应用电导率监测红豆杉细胞悬浮培养中细胞生长与紫杉醇的累积

对中国红豆杉细胞悬浮培养过程中细胞生长和紫杉醇累积及培养液的电导率变化规律进行了研究,实验表明,细胞悬浮培养过程中随着细胞生物量与紫杉醇含量的增加,培养液的电导率逐渐下降,细胞生长和紫杉醇累积曲线与培养液的电导率曲线恰成镜像相关,当生物量达到最高时电导率达到并稳定于最低;紫杉醇累积的高峰滞后于细胞生物量的高峰2～3 d;电导率可作为红豆杉细胞培养中确定生物量和紫杉醇累积高峰期的监测指标.     

补料培养与溶氧控制联合应用对红豆杉细胞培养的影响

为进一步提高红豆杉 (Taxuschinensis (Pilg.)Rehd .)细胞培养过程中紫杉醇的产量 ,采用细胞悬浮培养方法研究了补料培养与溶氧控制联合应用对紫杉醇产量的影响。 5L反应器中补料培养研究表明 ,培养过程中第 16天添加含 2 0g/L蔗糖的补料培养液有利于细胞的生长及紫杉醇的合成。 2 0L反应器中补料培养的研究结果表明 :2 0 %饱和度培养时紫杉醇含量最高 (0 .98mg/gDW) ,但 4 0 %～ 6 0 %溶氧饱和度能提高紫杉醇的产量。进一步研究表明 ,细胞在 6 0 %溶氧饱和度培养 2 0d后转入 2 0 %溶氧饱和度继续培养 12d ,能显著提高紫杉醇产量。补料培养与溶氧控制联合应用时 ,2 0L反应器中红豆杉细胞培养紫杉醇产量可达 18.7mg/L。     

内生真菌培养液对东北红豆杉细胞生长及紫杉醇合成的影响

产紫杉醇的内生真菌(Fusarium mairei)先培养在B5液体培养基中, 然后制备成内生真菌培养液。在东北红豆杉(Taxus cuspidata)细胞悬浮培养的不同阶段(5、10和15天), 用不同剂量的内生真菌培养液(2、4和6 mL)分别进行处理。结果表明,在用4 mL内生真菌培养液处理的植物细胞中可获得最高的紫杉醇产量(5.88 mg.L-1)与释放率(67%), 分别是对照的1.9 倍与5.6 倍。添加时间方面, 在植物细胞培养周期的第5天添加4 mL内生真菌培养液, 可获得最佳效果, 紫杉醇产量与释放率分别为6.1 mg.L-1与75%, 分别是对照的2倍与6.8倍。与其它诱导子相比, 4 mL内生真菌培养液不仅可提高紫杉醇的释放率, 而且不会引起东北红豆杉细胞膜的明显伤害, 说明内生真菌发酵液激活了紫杉醇主动运输过程中的相关酶类。     

补料培养与溶氧控制联合应用对红豆杉细胞培养的影响

为进一步提高红豆杉(Taxus chinensis (Pilg.) Rehd.)细胞培养过程中紫杉醇的产量,采用细胞悬浮培养方法研究了补料培养与溶氧控制联合应用对紫杉醇产量的影响.5 L反应器中补料培养研究表明,培养过程中第16天添加含20 g/L蔗糖的补料培养液有利于细胞的生长及紫杉醇的合成.20 L反应器中补料培养的研究结果表明:20%饱和度培养时紫杉醇含量最高(0.98 mg/g DW),但40%～60%溶氧饱和度能提高紫杉醇的产量.进一步研究表明,细胞在60%溶氧饱和度培养20 d后转入20%溶氧饱和度继续培养12 d,能显著提高紫杉醇产量.补料培养与溶氧控制联合应用时,20 L反应器中红豆杉细胞培养紫杉醇产量可达18.7 mg/L.     

