水翁悬浮细胞系的建立及其悬浮培养的生长特性

建立了水翁悬浮细胞系,并对其悬浮培养的生长特性作了初步探讨。以水翁新生芽尖作为外植体,接种于添加有不同浓度和配比的生长调节物质及各种附加物的MS固体培养基中,诱导培养产生初代愈伤组织;挑选Ⅰ和Ⅱ型的愈伤组织进行继代培养改良,考察愈伤组织的生长状况和统计生长量来决定最佳继代培养基的配方和得到适合悬浮培养的愈伤组织;将以上得到的愈伤组织转接于最佳继代液体培养基中,于24±1℃,120r/min条件下振荡培养,筛选分散度好、较均匀、生长快、色浅透明的细胞作为种子传代,数次传代后得到性能良好的悬浮细胞系;以细胞生长量(鲜重)为指标,绘制了水翁悬浮细胞的生长曲线。研究表明:2.0mg/L的2,4-D的诱导率最高(92%,初代愈伤组织为Ⅰ型),Ⅱ型愈伤组织的最高诱导率为75%;最佳的继代培养基配方为MS 0.5mg/L 2,4-D 0.5mg/L 6-BA 1.0mg/L IAA 0.5mg/L IBA 0.5mg/L NAA 0.1mg/L KT 700mg/L LH,形成Ⅱ型愈伤组织的生长量可达3.28g/瓶(鲜重);液体继代培养3代后,可得到性能良好的悬浮细胞系;水翁悬浮细胞的生长曲线表明,最佳接种期为培养后的16~18d。     

生姜离体叶片愈伤组织悬浮细胞系建立与植株再生

以‘莱芜大姜’为试材,研究了生姜离体叶片愈伤组织的诱导以及细胞悬浮系建立与植株再生。结果表明,以生姜试管苗叶片为外植体,接种到MS+1.0 mg/L 2,4-D+0.5 mg/L 6-BA+30 g/L蔗糖的培养基上,可有效诱导出生长迅速、质地疏松的愈伤组织。将获得的愈伤组织接种到MS+0.15 mg/L 2,4-D+6.0 mg/L 6-BA+30 g/L蔗糖的液体培养基上,25℃黑暗条件下震荡培养25-30 d,可建立分散性好、生长迅速的悬浮细胞系,细胞悬浮系培养的适宜参数为:初始接种量为1.0-1.5 g,继代培养的适宜间隔期为15 d,继代培养液体培养基更新比例为3/4。将悬浮细胞接种到固体培养基MS+0.2 mg/L NAA+10.0 mg/L 6-BA+30 g/L蔗糖上可获得再生植株。     

毛白杨悬浮细胞系的建立及再生植株的获得

以毛白杨基因型TC152无菌苗为材料,研究毛白杨悬浮细胞系建立与植株再生,结果表明,通过悬浮培养和固体培养两种方法诱导毛白杨悬浮细胞分化不定芽,最终获得无菌生根苗。愈伤组织在MS＋1.5mg·L-12,4-D＋30g·L-1蔗糖的液体培养基中振荡培养,12d可建立悬浮细胞系;悬浮细胞系继代培养基为MS＋0.8mg·L-12,4-D＋30g·L-1蔗糖,继代周期为7d,悬浮细胞在MS＋1.0mg·L-16-BA＋0.1mg·L-1NAA＋0.5～1.0mg·L-1ZT＋30g·L-1蔗糖培养基中悬浮培养,可分化大量不定芽,每个培养瓶中可得到40～50个芽,个别不定芽玻璃化;不定芽在1/2MS＋0.6mg·L-1IBA＋20g·L-1蔗糖＋5.5g·L-1琼脂培养基上可分化不定根。悬浮细胞通过固体平板培养增殖为愈伤组织块后,在MS＋1.0mg·L-16-BA＋0.1mg·L-1NAA＋1.0mg·L-1ZT＋30g·L-1蔗糖＋5g·L-1琼脂的固体培养基上,不定芽分化率可达到70.00%。     

