东北红豆杉细胞培养生产紫杉醇的调控研究

研究了诱导子、前体及抑制剂的协调作用对东北红平杉生产紫杉醇的影响。结果表明,向培养基中加入80mg/L水到、80mg/L茉莉酸甲酯、0.5mmol/L乙酸钠、2mmol/L苯丙氨酸、0.5mmol/L丝氨酸、0.1mmol/L甘氨酸、10mg/L肉桂酸、0.5mmol/L苯甲酸钠、5mmol/L丙酮酸钠、10mg/L氯化氯胆碱、和1mg/L赤霉酸可使紫杉醇含量提高368.65%。并且证明交互作用对紫杉醇合成有显著作用。     

响应面法在紫杉醇产生菌发酵前体优化中的应用

采用响应面法对美丽镰刀菌（Fusarium mairei K178）发酵合成紫杉醇途径中一些可能的前体进行优化研究。首先采用Plackett-Burman法对8个因素进行了筛选,结果表明,苯丙氨酸,苯甲酸钠和乙酸钠三个因素对紫杉醇产量影响较大。在此基础上,再通过Box-Behnken设计,利用Design-Expert软件进行二次回归分析,得到各因素的最佳浓度为：苯丙氨酸2.8mg/L,苯甲酸钠31.8mg/L,乙酸钠3.3g/L。在优化条件下紫杉醇的产量达到242.6μg/L,较前体单因素实验最高值提高15.6%。     

前体对水母雪莲悬浮培养细胞黄酮合成的影响

在水母雪莲（Saussurea medusa Maxim)细胞悬浮体系中加入苯丙氨酸、肉桂酸和乙酸钠3种前体。结果显示,3种前体均能促进细胞内黄酮的生物合成,但它们对细胞的生长也有一定的抑制作用。实验表明,3种前体的添加时间均以第6天为宜。苯丙氨酸的最佳添加浓度为0.05mmol/L,肉桂酸、乙酸钠的最佳添加浓度都是0.1mmol/L。3种前体中,难溶于水的肉桂酸对黄酮合成的促进作用最强,它可使培养物的黄酮产量高达1801mg/L,是对照1．98倍。苯丙氨酸、乙酸钠两种前体协同添加,比它们单独加入更能促进细胞的黄酮合成。     

前体及诱导子和发酵条件对烟曲霉TMS-26产紫杉醇发酵体系优化

紫杉醇是一种广谱的抗癌药物,因其具有独特的抗癌机制、良好的抗癌效果和供不应求的市场等特征而备受关注。紫杉醇具有重大经济效益,但产量受到制约,价格极为昂贵,通过内生真菌发酵法生产紫杉醇能在一定程度上缓解其来源困难的问题。在产紫杉醇内生真菌TMS-26发酵液中添加前体物质和诱导子,并通过对接种量、装液量、初始pH和发酵时间等条件进行优化研究。单因素及正交试验表明在PDB培养基中加入苯丙氨酸20mg/L、苯甲酸钠30mg/L、乙酸钠8g/L、甘氨酸15mg/L、CuSO₄ 0.05mg/L、H₂O₂ 6mmol/L、3,5-二硝基水杨酸15mg/L时能有效提高紫杉醇产量,比优化前增产46.64%,达到446.28µg/L,并且发现最适菌株TMS-26的发酵条件为pH7.5、接种量5%、装液量120mL/250mL、发酵时间为10d。     

