原生质体电融合再生柑橘属间体细胞杂种

电场诱导酸橙(CitrusaurantitumL.)叶肉原生质体与澳洲指橘(MicrocitruspapuanaSwingle)悬浮系原生质体融合,融合产物经培养再生出具有三种叶片形态的植株,绝大部分与酸橙叶片完全相似(即叶肉亲本型植株);有2棵植株叶片大且厚;有1棵植株出现二叶和三叶。细胞学检查表明这些植株均为二倍体。采用RAPD标记对前两种植株进行杂种特性分析,共选用4个10-mer随机引物进行扩增。在引物OPAA-17的扩增产物中,再生植株的带型与酸橙一致;在引物OPA-08的扩增产物中,再生植株的带型与酸橙或澳洲指橘相似;而在引物OPA-04和OPA-07的扩增产物中,再生植株的带型出现三种情况,4个引物的扩增结果证明所分析的植株均是体细胞杂种。综合染色体检查和RAPD标记的结果,表明获得了酸橙与澳洲指橘属间二倍体体细胞杂种植株。     

柑桔原生质体融合再生叶肉亲本型植株的遗传分析

叶肉亲本（粗柠檬）型植株叶形指数、气孔特征与亲本粗柠檬无异,与同组合体细胞杂种差异显著。染色体计数为二倍体（２ｎ＝２ｘ＝１８）。过氧化物酶（ＰＯＸ）、多酚氧化酶（ＰＰＯ）、谷草转氨酶（ＧＯＴ）同工酶图谱与粗柠檬一致。ＲＡＰＤ分析表明,在具多态性的５４个随机引物中,大多数引物（５２个）上的图谱与粗柠檬相同。但ＯＰＷ－１２上,叶肉亲本型植株含有哈姆林甜检的特征谱带。ＯＰＶ－０４扩增产物显示,叶肉亲本型     

柑橘细胞电融合参数选择及种间体细胞杂种植株再生

以“Ｐａｇｅ”橘柚（ＣｉｔｒｕｓｒｅｔｉｃｕｌａｔａＢｌａｎｃｏ×Ｃ．ｐａｒａｄｉｓｉＭａｃｆ）胚性悬浮系原生质体和粗柠檬（Ｃ．ｊａｍｂｈｉｒｉＬｕｓｈ）叶肉原生质体为融合试材,摸索了适合柑橘的电融合参数。研究表明,在ＡＣ（交变电场）１２５Ｖ／ｃｍ、ＤＣ（直流脉冲）１２５０Ｖ／ｃｍ、ＡＣ作用时间６０ｓ、ＤＣ脉冲时间５０μｓ、ＤＣ脉冲个数为３、ＤＣ脉冲间隔为０．５ｓ时融合率较高,双核异核体率可以达到１５％以上。利用不同类型原生质体比重的不同,融合后通过控制离心时间,可以收集到更高比例的双核异核体。融合产物经培养,３～４个月再生小植株。染色体计数结合形态学观察表明,再生的１５０株小植株中７８％为四倍体,其余为二倍体叶肉亲本再生类型。再生植株经过氧化物酶同工酶及ＲＡＰＤ分析,表明得到了体细胞杂种,还证明获得了１株叶肉亲本同源四倍体再生类型。     

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（Cit-rus 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,副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。     

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。     

宜昌橙与伏令夏橙种间体细胞杂种

宜昌橙(Citrus ichangensis SwingIe)试管实生苗叶肉原生质体与伏令夏甜橙(C．Sin-ensis Osbeck)胚性悬浮细胞系原生质体,经聚乙二醇(PEG)诱导融合。再生出的胚状体为畸形,转移到生芽培养基中诱导产生丛芽。丛芽微嫁接在15天龄的枳壳砧上成为完整植株。幼叶染色体检查表明,两亲本均为二倍体2n=2x=18,融合后再生出的植株为四倍体2n=4x=36。过氧化物酶(POX)及谷草酰胺转氨酶(GOT)同工酶分析证明,这些四倍体均为体细胞杂种,它们同时含有双亲的酶带。杂种植株叶片形态更像甜橙。植株移八土壤后生长旺盛。     

甜橙与酸橙体细胞杂种核质组成鉴定(英文)

采用流式细胞术(flow cytometry, FCM)、简单重复序列(simple sequence repeat, SSR)和酶切扩增多型性序列(cleaved amplified polymorphic sequence, CAPS)等技术分析酸橙(Citrus aurantium L. )叶肉原生质体和甜橙(C. sinenis Osbeck cv. Shamouti)胚性愈伤组织原生质体电融合再生的体细胞杂种。FCM研究结果表明,所有的体细胞杂种植株荧光强度是二倍体对照的2倍,说明所分析的植株为四倍体。用SSR和CAPS分析了体细胞杂种的核质遗传组成,在试验的4对SSR引物中,有2对能区分开融合亲本。在2对引物中,体细胞杂种植株包含双亲的全部特异带,表明它们为异核杂种。通用引物扩增结合限制性内切酶酶切能鉴别融合亲本,在具有多型性的引物/酶组合中,所有体细胞杂种的线粒体和叶绿体DNA带型与胚性亲本(甜橙)完全一样。结果表明体细胞杂种核基因组来自双亲,而胞质基因组来自悬浮系亲本。讨论了所用技术的特点、柑橘四倍体体细胞杂种核质遗传规律及本组合体细胞杂种的应用。     

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.     

