进行分析,发现杂种愈伤组织形成频率为９％ 。其中５个杂种细胞系具有分化能力,再生出大量丛生小苗。这些小苗多数在形态上兼有双亲特征并难以生根和长大。叶片酯酶同工酶分析表明,其中２ 个杂种细胞系（ＮＬ４ 和ＮＬ８）再生苗含有一条双亲没有的重组酶带。对亲本和杂种细胞系ＮＬ４ 的细胞学观察结果表明,杂种细胞系的染色体数目为２ｎ＝ ５５—８０,明显高于亲本。对亲本及ＮＬ４ 和ＮＬ８ 愈伤组织的基因组ＤＮＡ 进行ｒＤＮＡ Ｓｏｕｔｈｅｒｎ 杂交发现,ＮＬ８ 含有双亲的全部谱带,且在３．０ ｋｂ 处出现１ 条新带;ＮＬ４ 没有枸杞的特征带,但在３．０ ｋｂ 和５．５ ｋｂ 处出现２ 条新带,说明这两个杂种中的双亲ｒＤＮＡ 可能已发生分子间重组。从ＮＬ４ 愈伤组织得到４ 株形态上近似烟草的完整植株,并移栽成活     

普通小麦与无芒雀麦不对称体细胞杂交的研究

普通小麦（ＴｒｉｔｉｃｕｍａｅｓｔｉｖｕｍＬ．）９９Ｐ原生质体与经紫外线照射的无芒雀麦（ＢｒｏｍｕｓｉｎｅｒｍｉｓＬｅｙｓ）愈伤组织来源的原生质体用ＰＥＧ法诱导融合。融合再生的３个单细胞克隆（Ｎｏ．１～Ｎｏ．３）经染色体、同工酶和ＲＡＰＤ分析表明,它们均为杂种细胞系。Ｎｏ．１克隆形成的愈伤组织分化出大量白化苗,其叶片同工酶和ＲＡＰＤ分析均出现双亲特征谱带及新带,白化苗的染色体数目为４２～５４,大于亲本小麦,并具有无芒雀麦的小染色体和染色体断片,确认它们为不对称体细胞杂种。     

小麦胚性悬浮系与原生质体植株再生

普通小麦(Triticum aestivum)昌乐5号(冬性)胚性悬浮细胞系的组成成分对原生质体再生频率发生影响,此种悬浮系是由混合型愈伤组织建立起来的,建成的悬浮系中含有2—3mm的小愈伤组织和分散好的几十至上百个细胞的细胞团。分别用悬浮系中的小愈伤组织和细胞团分离原生质体进行培养。结果表明．由小愈伤组织来源的原生质体再生植株的频率显著高于由细胞团分离的原生质体的再生频率。培养基中不同成分对原生质体分裂的影响也作丁研究。     

Callus Formation from Somatic Hybridization of Wheat (Triticum aestivum L.) and Ryegrass (Lolium perenne L.) by Electrofusion

Somatic hybrid calli were recovered following electrofusion of protoplasts from a chloroplast-containing cell suspension culture of wheat (Triticum aestivum L.) and a cell suspension culture of ryegrass (Lolium perenne L.). The protoplasts of wheat were inactivated by iodoacetamide; in addition morphology and colour were used as markers to aid selection of putative hybrid calli. For isozyme analysis of putative hybrids, nine isozymes were tested for differences in bands between the parental lines. Of these, three showed differences (ADH, GOT, SDH). Analysis of ADH bands of calli indicated that six lines were hybrids. These lines were analysed with the ,ther isozymes, and at the DNA level by Southern hybridisation with a wheat ribosomal DNA probe. The overall results indicated that one line was an almost complete combination of the genomes of the parental lines, but the other 5 lines were probably partial hybrids. In the latter, some loss of the wheat genome had probably occurred.     

