中麻黄悬浮培养体系的建立

本文用中麻黄无菌苗为外植体,其切段培养在附加２ｍｇ／Ｌ２,４－Ｄ和０．５ｍｇ／Ｌ　６　ＢＡ的ＭＳ培养基上,全部脱分化形成白色疏松愈伤组织。愈伤组织继代培养于ＭＳ＋０．５ｍｇ／Ｌ２,４－Ｄ＋０．２ｍｇ／Ｌ６ＢＡ＋０．２ｍｇ／Ｌ　ＮＡＡ＋４％蔗糖的培养某上。以继代培养愈伤组织为材料进行悬浮培养,培养基为附加０．２ｍｇ／Ｌ２,４－Ｄ＋０．１ｍｇ／Ｌ６ＢＡ＋０．１ｍｇ／ＬＮＡＡ＋２％蔗糖的ＭＳ液体培养基,得到分散性好,细胞形状接近圆形,细胞大小均一,细胞团多由２－３０个细胞组成的悬浮培养体系。第三代悬浮培养细胞增长率为０．３５ｇ·ｆｗ／２０ｍｌ·ｄ,细胞有丝分裂指数为１１．２％。条件培养和高密度接种可缩短延迟期,条件培养不能提高分裂指数,１ｇ／１０ｍｌ接种密度可使分裂指数提高至２１．２％。     

草麻黄植株再生体系的建立

目的:以草麻黄的子叶为材料,建立草麻黄植株再生体系.方法:采用组织培养的方法进行了愈伤组织诱导、愈伤组织分化和不定芽生根研究.结果:MS+2,4-D 2.0mg/1+6-BA 1.0mg/l为诱导子叶形成具有分化能力愈伤组织的理想培养基;MS+2,4-D 1.5mg/l+6-BA 1.5mg/l是愈伤组织的最佳继代培养基;MS+IAA 0.2mg/l+TDZ 2.0mg/l是愈伤组织不定芽分化的最佳培养基,分化率为75%;试管苗生根培养基为MS+2,4-D 1.0mg/l.结论:建立了草麻黄子叶再生系统,为开发和保护麻黄野生资源提供一定的材料来源和技术方法.     

沙枣细胞悬浮培养体系的建立

分别以沙枣幼嫩叶片,茎段为外植体诱导沙枣愈伤组织,选择生长旺盛的松散愈伤组织进行细胞悬浮培养,探讨了培养基种类和激素组合对其产生的影响.结果表明,最适的沙枣愈伤组织诱导培养基为NT(包括0.1 mg·L-1BA和0.1 mg·L-1TDZ);沙枣悬浮细胞在MS,NT,WPM,B5和IS培养基中均可生长,其中在NT培养基中生长状态最好,呈现生长均一的绿色疏松状态.激素组合对沙枣细胞生长影响很大,其中附加BA 0.1 mg·L-1和TDZ 0.1 mg·L-1组合的NT液体培养基可获得大量繁殖速度快、生长均匀一致的悬浮细胞,细胞增长系数达5.73.HPLC测定结果证明沙枣细胞中含有一定量的浓缩鞣质达5.2022 mg/gDW,这为利用沙枣悬浮细胞生产次生代谢产物提供了一条有效途径.     

红豆草细胞悬浮培养中体细胞胚的形成

红豆草(Ooobrychis viciaefolia Scop.)为豆科蝶形花亚科红豆草属多年生草本植物。由于营养丰富,生活力强,抗旱,耐瘠薄,适合西北干旱地区种植,是农民喜爱的牧草。有的学者已对红豆草在组织培养中体细胞胚的形成     

