In vitro culture of <Emphasis Type="Italic">Taxus</Emphasis> sp.: strategies to increase cell growth and taxoid production

Interest in Taxus species has increased since paclitaxel, an anticancer drug, was isolated from the bark of Taxus brevifolia (Pacific yew) in the 1960’s. Great effort has been carried out to establish an efficient callus cultures of Taxus species. Culture media must be optimized for each Taxus species, and in general, there is no one method that guarantees success for Taxus cultures. The source of explant, culture medium composition and the growth regulators used appear to affect callus initiation and maintenance. Research effort has focused on obtaining a cell culture that exhibits good growth and a high rate of taxoid accumulation. In this sense, many strategies have been employed to stimulate taxoid production without affecting cell growth. In an attempt to scale-up cell culture, problems such us shear stress, oxygen supply and gas composition have been studied. A more detailed knowledge of the pathway and the fluxes of intermediates towards taxane accumulation will be key factors to obtain cell lines with increased taxane accumulation through metabolic engineering.     

红豆杉高产悬浮细胞系建立及其紫杉醇诱导的研究进展

紫杉醇是一种四环二萜酰胺类化合物,是从红豆杉科红豆杉属植物中提取分离出来的次生代谢物,是世界公认广谱、活性强的天然抗癌新药。但直接从植物中提取紫杉醇的传统生产方式,不仅产量低,且会对野生红豆杉资源造成严重破坏,同时紫杉醇的化学全合成也由于其结构复杂而不具备商业价值。与之相反,细胞培养技术具有受外界影响少、生产成本低、次生代谢产物多、细胞生长周期短的优势,是目前最具前景的紫杉醇生产方式。近年来随着科研水平的不断提升,紫杉醇无论在生理代谢调控、关键基因挖掘,还是新药物制剂与剂型及其类似物的开发和运用等方面,都取得了进展,但要建立紫杉醇商业化高产体系,还必须和前人的研究经验相结合。该文对红豆杉高产悬浮细胞系建立及其紫杉醇诱导的研究进展进行了综述,主要包括前人对红豆杉属植物组织与细胞培养相关的外植体、培养基、激素、培养条件、褐化等问题的研究,以及从代谢调节、培养方式、基因工程等多方面提高紫杉醇含量的最新进展,最后总结了当前研究的不足,并对今后通过多种组合方式来提高紫杉醇含量的生产途径进行了展望。以期促进红豆杉组织培养技术的进步,为药用资源保护和利用提供一定的理论基础与生产指导。     

Yew (Taxus x media Rehd.) cell suspension cultures as a source of taxanes

Natural resources of paclitaxel, an effective anticancer compound, were threatened with extinction soon after the discovery of this valuable substance. Cell suspension cultures derived from different Taxus species have rapidly become an alternative source of paclitaxel and other taxanes. In this paper we provide some insight into cell growth characteristics in cell suspension culture of Taxus x media cv. Hicksii, with emphasis on the effects of jasmonic acid (JA) on taxane production in cell lines with different initial taxane content. Additionally cell growth characteristics of two cell lines was followed during cultivation of cell suspension culture of Taxus x media cv. Hicksii. Packed cell volume (PCV) was shown to be a reliable and efficient alternative for measuring cell growth instead of fresh and dry weight. The initial total taxane content was screened in a number of cell lines, followed by observing the effect of JA on cell mass and total taxane production of selected lines. We showed a great variability in initial taxane content in different cell lines, which decreased during cell suspension maintenance. JA was shown to inhibit cell growth and increase total taxane production (14 to 106 fold).     

