烟草试管

几德明等闭曾用嫁接方法获得茄子品种间 无忆绮扮种,Car'.son[61首次用原生质体融合方法 获得粉蓝烟草与郎氏烟草种间体细胞杂种。我 们试rw一种简易获得体细胞杂种（即无性杂种） 方法,即将不同品种烟草茎段进行无菌操作嫁 接,然后取嫁接愈合具有两种组织的茎段离体 培养再生植株,从中获得了具有两亲本特性的 无忆杂种再生植株。我们暂称此方法为“植物 试管无性杂交”。     

普通烟草和粉蓝烟草体细胞杂种植株后代的育性研究

普通烟草(Nicotiana.tabacum)和粉蓝烟草（N.glauca）叶肉原生质体融合获得种间体细胞杂种植株,其当代育性很低,但株系间稍有差异。杂种植株自交系（SC）随着自交世代的增加,染色体数目变化不大,正常花粉粒的比率增加,育性提高。体细胞杂种植株的回交系(BC)随着回交世代的递增,染色体数目减少,直至接近回交亲本的染色体数,育性趋向正常。高度雄性不育的植株染色体数目稳定,回交仍保持高度的不育。其育性低的主要原因之一是雄性器官退化。     

烟草种间体细胞杂种的同工酶分析

在稍加修改的Kao^[7]方法的基础上使用培 养皿沉降法成功地进行了普通烟草（Nicotiana tabacum） 品种CY,和黄花烟草（N. rustica) 品种黄花原生质体的融合,并获得了种间体细 胞杂种植株^[1,2].     

烟草种间体细胞杂种后代的遗传性状观察和选育

1980年,通过原生质体融合获得普通烟草与黄花烟草(N.tabacum + N.rustica)、普通烟草与粉蓝烟草N.tabacum + N.glauca)种间体细胞杂种植株。 对其后代连续七年进行了遗传性状观察和选育。结果表明：杂种一代呈典型的双亲中间型,杂种三代和回交二代开始分离,也有一直不分离的稳定株系和雄性不育株系。杂种后代育性差,回交能转育并逐步累积轮回亲本性状,染色体数目则逐渐减少。在杂种后代选育中,已选出了有一定应用价值的烟草新类型。通过体细胞杂交技术,有可能开辟出烟草育种新途径。     

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.     

烟草毛状根多倍体诱导及其植株再生

为了提高烟草的烟碱含量,采用发根农杆菌遗传转化和人工染色体加倍技术,进行了烟草毛状根及其多倍体诱导、植株再生及其烟碱含量测定。结果表明,发根农杆菌ATCC15834感染烟草叶片外植体8 d后产生白色毛状根,15 d后所有叶片外植体产生毛状根。毛状根能在无外源激素的MS固体和液体培养基上自主生长。PCR扩增结果显示发根农杆菌Ri质粒的rol B和rol C基因以及冠瘿碱合成酶基因已在烟草毛状根基因组中整合并得到表达。烟草毛状根多倍体诱导的最适条件为0.1%的秋水仙素溶液处理36 h,其多倍体诱导率为64.71%。经秋水仙素加倍的烟草毛状根多倍体植株再生的最适宜培养基为MS+6-BA 2.0 mg/L+NAA0.2 mg/L。与对照(二倍体非转化植株)相比,烟草二倍体毛状根再生植株的顶端优势减弱,腋芽增多,叶片变窄;而烟草毛状根多倍体再生植株茎更粗,节间变短,叶色更深,叶片的宽度和厚度均较对照明显增大。根尖细胞染色体压片观察证实,所获得的烟草毛状根多倍体再生植株为四倍体,其根尖细胞染色体数约为4n=96。盆栽实验表明,烟草二倍体毛状根植株和多倍体毛状根再生植株比对照植株延迟约21 d开花。GC-MS检测表明,烟草毛状根多倍体再生植株的烟碱含量比对照及二倍体毛状根再生植株显著提高,分别约为对照及二倍体毛状根再生植株的6.90倍和4.57倍。     

