The Influence of Different Factors on Cell Growth and α-tocopherol Content of Culture from Carthamus tinctorius

Calli were induced from root, hypocotyl, cotyledon and flower bud of Carthamtus tinctorius. All calli had the capability to synthesize α-tocopherol. Among these calli, the hvpocotylcallus was better than others in cell growth rate and α-toeopherol content. Culture conditions could intensively influence the growth rate and α-tocopherol production of callus from Carthamus tinctorius. Sucrose (30g/L) was good for callus growth and glucose (30g/L) was good for α-tocopherol accumulation. High concentration (0.55%) of inositol could obviously stimulate both growth rate and α-tocopherol synthesis of callus. The inoculum quantity for best callus growth was 0.035 to 0.067g dry wt/flask (50ml volume). In addition, α-tocopherol content was effectively increased by culture callus in high CO2 concentration. Studies on optimum cuhure conditions of callus culture showed that the callus growth rate, α-tocopherol content and yield were 1.88, 2.03 and 3.30 times respectively as high as of the control by administration of 0.45%–0.55% inositol, 10% coconut milk, 0.1–0.5% casamino acid, 30g/L sucrose and 10g/L glucose.     

寡糖素对红花及三七培养细胞的生理作用

三种寡糖素,即来自人参(Panax ginseng)培养细胞的人参寡糖素、红花(Carthamus tinctorius)培养细胞的红花寡糖素、黑节草(Dendrobium candidum)植物的黑节草寡糖素对红花及三七 (Panax notoginseng)的培养细胞的生长及代谢产物的含量均有显著的促进作用。寡糖素可耐高温高压(121℃、1.2bs／cm2)灭菌15分钟而不失活,其对植物培养细胞的影响与利用过滤方法灭菌的效果相似。红花寡糖素对红花悬浮培养细胞作用的适宜浓度是5-10mg/L,而在愈伤组织中为15mg/L,在三七培养细胞进入生长旺盛(培养至22天)时加入黑节草寡糖素,再培养2天后其生长即提高。黑节草寡糖素均能缩短红花及三七培养细胞生长的延缓期,提前进入对数生长期及指数生长期。并且使红花培养细胞中a-生育酚在细胞生长最活跃的指数生长期大量积累,最终增加了培养细胞及代谢产物的产率。     

Production of tocopherols by cell culture of safflower

A new method for the production of tocopherols by safflower (Carthamus tinctorius) cell culture has been developed. The main tocopherol produced is α-tocopherol which has the strongest vitamin E activity among tocopherol analogues. In a time course experiment tocopherol production showed a secondary metabolic pattern rather than a primary one. Better cell lines in terms of both growth rate and amounts of tocopherols produced were obtained by selection using various growth regulators and media additives. In addition, tocopherol production was effectively stimulated by administration of biosynthetic precursors. In particular, phytol increased the total tocopherol content by some 18-fold, i.e. 63.6 mg per 100 g dry weight, and the α-tocopherol content by some 11- fold i.e. 28.8 mg per 100 g dry weight.     

人参寡糖素对三七悬浮培养细胞生长的效应

从人参培养细胞的细胞壁中分离纯化到不同分子量的单体人参寡糖素。试验结果表明命名为人参寡糖素Ⅶ和人参寡糖素Ⅷ的两种寡糖素对三七悬浮培养细胞的生长具有明显的促进作用,其增长率分别为１９．３４％和１０．５８％,人参寡糖素Ⅶ的适宜浓度为５—１０ｍｇ／ｌ。在高浓度下（大于２５ｍｇ／ｌ）稍抑制培养细胞生长。在细胞培养２２天（指数生长期）后．加入１０ｍｇ／ｌ的人参寡糖素Ⅶ．然后再培养２天。其生长速率即提高,加入人参寡糖素Ⅷ后．缩短了三七细胞悬浮培养生长的延缓期．提前进入对数生长期和指数生长期,并在对数生长期和指数生长期作用最明显,因而最终收获时培养细胞的产率增加。     