麻疯树悬浮细胞系的建立与优化

以麻疯树无菌幼苗为外植体,研究疏松愈伤组织诱导方案及不同培养条件对麻疯树悬浮细胞生长的影响,旨在建立麻疯树悬浮细胞体系.结果表明,麻疯树疏松愈伤组织诱导的最适培养基及激素组合为:MS+2,4-D0.6mg/L+BA 1.0 mg/L+蔗糖30 g/L,此培养基上诱导出的愈伤组织湿润松散,颜色鲜艳.接种愈伤组织进行悬浮培养的液体培养基最适激素组合为:NAA 0.2mg/L+2,4-D 1.0 mg/L+BA 0.5 mg/L.初代愈伤组织适宜用于悬浮培养,摇床转速应低于120 r/min为宜,这样培养的悬浮细胞分散度最高.培养基中添加500 mg/L水解酪蛋白能有效地促进悬浮细胞的生长.悬浮细胞振荡培养过程中悬浮细胞生长的时间进程为起始培养的第5天前,细胞增殖十分缓慢;第5-11天期间生长迅速;第13天后基本停止生长.在上述优化培养条件下,麻疯树悬浮细胞系增长速率最快,细胞生长状态最佳.     

油樟悬浮培养及次生代谢产物的诱导

以油樟(Cinnamomum longepaniculatum)叶片为外植体在附加6-BA和NAA不同激素浓度组合的MS培养基上筛选质地疏松、生长旺盛的愈伤组织, 分别接种在MS、B5、WPM三种液体培养基中进行细胞悬浮培养, 并检测诱导产生的次生代谢产物。结果表明: 2 mg.L-1 6-BA+ 0.5 mg.L-1 NAA能诱导质地疏松、生长旺盛的愈伤组织, B5基本培养基中细胞长势最好; 愈伤组织在B5+2 mg.L-1 6-BA+ 0.5 mg.L-1 NAA中悬浮培养, 继代2次后形成均一的单细胞; 从油樟悬浮培养物中检测出50%以上的成分是苯甲醇。     

巫山淫羊藿愈伤组织细胞的悬浮培养条件优化的初步研究

通过研究接种量、激素配比、糖浓度、培养基种类对巫山淫羊藿悬浮培养细胞生长及其愈伤组织黄酮类含量的影响,建立了巫山淫羊藿细胞悬浮培养的技术体系.结果表明:巫山淫羊藿愈伤组织细胞悬浮培养在B5基本培养基中并附加1.0 mg·L-12,4-D和0.2 mg· L-1BA,蔗糖浓度40 g·L-1,接种量每30 mL为鲜重2 ...     

诺丽茎段愈伤组织诱导优化及细胞悬浮系的建立

为获取诺丽茎段中的次生代谢物并为建立遗传转化体系奠定基础,以诺丽茎段(无腋芽)为外植体诱导愈伤组织,并建立细胞悬浮系,对影响愈伤组织的诱导及细胞悬浮系的因子进行了研究。结果表明:愈伤组织诱导的最优培养基是MS+1.0mg/L6-BA+0.1mg/L2,4-D;悬浮培养的最佳培养基为MS+1.0mg/L6-BA+0.1mg/L2,4-D+3%蔗糖,pH为5.85,当初始接种量为37.5g/L、摇床转速为110r/min且(25±2)℃暗培养时,悬浮细胞生长良好,生长速率最大;诺丽茎段悬浮细胞生长曲线呈"S"型,最适继代周期为12–20 d;培养过程中,培养基的pH呈先下降后缓慢升高的变化趋势,诺丽茎段愈伤组织悬浮细胞培养的最适pH在4.5–5.0之间。文中成功建立了以诺丽茎段为外植体的稳定的细胞悬浮系。     

亚麻胚性细胞悬浮培养体系的建立和影响因素

亚麻品种‘双亚五号’的胚性愈伤组织诱导最佳培养基为MB（MS无机盐加B5维生素）＋1.0mg·L^-12,4-D;细胞初始悬浮培养的最佳培养基为MB＋0.2mg·L-16-BA;细胞继代悬浮培养的最佳培养基为改良的MB（NH4NO3减半,KNO3加倍）＋0.02mg·L^-12,4-D＋0.2mg·L^-16-BA;适宜的蔗糖量为50g·L^-1;适宜的继代接种量为1.0～1.5g·（25mL）^-1;继代间隔为5～7d。     

黄山药细胞培养初步研究

以黄山药叶片为外植体诱导愈伤组织,经多次继代培养筛选后进行细胞悬浮培养,研究了两种培养基对细胞生长动态的影响以及4种培养参数对细胞生长量的影响。结果表明,培养在含6-BA1 mg/L和2,4-D1 mg/L的MS液体培养基中的细胞生长效果较好,培养20 d左右可达最高生长点。较适宜的培养条件为:接种量0.8~1.0 g/100 mL;培养温度24℃~27℃;pH 5.2~5.8;蔗糖用量20~40 g/L;继代培养周期15~20 d。     