甜橙与酸橙体细胞杂种核质组成鉴定

采用流式细胞术(flow cytometry,FCM)、简单重复序列(simple sequence repeat,SSR)和酶切扩增多型性序列(cleaved amplifiedpolymorphic sequence,CAPS)等技术分析酸橙(Citrus aurantium L.)叶肉原生质体和甜橙(C.sinenis Osbeck cv.Shamouti)胚性愈伤组织原生质体电融合再生的体细胞杂种.FCM研究结果表明,所有的体细胞杂种植株荧光强度是二倍体对照的2倍,说明所分析的植株为四倍体.用SSR和CAPS分析了体细胞杂种的核质遗传组成,在试验的4对SSR引物中,有2对能区分开融合亲本.在2对引物中,体细胞杂种植株包含双亲的全部特异带,表明它们为异核杂种.通用引物扩增结合限制性内切酶酶切能鉴别融合亲本,在具有多型性的引物/酶组合中,所有体细胞杂种的线粒体和叶绿体DNA带型与胚性亲本(甜橙)完全一样.结果表明体细胞杂种核基因组来自双亲,而胞质基因组来自悬浮系亲本.讨论了所用技术的特点、柑橘四倍体体细胞杂种核质遗传规律及本组合体细胞杂种的应用.     

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。     

Regeneration of Diploid Intergeneric Somatic Hybrid Plants Between Microcitrus a Electrofusion

Leaf-derived protoplasts of Rough lemon ( Citrus jambhiri Lush, 2n = 2x = 18) were electrofused with embryogenic suspension protoplasts of its relative, Microcitrus papuana 5wingle (2n = 2x = 18), with an intention of creating novel germplasm. Six plants were regenerated following protoplasts fusion. Cytological examination demonstrated that they were diploids with 18 chromosomes (2n = 2x = 18). RAPD (random amplified polymorphic DNA) analyses with six arbitrary 10-mer primers showed that the regenerated plants had identical band pattems to those of Rough lemon for primers OPA-07, OPAN-07, OPE-05 and OPA-08, whereas for the other two primers, OPA-04 and OPS-13, bands specific to M. papuana could be detected in the regenerated plants. Cytological and RAPD analysis revealed that the regenerated plants were diploid somatic hybrids between M. papuana and Rough lemon. The putative hybrids were morphologically similar to Rough lemon. This is the first report on production of diploid somatic hybrid plants between citrus with its related genus via symmetric fusion.     

原生质体电融合再生柑橘属间体细胞杂种

Leaf derived protoplasts of Sour orange (Citrus aurantium L.) were fused electrically with embryogenic protoplasts of Microcitrus papuana Swingle. Plants were regenerated from the fusion products, which were characteristic with three types of leaf morphology. Most of the plants were identical to Sour orange (namely, Leaf-parent-type plant) and two plants had large and thick leaves whereas one plant had bifoliate and trifoliate leaves. Chromosome examination showed that these plants were diploid with 18 chromosomes (2n = 2x = 18). RAPD analysis was employed to verify the hybrid characteristics of the plants in the first two types. Four 10-mer arbitrary primers with polymorphism were chosen. Band pattern of the plants was similar with the leaf parent (Sour orange) for the primer OPAA-17. Band pattern of the plants was similar with either Sour orange or M. papuana for OPA-08. As for OPA-07 and OPA-04 three kinds of band profiles were detected. Results of RAPD marker, together with chromosome determination, indicated that all of the analyzed plants were intergeneric diploid somatic hybrids between Sour orange and M. papuana.     