红花愈伤组织诱导、生长及其α-生育酚的产生

通过TLC和HPLC初步分析和鉴定,证明从红花(Carthamus tinctorius)无菌苗的胚根、胚轴及子叶和花蕾中诱导出的愈伤组织均具有合成α-生育酚的能力。其中以胚轴的愈伤组织和悬浮培养细胞的生长速率及α-生育酚的含量较高,分别达到0.35、0.39克干重/升·天和0.62、2.28毫克/100克干重样品。对红花细胞生长较适宜的培养基为MC培养基。培养基中附加10％椰子汁或0.1％酪蛋白氨基酸可使细胞生长显著提高,分别达到0.45和0.41克干重/升·天。     

Setting up a Single Cell Clone Lines of Cathamus tinctorius

Different concentrations of 2,4-D, KT and NAA were able to influence the plating efficiency (PE) of single cells of Cathamus tinctorius. The best combination of these three hormones for the growth of single cells was 2.0, 0.3 and 0.5 mg/l, respectively. The PE was obviously different as cells came from different generations of suspension subculture and the third generation of suspension culture cells, had the best PE which 8.5 times as high as that of the first generation of suspension culture cells. Single cell growth in condition medium or in solid-liquid dual layer culture was better than in normal plate culture. The PE of single cell clones in condition culture was 3.6 times as high as in normal plate culture. The PE of single cell clones in solid-liquid dual layer culture was 4.7 times as high as in normal plate culture. Many clones from single cells were set up. Different growth rates were observed in different single-cell clones. The lowest growth rate in these clones was 3.08 g/g/35 days, the highest growth rate in these clones was 23.33 g/g/35 days.     

Biotransformation of 3b-Hydroxyandrost-5-en-17-one by Cell Suspension Cultures of Catharanthus roseus

Catharanthus roseus (L.) G. Don cell suspension cultures were used to transform 3b-hydroxyandrost-5-en-17-one, the products were isolated by chromatographic methods. Their structures were established by means of NMR and MS spectral analyses. Nine metabolites were respectively elucidated as: androst-4-ene-3,17-dione (Ⅰ), 6a-hydroxyandrost-4-ene-3,17-dione (Ⅱ), 6a,17b-dihydroxyandrost-4-en-3-one (Ⅲ), 6b-hydroxyandrost-4-ene-3,17-dione (Ⅳ), 17b-hydroxyandrost-4-en-3-one (Ⅴ), 15a,17b-dihydroxyandrost-4-en-3-one (Ⅵ), 15b,17b-dihydroxyandrost-4-en-3-one (Ⅶ), 14a-hydroxyandrost-4-ene-3,17-dione (Ⅷ), 17b-hydroxyandrost-4-ene-3,16-dione (Ⅸ). It is the first time to obtain the above compounds by biotransformation with Catharanthus roseus cell cultures.     

Induction of a photomixotrophic plant cell culture of Helianthus annuus and optimization of culture conditions for improved α-tocopherol production

Tocopherols, collectively known as vitamin E, are lipophilic antioxidants, which are synthesized only by photosynthetic organisms. Due to their enormous potential to protect cells from oxidative damage, tocopherols are used, e.g., as nutraceuticals and additives in pharmaceuticals. The most biologically active form of vitamin E is α-tocopherol. Most tocopherols are currently produced via chemical synthesis. Nevertheless, this always results in a racemic mixture of different and less effective stereoisomers because the natural isomer has the highest biological activity. Therefore, tocopherols synthesized in natural sources are preferred for medical purposes. The annual sunflower (Helianthus annuus L.) is a well-known source for α-tocopherol. Within the presented work, sunflower callus and suspension cultures were established growing under photomixotrophic conditions to enhance α-tocopherol yield. The most efficient callus induction was achieved with sunflower stems cultivated on solid Murashige and Skoog medium supplemented with 30 g l^?1 sucrose, 0.5 mg l^?1 of the auxin 1-naphthalene acetic acid, and 0.5 mg l^?1 of the cytokinin 6-benzylaminopurine. Photomixotrophic sunflower suspension cultures were induced by transferring previously established callus into liquid medium. The effects of light intensity, sugar concentration, and culture age on growth rate and α-tocopherol synthesis rate were characterized. A considerable increase (max. 230 %) of α-tocopherol production in the cells was obtained within the photomixotrophic cell culture compared to a heterotrophic cell culture. These results will be useful for improving α-tocopherol yields of plant in vitro cultures.     