Molecular cloning and characterization of a cytochrome P450 taxoid 9á-hydroxylase in Ginkgo biloba cells

Taxol is a well-known effective anticancer compound. Due to the inability to synthesize sufficient quantities of taxol to satisfy commercial demand, a biotechnological approach for a large-scale cell or cell-free system for its production is highly desirable. Several important genes in taxol biosynthesis are currently still unknown and have been shown to be difficult to isolate directly from Taxus, including the gene encoding taxoid 9α-hydroxylase. Ginkgo biloba suspension cells exhibit taxoid hydroxylation activity and provides an alternate means of identifying genes encoding enzymes with taxoid 9α-hydroxylation activity. Through analysis of high throughput RNA sequencing data from G. biloba, we identified two candidate genes with high similarity to Taxus CYP450s. Using in vitro cell-free protein synthesis assays and LC–MS analysis, we show that one candidate that belongs to the CYP716B, a subfamily whose biochemical functions have not been previously studied, possessed 9α-hydroxylation activity. This work will aid future identification of the taxoid 9α-hydroxylase gene from Taxus sp.     

Taxol biosynthesis: Identification and characterization of two acetyl CoA:taxoid-O-acetyl transferases that divert pathway flux away from Taxol production

Two cDNAs encoding taxoid-O-acetyl transferases (TAX 9 and TAX 14) were obtained from a previously isolated family of Taxus acyl/aroyl transferase cDNA clones. The recombinant enzymes catalyze the acetylation of taxadien-5α,13α-diacetoxy-9α,10β-diol to generate taxadien-5α,10β,13α-tri-acetoxy-9α-ol and taxadien-5α,9α,13α-triacetoxy-10β-ol, respectively, both of which then serve as substrates for a final acetylation step to yield taxusin, a prominent side-route metabolite of Taxus. Neither enzyme acetylate the 5α- or the 13α-hydroxyls of taxoid polyols, indicating that prior acylations is required for efficient peracetylation to taxusin. Both enzymes were kinetically characterized, and the regioselectivity of acetylation was shown to vary with pH. Sequence comparison with other taxoid acyl transferases confirmed that primary structure of this enzyme type reveals little about function in taxoid metabolism. Unlike previously identified acetyl transferases involved in Taxol production, these two enzymes appear to act exclusively on partially acetylated taxoid polyols to divert the Taxol pathway to side-route metabolites.     

Combined use of six-well polystyrene plates and thin layer chromatography for rapid development of optimal plant cell culture processes: application to taxane production byTaxus sp.

TwoTaxus (T. chinensis andT. baccata) cell suspension cultures were used as a model system to demonstrate the similarities of biomass accumulation and secondary metabolite (taxane) production obtained from cultures in six-well polystyrene plates and glass shake flasks (25 ml and 125 ml). Interference from binding of taxanes in cell-free culture broth to the polystyrene plates was minimal with 85% of the paclitaxel (Taxol®) and 100% of baccatin and 10-deacetyl-7-xylosyl-taxol remaining in the medium after 24 h beyond which no further binding was observed. A simple thin layer chromatography (TLC) procedure with a chloroform: acentonitrile (4:1) solvent system on silica gel was developed to simultaneously test up to 17 cultures for taxane production. The combination of six-well plate technology for experimentation and TLC for rapid taxane analysis can greatly accelerate the establishment of conditions for an optimalTaxus plant-cell culture process for taxane production.Abbreviations TLC Thin layer chromatography - 2,4D 2,4-dichlorophenoxyacetic acid - HPLC high pressure liquid chromotography - UV ultraviolet - Rf retention factor     

Taxoids profiling of suspension Taxus chinensis var. mairei cells in response to shear stress