朱砂根愈伤组织培养及悬浮细胞系建立

以朱砂根(Ardisia crenata Sims.)无菌苗的茎段、叶片、胚轴和胚根为外植体进行愈伤组织诱导研究。结果表明:胚根在含有2,4-D的培养基中的诱导率最高,在添加5 mg L-1 AgNO3的MS+2,4-D 0.5 mg L-1+KT 0.01 mg L-1培养基中继代培养的增殖系数高达8倍以上。培养中获得了5种类型的愈伤组织(I-白色湿软状、Ⅱ-白色冰砂状、Ⅲ-淡黄色颗粒状、Ⅳ-黄绿色块状和V-绿色块状),其中Ⅱ和Ⅲ型愈伤组织可以成功建立悬浮细胞系,用M S+2,4-D 0.5 mg L-1+KT 0.01 mg L-1培养基进行固-液轮回培养,可以较好地保持悬浮细胞系。     

紫茉莉不定芽诱导和植株再生

紫茉莉(Mirabilis jalapa)观赏价值较高,是一种重要的污染修复植物.组织培养技术为植物品种改良和选育的重要途径,但紫茉莉离体快繁方面的研究尚未见有相关报道.该研究以紫茉莉叶片和茎段为外植体,通过观察和统计外植体愈伤组织和不定芽的诱导情况,分析不同植物生长物质对紫茉莉植株再生的影响.结果表明:紫茉莉带芽茎段比较适合丛生芽的诱导,当带芽茎段在MS+1.0 mg·L-16-BA+1.5 mg·L-1 KT+1.0 mg·L-1 NAA+0.05 mg·L-1 TDZ培养基中培养时,不定芽的增殖系数较高.无论是MS或1/2MS培养基,都可诱导不定根的产生,其中生根效果较好的培养基为1/2 MS+0.5 mg·L-1 NAA.该研究结果探索了紫茉莉组织培养的最适条件,根据愈伤组织诱导率和不定芽的增殖系数筛选出了适宜不定芽诱导的培养基类型,根据不定芽生根情况确定了最佳的生根诱导培养基,为建立紫茉莉高效稳定的再生和遗传转化体系奠定了基础.     

Production of human lactoferrin in transgenic cell suspension cultures of sweet potato

Shoot apical meristem-derived calli were transformed with a hLF cDNA in an attempt to produce human lactoferrin (hLF) in transgenic cell suspension cultures of sweet potato [Ipomoea batatas (L.) Lam.]. Calli were bombarded with tungsten particles coated with the binary vector pLSM1 containing a hLF cDNA under the control of the 35S promoter and the neomycin phosphotransferase gene as a selection marker. Calli were then transferred to Murashige and Skoog (MS) medium supplemented with 4.52 μM 2,4-dichlorophenoxyacetic acid (2,4-D) and 100 mg dm⁻³ kanamycin. Kanamycin-resistant calli were selected at four-week intervals and subcultured. Cell suspension cultures were established in liquid MS medium with 4.52 μM 2,4-D. Southern and Northern blot analyses confirmed that hLF cDNA was incorporated into the plant genome and was properly expressed in the cells. ELISA analysis showed that transgenic cells produced hLF up to 3.2 μg mg⁻¹ (total protein).     

青海野生黑果枸杞再生体系的建立及遗传稳定性分析

以野生黑果枸杞(Lycium ruthenicum Murr.)的无菌苗叶片作为外植体,建立了两条再生体系:一条是经愈伤组织再分化的间接再生体系,一条是不经愈伤组织再分化的直接再生体系。并采用流式细胞术(FCM)及ISSR分子标记技术对两种途径再生苗进行了遗传稳定性分析。结果表明:(1)最佳愈伤组织诱导培养基为MS+1.5 mg·L-12,4-二氯苯氧乙酸(2,4-D),诱导率达100%;最佳分化培养基为MS+1.5 mg·L-16-苄氨基腺嘌呤(6-BA)+0.1 mg·L-1吲哚-3-丁酸(IBA),1 g愈伤组织上的平均不定芽数为39.4个。(2)叶片直接诱导不定芽的最佳培养基为MS+0.5 mg·L-16-BA+0.3 mg·L-1α-萘乙酸(NAA),不定芽诱导率为92.9%,每个外植体上平均不定芽数为18.1个。(3)两条途径再生的不定芽在不含植物生长调节剂的MS培养基上,2周内均可正常生根。(4)FCM结果显示亲本苗及2种再生苗均为二倍体。(5)ISSR分析表明,间接再生苗的平均遗传相似性系数为0.84,直接再生苗的平均遗传相似性系数为0.91,直接再生体系是一种更加快速高效的繁殖方法。     