前体、诱导子及抑制剂对紫杉烷生物合成的促进作用研究

研究了前体、诱导子和抑制剂对中国红豆杉细胞培养生产紫杉烷的促进作用。结果表明,向培养基中加入30mg/L 3-甲基－2－丁烯－1－醇,2mmol/L苯甲酸钠,10mg/L矮壮素,100μmol/L茉莉酸甲酯,0.1mmol/L丝氨酸,可以使紫杉醇含量增加1141.1%;加入0.1mmol/L苯甲酸钠,80μmol/L茉莉酸甲酯,0.1mmol/L丝氨酸可以使2α,5α,10β,14β－四乙酰氧基－紫杉－4（20）,11－二烯含量增加134.6%;25mg/L矮壮素,100μmol/L茉莉酸甲酯,0.5mmol/L丝氨酸可以使1β－羟基巴卡亭I含量增加95.2%;5mg/L3－甲基－2－丁烯－1－醇,10mg/L矮壮纱,40μmol/L茉莉酸甲酯,可以使14β-(2-甲基丁酰氧基）－2α,5α,10β－三乙酰氧基－紫杉－4（20）,11－二烯的含量增加76.4%。     

前体、诱导子及抑制剂对细胞培养生产紫杉醇的调节作用

研究了前体、诱导子和抑制剂对中国红豆杉细胞培养生产紫杉醇的影响。结果表明 ,它们之间的协同作用对提高紫杉醇的产量有显著影响。其中向培养基中加入 30mg/L 3 甲基 2 丁烯 1 醇 ,2mmol/L苯甲酸钠 ,10mg/L氯化氯胆碱 (CCC) ,10 0 μmol/L茉莉酸甲酯 (MJ) ,0 1mmol/L丝氨酸 (Ser)可以使紫杉醇含量增加 1141 1%。     

几种促进剂的添加时间对中国红豆杉细胞悬浮培养紫杉醇合成的影响

采用正交实验检测中国红豆杉[Taxus chinensis(Pilger)Rehd.]细胞悬浮培养中水杨酸、硝酸银、氨基酸前体、D-果糖和硫酸镧的添加时间对细胞生长和紫杉醇(taxol)积累的影响.这些促进剂的添加时间对中国红豆杉细胞悬浮培养的生长没有明显的影响,但能明显促进紫杉醇的合成,当在细胞培养的第14 d添加1.67 mg/L硝酸银,第18 d添加0.1 mg/L水杨酸,第21 d添加氨基酸前体,第21 d添加10 g/L D-果糖和2 mg/L硫酸镧时对紫杉醇的促进作用最明显,在此最优组合处理时紫杉醇含量达到10.05 mg/L,相对于最差组合处理时紫杉醇含量仅有1.77 mg/L,紫杉醇含量提高5.7倍,这些因素的添加时间对紫杉醇合成的相互作用达不到显著水平.     

红豆杉内生真菌中巴卡亭Ⅲ产生菌的筛选及培养基的初步优化

目的:筛选出产巴卡亭Ⅲ的红豆杉内生真菌,为抗癌药物紫杉醇提供一个新的来源。方法:从云南红豆杉树皮中分离纯化出内生真菌,对其进行液体发酵培养,过滤,收集菌丝体并破碎,用二氯甲烷萃取,萃取液进行薄层层析,与巴卡亭Ⅲ标准品有相同比移值的样品再利用高效液型色谱与标样进行比照,进而筛选出产巴卡亭Ⅲ的内生真菌。同时以发酵培养基基础,对筛选出的真菌进行碳源和氮源的优化。并在此基础上探讨几种常见的紫杉烷类化合物代谢诱导剂乙酸钠、苯甲酸钠、苯丙氨酸和亮氨酸的浓度对巴卡亭Ⅲ积累的影响。结果:得到一株产巴卡亭Ⅲ的内生真菌NSZJ043,该菌株易培养,生长迅速,经鉴定属于曲霉属。NsZJ043产巴卡亭Ⅲ的培养条件的初步优化结果表明:最适碳源、氮源分别是蔗糖和蛋白胨;在含20g/L蔗糖、1．5g/L蛋白胨、0．1 mmol/L乙酸钠、0．01mmol/L苯甲酸钠的优化培养基中培养8d,巴卡亭Ⅲ含量为34．6μg/L。结论:筛选出一株产巴卡亭Ⅲ的内生真菌,其具有优良的发酵特性,巴卡亭Ⅲ前体物质苯甲酸钠和乙酸钠对巴卡亭Ⅲ的合成有促进作用;苯丙氨酸和亮氨酸对其含量影响不显著,优化后NSZJ043产巴卡亭Ⅲ含量有较大的提高。     