To develop an optimal bioprocess for paclitaxel (Taxols) supply, taxoid biosynthetic pathway regulation must be better understood. The main taxoid metabolites (paclitaxel, baccatin III, taxol C, etc.) in Taxus cell culture showed great difference under shear stress. However, the regulating mechanism of taxoids metabolism under shear stress remained elusive. Here an efficient metabolic profiling approach combined with multivariate analysis was employed to profile taxoids changes of Taxus cells under laminar shear stress. A total of 21 taxoids were identified and quantified by ultra-performance liquid chromatography coupled with Q-TOF mass spectrometry. The result showed the contents of paclitaxel and baccatin III were reduced by shear stress, indicating the inhibitory effect of shear stress on paclitaxel biosynthesis. The levels of other taxoids uninvolved in paclitaxel biosynthesis were decreased except several metabolites. Further analysis of mapping measured taxoids concentrations onto paclitaxel biosynthesis pathway illustrating proposed intermediates and “off-pathway” metabolites revealed shear stress might disrupt the appropriate cyclization process of geranylgeranyl-pyrophosphate, aggravate the inappropriate order of hydroxylations and acylations, and not be good for functional group oxetane formation. These findings revealed the possible mechanism for shear stress limiting paclitaxel production and might have important biotechnological applications to increase the yields of paclitaxel and relevant precursors.     

Stable transformation and long-term maintenance of transgenic <Emphasis Type="Italic">Taxus</Emphasis> cell suspension cultures

A cell line of Taxus cuspidata has been transformed with wild-type Agrobacterium rhizogenes ATCC strain 15834 containing binary vector pCAMBIA1301 and, separately, with A. tumefaciens strain EHA105 containing binary vector pCAMBIA1305.2. Additionally, a cell line of T. chinensis has been transformed with wild-type A. rhizogenes ATCC strain 25818 containing binary vector pCAMBIA1301. The two transgenic T. cuspidata cell lines have been maintained in culture for more than 20 months, and the transgenic T. chinensis cell line for more than 9 months, with no loss of reporter gene expression or antibiotic resistance. The introduced genes had no discernable effect on growth or Taxol production in the transgenic cell lines when compared to the parent control. The methods for transforming non-embryogenic Taxus suspension cultures are described.     

Effects of paclitaxel-producing fungal endophytes on growth and paclitaxel formation of <Emphasis Type="Italic">Taxus cuspidata</Emphasis> cells

Effects of a fungal endophyte, Fusarium mairei, on growth and paclitaxel formation of Taxus cuspidata cells were investigated by adding fungal endophyte culture supernatant (FECS) to suspension cultures of T. cuspidata cells. The main effective chemical responsible for paclitaxel formation in FECS was an exopolysaccharide (EPS) of molecular weight ~2 kDa. FECS fractions except EPS stimulated growth of Taxus cells but had no effects on paclitaxel accumulation. Additionally, elicitation efficiency of FECS based on different culture conditions was studied. EPS content in FECS was related to FECS culture conditions. FECS with long cultivation and high-aeration cultivation contained higher EPS content and resulted in higher paclitaxel yield than that with short cultivation and low-aeration cultivation. The maximum yield of paclitaxel from Taxus cultures, elicited by FECS with 9-day cultivation, was 4.7-fold that of the control cultures.     

Factors affecting the in vitro rapid germination of Taxus embryos and the evaluation of taxol content in the plantlets

A simple and efficient in vitro method for breaking the dormancy of Taxus baccata L. cv. Stricta seeds was investigated. The highest rate of germination (100%) of embryos isolated from seeds, which had been washed with running tap water for 7 days, was obtained after 7 days of culture on modified Murashige and Skoog or Heller media. The taxol equivalent content in 2-month-old Taxus plantlets was investigated using anti-taxol polyclonal antibodies. The results showed that the taxol equivalent content varied, depending on Taxus species and on the individuals in the same taxon.     

Recovery of extracellular paclitaxel from suspension culture of Taxus chinensis by adding inorganic salts

A new and simple method was developed to recover paclitaxel from the extracellular culture medium of Taxus chinensis. More than 80% of paclitaxel in the medium was obtained by adding 7.8 mM MgSO₄ or greater and then centrifuging. The concentration of baccatin III in the supernatant did not change after MgSO₄ treatment while paclitaxel was precipitated in the pellet. This method was used to recover paclitaxel without baccatin III from the extracellular culture medium of Taxus species.     