植物细胞工程技术生产紫杉醇研究进展

紫杉醇是一种二萜类生物碱,主要从红豆杉树皮中分离提取。目前采用植物细胞工程技术是提高紫杉醇产率、保护稀缺资源红豆杉、解决紫杉醇药源紧缺的一种最有效方法。该文对近十年来国内外有关采用植物细胞工程技术生产紫杉醇的研究进展,包括红豆杉细胞系的建立、悬浮培养条件的研究、生物反应器培养以及紫杉醇合成代谢调控方面的最新研究进展进行综述。并重点论述了前体、诱导子和代谢支路抑制剂对红豆杉细胞悬浮培养生产紫杉醇的影响,为植物细胞工程技术生产紫杉醇提供借鉴和参考。     

红豆杉细胞悬浮培养结构化数学模型的探讨

用１０Ｌ机械搅拌式生物反应器悬浮培养红豆杉细胞,得到细胞生长、基质消耗和紫杉醇合成动力学曲线。经过代谢动力学分析建立了结构化数学模型。并将模型值与实验值进行比较,结果表明模型预测值与实验值较吻合。     

超声波对红豆杉悬浮细胞生长及紫杉醇释放的研究

分析了超声波对中国红豆杉悬浮细胞培养的生长,紫杉醇合成及释放的影响,细胞对不同强度及作用时间的超声波反应不同,用38kHz,120s的超声强度处理悬浮细胞,紫杉醇胞外释放率由对照的10％左右提高到40－50％,总产量提高了47％,超声波处理植物细胞,提供了在保持细胞生长的前提下有效刺激胞内次生代谢物的简易操作方法。     

利用云南红豆杉悬浮细胞生产紫杉醇和紫杉烷类化合物

云南红豆杉(Taxus yunnanensis Cheng et L. K. Fu)的一株紫杉醇高产细胞系经过8年多的继代培养,仍保持较稳定的紫杉烷类化合物的生物合成能力.从此株紫杉醇高产细胞系的悬浮培养物中分离到8个紫杉烷类化合物,经核磁共振光谱和质谱数据分析,它们的化学结构分别是2,5,10-三乙酰氧基-14-丙酰氧基紫杉二烯(1)、 2,5,10-三乙酰氧基-14-(2′-甲基丙酰氧基)紫杉二烯(2)、 2,5,10,14-四乙酰氧基紫杉二烯(3)、 2,5,10-三乙酰氧基-14-(2′-甲基-3′-羟基丁酰氧基)紫杉二烯及其差向异构体(4和5)、巴卡亭Ⅳ(6)、巴卡亭Ⅲ (7)和紫杉醇(8).化合物3、 5-7为首次从云南红豆杉细胞培养物中分离到.定性分析表明,云南红豆杉细胞悬浮培养液中的化学成分与培养细胞中的相似.另外,此株紫杉醇高产细胞系的紫杉醇含量可高达0.3%,可用来进行大规模培养.     

利用运动红豆杉悬浮细胞生长紫杉醇和紫杉烷类化合物

云南红豆杉（Taxus yunnanensis Cheng et L.K.Fu）的一些株紫杉醇高产细胞系经过8年多的继代培养,仍保持较稳定的紫杉烷类化合物的生物合成能力。从此株紫杉醇高产细胞系的悬浮培养物中分离到8个紫杉烷类合物。经核磁共振光谱和质谱数据分析,它们的化学结构分别是2,5,10－三乙酰基－14－丙酰氧基紫杉二烯（1）、2,5,10－三酰氧基－14－（2′－甲基丙酰氧基）紫杉二烯（2）,2,5,10,14－四乙酰氧基紫杉二烯（3）、2,5,10－三乙酰氧基－14－（2′－甲基－3′－羟基丁酰氧基）紫杉二烯及其差向异构体（4和5）、巴卡亭Ⅳ（6）、巴卡亭Ⅲ（7）和紫杉醇（8）。化合物3、5－7为首次从云南红豆杉细胞培养物中分离到。定性分析表明,云南红豆杉细胞悬浮培养液中的化学成分与培养细胞中的相似。另外,此株紫杉高产细胞系的紫杉醇含量可达高0．3％,可用来进行大规模培养。     

