柑桔细胞电融合再生两个种间体细胞杂种

朋娜脐橙(Citrussinensis Osbeck)胚性细胞悬浮系原生质体分别与粗柠檬(C.jambhiri Lush)、枸头橙(C.aurantium)叶肉原生质体经电场诱导而融合。经培养,两组合均获得再生植株。对朋娜脐橙+粗柠檬的再生胚状体进行染色体计数,随机取样的52个胚状体中,26个为四倍体,另外26个为二倍体;对74棵再生植株进行染色体计数,由此说明都为四倍体;表明体细胞杂种在植株再生过程中具有明显的竞争优势。朋娜脐橙+枸头橙再生的14棵植株都为四倍体。对朋娜脐橙+粗柠檬部分植株进行POX同工酶和RAPD分析,表明所有检测植株都为杂种。朋娜脐橙+枸头橙再生植株经RAPD分析,表明也为杂种。     

棉花组织培养研究的现状和前景

对棉花组织培养中胚珠（幼）培养和杂种植株获得,体细胞无性系变异和抗性突变体筛选,花药培养和单倍体育种,体细胞胚发生和人工种子的制作,离体棉纤维诱导和超级棉生产,原生质体培养和植株再生等研究进展,问题和前景作了概述。     

原生质体融合获得柑桔种间体细胞杂种

粗柠檬(Citrus jambhiri Lush)叶肉原生质体与哈姆林甜橙(C.sinensis L.Osbeck)胚性悬浮细胞系原生质体经PEG诱导融合,培养7天时原生质体恢复分裂。再生的胚状体在含有GA_3的培养基中萌发出茎芽。茎芽经生根诱导成为完整植株。对首批再生的5棵植株进行染色体检查,结果表明,全为四倍体,2n=4x=36。淀粉胶电泳分析过氧化物酶同工酶,结果显示这5棵植株为体细咆杂种。粗柠檬和哈姆林甜橙在该位点上均为同质结合,基因型分别是MM和FF。体细胞杂种含有双亲的酶带,基因型为MMFF。杂种植株生长旺盛,根系发达,叶片及植株形态介于双亲之间。本文对其作为砧木品种的可能性等问题作了讨论。     

结球白菜下胚轴原生质体培养及其体细胞胚植株再生

结球白菜(Brassica campestris ssp. pekinensis)的原生质体培养由于基因型依赖性强, 细胞易褐化,愈伤组织的芽诱导率低等而难于再生植株。本实验以结球白菜的下胚轴原生质体为试材, 研究了影响其细胞分裂及愈伤组织形成的因素, 探索了经过体细胞胚发生途径获得再生植株的技术。结果表明, 试材的基因型及培养基组成影响细胞分裂及褐化; KM8P是结球白菜原生质体培养更适宜的培养基, 能显著减轻细胞的褐化; 液体培养基中一定浓度的活性炭能在一定程度上减轻细胞褐化进程, 并有利于星状细胞团的形成; 基因型Asko中, 愈伤组织形成体细胞胚的结构, 其发生的频率约为5%, 该类体细胞胚能全部顺利地发育成完整植株。本技术具有再生植株形成容易、频率较高且通过体细胞胚发生途径等优点。     

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.     

结球白菜下胚轴原生质体培养及其体细胞胚植株再生

结球白菜（Brassica campestris ssp．pekinensis）的原生质体培养由于基因型依赖性强,细胞易褐化,愈伤组织的芽诱导率低等而难于再生植株。本实验以结球白菜的下胚轴原生质体为试材,研究了影响其细胞分裂及愈伤组织形成的因素,探索了经过体细胞胚发生途径获得再生植株的技术。结果表明,试材的基因型及培养基组成影响细胞分裂及褐化;KM8P是结球白菜原生质体培养更适宜的培养基,能显著减轻细胞的褐化;液体培养基中一定浓度的活性炭能在一定程度上减轻细胞褐化进程,并有利于星状细胞团的形成;基因型Asko中,愈伤组织形成体细胞胚的结构,其发生的频率约为5％,该类体细胞胚能全部顺利地发育成完整植株。本技术具有再生植株形成容易、频率较高且通过体细胞胚发生途径等优点。     