普通烟草与黄花烟草体细胞杂种的花粉粒、果实、种子及气孔的观察

长尾照义[97对有性杂交不易成功的普通烟 草(Nicotiana tabacum）粉红花品种和黄花烟草 (N. rustica）利用体细胞融合的方法,获得了 体细胞杂种。我们利用了普通烟草的红花品种 (Copes yusuhe及u No. 4）和黄花烟草的黄花烟 品种进行了体细胞融合,获得了体细胞杂种植 株^[1,2]。对这些植株的花型、花色、叶型等形态 学的特征和根尖染色体进行了观察,并作了过 氧化物酶和细胞色素氧化酶同功酶的酶谱分 析^[3],证明我们获得了真正的体细胞杂种。在 杂种植株开花、结实时,又对体细胞杂种株及 其亲本的花粉粒、果实、种子和气孔进行了观 察和比较,以期找到一种简便易行的鉴定方 法。     

花椰菜与黑芥非对称体细胞杂种的鉴定分析

选用兼具抗黑腐病、黑胫病、根肿病的野生种质黑芥(B.nigra)作为供体,具有良好原生质体培养能力的花椰菜(Boleracea var.botrytis L.)基因型"0307"作为受体,供体叶肉原生质体经不同剂量UV照射处理后,通过PEG介导,与不经任何处理的受体下胚轴原生质体融合,培养获得再生植株.形态学观察显示再生植株的表型多样,呈偏向受体花椰菜类型及中间类型分布:SRAP分子标记特征表明,杂种中受体的遗传信息较为完整,而来自供体的特异扩增带丢失量约为20.0%-97.8%,且不同杂种中存在热点丢失序列;约23.0%的再生植株其染色体数目小于供、受体染色体数之和;采用流式细胞仪对再生株的细胞DNA含量进行分析,结果显示,20%的植株其DNA含量小于供、受体DNA含量总和.对22棵再生植株进行了黑腐病人工接种抗性鉴定,17棵再生植株表现良好抗性,初步证明通过非对称体细胞杂交技术已将外源抗性基因转入花椰菜中.实验表明UV辐射处理,导致再生植株中供体遗传信息的部分丢失或者染色体在不同程度上的消减,获得了花椰菜与黑芥的非对称体细胞杂种,但UV的剂量效应不明显.     

白菜与甘蓝之间体细胞杂交种获得与遗传特性鉴定

为拓宽白菜育种的基因资源,改良白菜品质,以白菜(Brassica campestris,2n=20,AA)和甘蓝(B.oleracea L.var.capitata,2n=18,CC)的子叶和下胚轴为材料分离、制备原生质体。采用40%聚乙二醇(Polyethylene glycol,PEG)进行原生质体融合。融合细胞在以0.3 mol/L蔗糖、0.3 mol/L葡萄糖为渗透稳定剂,附加1.0 mg/L 2,4-D+0.5 mg/L 6-苄氨基嘌呤(6-BA)+0.1 mg/L 1-萘乙酸(NAA)+1.0 mg/L激动素(Kinetin,Kin)的改良K8p培养基中培养并诱导细胞分裂。小愈伤组织经增殖培养后在MS+0.2 mg/L玉米素(Zeatin,ZEA)+1 mg/L 6-BA+0.5 mg/L Kin+0.4 mg/L NAA的固体分化培养基上诱导出不定芽。30 d后再转入MS基本培养基,获得完整的再生植株。将生根的植株转移到花盆,并对其杂种性质进行形态学、细胞学和分子生物学鉴定。结果表明,经细胞融合分裂出的320个愈伤组织中,获得了35棵再生植株,其再生率达10.94%。形态学观察显示,绝大多数再生植株的叶面积较大,株型和叶型为两种杂交亲本的中间型,部分植株的叶片浓绿、肥厚。染色体计数结果显示,36.4%的再生植株染色体数为2n=38;36.4%的再生植株的染色体数为2n=58 60;27.2%的再生植株的染色体数为2n=70 76,超过两个融合亲本的染色体数的总和。流式细胞仪测定DNA含量显示,再生植株DNA含量变化比较大,其结果与染色体鉴定结果相吻合。随机扩增多态性DNA(Randomamplified polymorphic DNA,RAPD)和基因组原位杂交(Genomic in situ hybridization,GISH)分析结果证明再生植株具有双亲基因组。体细胞杂种花粉育性比较低,杂交、回交后其育性逐渐获得恢复,与白菜回交后代逐渐恢复了育性。通过体细胞杂交和回交、杂交获得了形态变化广泛的个体,为白菜的品种育种提供多样的种质资源。     

