小麦与多年生黑麦草原生质体的电融合及杂种愈伤组织的形成

多年生黑麦草(Lolium perenne L.)悬浮培养细胞来源的原生质体和小麦(Triticumaestivum L.)含叶绿体的悬浮培养细胞来源的原生质体间,用直流方波脉冲进行电融合,获得了体细胞杂种愈伤组织。小麦的原生质体经过碘乙酰胺失活。愈伤组织的形态和颜色被用作识别预期杂种的标记。为了对杂种愈伤组织进行同工酶分析,观察了亲本的9种同工酶谱,其中3种在亲本间表现出差异(ADH、GOT 和 SDH)。酒精脱氢酶(ADH)的分析结果表明,有6个细胞系表现出杂种带。这些细胞系经过其他两种同工酶分析和 rDNA 探针杂交试验表明,一个细胞系表现出基本完全的亲本基因组间的组合,其余5个细胞系是部分杂种。     

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     

逆境处理和DNA甲基化影响柑橘体细胞胚发生

对 1 5种柑橘胚性愈伤组织进行体细胞胚诱导 ,发现逆境处理有利于体细胞胚发生 ,并可以恢复部分品种的体细胞胚发生能力。对具有和失去体细胞胚发生能力的两种纽荷尔脐橙 (CitrussinensisOsb .)愈伤组织进行随机扩增多态性DNA (RAPD)分析没有检测到带型的差异 ,而对它们的甲基化敏感扩增多态性 (MSAP)进行分析则发现两种愈伤组织间具有明显的DNA甲基化差异 ,具体细胞胚发生能力的愈伤组织的甲基化水平较失去体细胞胚发生能力的低     

毛叶曼陀萝(Datura innoxia Mill.)和颠茄(Atropa belladonna L.)属间体细胞杂交成功

据G.Krumbiegcl和O.Schieder报道,他们通过原生质体融合的途径,将曼陀萝和颠茄杂交成功。 筛选了13个体细胞杂种,其中大部分已经开始分化出根和叶。杂种愈伤组织可以根据形态特征加以辨认。毛叶曼陀萝用的是白化苗突变体,因此杂种愈伤组织应是有毛(来自毛叶曼陀萝)和绿色(来自颠茄)的。 杂种经过了细胞学鉴定,两个种的染色体     

逆境处理和DNA甲基化影响柑橘体细胞胚发生

对15种柑橘胚性愈伤组织进行体细胞胚诱导,发现逆境处理有利于体细胞胚发生,并可以恢复部分品种的体细胞胚发生能力.对具有和失去体细胞胚发生能力的两种纽荷尔脐橙( Citrus sinensis Osb.)愈伤组织进行随机扩增多态性DNA (RAPD) 分析没有检测到带型的差异,而对它们的甲基化敏感扩增多态性 (MSAP) 进行分析则发现两种愈伤组织间具有明显的DNA甲基化差异,具体细胞胚发生能力的愈伤组织的甲基化水平较失去体细胞胚发生能力的低.     

香果树体细胞胚胎发生过程中4种同工酶的研究

用非变性聚丙烯凝胶电泳技术对香果树体细胞胚胎发生及形态建成过程中过氧化物酶(POD)、酯酶(EST)、淀粉酶(AMY)和超氧化物歧化酶(SOD)4种同工酶进行分析.结果表明:香果树体细胞胚胎发生及形态建成过程中,POD、EST、AMY和SOD活性变化与胚性愈伤组织的诱导及体细胞胚的发生发育密切相关.非胚性愈伤组织和胚性愈伤组织酶谱差异明显,胚性愈伤组织中EST和AMY同工酶酶带多且活性高,非胚性愈伤组织中缺乏EST和AMY同工酶表达,AMY同工酶可作为胚性细胞分化和发育的重要标志.香果树体细胞胚形态建成过程中,球形胚时期的AMY、POD、EST同_T酶活性最强,表明这一时期生理代谢旺盛,是体细胞胚形态建成的关键时期;POD、AMY和SOD 3种同工酶的酶谱及表达强弱在形态建成的不同时期呈现有规律的变化,可作为香果树体细胞胚发生发育特定时期的参考标记. 与胚性愈伤组织的诱导及体细胞胚的发生发育密切相关.非胚性愈伤组织和胚性愈伤组织酶谱差异明显,胚性愈伤组织中EST和AMY同工酶酶带多且活性高,非胚性愈伤组织中缺乏EST和AMY同工酶表达,AMY同工酶町作为胚性细胞分化和发育的重要标志.香果树体细胞胚形态建成过程 ,球形胚时期的AMY、POD、EST同_T酶活性最强,表明这一时期生理代谢旺盛,是体细胞胚形态建成的关键时期;POD、AMY和SOD 3种同工酶的酶谱及表达强弱在形态建成的不同时期呈现有规律的变化,可作为香果树体细胞胚发生发育特定时期的参考标记. 与胚性愈伤组织的诱导及体细胞胚的发生发育密切相关.非胚性愈伤组织和胚性愈伤组织     