烟曲霉TMS-26产紫杉醇补料分批发酵条件初步探索

内生真菌发酵法是解决紫杉醇药源短缺问题的有效途径之一。本研究以摇瓶分批发酵为基础,进行摇瓶补料分批发酵研究,探究了苯丙氨酸、甘氨酸、苯甲酸钠乙酸钠混合液、3,5-二硝基水杨酸、H₂O₂、CuSO₄在发酵周期（13d）中,不同添加时间点对TMS-26菌体量及紫杉醇产量的影响,发现在第8天添加苯丙氨酸、甘氨酸、3,5-二硝基水杨酸时,其产量分别达到了(664.80±40.34)µg/L、(628.72±30.44)µg/L、(641.36±19.62)µg/L;在第9天添加CuSO₄时,其产量达到了(697.46±15.76)µg/L;在第10天添加H₂O₂、苯甲酸钠乙酸钠混合液,其产量分别达到了(615.78±36.28)µg/L、(792.54±10.04)µg/L。在摇瓶补料分批发酵研究结果的基础上,进行了5L罐发酵工艺放大研究,探究了前体和诱导子通过进行一次补加和恒速补加的方式对Aspergillus fumigatus TMS-26菌体量及紫杉醇产量的影响,结果表明恒速补加苯丙氨酸乙酸钠混合液,紫杉醇产量达到了746.17µg/L。通过本次研究,优化了TMS-26产紫杉醇摇瓶补料分批发酵和5L罐发酵工艺,为后续实现紫杉醇工业化生产奠定基础。     

培养基组成对树状多节孢(Nodulisporium sylviforme)紫杉醇产量的影响

采用正交试验法 ,研究了醋酸钠、苯丙氨酸、酪氨酸、亮氨酸对紫杉醇产生菌HQD3 3 产生紫杉醇的影响。结果表明 ,它们之间的协同作用对提高紫杉醇产量有显著影响。在改良的S - 7培养基基础上 ,再加入醋酸钠 1 0g/L、苯丙氨酸 5 0mg/L、酪氨酸 1 5mg/L、亮氨酸 6 0mg/L ,可以使紫杉醇产生菌HQD3 3 产生紫杉醇产量提高到 2 0 3 6 5 6 μg/L。     

Paclitaxel production is enhanced in suspension‐cultured hazel (Corylus avellana L.) cells by using a combination of sugar,precursor, and elicitor

Hazel (Corylus avellana L.) has recently been drawing attention as an alternative source of taxol. In the present study, the effects of sugar type, and different concentrations of phenylalanine (Phe) and vanadyl sulfate (V) on the production of taxol in C. avellana were investigated. A factorial experiment was used to optimize the concentrations of the precursor and elicitor. The cells were treated with Phe and V on the fourth day of culture and were harvested every 2 days until the 10th day. By increasing the Phe and V supply, taxol production increased during the culture period and the maximum level of 4.2 μg/g (dry weight) was obtained at day 10 by combining 3 μM of Phe and 0.05 and 0.1 mM of V in media supplemented with fructose (3%). The time course study on taxol production suggested that the appropriate time for using Phe is day 4 of culture, and day 8 for V. Overall, taxol production in C. avellana cell suspension culture was improved by the use of the combined strategy.     

