红豆杉细胞两相培养生产紫杉醇的研究

研究了两相培养系统中红豆杉细胞的生长与代谢规律,经４０天培养,细胞生物量为１７．８５ｇ／Ｌ（干重）,紫杉醇产量为３０．１９ｍｇ／Ｌ。     

云南红豆杉细胞培养中紫杉醇的代谢调控

云南红豆杉细胞培养中紫杉醇的代谢调控甘烦远彭丽萍郑光植（中国科学院昆明植物研究所,昆明６５０２０４）ＭＥＴＡＢＯＬＩＣＲＥＧＵＬＡＴＩＯＮＯＮＴＡＸＯＬＯＦＣＥＬＬＣＵＬＴＵＲＥＦＲＯＭＴＡＸＵＳＹＵＮＮＡＮＥＮＳＩＳＧＡＮＦａｎ－Ｙｕａｎ,ＰＥＮ...     

桔青霉中紫杉醇诱导子对红豆杉细胞代谢的影响

在红豆杉细胞培养第２０ｄ时,加入桔青霉紫杉醇诱导子处理５ｄ及１０ｄ后细胞中可溶性蛋白质含量增加,苯丙氨酸解氨酶活性增强,培养基ｐＨ值降低,细胞可溶性蛋白质,过氧化物酶与酯酶同工酶电泳扫描图谱中出现新的谱带为茂本原有个别谱带强度发生变化。     

寡聚糖诱导悬浮培养南方红豆杉细胞的凋亡

在真菌(Fusarium oxysporum f.vasinfectum (Atkinson) Snyder et Hansen)寡聚糖诱导悬浮培养南方红豆杉(Taxus chinensis (Pilger) Rehd.var.mairei (Lemee et Lévl.) Cheng et L.K.Fu)细胞生产紫杉醇的体系中发现细胞出现凋亡,次生代谢增强.电镜观察到细胞核质和原生质出现凝集现象,液泡内出现大量的高电子致密体.核DNA经琼脂糖凝胶电泳,呈200 bp的整数倍的梯状条带(ladders);而对照组细胞核DNA完整,呈大片段,细胞完整,细胞器发达,但紫杉醇合成速率很低.加入寡聚糖后,细胞防御系统开启,细胞生长停止,次生代谢物酚类物质大量积累且次生壁加厚,多酚氧化酶活性迅速提高,苯丙烷类代谢途径的关键酶苯丙氨酸解氨酶的活性在1 h后急速提高,目的产物紫杉醇在诱导后72 h达到峰值,比对照组提高了6倍,且细胞凋亡的出现与紫杉醇合成的峰值具有时间上的一致性.     

水杨酸对红豆杉细胞的诱导作用

通过添加不同浓度的水杨酸（ＳＡ）,比较了它们对红豆杉细胞过氧化物酶（ＰＯＤ）、苯丙氨酸解氨酶（ＰＡＬ）、过氧化氢（Ｈ２Ｏ２）含量及以细胞生长和紫杉醇含量的影响,结果表明,ＳＡ可提高ＰＯＤ及ＰＡＬ的活性,促进细胞内Ｈ２Ｏ２含量的上升并有利于紫杉醇的合成,其中２０ｍｇ／Ｌ ＳＡ对紫杉醇合成的促进效果最明显,紫极醇含量可达对照组的１３倍。     

寡聚糖诱导悬浮培养南方红豆杉细胞的凋亡(英)

在真菌 (Fusariumoxysporumf.vasinfectum (Atkinson)SnyderetHansen)寡聚糖诱导悬浮培养南方红豆杉(Taxuschinensis (Pilger)Rehd .var.mairei (LemeeetL啨ｖｌ.)ChengetL .K .Fu)细胞生产紫杉醇的体系中发现细胞出现凋亡 ,次生代谢增强。电镜观察到细胞核质和原生质出现凝集现象 ,液泡内出现大量的高电子致密体。核DNA经琼脂糖凝胶电泳 ,呈 2 0 0bp的整数倍的梯状条带 (ladders) ;而对照组细胞核DNA完整 ,呈大片段 ,细胞完整 ,细胞器发达 ,但紫杉醇合成速率很低。加入寡聚糖后 ,细胞防御系统开启 ,细胞生长停止 ,次生代谢物酚类物质大量积累且次生壁加厚 ,多酚氧化酶活性迅速提高 ,苯丙烷类代谢途径的关键酶苯丙氨酸解氨酶的活性在 1h后急速提高 ,目的产物紫杉醇在诱导后 72h达到峰值 ,比对照组提高了 6倍 ,且细胞凋亡的出现与紫杉醇合成的峰值具有时间上的一致性。     