藏红花细胞悬浮培养体系的建立及优化

基于诱导的藏红花细胞系,通过摇瓶法,优化了其液体培养基、接种量和种龄等培养条件,以建立藏红花细胞悬浮培养体系。结果表明,将生长在固体培养基上的藏红花愈伤组织接种在MS液体培养基(添加了2mg/L2,4-D,1mg/L6-BA和300mg/LCH)中,于(22±0.3)℃,120r/min的摇床上,暗培养30d,便可获得藏红花的悬浮细胞系。经优化其培养基、接种量和种龄,将种龄为20d的细胞系,按照5%接种量接种在液体B5培养基(添加了2mg/LNAA,1mg/L6-BA和300mg/LCH)中,于(22±0.3)℃,120r/min的摇床上,培养36d,细胞生物量(13.4g/L)和藏红花素产量(0.91g/L)均达到最高。本研究建立的藏红花细胞悬浮培养体系为其生物反应器放大培养奠定了基础。     

薰衣草细胞悬浮培养体系的优化

采用正交设计方法对影响薰衣草悬浮细胞生长的因素进行了优化研究,筛选了最有利于薰衣草悬浮细胞生长的培养条件:含有0.025mg/L2,4-D、0.5mg/L6-BA、40g/L蔗糖的B5培养基和120r/min的转速,在此条件下培养15天,悬浮活细胞密度可达到4.4×105个/ml;经过3个月的培养,悬浮细胞的分化率可达到90%以上。通过分析薰衣草细胞对残糖的消耗规律,探讨了蔗糖浓度影响活细胞密度的原因。     

紫茉莉悬浮细胞培养体系的建立

为建立紫茉莉(Mirabilis jalapa L.)悬浮细胞培养体系,以紫茉莉无菌苗叶片诱导的愈伤组织为材料,筛选紫茉莉悬浮细胞的适宜培养体系。结果表明,紫茉莉愈伤组织在MS+2,4-D 1 mg L-1+KT 0.5 mg L-1的液体培养基中悬浮继代培养3~4次,能得到稳定的悬浮细胞系。培养基的pH值为5.5~5.9,蔗糖浓度为30 g L-1更适合悬浮细胞的生长。紫茉莉悬浮细胞的生长曲线大致呈S型。最佳继代培养时间是10 d,培养液的体积为40 mL时,接种量为7.5 mL,可以较好地保持悬浮细胞系。1 L培养液中可提取分泌蛋白(0.42±0.15) g。这些有助于对悬浮细胞提取分泌蛋白的研究。     

几种外源含氮化合物对草麻黄愈伤组织增殖和麻黄碱含量的影响

在20和40mg·L-1的亚硝酸钠以及50mg·L-1的苯丙氨酸处理下草麻黄茎段愈伤组织增殖量增大,而酪氨酸和蛋氨酸处理的愈伤组织增殖量则下降,且随着这类外源物质浓度的增大其下降幅度也增大。60mg·L-1蛋氨酸、20mg·L-1酪氨酸和50mg·L-1苯丙氨酸可以有效提高草麻黄愈伤组织中麻黄碱的生成量。     

除虫菊细胞的悬浮培养

除虫菊悬浮细胞从培养后第8天开始迅速生长,14 d达到最大生长量,其最适培养基为:MS 4mg·L-12,4-D 0.1mg·L-1NAA 0.3 mg·L-16-BA 30 g·L-1蔗糖,最适接种量为15 g·L-1,摇瓶装液的体积分数为40%,初始培养的最适pH值为5.8,收获时pH下降为4.6±1,最适培养温度为25℃.     

Composition and stereochemistry of ephedrine alkaloids accumulation in Ephedra sinica Stapf