云南红豆杉细胞发酵培养的研究

利用云南红豆杉(Taxus yunnanensis)细胞悬浮培养的最佳培养条件,进行了细胞10L规模的发酵培养研究。对细胞发酵培养过程中的pH值变化、糖利用率以及细胞生长周期等实验参数进行了测定。已进行的3次发酵培养的实验结果表明:培养细胞的生长率已达0.4g/L.d(即12.0g/L),培养细胞中紫杉酵的含量为0.119％(其中培养液中的紫杉醇含量约占42％)。初步建立了优化的云南红豆杉细胞大量培养系统。     

基于定量PCR技术探讨紫杉醇生物合成的限速步骤

次生代谢产物牛物合成受到发育和诱导的调控,本实验研究了组织分化和诱导处理对紫杉醇生物合成的影响,并采用定量PCR技术分析了紫杉醇生物合成不同阶段关键酶基因的动态表达特征。结果表明。紫杉醇主要分布在中国红豆杉（Taxus chinensis）树皮和根皮组织中,针叶内含量很少,催化紫杉醇功能官能团连接的关键酶摹因也主要定位在树皮和根皮组织巾;茉莉酸甲酯（MJ）和真菌诱导子F5分别提高了中国红豆杉悬浮培养细胞HG-1紫杉醇得率8倍和10倍,同时有效诱导紫杉醇生物合成基因的表达。发现催化紫杉醇侧链连接的基因与紫杉醇生物合成早正相关。结果表明。紫杉醇生物合成的限速步骤是催化功能官能团连接的步骤。     

红豆杉细胞培养生产紫杉醇产量稳定性的探讨

通过磷酸盐双饥饿和秋水仙碱这两种经典的同步化方法处理悬浮培养的红豆杉细胞 ,以实现培养物的均一性 ,并比较了同步化与非同步化细胞及不同同步化方法处理的细胞紫杉醇产量。结果表明 ,不同同步化方法处理的细胞紫杉醇产量有差异 :秋水仙碱同步处理处于中期的细胞紫杉醇产量高于非同步化细胞 ,而磷酸盐双饥饿同步处理处于间期的细胞紫杉醇产量则相反。这表明紫杉醇产量与培养物的均一性有关 ,且与细胞同步的周期时相有关 ,采用同步化方法来选择合适的细胞周期时相有利于紫杉醇产量的稳定 ,通过比较不同同步化方法处理对细胞生物量和 POD活性的影响进一步探讨紫杉醇产量产生差异的原因     

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％。     

红豆杉离体细胞四倍体的诱导

细胞大规模培养被认为是目前生产紫杉醇最有希望的替代途径之一,获得更高产的细胞系,可降低细胞大规模培养生产紫杉醇的成本,加速其产业化进程。药用植物多倍体与二倍体相比具有根,茎,叶和花果的巨型性,抗逆性强,次生代谢产物含量提高等特性。本研究通过同步化培养和秋水仙素诱导处理,成功建立了红豆杉四倍体细胞系并且经过7个周期的继代证明了该细胞系的稳定性。结果显示,用浓度为750mg/L的秋水仙素处理3d可以得到稳定传代的四倍体细胞系,其四倍体细胞比例稳定在62.5%。进一步对其次生代谢产物紫杉醇的检测显示该四倍体细胞比对照二倍体细胞具有更高的合成紫杉醇的能力。     

Stimulation of taxol production and excretion in Taxus spp cell cultures by rare earth chemical lanthanum