对粉蓝烟草与矮牵牛体细胞杂种植株的进一步观察

以亲本为对照,观察了粉蓝烟草和矮牵牛的体细胞杂种植株的叶片、气孔和花粉,发现杂种植株的叶片形态及其气孔大小、分布密度都与双亲有显著的差异。同时发现了杂种植株花粉的不育性。进一步证实了我们用原生质体融合的方法得到的植株是远缘杂种植株。     

Pollen-Mesophyll Protoplast Fusion and Hybrid Plant Regeneration in Nicotiana

Isolated pollen protoplasts of Nicotiana tabacum L. N364 Km+ were fused with mesophyll protoplasts of N. rustica L. using PEG-high Ca/pH method. The cells resulted from fusion between immature (early-middle bicellular) pollen protoplasts and mesophyll protoplasts could divide to produce microcalli and regenerated plantlets when cultured in a selection KM8p medium containing 50 g/L kanamycin. Four plantlets were regenerated. The isoenzyme patterns of leaf peroxidases of these plantlets had bands characteristic of both parents. Root-tip squash showed that the gameto-somatic hybrids had the expected triploid chromosome number. Aside from these kanamycin-selected plantlets, six of the twenty-one plantlets that had not undergone selection were also evidenced to be gameto-somatic hybrids.     

烟草属花粉—叶肉原生质体的融合及杂种植株再生

用饥饿预处理分离烟草（Ｎｉｃｏｔｉａｎａ ｔａｂａｃｕｍ Ｌ．）品系Ｎ３６４ Ｋｍ ＋ 二核早中期的花粉原生质体,用ＰＥＧ－高钙高ｐＨ 法诱导其与黄花烟草（Ｎ．ｒｕｓｔｉｃａ Ｌ．）叶肉原生质体融合。通过抗性筛选再生的４ 株小植株,经过氧化物酶同工酶、根尖染色体计数鉴定均为配子－体细胞三倍体杂种。未经筛选处理再生的２１株小植株,经鉴定有６ 株为配子－体细胞杂种。     

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。     

接种叶锈菌的小麦叶片胞间洗脱液对叶肉细胞原生质体微丝骨架的影响

用异硫氰酸 鬼笔环肽 (FITC Ph)标记和共聚焦激光扫描显微镜 (CLSM )观察发现 ,以具有激发子活性的接种叶锈菌的小麦叶片的胞间洗脱液 (IWF)处理叶肉细胞原生质体一定时间后 ,抗病小麦品种洛夫林 10的原生质体内微丝骨架保持完整的网络状结构 ,而感病品种 5 389的大部分微丝骨架处于解聚状态。同时 ,抗病品种因IWF处理诱发的防卫反应———H2 O2 突发和HR反应的程度 (用原生质体活力下降的程度表示 )也大大高于感病品种。用细胞松弛素D(CD)预处理抗病品种原生质体可以明显抑制IWF处理诱发的H2 O2突发和HR反应 ,表明微丝骨架的状态可能与抗病性有密切的关系 ,完整的微丝骨架是H2 O2 突发和HR反应的一个重要条件。     

Expression of nuclear and chloroplastic genes coding for fraction-1 protein in somatic hybrids of Nicotiana tabacum + rustica

In the sexual interspecific cross, Nicotiana rustica L.xN. tabacum L., N. rustica can serve as the female but not as the male parent. By fusion of protoplasts, the barrier to fertilization was overcome and somatic hybrids containing N. tabacum cytoplasm were produced as shown by isoelectric focusing of the Fraction-1 protein (F-1-protein). All somatic hybrids displayed polypeptides of the large subunit of F-1 protein (which is coded by the chloroplast genome) characteristic of only one or the other parental species. Two hybrids had large subunits of the N. tabacum type and two hybrids had those of the N. rustica type. Three hybrids contained three smallsubunit polypeptides (coded by the nuclear genome), one being characteristic of N. rustica, one characteristic of N. tabacum, and one with an isoelectric point common to both species. A fourth hybrid contained only two small-subunit polypeptides of the N. tabacum type but in a F-1 protein macromolecule whose large subunits were of the N. rustica type. One somatic hybrid was self-fertile and its F₂ progeny contained large- and small-subunit polypeptides indistinguishable in their isoelectric points from those in the parent F₁ hybrid. All somatic hybrids showed an aneuploid chromosome number and morphological characteristics intermediate between those of N. rustica and N. tabacum.     

