‘杨氏金红50号’猕猴桃的离体快繁研究

为建立‘杨氏金红50号’猕猴桃的离体快繁体系,该研究以其带腋芽茎段为外植体,采用组织培养的方法进行离体培养,并建立了两种离体再生途径:途径I为直接诱导茎段腋芽出芽;途径Ⅱ为茎段基部先产生愈伤组织,再分化不定芽。结果表明:‘杨氏金红50号’猕猴桃带腋芽茎段的最佳灭菌方式为75%酒精30 s+15%Ca(Cl O)_25 min+0.1%升汞8 min;在途径I中,诱导茎段腋芽出芽的最优培养基为MS+4.0 mg·L~(-1)6-BA+0.1 mg·L~(-1)NAA;在途径Ⅱ中,诱导茎段基部产生愈伤组织并产生不定芽的最优培养基为MS+3.0 mg·L~(-1)6-BA+0.3 mg·L~(-1)NAA;培养丛生芽的最佳植物生长调节剂组合为MS+4.0 mg·L~(-1)6-BA+0.4 mg·L~(-1)NAA;不定芽生根培养的最佳植物生长调节剂组合为1/2 MS+0.9 mg·L~(-1)IBA,20 d左右分化出不定根,40 d左右获得完整植株;生根后的组培苗在田园土∶细沙=1∶1的基质中能达到96%的移栽成活率。     

高效诱导冬瓜再生植株的研究

将台湾冬瓜的种子接种于pH值为7.2的1/2MS培养基上预培养,5d左右种子即可萌发,萌发率为100%,幼苗生长正常。切取预培养15-20d的无菌幼苗的茎尖和带腋芽的茎段接种于MS 1mg/LNAA 4mg/L6-BA培养基上,10d左右在茎尖和茎段（带腋芽）切口处长出愈伤组织,30d左右在愈伤组织处分化出丛生芽,丛生芽的诱导频率接近95%,繁殖系数25.6。将小芽切下转入不加任何生长调节剂MS培养基上,培养几天后芽逐渐长大,并在芽的基部长出白色根系。选取生长健壮的试管苗经过炼苗后移栽到大田中,生长良好。     

白术茎段培养快速繁殖及细胞组织学研究

在白术茎段培养的培养基中添加0.5—1.0mg/L的GA_3,可以促进芽的分化增殖和伸长。茎段培养在Ms+BA 5+NAA 0.1+GA3 0.5-1.0(mg/L)培养基中,芽的增殖倍数达7.7。细胞组织学研究表明,愈伤组织主要起源于髓部的薄壁细胞,愈伤组织分化出分生组织结节和鸟巢状维管结节。芽的起源有3种形式:①腋芽的萌动,②在愈伤组织中通过内起源和外起源分化形成芽,③从形成的畸形胚上由内起源分化形成芽。嫩茎接入1/2Ms+NAA 0.5培养基中可通过内起源诱导生根。     

金桔组织培养中愈伤组织和芽形成的组织细胞学观察

用金桔茎段为外植体,培养在附加1.0毫克/升BA和0.l毫克/升IBA的MS培养基上,诱导愈伤组织和芽形成。观察了愈伤组织和芽形成过程中的组织细胞学变化。培养一周后,在茎组织切口两端开始膨大,细胞增大和开始分裂。培养两周后,开始形成瘤状愈伤组织。在愈伤组织中有形成层状分生组织、维管组织结节和分生细胞团。培养四周后,表层的分生细胞团分化形成大量芽原基,同时愈伤组织深层也出现分生细胞团。带节茎段可从切口两端的愈伤组织分化形成芽,亦可从叶腋的潜伏芽直接形成芽。     