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。     

红豆杉细胞与赤霉菌交互诱导对红豆杉细胞紫杉醇含量的影响

在赤霉菌培养过程中加入红豆杉细胞诱导物,再用此赤霉菌诱导悬浮培养的红豆杉细胞。与未受植物来源物质作用的单向诱导相比,该交互诱导使红豆杉细胞的紫杉醇含量提高5倍,交互诱导的效果受诱导物的各类的影响,其中,诱导物是红豆杉细胞壁和赤霉菌细胞壁时,交互诱导效果最好。     

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。     

红豆杉细胞悬浮培养生产紫杉醇研究进展

介绍了近年来由红豆杉细胞培养生产紫杉醇领域取得的进展,其中特别介绍了由紫杉醇生物合成途径及其代谢酶类的研究发展而来的用基因工程方法改良细胞系,为提高紫杉醇产量而采取添加前体物质,诱导子,抑制子等方面的研究。     

稀土元素对红豆杉细胞悬浮培养及紫杉醇合成的影响

研究了在250mL摇瓶中,不同浓度的硝酸镧、硫酸铈铵、硝酸亚铈3种稀土化合物对细胞生长及紫杉醇分泌和释放的影响。结果表明,在培养初期加入稀土元素。3种不同稀土化合物对细胞生长影响强弱不同,但趋势相似,均使细胞的延迟期缩短。1ppm的Ce^4 促进细胞生长的效果最明显。细胞干重第17d达到10.9g/L。在指数期加入稀土元素。10ppmCe^3 刺激细胞生长的效果最明显,细胞干重最高值达到11.5g/dL,比对照高1.5g/L,而10ppm的La^3 抑制细胞的生长。经稀土元素处理后,细胞胞内和胞外紫杉醇含量都有大幅度的提高,其中以10ppmCe^3 处理,胞外紫杉醇释放率最大,达37.7%。     

悬浮培养红豆杉细胞活力及存活率与生长周期的关系

用TTC法制定红豆杉细胞活力,用中性红测细胞存活率,探讨生长周期中细胞活力及存活率的变化规律。结果显示延迟期细胞活力最强,对数生长期活力较低,稳定期活力最低;而细胞存活率在整个周期中基本保持在70%-80%。     

Improved paclitaxel accumulation in cell suspension cultures of Taxus chinensis by brassinolide

When brassinolide was added at 17 ng l^–1 to Taxus chinensis cell suspension cultures, the paclitaxel content was increased by over 100% to 580 g g^–1 dry weight. Brassinolide may therefore be a novel regulator of paclitaxel biosynthesis.     

Paclitaxel production in suspension cell cultures of Taxus

Five separate cell lines, three of Taxus canadensis Marsh. and two of Taxus cuspidata Sieb. et Zucc., were used to test the effect of carbohydrates and plant growth regulators on the growth of cells and production of paclitaxel in culture. There was no significant correlation between growth of cells and paclitaxel production. While no single medium was developed that was optimal for all cell lines, it was possible to develop a medium for each species that represented a superior combination of growth and paclitaxel production. A combination of NAA and thidiazuron produced the best combination of growth and paclitaxel production in cell lines of T. canadensis, while IAA and BA produced the best results in cell lines of T. cuspidata. A mixture of sucrose and fructose gave the best combination of growth and paclitaxel production. The addition of carbohydrates midway through the growth cycle increased the rate at which paclitaxel accumulated in the culture medium. The highest paclitaxel concentration obtained was 14.78±0.86 mg 1^–1 (n=3).Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - 2ip 6-(,-dimethylamino)-purine - BA 6-benzyladenine - IAA indole-3-acetic acid - IBA indole-3-butyric acid - kinetin 6-furfurylaminopurine - NAA -napthaleneacetic acid - picloram 4-amino-3,5,6-trichloropicolinic acid - thidiazuron 1-phenyl-3 (1,2,3-thiadiazol-5-yl)urea     