氨基酸对无外源激素悬浮培养肉苁蓉细胞合成苯乙醇苷的影响

通过不添加外源激素进行肉苁蓉细胞悬浮培养,考察4种氨基酸对无外源激素悬浮培养肉苁蓉细胞生长和产苯乙醇苷(PeGs)的影响。结果表明:苯丙氨酸(Phe)和酪氨酸(Tyr)对PeGs合成的促进作用较大,而色氨酸(Try)和精氨酸(Arg)的促进效果较弱。在培养的第12天向无外源激素液体培养基中分别添加0.3mmol/LPhe和0.03mmol/LTyr,PeGs产量(按细胞干质量计)均达到了最高,为1.19g/L,是添加生长调节剂激动素(KT)和吲哚乙酸(IAA)培养的细胞(简称HC)的2.02倍。0.3mmol/LPhe和0.03mmol/LTyr分别在第8天和第12天添加时,肉苁蓉细胞PeGs产量分别为5.43g/L和5.16g/L,分别是对照HC的1.49倍和1.41倍。     

Improved taxol yield by aromatic carboxylic acid and amino acid feeding to cell cultures of taxus cuspidata

Cell culture of Taxus cuspidata represents an alternative to whole plant extraction as a source of taxol and related taxanes. Feeding phenylalanine to callus cultures was previously shown to result in increased taxol yields, probably due to the involvement of this amino acid as a precursor for the N-benzoylphenylisoserine side chain of taxol. Inthis study, we have examined the effect of various concentrations of phenylalanine, benzoic acid, N-benzoylglycine, serine, glycine, alanine, and 3-amino-3-phenyl-propionic acid on taxol accumulation in 2-year-old cell suspensions of Taxus cuspidata, cell line FCL1F, and in developing callus cultures of T. cuspidata. All compounds tested were included in media at stationary phase (suspensions) or after the period of fastest growth (calli). Alanine and 3-amino-3-phenyl-propionicacid were tested only in callus cultures and did not affect taxol accumulation. Significant increases or trends toward increases in taxol accumulationin callus and suspensions were observed in the presence of phenylalanine, benzoic acid, N-benzoylglycine, serine, and glycine. The greatest increases in taxol accumulation were observed in the presence of various concentrations of phenylalanine (1 mM for callus; 0.05, 0.1, and 0.2 mM for suspensions) and benzoic acid (0.2 and 1 mM for callus and 0.05, 0.1, and 0.2 mM for suspensions). Increases in taxol yields of cell suspensions in the presence of the most effective precursors brought taxol amounts at stationary phase from 2 mug . g(-1) to approximately 10 mug . g(-1) of the extracted dry weight. The results are discussed in termsof possible implications to taxol biosynthesis and in terms of practical applications to large-scale cell culture systems for the production ofthis drug. (c) 1994 John Wiley & Sons, Inc.     

Effects of inoculum size and age on biomass growth and paclitaxel production of elicitor-treated Taxus yunnanensis cell cultures

Suspension cultures of Taxus yunnanensis cells were inoculated with cells of different culture ages (12-24 days) at various densities [50-250 g fresh weight (fw)/l], and treated (on day 7) with a mixture of elicitors, including Ag(+), chitosan and methyl jasmonate. The biomass productivity (during the production stage) increased dramatically with inoculum size, but decreased with inoculum age over 16 days. The volumetric yield and productivity of taxol (paclitaxel) also increased with inoculum size, while the specific taxol yield (per cell) was mainly dependent on inoculum age, with an optimum of 20 days, during the early stationary phase. The highest taxol yield and productivity, 39.8 mg/l and 1.9 mg/l per day, respectively, were obtained with a 20-day-old inoculum at 200 g fw/l. Taxol excretion by the cells increased with inoculum age but decreased with inoculum size. The elicitor-induced activities of catalase (CAT) and phenylalanine ammonia-lyase (PAL) also depended mainly on inoculum age; higher PAL activity and lower CAT activity were obtained with an older inoculum, corresponding to a higher taxol yield. The results show that both inoculum size and age are important variables for taxol production, though the latter more profoundly influences elicitor-induced taxol biosynthesis of the cells. Inoculum size and age are also interrelated and should be optimized together in a two-stage culture process.