小麦远缘杂种幼胚胚状体的发生、发育及低温对愈伤组织分化能力的影响

通过普通小麦与滨麦、簇毛麦及山羊草属7个种杂交幼胚培养,获得8个体细胞胚性无性系(8个组合10个胚)及大量试管苗。愈伤组织及胚性愈伤组织诱导率分别为65.79%和26.32%。形态学及细胞学鉴定结果,均为真杂种。不同染色体组及同一染色体组不同基因型的幼胚,在组织培养中有明显差异。非整倍体细胞具有遗传的全能性,但当染色体数目严重偏离双单倍体数目时,其全能性即丧失。胚状体的发育具有与合子胚极相似的典型结构。由愈伤组织表层和深层细胞产生的胚状体,在形态结构上有明显区别。低温(4℃)处理早代胚性愈伤组织180—240天,以及严格筛选和及时转移,可使培养65—80代(5—6年)的愈伤组织植株分化率保持在77.73%以上。     

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。     

黄山栾树体细胞胚的发生和组织学观察

黄山栾树无菌苗的节间和叶柄离体培养后,其体细胞胚发生的结果表明：节间愈伤组织可诱导产生体细胞胚,而叶柄愈伤组织则生根：节间愈伤组织诱导培养基为MS＋3．0mg．L～2,4．D＋0．5～3．0mg．L-1NAA;节间胚性愈伤组织诱导培养基为MS＋2．0nag．L-2,4-D;胚性愈伤组织转移到无植物生长调节剂的MS培养基上可发育成正常植株。组织学观察表明,体细胞胚在胚性愈伤组织中有的发生于愈伤组织表层细胞,有的发生在愈伤组织内部。黄山栾树体细胞胚的形成经历球形胚、心形胚、鱼雷胚和子叶胚几个阶段,这与合子胚的发育途径相似。     

Ginsenoside Rb1 in asymmetric somatic hybrid calli of Daucus carota with Panax quinquefolius

American ginseng (Panax quinquefolius L.) is one of the most valuable herbs in the world. Its major active components are ginsenosides. In order to produce ginsenoside heterogeneously, somatic hybridization, a novel approach for genetic introgression, was employed in this study. Protoplasts derived from respective calli of carrot (Daucus carota var. sativus Hoffm.) and American ginseng (P. quinquefolius L.) were used as the fusion partners. Hybrid calli derived from single cell lines containing chromatin of American ginseng were confirmed by the analyses of isozyme, Random amplified polymorphic DNA (RAPD) and genomic in situ hybridization (GISH). High performance liquid chromatography (HPLC) results showed that the ginseng monomer Rb₁ was synthesized in seven of the hybrid calli identified as well as in the parent American ginseng calli but not in the parent carrot calli. Results indicated that hybrid introgression lines could produce ginsenoside Rb₁ and the ginsenoside Rb₁ biosynthesis pathway has been introgressed into carrot cells via somatic hybridization. From the point of biosafety view concerning the consumer acceptance, the potential predominance to produce ginsenosides with somatic hybridization other than with genetic transformation is discussed. Lu Han and Chuanen Zhou contributed equally to this work.     