The trivalent ion of a rare earth element, lanthanum, was tested for elicitor-like effects on taxol production in suspension cultures of four different Taxus spp cells. In T. yunnanensis cell cultures, the lanthanum ion at concentrations from 1.15 to 23.0 microM stimulated taxol production. The lanthanum ion also promoted taxol excretion by the T. yunnanensis cells considerably. The maximum stimulation of taxol production was achieved by the addition of 5.8 microM La3+ to the culture during mid-log growth phase, increasing the volumetric taxol yield by nearly threefold, from 2.61+/-0.37 to 9.89+/-1.92 mg l(-1) over a 28 day culture period. At higher concentrations, i.e. 23.1 and 46.2 microM, however, the lanthanum ion caused significant growth inhibition. For the other three Taxus cell lines, namely an embryo and a leave cell of T. chinensis and a stem cell of T. chinensis marv, the addition of lanthanum ion to the culture only had a significant effect on taxol production by the T. chinensis marv stem cells, increasing the volumetric yield by about threefold to 4.69+/-0.76 mg l(-1). These results suggest that lanthanum has elicitor-like effects on secondary metabolite synthesis of plant cell cultures.     

Enhanced taxol production and release in Taxus chinensis cell suspension cultures with selected organic solvents and sucrose feeding

Suspension culture of Taxus chinensis cells was carried out in aqueous-organic two-phase systems for the production and in situ solvent extraction of taxol (paclitaxel). Three organic solvents, hexadecane, decanol, and dibutylphthalate, were tested at 5-20% (v/v) in the culture liquid. All of these solvents stimulated taxol release and the yield per cell, though decanol and higher concentrations of the other two solvents depressed biomass growth significantly. Ten percent dibutylphthalate was the optimal solvent for improving taxol production and release with minimal cell growth inhibition. The time of solvent addition to the culture also affected taxol production, with the addition during the late-log growth phase being most favorable. By feeding sucrose to the culture near the stationary growth phase, the cell growth and taxol production period was extended from 27 to 42 days. The combining of the two-phase culture and sucrose feeding increased the taxol yield by about 6-fold compared with the single-phase batch culture, to 36.0 +/- 3.5 mg/L, with up to 63% taxol released. This study shows that in situ solvent extraction combined with nutrient feeding is an effective process strategy for production and recovery of secondary metabolites in plant cell suspension culture.     

DMSO 对悬浮培养的东北红豆杉细胞凋亡和紫杉醇合成的影响

研究了不同浓度的DMSO对悬浮培养的东北红豆杉(Taxus cuspidata)细胞的增殖能力、细胞活性以及紫杉醇合成和释放等方面的影响,同时应用荧光指示剂双染法检测了细胞凋亡的发生情况.结果显示2%的DMSO处理能显著降低细胞活性,抑制细胞的增殖能力,使细胞核内DNA含量减少,培养中、后期在荧光显微镜下可见部分细胞核出现典型的凋亡形态,同时伴有紫杉醇产量的明显增加;对照组及1%以下浓度组未出现上述改变.结果表明一定浓度的DMSO能诱导细胞凋亡,促进细胞紫杉醇合成能力的提高.     

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.     

Salicylic acid-induced taxol production and isopentenyl pyrophosphate biosynthesis in suspension cultures of Taxus chinensis var. mairei

The influences of salicylic acid (SA) on taxol production and isopentenyl pyrophosphate (IPP) biosynthesis pathways in suspension cultures of Taxus chinensis var. mairei were investigated by adding SA and mevastatin (MVS), a highly specific inhibitor of 3-hydroxy-3-methylglutaryl-CoA reductase in the mevalonate pathway for IPP biosynthesis, into the culture systems. The cell death and taxol production were induced upon the introduction of SA, and 20mg/l was proved to be the optimal SA concentration in terms of the less damage to Taxus cells and marked activation of phenylalanine ammonia lyase (PAL). In the coexistence of SA (20mg/l) and MVS (100 nmol/l), the taxol content (1.626 mg/g dry wt) was higher than that (0.252 mg/g dry wt) of the MVS-treated system but almost equal to that (1.581 mg/g dry wt) of the SA-treated system. It is thus inferred that the activated non-mevalonate pathway should be responsible for the formation of IPP in taxol biosynthesis in the presence of SA.