双色真藓的组织培养和发育研究

对双色真藓(Bryum dichotomum Hedw.)的孢子发育过程及愈伤组织的诱导和培养进行了研究。结果表明,双色真藓孢子萌发和原丝体发育属于典型的真藓型。将双色真藓原丝体接种在含有2.0 mg L-1的硅酸钠和3.0 mg L-1 6-BA的MS固体培养基上,可诱导双色真藓原丝体分化为愈伤组织。愈伤组织在含有2.0 mg L-1的硅酸钠、1.0 mg L-12,4-D和1.0 mg L-1 6-BA的MS固体培养基上可以长期继代培养。而愈伤组织在含有2.0 mg L-1的硅酸钠、1.0 mg L-1 2,4-D和1.0 mg L-1 6-BA的MS液体培养基中可以悬浮培养,且生长迅速,培养28 d达到接种鲜重的9.25倍。     

菜心组织培养技术初探

为建立菜心(Brassica campestris ssp.chinensis var.utilis)的快繁技术体系,以花药和子叶-子叶柄为外植体进行组织培养研究。结果表明,花药培养以选取未开放的花蕾为宜,且花柱略高于花瓣,此时小孢子多数处于单核靠边期。菜心花粉的萌发率不高,且秋冬季的花粉比夏季的萌发率高。菜心花药愈伤组织诱导培养基为:MS+1.0 mg L–1 KT+1.0 mg L–1 2,4-D+3%糖+6 g L–1琼脂+8%椰乳,不定芽诱导培养基为:MS+2.0 mg L–1 6-BA+0.5 mg L–1 NAA+1.0 g L–1活性炭+2%糖+6 g L–1琼脂或MS+2.0 mg L–1 ZT+0.5 mg L–1 IAA+0.5 g L–1 AgNO3+1.0 g L–1活性炭+2%糖+6 g L–1琼脂。花药培养的不定芽诱导率为36.7%,不定芽培养出现褐化现象,不能形成再生植株;而以子叶-子叶柄为外植体培养获得的植株再生率可达80%。     

<Emphasis Type="Italic">In vitro</Emphasis> plant regeneration of the heavy metal tolerant and hyperaccumulator <Emphasis Type="Italic">Arabidopsis halleri</Emphasis> (Brassicaceae)

Plants were regenerated from root explants of Arabidopsis halleri (L.) O’Kane and Al-Shehbaz via a three-step procedure callus induction, induction of somatic embryos and shoot development. Callus was induced from root segments, leaflets and petiole segments after incubation for 2 weeks in Murashige and Skoog medium (MS) supplemented with 0.5 mg/l⁻¹ (2.26 μM) 2,4-D (2,4-dichlorophenoxyacetic acid) and 0.05 mg/l⁻¹ (0.23 μM) kinetin. Only calli developed from root segments continued to grow when transferred to a regeneration medium containing 2.0 mg/l⁻¹ (9.8 μM) 6-γ-γ-(dimethylallylamino)-purine (2ip) and 0.05 mg/l⁻¹ (2.68 μM) α-naphthalenacetic acid (NAA) and eventually 40 of them developed embryogenic structures. On the same medium 38 of these calli regenerated shoots. Rooting was achieved for 50 of the shoots subcultured in MS medium without hormones. The regeneration ability of callus derived from root cuttings, observed in this study, makes this technique useful for genetic transformation experiments and in vitro culture studies.     

High-frequency plant regeneration through callus initiation from mature embryos of maize (<Emphasis Type="Italic">Zea Mays</Emphasis> L.)

An efficient maize regeneration system was developed using mature embryos. Embryos were removed from surface-sterilized mature seeds and sliced into halves. They were used as explants to initiate callus on induction medium supplemented with 4.0 mg l^–1 2,4-dichlorophenoxyacetic acid (2,4-D). The induction frequency of primary calli was over 90% for all inbred lines tested. The primary calli were then transferred onto subculture medium supplemented with 2.0 mg l^–1 2,4-D. Following two biweekly subcultures, embryogenic calli were formed. Inclusion of a low concentration (0.2 mg l^–1) of 6-benzylaminopurine (BA) in the subculture medium significantly promoted the formation of embryogenic callus. The addition of silver nitrate (10 mg l^–1) also supported an increased frequency of embryogenesis. The embryogenic callus readily formed plantlets on regeneration medium supplemented with 0.5 mg l^–1 BA. The regenerated plantlets were transferred to half-strength Murashige and Skoog medium supplemented with 0.6 mg l^–1 indole-3-butyric acid to develop healthy roots. The regenerated plantlets were successful on transfer to soil and set seed. Using this system, plantlets were regenerated from seven elite maize inbred lines. The frequency of forming green shoots ranged from 19.8% to 32.4%. This efficient regeneration system provides a solid basis for genetic transformation of maize.Abbreviations BA 6-Benzylaminopurine - 2,4-D 2,4-Dichlorophenoxyacetic acid - IBA Indole-3-butyric acid - KT KinetinCommunicated by M.C. Jordan     