Molecular characterization of the nuclear and cytoplasmic genomes of intergeneric diploid plants from cell fusion between Microcitrus papuana and Rough lemon

Simple-sequence-repeat (SSR) and PCR-RFLP were employed to characterize the nuclear and cytoplasmic genomes of intergeneric diploid plants derived from symmetric fusion between Microcitrus papuana Swingle and Rough lemon ( Citrus jambhiri Lush). Three out of five SSR primers distinguished the fusion parents from each other and the regenerated plants showed band profiles completely identical to the leaf parent, Rough lemon. Amplified products from the intergenic regions of cpDNA between trnD -trnT were digested with HaeIII and MspI, and those between trnH -trnK were digested with HinfI, and both the regenerated plants and Rough lemon shared the same band patterns, which were different from the embryogenic parent, M. papuana. With mtDNA, only 2 out of 12 primer pair/restriction enzyme combinations ( nad4 ex 1–2/ TaqI and nad4 ex 1–2/ HindIII) revealed polymorphisms between the fusion parents. With the former combination the regenerated plants showed the same fragment distribution as that of the embryogenic parent, M. papuana, whereas with the latter, a novel band absent in the fusion parents was detected in all of the regenerated plants, suggesting a possible rearrangement. The present research indicates that the plants analyzed were putative cybrids containing nuclear DNA and cpDNA from Rough lemon and mtDNA from M. papuana. Presumed mechanisms leading to the regeneration of diploid hybrid plants following symmetric fusion are discussed herein.     

Somatic hybrid plants produced by electrofusion between Solanum melongena L. and Solanum torvum Sw

Summary Somatic hybrid plants between eggplant (Solanum melongena) and Solanum torvum have been produced by the electrofusion of mesophyll protoplasts in a movable multi-electrode fusion chamber. Using hair structure as a selection criteria, we identified a total of 19 somatic hybrids, which represented an overall average of 15.3% of the 124 regenerated plants obtained in the two fusion experiments. Several morphological traits were intermediate to those of the parents, including trichome density and structure, height, leaf form and inflorescence. Cytological analyses revealed that the chromosome numbers of the somatic hybrids approximated the expected tetraploid level (2n=4x=48). Fifteen hybrid plants were homogeneous and had relatively stable chromosome numbers (46–48), while four other hybrids had variable chromosome numbers (35–48) and exhibited greater morphological variation. The hybridity of these 19 somatic hybrid plants was confirmed by analyses of phosphoglucomutase (Pgm) and esterase zymograms.     

猕猴桃属种间体细胞杂种

利用PEG融合方法,分别进行了中华猕猴桃(Actinidia chinensis var.chinensis)(2n=2x=58)子叶愈伤组织来源的原生质体与美味猕猴桃(A.deliciosa var.deiciosa)(2n=6x=174)子叶愈伤组织原生质体、以及狗枣猕猴桃(A.kolomikta)(2n=2x=58)叶肉原生质体种间原生质体融合。结果表明:中华猕猴桃与美味猕猴桃融合的1个克隆和中华猕猴桃与狗枣猕猴桃融合的4个克隆的RAPD谱带分别具有双亲特异的DNA谱带;经流式细胞仪分析,前者细胞核倍性推测为8倍体,后者细胞核为3倍体、4倍体和5倍体。初步鉴定这5个克隆是猕猴桃属种间体细胞杂种。     

Intergeneric Somatic Hybrid Plants Between Citrus and Poncirus trifoliata and Evaluation of Their Root Rot Resistance

Protoplasts of Page tangelo (Citrus reticulata Blanco×C. paradisi Macf.) cell suspension culture were electrically fused with mesophyll protoplasts isolated from trifoliate orange (Poncirus trifoliata (L.) Raf.). More than 150 plantlets regenerated after 4-5 months of culture. The regenerated plants were trifoliate with well developed root systems. Root-tip chromosome counting of more than 20 randomly selected plants revealed that they were all tetraploids (2n=4x=36). RAPD analysis of 7 randomly selected plants verified their hybridity. Inoculation of citrus Phytophthora parasitica Dastar toxin on leaves of somatic hybrids and both parental genotypes showed that Page tangelo was moderately susceptible, and trifoliate orange was highly resistant while the somatic hybrids were resistant. The potential of this somatic hybrid as rootstock is also discussed.     

Chromosome markers and alterations in mitotic cells from interspecific Citrus somatic hybrids analysed by fluorochrome staining

Mitotic cells from Rough lemon (Citrus jambhiri Lush.), Ohta ponkan (C. reticulata Blanco) and two somatic hybrid plants obtained from protoplast fusion were analysed by double staining with chromomycin A₃ (CMA) and 4′-6-diamidino-2-phenylindole. Only CMA-positive bands were observed in metaphasic chromosomes. The two parental karyotypes (2n=2x=18) were heteromorphic, yielding some marker chromosomes that could be identified in the somatic hybrids. One of the somatic hybrids had 2n=37 chromosomes, and the possible extra chromosome was distinguishable. The second somatic hybrid was tetraploid (2n=4x=36), with one of the chromosomes bearing a putative structural alteration. Furthermore, aneusomaty and some mitotic abnormalities were also observed in this latter plant. Such irregularities are reported for the first time for citrus somatic hybrids, and their possible causes and implications are discussed. Received: 23 December 1996 / Revision received: 21 May 1997 / Accepted: 16 June 1997