罗汉果叶片离体再生快繁技术

以罗汉果(Ssiraiti grosvenori)叶片为外植体,探讨培养方式、激素组合对愈伤组织诱导和不定芽分化的影响。结果表明:罗汉果叶片在培养基MS+BA 1.0 mg/L+IBA 0.7 mg/L上培养4周愈伤组织的诱导率达90%以上;罗汉果愈伤组织在培养基MS+BA 1.0 mg/L+IBA0.2 mg/L+赛苯隆(TDZ)0.1 mg/L上不定芽的分化率可达70%,平均出芽指数3.7;罗汉果试管苗在培养基MS+BA 2.0 mg/L+IBA 0.2 mg/L上茎芽增殖比较稳定,在培养基MS+IBA0.1 mg/L上培养2周开始分化不定根,其生根率在90%以上。     

叶子花的组织培养与微繁技术研究

叶子花茎尖、茎段接种在MS附加不同浓度组合的6-BA、IAA、IBA、NAA培养基上可诱导茎尖及腋芽的生长而获得无性系芽,无性系芽茎尖和茎段在MS附加6-BA0．5mg／L,NAA0．05mg／L进行继代培养,一般不形成丛生芽,以茎尖生长和腋芽萌生增殖,增殖系数为2．73;高度大于3cm的增殖芽在1／2 MS附加IAA lmg／L、IBA lmg／L、NAA0．2mg／L培养基上生根率为80．5％,生根苗用“二步法”移栽成活率在97％以上。无性系芽的幼叶、茎段在MS附加6-BA和NAA、2,4-D培养基上能高频产生愈伤组织,但愈伤组织在所试验的所有培养基上均无不定芽或胚状体的分化。     

大果良种沙棘愈伤组织诱导及植株再生的研究

大果良种沙棘的幼嫩茎尖,茎段外植体接种在MS,1／2MS附加不同浓度配比的IAA,IBA,BA,NAA培养基上可诱导茎尖及腋芽生长,将诱导产生的无性系芽接种在MS或1／2MS附加BA0．3－0．5mg/L,NAA0．05mg/L的培养基上可形成丛生芽,同时在小叶片和嫩茎上诱导产生愈伤组织,继续培养愈伤组织表面形成大量的绿色突起,进一步分化成不定芽,在相同培养基上,不定芽上可直接产生不定芽,从而形成多达数百个的不定芽族,不定芽长至3cm时切下转至1／2MS附加IAA或IBA 0．2mg/L的培养基上可生根而形成完整 的再生植株。     

盐生植物海马齿离体再生

建立盐生植物海马齿(Sesuvium portulacastrum)的离体再生体系,为其生物技术改良奠定基础。以海马齿叶片、茎和腋芽为外植体, 在不同激素配比的培养基上进行愈伤组织诱导、继代培养以及不定芽的分化和生根培养。结果表明: 最适愈伤组织诱导的外植体为叶片, 其次为幼嫩的茎段和腋芽。以叶片为外植体, 愈伤组织诱导率最高的培养基为MS+2.0mg·L^–12, 4-D + 0.5 mg·L^–16-BA + 3%sucrose; 芽分化最适培养基为MS + 1.0 mg·L^–1 2, 4-D + 0.2 mg·L^–1 6-BA + 3% sucrose;生根最适培养基为MS + 3%sucrose + 0.1%AC。炼苗移栽后, 成活率可达80%。     

“菊花组织培养”实验选取不同部位为外植体的结果比较

以菊花带芽的茎段、节间中段及叶片为外植体进行组织培养,结果表明,在MS+6-BA 2 mg/L+NAA 0.5 mg/L的培养基中,带芽的茎段为外植体容易成活,且生长迅速,容易直接从芽生成幼苗;节间中段为外植体经过脱分化形成愈伤组织,然后再分化形成幼苗;叶片为外植体能观察到脱分化形成愈伤组织,但是再分化形成幼苗的成功率比较低。     

梨枣叶片和茎段再生体系的建立

用不同浓度配比的生长素和细胞分裂素诱导梨枣叶片和茎段愈伤组织的产生,并研究了不定芽诱导的最佳配方,建立了梨枣叶片和茎段的再生体系.结果表明,梨枣叶片愈伤组织诱导的最佳培养基为MS+2,4-D 1.5 mg·L-1+6-BA 0.5 mg·L-1;茎段为MS+2,4-D 1.0 mg·L-1+6-BA 0.5 mg·L-1.叶片不定芽诱导的最佳培养基为MS+IBA 0.1 mg·L-1+6-BA 1.5 mg·L-1. AgNO3能阻止叶片外植体褐化并有效地促进叶片愈伤组织分化.茎段能在同一培养基上产生愈伤组织并直接分化出不定芽.     