电融合法产生骆驼刺与鹰嘴紫云英属间体细胞杂种

采用电融合法获得了骆驼刺和鹰嘴紫云英属间体细胞杂种。骆驼刺原生质体来自发根农杆菌A4转化系细胞,并经碘乙酰胺处理;鹰嘴紫云英原生质体从甲硫氨酸抗性系细胞分离。双亲及同源融合产物均不能在无激素的筛选培养基上持续分裂,融合后的杂种细胞由于双亲生理互补效应可恢复持续分裂能力而被筛选出来。本实验优化了电融合参数,如直流脉冲、交流脉冲和脉冲次数。融合产物经培养获得的杂种细胞系经形态学、染色体数目检查、生化及随机扩增多态性DNA分析,鉴定出10个杂种克隆,并从3个杂种克隆再生了小植株。     

电融合获得用于选择抗CTV砧木的酸橙与甜橙体细胞杂种植株

在已知参数条件下,通过电场诱导酸橙(Citrus aurantium L.)叶肉原生质体和沙漠蒂甜橙(C.sinensis Osbeck cv.Shamouti)的胚性愈伤组织原生质体融合,融合产物经培养再生出40棵植株.染色体检查表明所得到的植株具有36条染色体,为四倍体植株.再生植株具有翼叶,叶片厚,表现出多倍体的特征.采用2个10-碱基随机引物鉴别再生植株的杂种特性.在2个引物的扩增带型中,再生植株的随机扩增带图里出现了融合亲本的特征带.对再生植株染色体计数和RAPD分析的结果表明它们是酸橙和甜橙种间异源四倍体体细胞杂种植株.这些体细胞杂种植株的获得为选择具有酸橙优良性状、同时抗CTV的新型砧木提供了好的试材.     

脐橙与柠檬种间细胞电融合再生杂种植株

‘纽荷尔’脐橙（Ｃｉｔｒｕｓｓｉｎｅｎｓｉｓ（Ｌ．）Ｏｓｂｅｃｋ）胚性细胞悬浮原生质体与‘尤力克’柠檬（Ｃｉｔｒｕｓｌｉｍｏｎ（Ｌ．）Ｂｕｒｍ．ｆ）叶肉原生质体经电场诱导融合,培养８个月,首批再生了１棵植株,形态学观察,染色体计数及ＲＡＰＤ分析证明异源四倍体体细胞杂种,该杂种的获得为三倍体无籽柠檬品种培育提供了杂交亲本。     

花椰菜与黑芥种间体细胞杂种的获得和鉴定

利用非对称体细胞杂交技术, 获得芸薹属花椰菜(Brassica oleracea var. botrytis)与黑芥(B. nigra)的种间杂种, 实现了野生种质抗病基因向甘蓝类蔬菜作物的渗透。以具有良好再生能力的花椰菜下胚轴原生质体作为融合受体, 具有抗黑腐、黑胫和根肿病优良性状的黑芥叶肉原生质体作为融合供体, 用不同强度的UV射线处理后, 利用PEG方法诱导供、受体原生质体融合。培养后获得170棵再生植株, 选取来自40个不同愈伤组织的40棵单株进行形态学观察及RAPD和SRAP分子标记检测, 结果表明其中30棵为体细胞杂种。染色体计数显示, 约23%杂种植株的染色体数目小于供、受体染色体数之和。用流式细胞仪测定DNA含量显示, 杂种植株DNA含量是受体的2-4倍, 20%杂种植株DNA含量小于供、受体之和。     

A somatic hybrid plant obtained by protoplast fusion between navel orange (Citrus sinensis) and satsuma mandarin (C. unshiu)

A somatic hybrid plant was obtained by protoplast fusion between navel orange and satsuma mandarin. Protoplasts isolated from nucellar calli of navel orange and from leaves of satsuma mandarin were fused by the PEG method. The fusion products were cultured in a Murashige & Tucker medium containing 0.6 M sucrose. In this medium, some colonies developed into whole plants through embryogenesis. One of the regenerated plants was shown to be a hybrid, which was proven by restriction endonuclease analysis of nuclear ribosomal DNA. The chromosome number of the hybrid was 36. Both parents have a chromosome number 2n=18.     

Characterization of allotetraploids derived from protoplast fusion between navel orange and kumquat