Engineering the plant cell factory for secondary metabolite production

Plant secondary metabolism is very important for traits such as flower color, flavor of food, and resistance against pests and diseases. Moreover, it is the source of many fine chemicals such as drugs, dyes, flavors, and fragrances. It is thus of interest to be able to engineer the secondary metabolite production of the plant cell factory, e.g. to produce more of a fine chemical, to produce less of a toxic compound, or even to make new compounds, Engineering of plant secondary metabolism is feasible nowadays, but it requires knowledge of the biosynthetic pathways involved. To increase secondary metabolite production different strategies can be followed, such as overcoming rate limiting steps, reducing flux through competitive pathways, reducing catabolism and overexpression of regulatory genes. For this purpose genes of plant origin can be overexpressed, but also microbial genes have been used successfully. Overexpression of plant genes in microorganisms is another approach, which might be of interest for bioconversion of readily available precursors into valuable fine chemicals. Several examples will be given to illustrate these various approaches. The constraints of metabolic engineering of the plant cell factory will also be discussed. Our limited knowledge of secondary metabolite pathways and the genes involved is one of the main bottlenecks. This revised version was published online in August 2006 with corrections to the Cover Date.     

Enhancement of paclitaxel production by abscisic acid in cell suspension cultures of Taxus chinensis

Addition of 5 mg abscisic acid l^–1 after 12 days' growth of Taxus chinensis suspension culture gave the greatest paclitaxel accumulation at 11 mg l^–1, which was almost 5 times that of the control culture. The highest paclitaxel production, 18 mg l^–1, was obtained using 5 mg abscisic acid l^–1 and 20 mg methyl jasmonate l^–1.     

Abscisic acid plays critical role in ozone‐induced taxol production of Taxus chinensis suspension cell cultures

Exposure to ozone induced a rapid increase in the levels of the phytohormone abscisic acid (ABA) and sequentially followed by the enhancement of Taxol production in suspension cell cultures of Taxus chinensis. The observed increases in ABA and Taxol were dependent on the concentration of ozone applied to T. chinensis cell cultures. To examine the role of ABA in ozone‐induced Taxol production, we pretreated the cells with ABA biosynthesis inhibitor fluridone to abolish ozone‐triggered ABA generation and assayed the effect of fluridone on ozone‐induced Taxol production. The results showed that pretreatment of the cells with fluridone not only suppressed the ozone‐triggered ABA generation but also blocked the ozone‐induced Taxol production. Moreover, our data indicate that the effect of ABA on Taxol production of T. chinensis cell cultures is dose‐dependent. Interestingly, the suppression of fluridone on ozone‐induced Taxol production was reversed by exogenous application of low dose of ABA, although treatment of low dose ABA alone had no effect on Taxol production of the cells. Together, the data indicated that ozone was an efficient elicitor for improving Taxol production of plant cell cultures. Furthermore, we demonstrated that ABA played critical roles in ozone‐induced Taxol production of T. chinensis suspension cell cultures. © 2011 American Institute of Chemical Engineers Biotechnol. Prog., 2011     

Taxol-induced apoptotic cell death in suspension cultures of Taxus cuspidata

Taxol caused apoptotic cell death of Taxus cuspidata in suspension cultures. Typical morphological and biochemical changes of apoptosis were observed by microscopy and total DNA agarose gel electrophoresis. Taxus cuspidata responded to the added Taxol by increasing the biosynthesis of Taxol. The percentage of apoptotic cells in total cells increased with the concentration of added Taxol. With Taxol added at 10 mg l^–1, the maximum concentration of Taxol produced was 23 mg l^–1, 3 times higher than that of the control culture.     

Characterization of aggregate size in Taxus suspension cell culture

Plant cells grow as aggregates in suspension culture, but little is known about the dynamics of aggregation, and no routine methodology exists to measure aggregate size. In this study, we evaluate several different methods to characterize aggregate size in Taxus suspension cultures, in which aggregate diameters range from 50 to 2,000 μm, including filtration and image analysis, and develop a novel method using a specially equipped Coulter counter system. We demonstrate the suitability of this technology to measure plant cell culture aggregates, and show that it can be reliably used to measure total biomass accumulation compared to standard methods such as dry weight. Furthermore, we demonstrate that all three methods can be used to measure an aggregate size distribution, but that the Coulter counter is more reliable and much faster, and also provides far better resolution. While absolute measurements of aggregate size differ based on the three evaluation techniques, we show that linear correlations are sufficient to account for these differences (R ² > 0.99). We then demonstrate the utility of the novel Coulter counter methodology by monitoring the dynamics of a batch process and find that the mean aggregate size increases by 55% during the exponential growth phase, but decreases during stationary phase. The results indicate that the Coulter counter method can be routinely used for advanced process characterization, particularly to study the relationship between aggregate size and secondary metabolite production, as well as a source of reliable experimental data for modeling aggregation dynamics in plant cell culture.