香蕉小茎尖培养中芽产生的细胞学观察

报道6个香蕉品种的小茎尖离体繁殖无病苗中芽产生的细胞学观察。小茎尖在改良MS附加BA 3.0 mg/l的培养基上培养,5天后可以看见外植体基部膨大,10天后叶原基伸长、转绿,20天后长出叶子形成苗。20—30天左右,所形成苗的两侧表皮下的薄壁细胞转化为分生细胞,形成芽原基,继续分化形成芽,一般芽数为2—3个。     

Efficient shoot regeneration from internodal explants of Populus angustifolia, Populus balsamifera and Populus deltoids

In the present study, interactions between the duration of treatment with auxin and different cytokinins and their effect on shoot regeneration were evaluated with the aim to establish a rapid and efficient in vitro regeneration method applicable to a variety of Populus species. Three different species, Populus angustifolia, P. balsamifera, and P. deltoids, were chosen for that purpose. We were successful in regenerating plantlets from stem and petiole explants from all three chosen species using a four-step simple procedure. The first step was callus induction when the explants were exposed to an auxin-rich medium for 0-20 days. During the second step, they were transferred onto a cytokinin-rich medium for shoot bud induction. In the third step, the shoots regenerated were transferred onto a medium with reduced levels of cytokinins to promote shoot proliferation and elongation; finally, in the fourth step, the shoots were rooted and acclimated. A short period (6-10 days) of time of exposure to auxin was sufficient for shoot regeneration. A culture time longer than ten days in callus induction medium drastically reduced the efficiency of shoot regeneration. Besides, cytokinin type and concentration also affected the frequency of shoot induction. A 0.2 mg/l concentration of 2,4-D for callus induction followed by 0.02 mg/l of Thidiazuron for shoot formation proved to be the best treatment for adventitious shoot bud multiplication, generating a maximum of 10-13 shoots of P. balsamifera and P. angustifolia in ten weeks. In contrast, for P. deltoids, a combination of 1.1mg/l 2,4-D, 1.0mg/l NAA, 0.1mg/l zeatin for callus induction followed by a combination of 1mg/l zeatin plus 1.0mg/l BA for shoot bud induction was found to be the most effective, generating on average 15 shoots over a period of ten weeks.     

菊芋试管苗的初代培养及愈伤组织不定芽诱导

菊芋（Helianthus tuberosus Linn.）为菊科（Asteraceae）向日葵属（Helianthus Linn.）多年生草本植物,耐寒、耐旱、耐贫瘠、耐盐碱[1];其地下块茎富含菊糖,还可通过发酵生产乙醇,在功能性食用多糖及生物能源方面的开发潜力巨大。菊芋主要通过块茎进行无性繁殖,其种子成活率和发芽率均很低[2],严重阻碍了菊芋的杂交育种。近年来以植物组织培养为基础的一系列现代育种技术为菊芋的种质改良提供了新途径,但由于菊芋的愈伤组织难以诱导不定芽或体胚发生,导致以农杆菌转化为主的转基因育种技术的应用受到限制。     

Anatomy of shoots and tumors of in vitro habituated Rhododendron 'Montego' (Ericaceae) cultures with tissue proliferation