The Chemical Constituents of Antitumor from Sabina vulgaris Ant

Eleven known compounds, transcommunic acid (Ⅰ), cis-communic acid (Ⅱ), sandaracopimaric acid (Ⅲ), isocupressic acid (Ⅳ), sugiol (Ⅴ), 12-hydroxy-6, 7-seco- abieta-8, 11, 13-triene 6, 7-dial (Ⅵ), β-peltatin-A-methyl ether (Ⅶ), bergaptin (Ⅷ), β-sitosterol (Ⅹ), lignoceric acid (Ⅺ), cerotic acid(Ⅻ) and a new 3, 4-benzocumarins sabilactone (Ⅸ) were newly isolated from the bark of Sabina vulga ris Ant. (= Juniperus sabina L.). Their structures were determined from spectra data and chemical evidence. Compounds Ⅳ–Ⅹ were first isolated from this plant. The bioassay results showed that compounds Ⅰ–Ⅳ, Ⅵ andⅦ were shown to be cytotoxic effects for P-388 leukemia cell in vitro.     

Alkaloid production by plant cell cultures of Holarrhena antidysenterica: II. Effect of precursor feeding and cultivation in stirred tank bioreactor

Precursor feeding strategy for increasing the yield of conessine, a steroidal alkaloid of Holarrhena antidysenterica, was established in cell suspension culture. A total of 50 mg/L added cholesterol was converted into 43 mg/L of alkaloid, 90% of which constituted the conessine. By applying the precursor feeding policy to the cell suspension culture in modified Murashige and Skoog (MS) medium, a total of 143 mg/L of alkaloid was produced in 8 days. In this way the alkaloid content of the cells was increased more than six times compared to that obtained in the standard MS medium. The steps leading to biotransformation of cholesterol into alkaloids were unaffected by phosphate. The shake flask data were successfully transferred to a bench scale 6-L stirred tank bioreactor in which the specific biosynthetic rate of alkaloid production was 110 mg/100 g dry cell weight per day, about 160 times higher than that of whole plant.     

真菌诱导子对悬浮培养西洋参细胞的生理效应

报道了不同真菌诱导子对悬浮培养的西洋参（Ｐａｎａｘｑｕｉｎｑｕｅｆｏｌｉｕｍ）细胞生长、皂甙和多糖合成,以及细胞内和培养液中过氧化物酶活性的生理效应。悬浮培养的西洋参细胞经刺盘孢菌（Ｃｏｌｌｅｔｏｔｒｉｃｈｕｍｎｉｃｏｌｔｉａｎａｅ）丝体诱导子处理后,总皂甙产率可由对照的２９６ｍｇ／Ｌ增加到６７９ｍｇ／Ｌ（约占细胞干重的（１６．３％）,比对照提高约１．３倍,而且总皂甙的８５％排放在培养液中;经黑曲霉（Ａｓｐｅｒｇｉｌｌｕｓｎｉｇｒａｎ）诱导子处理后,细胞多糖含量可达到１１．７９％（细胞干重）,比对照增加１倍多。初步纯化的刺盘孢菌丝体诱导子和尖孢镰刀菌（Ｆｕｓｕｒｉｕｍｏｘｙｓｐｏｒｕｍ）滤液诱导子在诱导处理前期能明显促进西洋参细胞生长,同时细胞内及培养液中过氧化物酶活性显著增加;随时间延长,细胞生长和酶活性逐步受到抑制。     