Asymmetric somatic hybridization between wheat (Triticum aestivum) and Avena sativa L.

Common wheat is one of the most important cereal crops in the world. The improvement of its yield and quality by the introduction of heterologous gene(s) is very significant. Avena sativa L. (2n = 42), belonging to the Avena tribe, possesses resistance to drought, coldness and many dis-eases. Its contents of proteins and fat in seed, especially lysine and unsaturated fatty acid are highest in crops, therefore it is regarded as healthy food. Sexual hybridization between wheat and Avena sativa…     

Asymmetric somatic hybridization between wheat (<Emphasis Type="Italic">Triticum aestivum</Emphasis>) and <Emphasis Type="Italic">Avena sativa</Emphasis> L.

Protoplasts from cell suspensions of young-embryo-derived calli, whichwere non- regenerable for long-term subculture and protoplasts from embryogenic calli with the regeneration capacity of 75% of the same wheat Jinan 177, were mixed as recipient. Protoplasts from embryogenic calli of Avena sativa (with the regeneration capacity of less than 10%) irradiated with UV at an intensity of300 μW/cm2 for 30 s, 1 min, 2 min, 3 min, 5 min were used as the donor. Protoplasts of the recipient and the donor were fused by PEG method. Many calli and normal green plants were regenerated at high frequency, and were verified as somatic hybrids by chromosome counting, isozyme, 5S rDNA spacer sequence analysis and GISH (genomic in situ hybridization). Fusion combination between protoplasts either from the cell suspensions or from the calli and UV-treated Avena sativa protoplasts could not regenerate green plants.     

沙打旺与苜蓿属间体细胞杂交

以豆科牧草沙打旺为一亲本,碘乙酰胺处理的紫花苜蓿发根农杆菌A4菌株转化系为另一亲本,通过PEG-高pH,高钙法诱导原生质体融合。在不加外源激素的DPD培养基上有效地筛选了杂种细胞。经培养首次得到沙打旺( )紫花苜蓿的属间体细胞杂种。尽管双亲原生质体均已丧失分化植株的能力,但杂种细胞系R1仍得到苗的分化。杂种R1细胞的染色体数检查、冠瘿碱检测、同工酶和RAPD分析结果,都证实了其杂种特性。     

Analysis of remote asymmetric somatic hybrids between common wheat and <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Callus-derived protoplasts of common wheat (Triticum aestivum L. cv. Hesheng 3) irradiated with ultraviolet light were fused by using the PEG method with cell suspension-derived protoplasts of Arabidopsis thaliana. Regenerated calli and green plants resembling that of wheat were obtained. The hybrid nature of putative calli and plants were confirmed by isozyme, random amplified polymorphic DNA and genomic in situ hybridization (GISH) analyses. GISH results indicated that 1∼3 small chromosome fragments of A. thaliana were found introgression into the terminals of wheat chromosomes, forming highly asymmetric hybrids. Cytoplasmic genome tests did not show any cytoplasmic genetic materials from A. thaliana. However, variations from the normal wheat cytoplasmic genome were found, indicating recombination or rearrangement occurred during the process of somatic hybridization. The chromosome elimination in the asymmetric somatic hybridization of remote phylogenetic relationship was discussed. A miniature inverted-repeat transposable element related sequence was found by chance in the hybrids which might accompany and impact the process of somatic hybridization. Jingyao Deng and Haifeng Cui provided same contribution to this work.     

The role of irradiation dose and DNA content of somatic hybrid calli in producing asymmetric plants between an interspecific tomato hybrid and eggplant