Tissue proliferation (TP) is characterized primarily by the formation of galls or tumors at the crown of container-grown rhododendrons that were initially propagated in vitro. In the cultivar 'Montego', TP-like symptoms are first observed in vitro as shoot clusters with small leaves and nodal tumors. In addition, unlike the normal in vitro non-TP (TP-) shoots, in vitro TP (TP+) shoots proliferate rapidly without the presence of the plant growth regulator cytokinin in the tissue culture medium. Comparisons of the anatomy of TP+ and TP- shoot tips showed that TP+ shoots had a less developed vascular system, longer cells in the pith and cortex, and altered internodal elongation at the shoot apex. In addition, TP+ axillary buds were abnormal in that they were displaced onto the stem above the leaf axil, and a small group of proliferating cells replaced the shell zone at the base of the bud. Initiation of tumor formation began with the expansion of this region of cell proliferation (RCP) and shoot growth from the abnormal axillary bud (tumor bud). Organization of the tumor bud and extension of the RCP characterized the further development of two types of tumors. In polar shoot tumors, shoot growth continued from the persistent tumor bud and the tumor at the base of the shoot remained small in size. The RCP extends downward to the vascular junction of the subtending leaf and the stem of the TP+ shoot. In nonpolar tumors, continuous de novo meristem formation led to the development of large tumors with or without shoots. The RCP is present throughout the tumor and is associated with de novo meristem formation. Comparisons to the anatomy of other tumor-like structures showed that TP tumors of Rhododendron 'Montego' are most similar to tobacco genetic tumors.     

In Vitro Culture and Plant Regeneration in Vicia faba subsp. Equina (var. Spring Blaze)

Explants of stem, leaves, roots, and cotyledons from etiolatedaxenically grown Vicia faba seedlings were cultured on a rangeof media. Shoot organogenesis was only obtained with nodal stemand cotyledonary node explants when cultured on MS medium with3% sucrose, 2.0 mg 1^–1 BAP and 02 mg 1^–1 NAA. Callusproliferation accompanied shoot organogenesis from nodal stemexplants. Successive subculture of nodal stem callus resultedin proliferation of regenerative callus which contained severalshoot bud initials. The capacity for shoot regeneration fromthis callus was maintained for 9 months. Histological studiesreveal de novo formation of meristematic centres in callus andtheir further development into bud primordia. High frequencyrooting of these adventitious shoots was obtained on half-strengthMS medium with 1.5% sucrose, 0.1 mg 1^–1 NAA and 0.5 mg1^–1 kinetin. Key words: Vicia faba, adventitious shoots, axillary shoots, de novomeristem formation, organogenesis, tissue culture     

Cells within the nodal region of carnation shoots exhibit a high potential for adventitious shoot formation

Adventitious shoot formation was studied with leaf, stem and axillary bud explants of carnation (Dianthus caryophyllus L.). The shoot regeneration procedures were applicable for a wide range of cultivars and shoot regeneration percentages were high for all explant types. Using axillary bud explants, shoot regeneration efficiency was independent of the size of the bud and of its original position in the plant. In contrast, shoot regeneration from stem and leaf explants was strongly dependent on their original position on the plant. The most distal explants (just below the apex) showed the highest level of shoot regeneration. The adventitious shoot primordia developed at the periphery of the stem segment and at the base of leaf explants. In axillary bud, stem and leaf explants, shoot regeneration originated from node cells, located at the transition area between leaf and stem tissue. Moreover, a gradient in shoot regeneration response was observed, increasing towards the apical meristem.Abbreviations BA benzyladenine - NAA naphthaleneacetic acid     

Histo-Cytological Observations on Callus and Bud Formation in Cultures of Nicotiana tabacum L.