In this study, we aimed to produce a citrus fruit with no seed and with edible peel. Therefore, the seedless Yoshida navel oranges (Citrus sinensis ‘Yoshida navel’) and Jangsil kumquat (Fortunella japonica) with edible peel were used as the starting materials. Since two varieties of different genera and different flowering periods would be difficult to crossbreed, protoplast fusion was conducted using the polyethylene glycol method. Yoshida navel orange and Jangsil kumquat were used as an embryogenic callus line and a mesophyll line, respectively. The regenerated plants were analyzed by flow cytometry to identify tetraploids, which were further evaluated by polymerase chain reaction, using simple sequence repeat markers specific for the nuclear and cytoplasmic organellar DNAs of the two parents, to confirm allotetraploids and cybrids. Sixteen allotetraploids were finally produced and characterized phenotypically for leaf morphology and fruit quality. All allotetraploids contained mitochondria originating from Yoshida navel orange; 12 contained chloroplasts derived from navel orange whereas four contained chloroplasts of kumquat origin. We investigated both plant and fruit characteristics of allotetraploids derived from the protoplast fusion of navel orange and kumquat. The sizes of the allotetraploid leaves were intermediate between those of both parents. However, in contrast to the spindle-shaped leaves of both parents, those of the allotetraploids were obovate. Petiole wings were absent in the allotetraploids, a known kumquat trait. Similar to navel oranges, flowering time was mid-May, and pollen was sterile, whereas fruit size, external shape, soluble solids content, and acidity were all intermediate between the two parents. Peel thickness and the number of segments were similar to those of kumquat, and flesh weight was similar to that of navel orange. Collectively, these results indicated that the intergeneric allotetraploids derived from navel orange and kumquat inherited favorable traits of both parents and could be produced and selected despite a lack of extensive parental variation. This is one of the first reports showing fruiting results of protoplast-fused citrus plants. The study reported characteristics of the fruits from both the original plants as well as from the protoplast-fused plant. Detailed characteristics of the allotetraploid fruit produced by protoplast fusion would be very helpful for future polyploid studies.

     

Green fluorescent protein as a visual marker in somatic hybridization

Using a transgenic citrus plant expressing Green Fluorescent Protein (GFP) as a parent in somatic fusion experiments, we investigated the suitability of GFP as an in vivo marker to follow the processes of protoplast fusion, regeneration and selection of hybrid plants. A high level of GFP expression was detected in transgenic citrus protoplasts, hybrid callus, embryos and plants. It is demonstrated that GFP can be used for the continuous monitoring of the fusion process, localization of hybrid colonies and callus, and selection of somatic hybrid embryos and plants.     

Somatic hybrid plants from sexually incompatible woody species: Citrus reticulata and Citropsis gilletiana

Summary Allotetraploid intergeneric somatic hybrid plants between Citrus reticulata Blanco cv. Cleopatra mandarin and Citropsis gilletiana Swing. & M. Kell. (common name Gillet's cherry orange) were regenerated following protoplast fusion. Cleopatra protoplasts were isolated from an ovule-derived embryogenic suspension culture and fused chemically with leaf-derived protoplasts of Citropsis gilletiana. Cleopatra mandarin and somatic hybrid plants were regenerated via somatic embryogenesis. Hybrid plant identification was based on differential leaf morphology, root-tip cell chromosome number, and electrophoretic analyses of phosphoglucose mutase (PGM) and phosphohexose isomerase (PHI) isozyme banding patterns. This is the first somatic hybrid within the Rutaceae reported that does not have Citrus sinensis (sweet orange) as a parent, and the first produced with a commercially important citrus rootstock and a complementary but sexually incompatible, related species.Abbreviations PGM phosphoglucose mutase - PHI phosphohexose isomerase - MES 2[N-morpholino] ethane sulfonic acid - BH3 protoplast culture medium (Grosser and Chandler, 1987) - PEG polyethylene glycol - MT Murashige and Tucker (1969) basal medium - NAA 1-naphthaleneacetic acid - GA3 gibberellic acid - H+H and EME citrus embryogenic cell culture media (Grosser and Gmitter, 1990b) - B embryo germination medium - RMAN rooting medium Florida Agricultural Experiment Station Journal Series No. R-00298.     

Production of additional allotetraploid somatic hybrids combining mandarings and sweet orange with pre-selected pummelos as potential candidates to replace sour orange rootstock

Summary Sour orange (Citrus aurantium L.) rootstock has historically been a widely utilized eitrus rootstock throughout the world due to its wide soil adaptability and superior horticultural performance. However, quick-decline isolates of citrus tristeza virus (CTV) have demolished entire industries of sour orange rootstock in some countries, including Brazil and Venezuela. CTV is presently destroying millions of trees of sour orange rootstock in Florida and threatens the citrus industries of Texas and Mexico, where sour orange is the predominant rootstock. Efforts to replace sour orange rootstock are combining traditional breeding and biotechnology approaches, including somatic hybridization and transformation. Molecular techniques have confirmed that sour orange is probably a hybrid of mandarin and pummelo. A major focus of our program continues to be the somatic hybridization of superior mandarins with pre-selected pummelo parents. Here, we report the regeneration of allotetraploid somatic hybrid plants from seven new mandarin+pummelo combinations and one new sweet orange+pummelo combination. All new somatic hybrids were confirmed by leaf morphology, ploidy analysis via flow cytometry, and random amplified polymorphic DNA analysis to show nuclear contributions from both parents in corresponding hybrids. These new somatic hybrids are being propagated by tissue culture and/or rooted cuttings for further evaluation of disease resistance and horticultural performance in field trials.     