Regeneration of asymmetric somatic hybrid plants from the fusion of two types of wheat with Russian wildrye

Two types of protoplasts of wheat (Triticum aestivum L. cv. Jinan 177) were used in fusion experiments—cha9, with a high division frequency, and 176, with a high regeneration frequency. The fusion combination of either cha9 or 176 protoplasts with Russian wildrye protoplasts failed to produce regenerated calli. When a mixture of cha9 and 176 protoplasts were fused with those of Russian wildrye, 14 fusion-derived calli were produced, of which seven differentiated into green plants and two differentiated into albinos. The morphology of all hybrid plants strongly resembled that of the parental wheat type. The hybrid nature of the cell lines was confirmed by cytological, isozyme, random amplified polymorphic DNA (RAPD) and genomic in situ hybridization (GISH) analyses. GISH analysis revealed that only chromosome fragments of Russian wildrye were transferred to the wheat chromosomes of hybrid calli and plants. Simple sequence repeat (SSR) analysis of the chloroplast genome of the hybrids with seven pairs of wheat-specific chloroplast microsatellite primers indicated that all of the cell lines had band patterns identical to wheat. Our results show that highly asymmetric somatic hybrid calli and plants can be produced via symmetric fusion in a triparental fusion system. The dominant effect of two wheat cell lines on the exclusion of Russian wildrye chromosomes is discussed.Abbreviations GISH Genome in situ hybridization - RAPD Random amplified polymorphic DNA - SCF Small chromosome fragment - SSR Simple sequence repeat     

Somatic hybridization between birdsfoot trefoil (Lotus corniculatus L.) and L. conimbricensis Willd

Summary Somatic hybrid plants were produced by fusion of birdsfoot trefoil (Lotus corniculatus) cv Leo and L. conimbricensis Willd. protoplasts. Birdsfoot trefoil etiolated hypocotyl protoplasts were inactivated with iodoacetate to inhibit cell division prior to fusion with L. conimbricensis suspension culture protoplasts. L. conimbricensis protoplasts divided to form callus which did not regenerate plants. Thus, plant regeneration from protoplast-derived callus was used to tentatively identify somatic hybrid cell lines. Plants regenerated from three cell lines exhibited additive combinations of parental isozymes of phosphoglucomutase, and L. conimbricensis-specific esterases indicating that they were somatic hybrids. The somatic chromosome number of one somatic hybrid was 36. The other somatic hybrid exhibited variable chromosome numbers ranging from 33 to 40. These observations approximate the expected combination of the birdsfoot trefoil (2n=4x=24) and L. conimbricensis (2n=2x=12) genomes. Somatic hybrid flowers were less yellow than birdsfoot trefoil flowers and had purple keel tips, a trait inherited from the white flowered L. conimbricensis. Somatic hybrids also had inflorescence structure that was intermediate to the parents. Fifteen somatic hybrid plants regenerated from the three callus lines were male sterile. Successul fertilization in backcrosses with birdsfoot trefoil pollen has not yet been obtained suggesting that the hybrids are also female sterile. This is the first example of somatic hybridization between these two sexually incompatible Lotus species.Formerly USDA-ARS, St. Paul, Minn, USA     

Somatic hybridization in the gramineae: Pennisetum americanum (L.) K. Schum. (Pearl millet) +Panicum maximum Jacq. (Guinea grass)

Summary Protoplasts from Pennisetum americanum resistant to S-2-amino-ethyl-l-cysteine (AEC) were fused with protoplasts of Panicum maximum utilizing polyethylene glycol-dimethylsulfoxide after inactivation of the Pennisetum protoplasts with 1 mM iodoacetic acid. The iodoacetate treatment prevented division of Pennisetum protoplasts; therefore, only Panicum protoplasts and heterokaryons potentially could give rise to colonies. A second level of selection was imposed by plating 3–4-week-old colonies on AEC medium. Putative somatic hybrid calli were analyzed for alcohol dehydrogenase, 6-phosphogluconate dehydrogenase, aminopeptidase, and shikimate dehydrogenase isozymes. Three somatic hybrid cell lines (lines 2, 3, and 67) were identified which showed two bands of alcohol dehydrogenase activity representing homodimers of P. maximum and P. americanum as well as a novel intermediate band of activity where Panicum-Pennisetum heterodimers would be expected. Aminopeptidase and shikimate dehydrogenase were useful for identifying presumptive hybrid calli but the isozyme patterns were additive-evidence which would not preclude the selection of chimeric callus. A more complex isozyme pattern which varied among the somatic hybrids was observed for 6-phosphogluconate dehydrogenase. In the hybrid calli, the presence of DNA sequences homologous to both P. maximum and P. americanum sequences was confirmed by hybridization of a maize ribosomal DNA probe to XbaI and EcoRI restriction fragments. Growth of hybrid lines on various concentrations of AEC was either similar to the AEC-resistant parent (hybrid line 2) or intermediate between the resistant and sensitive parents (hybrid lines 3, 67).     