Leaf explants of tobacco were cultured on MS medium supplemented with 2 mg/ l NAA and 0.5 mg/l BA for induction of callus formation, or supplemented with 2 mg/l BA for bud formation. Histocytological observations on callus and bud formation were carried out. Three days after cultivation, mesophyll cells enlarged, the nuclei became more apparent and dark stained, and starch accumulated in the cells. Cell divisions began in the mesophyll cells at the cut ends, in the palisade cells near the vascular bundles and in the vascular parenchyma. Mitotic activity then spreaded over tbc explants, and was most active at the edges of leaf explants. Regular rows of cells appeared as a result of series of transverse divisions in the palisade. The number of chloroplast in the mesophyll cells decreased and degenerated gradually. A number of meristemoids ware initiated in the cultured leaf explants after 7 days of cultivation. They were originated from two kinds of tissues, the mesophyll and vascular bundle, including the phloem parenchyma and vascular sheath. On the medium with NAA and BA, callus formation was induced with vigorous divisions, whereas bud primordia were differentiated from the meristomoids on the medimn with 2 mg/l BA. The buds were developed from both the superficial meristemoids and the meristematic regions deep within the callused leaf explants. The accumulated starch in the cells gradually disappeared as bud formation proceeded.     

ADVENTIVE ORGANOGENESIS FROM SOMATIC TISSUE CULTURES OF SOLANUM CAROLINENSE: ORIGIN AND DEVELOPMENT OF REGENERATED PLANTS

The development of adventitious shoot formation from cultured somatic tissues of Solanum carolinense was studied using light microscopy. For purposes of comparison, callus initiation and proliferation were also followed. When stem segments of this plant were cultured on medium supplemented with 6 mg/l benzyladenine (BA), cell division was first observed after 48 hr in the external phloem and inner cortex of the segments. This division activity gave rise to meristematic zones which subsequently formed shoot primordia within 6 days of culture. While organogenic potential appears to be limited to specific regions, all tissues of the explant were capable of callus formation when cultured on medium containing 3 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D). In conjunction with a previous study, it appears that unlike somatic embryogenesis in this species, organogenesis does not require an intermediate callus phase for differentiation to occur.     

不同浓度卡那霉素、潮霉素对楸树试管苗生长的影响

目的:将不同质量浓度的卡那霉素、潮霉素加入楸树培养基中,研究卡那霉素、潮霉素对楸树组培苗生长的影响,以确定抗生素对楸树茎段分化与生根的敏感质量浓度。方法:待楸树继代、生根培养基灭菌后温度降至30~50℃,将不同质量浓度的卡那霉素、潮霉素经抽滤式灭菌加入培养基中,在培养基中接入楸树组培无菌茎段培养,观测茎段继代(增殖芽数、芽长、叶数等)、生根(发根数、根长、芽长等)生长指标并统计分析。结果:楸树组培继代培养基添加卡那霉素质量浓度为100 mg/L时组培瓶苗生长缓慢,浓度为150 mg/L时叶片大部分发白并干枯,茎段基部无愈伤组织形成,瓶苗基本停止生长,楸树继代瓶苗对卡那霉素耐受性范围为100~150 mg/L;添加潮霉素质量浓度为5 mg/L时瓶苗生长较为缓慢,浓度为10 mg/L时叶片开始干枯,茎段基部愈伤组织较小,瓶苗基本停止生长,楸树继代瓶苗对潮霉素耐受性范围为10 mg/L左右。楸树组培生根培养基添加卡那霉素质量浓度为100 mg/L时大部分茎段干枯,少部分为绿但未分化芽与根,浓度为150 mg/L时大部分茎段干枯,极少上部为绿,基部干枯,但未分化芽与根,楸树组培瓶苗生根培养苗对卡那霉素耐受性范围为100~150 mg/L;添加潮霉素质量浓度为5 mg/L时少部分茎段干枯,浓度为10 mg/L时大部分茎段干枯,少部分为绿,茎段未出现芽的分化与根的萌发现象,楸树组培瓶苗生根培养苗对潮霉素耐受性范围为5~10 mg/L。结论:卡那霉素、潮霉素对楸树组培苗生长有明显的抑制作用且与抗生素浓度呈负相关,但低质量浓度(1 mg/L)的潮霉素对楸树继代分化芽数有促进作用;同一抗生素对楸树不同无性系间组培苗生长的影响无显著差异。