柑橘愈伤组织倍性变化及其与体细胞胚胎发生能力的关系

柑橘愈伤组织是细胞融合、遗传转化等生物技术研究的良好材料。本实验室通过近20年的工作,先后诱导和保存了近80份不同种类和品种的柑橘愈伤组织。这些愈伤组织在MT基本培养基上继代保存。在长期保存过程中,部分材料仍然保持较好的胚胎发生能力。为研究愈伤组织在继代过程中的染色体变异趋势以及这种变异对胚胎发生能力的影响,本文选择有代表性的35份材料作为试材,在4年中连续3次使用流式细胞仪,对细胞DNA含量进行测定。结果发现,待测的35种愈伤组织均存在部分细胞DNA含量加倍的现象,而且,随着时间的推移,除佩奇橘柚、沙漠蒂甜橙、鲁斯脐橙、印度酸橘等4种愈伤组织的DNA含量加倍的细胞有减少的趋势外,其他愈伤组织的DNA含量加倍的细胞均有增加的趋势。数据分析表明,在待测的35种愈伤组织中,有71．4％的基因型的愈伤组织细胞出现了多倍体细胞增加的趋势。对这35种柑橘愈伤组织进行体细胞胚诱导,发现只有9种愈伤组织具有不同程度的胚胎发生能力,其他26种愈伤组织不能再生。相关性分析表明,柑橘愈伤组织细胞DNA含量增加的细胞比例与体细胞胚胎发生能力之间的相关性较小,相关系数为忙-0．10（P〈0．01）,未达到显著水平。另外,柑橘胚性愈伤组织继代时间与体细胞胚胎发生能力之间的相关性也不显著。     

Somatic hybridization in Citrus: navel orange (C. sinensis Osb.) and grapefruit (C. paradisi Macf.)

Summary Protoplasts of navel orange, isolated from embryogenic nucellar cell suspension culture, were fused with protoplasts of grapefruit isolated from leaf tissue. The fusion products were cultured in the hormone-free medium containing 0.6 M sucrose. Under the culture conditions, somatic embryogenesis of navel orange protoplasts was suppressed, while cell division of grapefruit mesophyll protoplasts was not induced. Six embryoids were obtained and three lines regenerated to complete plants through embryogenesis. Two of the regenerated lines exhibited intermediate morphological characteristics of the parents in the leaf shape. Chromosome counts showed that these regenerated plants had expected 36 chromosomes (2n=2x=18 for each parent). The rDNA analysis using biotin-labeled rRNA probes confirmed the presence of genomes from both parents in these plants. This somatic hybridization system would be useful for the practical Citrus breeding.     

Analysis of cytoplasmic genomes in somatic hybrids between navel orange (Citrus sinensis Osb.) and ‘Murcott’ tangor

Summary Somatic hybrid plants were produced by protoplast fusion of navel orange and Murcott tangor. Hybridity of the plants was confirmed by the restriction endonuclease analysis of nuclear ribosomal DNA. All of the plants (16 clones) were normal, uniform, and had the amphidiploid chromosome number of 36 (2n=2x=18 for each parent). The cpDNA analysis showed that each of the 16 somatic hybrids contained either one parental chloroplast genome or the other. In all cases, the mitochondrial genomes of the regenerated somatic hybrids were of the navel orange type.Contribution No. E-132 of the Fruit Tree Research Station     

Relationship Between Ploidy Variation of Citrus Calli and Competence for Somatic Embryogenesis

This study focuses on the relationship between the genetic variation of calli and the competence for somatic embryogenesis in citrus. The DNA content of 35 citrus calli of different genotypes was measured three times by flow cytometry during a period of four years. The results showed that 71.4% of the genotypes had a progressive increase of varied cells, while those of Page tangelo, Shamouti sweet orange, Russ navel orange and Cleopatra decreased; significant difference in the variation degree (percentages) existed among genotypes. Studies carried out on the induction of somatic embryogenesis revealed that 9 out of the 35 genotypes had still kept the competence of somatic embryogenesis, and the rest 26 had lost the competence. Correlation analysis indicated that there was no significant relationship between the variation degree and the embryogenesis competence r=−0.10 (P<0.01), neither for the relationship between the subculture duration and the regeneration capacity.