红豆杉细胞培养的研究

从红豆杉（Ｔａｘｕｓｃｈｉｎｅｎｓｉｓ（Ｐｉｌｇ）Ｒｅｈｄ）的嫩茎及针叶诱导的出愈伤组织,对愈伤组织培养及细胞悬浮培养进行了研究,利用ＨＰＬＣ方法测定它们合成紫杉醇的能力,发现了能够提高培养细胞生长速率及紫杉醇含量的一些因子,红豆杉愈伤组织及悬浮培养细胞的生长速率已分别达到０．２５ｇ／Ｌ．ｄ和０．２８ｇ／Ｌ．ｄ。而他们的紫杉醇含量分别是０．００２６％和０．０１２％。     

人参细胞悬浮培养中的激素调节及细胞分裂的研究

在人参细胞悬浮培养中,单使用植物生长调节剂时以Zmg/L 2,4—D和2mg/LNAA的效果较好.在不同激素组合的试验中,以2mg/L 2,4—D+2mg/L NAA+0.5mg/L KT的效果最好.悬浮条件下人参细胞的再生方式有有丝分裂、无丝分裂和出芽繁殖,其中直径为50μm以下的小型园形细胞的分裂为有丝分裂,而葫芦形、肾形、长园形及不定形的巨型细胞常表现为无丝分裂和出芽繁殖.植物激素对不同类型细胞的分裂有一定的影响作用.和愈伤组织固体培养相比,细胞悬浮培养可使细胞干重增加近5倍.     

几种生理因子对印楝细胞悬浮培养生长的影响

通过研究不同生理因子对印楝悬浮细胞生长的影响 ,建立了一种快速生长的印楝细胞悬浮培养体系。结果表明 ,在添加了 6 BA 0 .8mg/L、NAA 0 .8mg/L、蔗糖 3 0 g/L且初始 pH值为 5 .8的MS培养液中 ,以 60g/L的接种量进行印楝细胞的悬浮培养 ,细胞生长速率可达 4.49g/L·d。     

胡萝卜细胞培养产胡萝卜素的研究

从鲜红胡萝卜主根部选取外植体,用MS型培养基诱导出愈伤组织,继代培养,周期22d,接着进行细胞的液体悬浮培养。液体培养20d时,测定β-胡萝卜素含量达41．7mg／L,占细胞干重的0．35％。培养细胞中含胡萝卜素是胡萝卜根部的3．38倍,色素比产率提高15．4倍。     

Studies on the Chemical Constituents of Pyrus Communis

An aqueous extract of the twigs of Pyrus communis L. var. sativa (DC) DC. showed inhibitory effect against S-180. Compounds were isolated from the twigs of P. communis and eight of them were identified as nonacosane (Ⅰ), lupeol (Ⅲ), β-sitosterol (Ⅳ), betulin (Ⅴ), betulinic acid (Ⅵ), daucosterol (Ⅶ), hydroquinone (Ⅷ) and arbutin (Ⅸ) by MS, NMR, IR, UV and some chemical techniques. It was showed that the compounds Ⅲ, Ⅳ, Ⅴ, Ⅵ, Ⅷ and Ⅸ possessed some bacteriostatic activities on Escherichia coli, Salmonella typhi, Shigclla flexneri and Staphylococus aureus. Primary pharmacology tests showed that Ⅷ had inhibitory effect against S-180 (47.5%).     