Highly asymmetric somatic hybrid plants were obtained by PEG/DMSO fusion of gamma-irradiated mesophyll protoplasts of the kanamycin-resistant (KmR⁺) interspecific hybrid Lycopersicon esculentum x L. pennellii (EP) with mesophyll protoplasts of Solanum melongena (eggplant, E). Elimination of the EP chromosomes was obtained by irradiating the donor genome with different doses of gamma rays (100, 250, 500, 750 and 1000 Gy). The selection of somatic hybrid calli was based on kanamycin resistance; EP and E protoplasts did not divide due to the irradiation treatment and sensitivity to kanamycin, respectively. KmR⁺ calli were recovered following all irradiation doses of donor EP protoplasts. The hybrid nature of the recovered calli was confirmed by PCR amplification of the NptII gene, RAPD patterns and Southern hybridizations using potato ribosomal DNA and pTHG2 probes. Ploidy levels of calli confirmed as hybrid were further analyzed by flow cytometry. Such analyses revealed that the vast majority of hybrid calli that did not regenerate shoots were 5–9n polyploids. The three asymmetric somatic hybrid plants obtained were regenerated only from callus with a ploidy level close to 4n, and such calli occurred only when the donor EP had been exposed to 100 Gy. The amount of DNA in somatic hybrid calli, from 100-Gy exposure, was found by dot blot hybridization with the species-specific probe, pTHG2, to be equivalent with 3.1–25.8% of the tomato genome. Thus, DNA contained in 3.8–13.2 average-size tomato chromosomes was present in these hybrid calli. The asymmetric somatic hybrid plants had the eggplant morphology and were regenerated from one hybrid callus that contained an amount of tomato DNA equivalent to 6.29 average-size tomato chromosomes.     

Analysis of chromosomal and organellar DNA of somatic hybrids between Triticum aestiuvm and Haynaldia villosa Schur

Intergeneric somatic hybridization between wheat (cv. Jinan 177) protoplasts that have 24-28 chromosomes and Haynaldia villosa protoplasts containing 11-14 chromosomes was carried out by the polyethylene glycol (PEG) method. A high frequency of hybrid calli and plants were obtained from the fusion products, as revealed by cytological and biochemical techniques and by PCR analysis of 5S rDNA spacer sequences. GISH (genomic in situ hybridization) analysis confirmed the presence of chromosomes from both parents in the hybrid clones and the common occurrence of translocations between them. The RFLP analysis of the organellar DNA using mitochondrion- and chloroplast-specific probes revealed that mitochondria from both parents existed in the cells of hybrid calli and their recombination, whereas chloroplasts segregated and recombined randomly. The gross morphology of hybrid plants resembled that of wheat, but the gross morphology of their ovaries and anthers were intermediate between those of the two parents. The relationship between hybrid plant regeneration and the balance of genetic materials in hybrid clones is discussed.     

Studies on the Somaclonal Variation of Regenerated Plants from Protoplasts of Actinidia deliciosa

Protoplasts were isolated from leaf, petiole and stem segment-derived calli induced from one pistillate plant of Actinidia deliciosa line No. 26. Regenerated plantlets were obtained from protoplasts of leaf-derived and stem segment-derived calli, while only calli regenerated from protoplasts of petiole-derived calli. Seventy-six plants from protoplasts of leaf-derived calli and 21 plants from that of stem segment-derived calli survived after transplanting or grafting during 1987–1989. One staminate plant and two pistillate plants bloomed in May, 1991 and fruited soon afterwards. In all of those three plants regenerated from protoplasts of leafderived calli, sex differentiation occurred from somatic cells of Actinidia was verified. Somaclonal variation on leaf shape and plant morphology was obviously appeared. Chromosome number identified from 16 plants varied from 116 to 180.     

Asymmetric somatic hybridization between wheat (Triticum aestivum) and Avena sativa L.

Protoplasts from cell suspensions of young-embryo-derived calli, which were nonregenerable for long-term subculture and protoplasts from embryogenic calli with the regeneration capacity of 75% of the same wheat Jinan 177, were mixed as recipient. Protoplasts from embryogenic calli of Avena sativa (with the regeneration capacity of less than 10%) irradiated with UV at an intensity of 300 μW/cm² for 30 s, 1 min, 2 min, 3 min, 5 min were used as the donor. Protoplasts of the recipient and the donor were fused by PEG method. Many calli and normal green plants were regenerated at high frequency, and were verified as somatic hybrids by chromosome counting, isozyme, 5S rDNA spacer sequence analysis and GISH (genomic in situ hybridization). Fusion combination between protoplasts either from the cell suspensions or from the calli and UV-treated Avena sativa protoplasts could not regenerate green plants.