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.     

Somatic hybrid plants produced by electrofusion between dihaploid potatoes: BF15 (H1), Aminca (H6) and Cardinal (H3)

In order to regenerate somatic hybrids, mesophyll protoplasts from a dihaploid potato, BF15 (H1), were electrofused with those from two other dihaploid clones, Aminca (H6) and Cardinal (H3). Determination of the ploidy level by flow cytometry showed that 10% of plants regenerated from the fusion experiment with BF15 + Aminca were diploids, 14% triploids, 63% tetraploids and very few were mixoploids or had a higher ploidy level. Using morphological markers and vigour in plant growth, we were able to recover a total of 24 somatic hybrid plants, respectively 20 and 4 hybrids (accounting for 12% and 13% of regenerants) from the fusions BF15 + Aminca and BF15 + Cardinal. Most of the somatic hybrids were at the expected tetraploid level (2n=4x=48). The hybrid nature was confirmed by examining isoenzyme patterns for malate dehydrogenase (MDH) and isocitrate dehydrogenase (ICD).     

普通烟草和黄花烟草及体细胞杂种过氧化物酶同工酶等电聚焦电泳

日本学者长尾照义(1978)用原生质体融合获得普通烟草与黄花烟草的体细胞杂种植株。1980年陈家玉等在国内首先获得普通烟草(Copus Yeusuku No.4)和黄花烟草(Yellow Flower)的体细胞杂种植株。之后,中国农科院烟草所(1981)也得到相同的结果。陈家玉等(1983)对上述杂种进行了形态学、细胞学和同工酶的分析并取得一定的结果。Dlineee等(1975)分析比较了用等电聚焦技术分离的过氧     

Somatic hybrid plants of Nicotiana glauca and Nicotiana tabacum obtained by protoplast fusion

Somatic hybrid plants were produced by fusion of protoplasts from cell cultures of the Nicotiana tabacum L. sulfur mutant Su/Su and from leaf mesophyll of Nicotiana glauca Graham. After fusion the N. glauca protoplasts failed to survive under the selected culture condition. From the hybrid cells light green shoots were produced. The hybrid plants exhibited intermediate characters between parental species with respect to leaf morphology, trichome density, floral structure and flower color. The chromosome number of 25 hybrid plants was 2n = 72 and both N. glauca and N. tabacum chromosomes were identified in the hybrids. Results of isoenzyme analysis showed bands of both parents and a specific (hybrid) band for aspartate amino-transferase. Small subunit fraction-1-protein of somatic hybrids also consisted of the sum of N. glauca and N. tabacum bands. Leaf spot formation associated with the Su locus of N. tabacum was observed in somatic hybrids.     

Characterization of somatic hybrids of potato by use of RAPD markers and isozyme analysis

Electrofusion of mesophyll protoplasts from two male sterile dihaploid Solanum tuberosum genotypes. DHAK-11 and DHAK-33, was performed. Selection of putative fusion products was based on vigorous callus growth. Regeneration of rooted putative hybrid plants was scored 14 weeks after fusion. Characterization of hybrids was performed by use of morphological assessment, random amplified polymorphic DNA (RAPD), and cytological and isozyme analysis. The rate of regenerated hybrids from callus was ca 6%. Of the putative hybrids, 45% were confirmed as true hybrids. Morphological assessment of the putative hybrids revealed that tetraploid and neartetraploid hybrids were vigorous plants with intermediate characteristics between the two parental phenotypes in respect to internode length, leaf size and shape, and purple pigmentation on the abaxial side of the leaves. Near-hexaploid hybrids were slender plants with small leaves and short petioles. Selected RAPD primers showed unique marker bands for the two parental genotypes. Hybrid plants revealed the unique marker bands from both parents. A total of 53 randomly chosen decamer primers were tested and 26 primers (49%) detected polymorphism between the two dihaploid parentals. Two primers revealed that one parental marker band was missing in two aneuploid hybrids. However, of 51 putative hybrids, a double test with two independently chosen primers showed unequivocally the hybrid character of 23 plants. The ploidy level of the hybrids was analysed by chromosome numbers in root tip cells and by number of guard cell chloroplasts. A strong correlation between the chromosome number and the number of chloroplasts was obtained. The hybrid nature of all RAPD-verified hybrids was confirmed by isozyme analysis with malate dehydrogenase.