Ephedra sinica Stapf (Ephedraceae) is a widely used Chinese medicinal plant (Chinese name: Ma Huang). The main active constituents of E. sinica are the unique and taxonomically restricted adrenergic agonists phenylpropylamino alkaloids, also known as ephedrine alkaloids: (1R,2S)-norephedrine (1S,2S)-norpseudoephedrine, (1R,2S)-ephedrine, (1S,2S)-pseudoephedrine, (1R,2S)-N-methylephedrine and (1S,2S)-N-methylpseudoephedrine. GC–MS analysis of freshly picked young E. sinica stems enabled the detection of 1-phenylpropane-1,2-dione and (S)-cathinone, the first two putative committed biosynthetic precursors to the ephedrine alkaloids. These metabolites are only present in young E. sinica stems and not in mature stems or roots. The related Ephedra foemina and Ephedra foliata also lack ephedrine alkaloids and their metabolic precursors in their aerial parts. A marked diversity in the ephedrine alkaloids content and stereochemical composition in 16 different E. sinica accessions growing under the same environmental conditions was revealed, indicating genetic control of these traits. The accessions can be classified into two groups according to the stereochemistry of the products accumulated: a group that displayed only 1R stereoisomers, and a group that displayed both 1S and 1R stereoisomers. (S)-cathinone reductase activities were detected in E. sinica stems capable of reducing (S)-cathinone to (1R,2S)-norephedrine and (1S,2S)-norpseudoephedrine in the presence of NADH. The proportion of the diastereoisomers formed varied according to the accession tested. A (1R,2S)-norephedrine N-methyltransferase capable of converting (1R,2S)-norephedrine to (1R,2S)-ephedrine in the presence of S-adenosylmethionine (SAM) was also detected in E. sinica stems. Our studies further support the notion that 1-phenylpropane-1,2-dione and (S)-cathinone are biosynthetic precursors of the ephedrine alkaloids in E. sinica stems and that the activity of (S)-cathinone reductases directs and determines the stereochemical branching of the pathway. Further methylations are likely due to N-methyltransferase activities.     

Establishment of Orthosiphon stamineus Cell Suspension Culture for Cell Growth

Callus of Orthosiphon stamineus could be induced successfully from petiole, leaf and stem tissues but not roots when cultured on MS medium containing different concentration of NAA (0–4.0 mg l^–1) and 2,4-D (0–2.0 mg l^–1). Highest fresh weight callus production was obtained from leaf explants and those with best friability were obtained on MS medium plus 1.0 mg l^–1 2,4-D plus 1.0 mg l^–1 NAA. Cell suspension cultures were established from these cultures. The appropriate cell inoculum size for the best cell growth was 0.75 g of cells in 20 ml culture medium. Cell suspension culture using MS medium supplemented with 1.0 mg l^–1 2,4-D promoted the best cell growth with maximum biomass of 8.609 g fresh weight and 0.309 g dry weight 24 days after inoculation. Cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D reached the stationary growth phase in 15 days as compared to the cells that grew in MS medium supplemented with 1.0 mg l^–1 2,4-D + 1.0 mg l^–1 NAA reached the stationary phase in 24 days. MS medium supplemented with 1.0 mg l^–1 2,4-D was considered as the maintenance medium for maintaining the optimum cell growth of O. stamineus in the cell suspension cultures with 2-week interval subculture.     

Studies on Cell Suspension Culture of Panax notoginseng

The optimum period of harvesting in cell suspension culture of Panax notoginseng was 30 days. The time course of sap.nih formation proceeded almost in parallel with the cell growth. An appropriate concentration of oligosaccharms from Panax ginseng, precursor fames.l, mannffol and lysozymum which were added into tbe culture broth 10 days before harvesting, all induced saponin biosynthesis significantly. Oligosaecharins at a concentration of 15ppm(it increased 1 fold of saponin yield, and increased 22.7%(of cell growth rate compared with those of the control) and farnesol at 200ppm(it increased 70.5% of sap.nih yield and stimulated cell growth compared with those of the control) were more effective.     

云南红豆杉细胞的悬浮培养

在云南红豆杉细胞悬浮培养中,适宜的培养基为B5,接种量为0．5～0．8g干重细胞／100ml培养基,2,4－D浓度为1．0mg／L;培养细胞的生长周期约30d;培养基中较高浓度的蔗糖（40g／L）可提高紫杉醇含量;添加的椰子汁（CM）、酪蛋白氨基酸（C）和水解乳蛋白（LH）3种有机添加剂均能提高培养细胞中紫杉醇的含量,但只有CM和CA能促进细胞的生长。于B5培养基中添加不同浓度的NH4NO3对培养细胞无明显影响。