Production and characterization of fertile somatic hybrids of eggplant (Solanum melongena L.) with Solanum aethiopicum L.

Summary In order to produce fertile somatic hybrids, mesophyll protoplasts from eggplant were electrofused with those from one of its close related species, Solanum aethiopicum L. Aculeatum group. On the basis of differences in the cultural behavior of the parental and hybrid protoplasts, 35 somatic hybrid plants were recovered from 85 selected calli. When taken to maturity either in the greenhouse or in the field, the hybrid plants were vigorous, all rapidly overtopping parental individuals. The putative hybrids were intermediate with respect to morphological traits, and all of their organs were larger, particularly the leaves and stems. DNA analysis of the hybrids using flow cytometry in combination with cytological analysis showed that 32 were tetraploids, 1 hexaploid and 2 mixoploids. The hybrid nature of the 35 selected plants was confirmed by a comparison of the isoenzyme patterns of isocitrate dehydrogenase (Idh), 6-phosphogluconate dehydrogenase (6-Pgd) and phosphoglucomutase (Pgm). Chloroplast DNA (ctDNA) restriction analysis using Bam HI revealed that among the 27 hybrid plants analyzed, 10 had S. aethiopicum patterns and the 17 remaining hybrids exhibited bands identical with those of eggplant without any changes. All of the somatic hybrid plants flowered. Both parental plants had 94% stainable pollen, while the hybrids varied widely in pollen viability ranging from 30% to 85%. The somatic hybrids showed high significant variation in fruit production. Nevertheless, there was a tendency for low fertility to be associated often with S. aethiopicum chloroplast type and/or with an abnormal ploidy level, while good fertility was mostly associated with the tetraploid level and eggplant chloroplasts. Interestingly, 2 tetraploid somatic hybrid clones were among the most productive, yielding up to 9 kg/plant. As far as the fertility of the F₁ sexual counterpart was concerned, only 2 fruits of 50 g were obtained. Hybrid fertility in relation to phylogenetic affinities of the fusion partners is discussed.     

Rapid alterations of DNA sequence and cytosine methylation induced by somatic hybridization between Brassica oleracea L. var. italica and Brassica nigra (L.) Koch

Somatic hybrids were produced between hypocotyl protoplasts of Brassica oleracea L. var. italica (broccoli) and mesophyll protoplasts of B. nigra (black mustard) using polyethylene glycol—mediated protoplast fusion. A total of fifteen somatic hybrids derived from six calli (no. 1, 3, 8, 21, 38 and 44) were obtained. Cytological analysis showed that all the hybrids possessed 2n = 34, the sum of the parental chromosomes and the genomic in situ hybridization analysis revealed their BBCC genome constitutes. Moreover, all the hybrids exhibited different type of meiosis abnormalities, which were more usually observed in pollen mother cells at metaphase II/anaphase II (MII/AII, 16.1–39.6 %) than at metaphase I/anaphase I (MI/AI, 7.8–15.2 %). Simple sequence repeat analysis revealed that all the hybrids showed the same cytoplasmic genome as broccoli. Structure and methylation-variation of the nuclear were investigated by amplified fragment length polymorphism (AFLP) and DNA methylation-sensitive amplification polymorphism (MSAP). Our results indicated that all the hybrids mainly had the AFLP and MSAP banding patterns from the addition of two parents plus some alterations. The incidences of the AFLP polymorphic bands in the hybrids showed a range of 9.8–18.7 % while the DNA methylation alteration in the hybrid no. 38 was 4.07 %. This result suggested that somatic hybridization could induce more DNA sequence changes than methylation alterations in the early stage of allotetraploid hybrids.     

Production and characterization of somatic hybrid plants between leek (Allium ampeloprasum L.) and onion (Allium cepa L.)