青扦胚性细胞悬浮培养中影响体细胞胚发生因素的研究

试验以青扦（Ｐｉｃｅａｗｉｌｓｏｎｉ）的胚性愈伤组织为材料,以改良５９基本成分附加２４－Ｄ１ｍｇ／Ｌ及ＫＴ１ｍｇ／Ｌ为培养介质,比较了液体悬浮与半固体二种培养方式对胚性愈伤组织增殖和体细胞发生的影响,研究了液体悬浮培养过程中影响体细胞胚发生的因素。结果表明：液体悬浮培养好于半固体培养,它的胚性愈伤组织的生长率为２６８％,是半固体培养的１２４倍;体细胞胚的分化率为９３％,是半固体培养的２２倍;悬浮培养较佳的培养条件为：初始细胞密度为２％（鲜重）,蔗糖浓度为２０ｇ／Ｌ,摇床转速为１００ｒ／ｍｉｎ,ｐＨ为５８。经过两个月悬浮培养,将培养物转至１／２改良５９附加ＡＢＡ１ｍｇ／Ｌ的分化培养基上,３个月后每ｇ培养物上可获得２８５个正常的子叶期体细胞胚。     

石竹细胞悬浮培养研究

石竹细胞继代周期为 7d时 ,悬浮细胞培养系生长最快 ,生长率最高 ,而且培养物中胚性细胞较多 ,并能保持较快的分裂和生长 ,能促进已形成的大细胞团的生长和分化。转代时接种物与新鲜培养基的体积比以1∶2较好 ,悬浮系细胞生长最快 ,生长率最高 ,以 1∶2和 1∶3的高倍稀释接种有利于胚性细胞的形成及产生小的胚性细胞团 ,对悬浮系添加椰乳和水解乳蛋白的混合物 ,可较大幅度地提高悬浮细胞系的生长速率 ,单独添加上述两种物质的效果均不如二者的综合效应好。在 6种不同激素组合中 ,配方 2 (2 ,4 D 1 .5mg/L +NAA0 .5mg/L +6 BA 0 .5mg/L)最好 ,生长率最高。配方 5 (2 ,4 D 1 .5mg/L +NAA 0 .5mg/L +6 BA 1 .0mg/L)其次 ;配方 1 (2 ,4 D 1 .0mg/L +NAA 0 .5mg/L +6 BA 0 .5mg/L)次之。     

杜仲细胞悬浮培养产黄酮及其动力学研究

本文应用正交设计对杜仲细胞悬浮培养的基本培养基和植物生长物质浓度进行了筛选,并对影响杜仲细胞悬浮培养和总黄酮含量的不同因素进行了考察。结果表明,B5培养基+0.5mg/L NAA+0.6mg/L 6-BA、蔗糖30g/L、初始pH 5.0-5.5、接种量20g(FW)/L以及摇床转速110r/min为杜仲细胞悬浮培养的适宜条件。通过对杜仲悬浮细胞生长和代谢动力学的分析表明：杜仲细胞悬浮培养生长符合Logistic生长模型,最大比生长速率( m)为0.417d-1;细胞基于蔗糖的真正比生长得率(YG)与维持系数(m)分别为0.619g/g和0.0206g/(g·d-1);黄酮合成属部分生长耦联型,可用Luedeking-Piret模型进行描述。研究结果为杜仲细胞大规模悬浮培养生产天然活性成分奠定了基础。     

三七.人参和西洋参细胞悬浮培养的比较研究

用薄层层析对三七、人参和西洋参愈伤组织进行的初步鉴定表明,三种愈伤组织都含有皂甙和主要皂甙成分Rb_1、Rg_1,三七愈伤组织还含有一种抗癌皂甙Rh_1。对愈伤组织的生长,三七低于人参高于西洋参;对愈伤组织中总皂甙含量,三七均高于人参和西洋参。三种植物细胞悬浮培养结果类似于他们的愈伤组织培养,但生长又进一步提高。三七细胞悬浮培养中皂甙产生的时间进程几乎与生长平行,合适的收获期为培养30天。寡糖素不仅增强三七培养细胞的皂甙形成而且促进细胞生长,较合适的浓度为1.25 ppm。通过以上研究,使三七悬浮培养细胞的生长(干重增加178毫克)为最初培养愈伤组织的4倍以上,总皂甙产率高达20.6毫克,为最初培养愈伤组织的8.5倍。