An interchangeable system of hairy root and cell suspension cultures ofCatharanthus roseus for indole alkaloid production

Hairy roots ofCatharanthus roseus obtained by co-cultivation of hypocotyl segments withAgrobacterium rhizogenes, and cultured in SH (Schenk and Hildebrandt) basal medium, formed two types of calli when subcultured in SH medium with 1 mg/1 -naphthaleneacetic acid and 0.1 mg/l kinetin. One of them, a compact callus, when re-subcultured in SH basal medium gave rise to hairy roots again. A rhizogenic cell suspension culture was established from this type of callus. When cultured in SH medium with growth regulators, the rhizogenic callus produced catharanthine at a level of 41% of the level in the initial hairy roots. Upon transfer to SH basal medium, regenerated hairy roots produced this alkaloid at the original level of 1.5 mg/g dry wt. Using this cell/hairy root interchange system a new management system for hairy root culture in bioreactors has been devised and examined involving production of biomass in the form of a cell suspension in medium supplemented with growth regulators, and catharanthine production by hairy roots regenerated from these cells in medium without growth regulators.Abbreviations NAA -naphthaleneacetic acid - SH Schenk and Hildebrandt - SHNK SH medium + 1 mg 1^–1 NAA + 0.1 mg 1^–1 kinetin     

Genetic transformation and regeneration of rubber tree (Hevea brasiliensis Muell. Arg) transgenic plants with a constitutive version of an anti-oxidative stress superoxide dismutase gene

Agrobacterium tumefaciens-mediated genetic transformation and the regeneration of transgenic plants was achieved in Hevea brasiliensis. Immature anther-derived calli were used to develop transgenic plants. These calli were co-cultured with A. tumefaciens harboring a plasmid vector containing the H. brasiliensis superoxide dismutase gene (HbSOD) under the control of the CaMV 35S promoter. The -glucuronidase gene (uidA) was used for screening and the neomycin phosphotransferase gene (nptII) was used for selection of the transformed calli. Factors such as co-cultivation time, co-cultivation media and kanamycin concentration were assessed to establish optimal conditions for the selection of transformed callus lines. Transformed calli surviving on medium containing 300 mg l^-1 kanamycin showed a strong GUS-positive reaction. Somatic embryos were then regenerated from these transgenic calli on MS2 medium containing 2.0 mg l^-1 spermine and 0.1 mg l^-1 abscisic acid. Mature embryos were germinated and developed into plantlets on MS4 medium supplemented with 0.2 mg l^-1 gibberellic acid, 0.2 mg l^-1 kinetin (KIN) and 0.1 mg l^-1 indole-3-acetic acid. A transformation frequency of 4% was achieved. The morphology of the transgenic plants was similar to that of untransformed plants. Histochemical GUS assay revealed the expression of the uidA gene in embryos as well as leaves of transgenic plants. The presence of the uidA, nptII and HbSOD genes in the Hevea genome was confirmed by polymerase chain reaction amplification and genomic Southern blot hybridization analyses.Communicated by L. Peña     

睡菜离体快繁技术的研究

以睡菜的幼嫩茎段为外植体,接种到附加不同浓度激素配比(6-BA/NAA)的MS培养基,诱导睡菜愈伤组织、芽及根的生长。研究发现,外植体在1.0mg/L 6-BA+0.1mg/L NAA+MS的培养基上培养10d,可观察到浅绿色的愈伤组织。愈伤组织转接到4.0mg/L 6-BA+0.3mg/L NAA+MS培养基上2周左右可生成芽。对带芽的愈伤组织再进行诱导生根进而形成完整再生植株,最适根诱导培养基为0.3mg/L 6-BA+1.0mg/L NAA+MS培养基。该实验采用植物离体快繁技术成功建立了睡菜再生体系,为睡菜种苗规模化奠定了技术基础。