 Results are reported on the production and characterization of somatic hybrids between Allium ampeloprasum and A. cepa. Both symmetric and asymmetric protoplast fusions were carried out using a polyethylene-based mass fusion protocol. Asymmetric fusions were performed using gamma ray-treated donor protoplasts of A. cepa and iodoacetamide-treated A. ampeloprasum protoplasts. However, the use of gamma irradiation to eliminate or inactivate the donor DNA of A. cepa proved to be detrimental to the development of fusion calli, and thus it was not possible to obtain hybrids from asymmetric fusions. The symmetric fusions yielded a high number of hybrid calli and regenerated plants. The analysis of the nuclear DNA composition using interspecific variation of rDNA revealed that most of the regenerated plants were hybrids. Flow cytometric analysis of nuclear DNA showed that these hybrid plants contained a lower DNA content than the sum of the DNA amounts of the parental species, suggesting that they were aneuploid. A shortage of chromosomes in the hybrids was confirmed by genomic in situ hybridization. Chromosome counts in metaphase cells of six hybrids revealed that these plants lacked 2–7 leek chromosomes. One hybrid showed also the loss of onion chromosomes. The hybrids had an intermediate phenotype in leaf morphology. The application of these somatic hybrids in breeding is discussed. Received: 7 April 1997 / Accepted: 10 September 1997     

Mixing of maize and wheat genomic DNA by somatic hybridization in regenerated sterile maize plants

Intergeneric somatic hybridization was performed between albino maize (Zea mays L.) protoplasts and mesophyll protoplasts of wheat (Triticum aestivum L.) by polyethylene glycol (PEG) treatments. None of the parental protoplasts were able to produce green plants without fusion. The maize cells regenerated only rudimentary albino plantlets of limited viability, and the wheat mesophyll protoplasts were unable to divide. PEG-mediated fusion treatments resulted in hybrid cells with mixed cytoplasm. Six months after fusion green embryogenic calli were selected as putative hybrids. The first-regenerates were discovered as aborted embryos. Regeneration of intact, green, maize-like plants needed 6 months of further subcultures on hormone-free medium. These plants were sterile, although had both male and female flowers. The cytological analysis of cells from callus tissues and root tips revealed 56 chromosomes, but intact wheat chromosomes were not observed. Using total DNA from hybrid plants, three RAPD primer combinations produced bands resembling the wheat profile. Genomic in situ hybridization (GISH) using total wheat DNA as a probe revealed the presence of wheat DNA islands in the maize chromosomal background. The increased viability and the restored green color were the most-significant new traits as compared to the original maize parent. Other intermediate morphological traits of plants with hybrid origin were not found.     

Intergeneric Somatic Hybrid Plants of Nicotiana tabacum L. and Lycium barbarum L. by Protoplast Electrofusion

Mesophyll protoplasts of Nicotiana tabacum L. and protoplasts from cell suspension of Lycium barbarum L. were heterofused by electrofusion with a frequency of ca. 4%--5%. One hundred cell lines were selected at random identified by isozyme analysis with peroxidase and superoxide dismatase, and the differences from their parent were found. Results indicated that 9 cell lines expressed enzymatic bands characteristic of both parents. Five of the 9 cell lines were highly morphogenic and regenerated numerous young shoots that manifested morphological traits specific to both parents. However, these shoots never grew up or regenerate roots. Esterase analysis of leaf material from the regenerants of 5 morphogenic hybrid cell lines demonstrated that two of them (NL4 and NL8) expressed an unique hybrid band which were not shown in either parents. Cytological observation on parental and NL4 hybrid cell lines revealed that the somatic chromosome number of NL4 varied from 58 to 80, significantly higher than that of either parents. Ribosomal DNA analysis of NL4 and NL8 showed that NL8 covered all fragments of both parents: NL4 did not have the fragments characteristic of Lyciurn barbarurn L. Both hybrids had new fragments, suggestive of intermolecular recombination of rDNAs of the parents. Four normal plants morphologically similar to tabacco parent were obtained from hybrid cell hne NL4, which survived after being transferred to soil. Cytological analysis of root-tips from one of the plants indicated that it has ca. 58 chromosomes. This paper also discussed the problems on the production frequency and incompatibility of somatic cell hybrid.