Paclitaxel production using co-culture of <Emphasis Type="Italic">Taxus</Emphasis> suspension cells and paclitaxel-producing endophytic fungi in a co-bioreactor

The co-culture of the suspension cells of Taxus chinensis var. mairei and its endophytic fungi, Fusarium mairei, in a 20-L co-bioreactor was successfully established for paclitaxel production. The co-bioreactor consists of two-unit tanks (10 L each) with a repairable separate membrane in the center, culturing Taxus suspension cells in one tank and growing fungi in another. By optimizing the co-culture conditions, there was a desirable yield of paclitaxel in Taxus cell cultures. The Taxus cell cultures by co-culture produced 25.63 mg/L of paclitaxel within 15 days; it was equivalent to a productivity of 1.71 mg/L per day and 38-fold higher than that by uncoupled culture (0.68 mg/L within 15 days). The optimum conditions for co-culture in the co-bioreactor were: B5 medium, inoculating fungi when Taxus cells had grown for 5 days in the co-bioreactor, hydrophilic separate membrane in the center of the co-bioreactor, and air flow rate of 1:0.85 v/v/m in fungus cultures.     

Specificity of the N-benzoyl transferase responsible for the last step of Taxol biosynthesis

The last few steps in the biosynthesis of the anticancer drug Taxol in yew (Taxus) species are thought to involve the attachment of β-phenylalanine to the C13-O-position of the advanced taxane diterpenoid intermediate baccatin III to yield N-debenzoyl-2′-deoxytaxol, followed by hydroxylation on the side chain at the C2′-position to afford N-debenzoyltaxol, and finally N-benzoylation to complete the pathway. A cDNA encoding the N-benzoyl transferase that catalyzes the terminal step of the reaction sequence was previously isolated from a family of transferase clones (derived from an induced Taxus cell cDNA library) by functional characterization of the corresponding recombinant enzyme using the available surrogate substrate N-debenzoyl-2′-deoxytaxol [K. Walker, R. Long, R. Croteau, Proc. Nat. Acad. Sci. USA 99 (2002) 9166–9171]. Semi-synthetic N-debenzoyltaxol was prepared by coupling of 7-triethylsilybaccatin III and (2R,3S)-β-phenylisoserine protected as the N-Boc N,O-isopropylidene derivative by means of carbodiimide activation and formic acid deprotections. The selectivity of the recombinant N-transferase for N-debenzoyltaxol was evaluated, and the enzyme was shown to prefer, by a catalytic efficiency factor of two, N-debenzoyltaxol over N-debenzoyl-2′-deoxytaxol as the taxoid co-substrate in the benzoyl transfer reaction, consistent with the assembly sequence involving 2′-hydroxylation prior to N-benzoylation. Selectivity for the acyl/aroyl-CoA co-substrate was also examined, and the enzyme was shown to prefer benzoyl-CoA. Transfer from tigloyl-CoA to N-debenzoyltaxol to afford cephalomannine (Taxol B) was not observed, nor was transfer observed from hexanoyl-CoA or butanoyl-CoA to yield Taxol C or Taxol D, respectively. These results support the proposed sequence of reactions for C13-O-side chain assembly in Taxol biosynthesis, and suggest that other N-transferases are responsible for the formation of related, late pathway, N-acylated taxoids.     

A rational approach to improving the biotechnological production of taxanes in plant cell cultures of Taxus spp.

Taxol is a complex diterpene alkaloid scarcely produced in nature and with a high anticancer activity. Biotechnological systems for taxol production based on cell cultures of Taxus spp. have been developed, but the growing commercial demand for taxol and its precursors requires the optimization of these procedures. In order to increase the biotechnological production of taxol and related taxanes in Taxus spp. cell cultures, it is necessary not only to take an empirical approach that strives to optimize in-put factors (cell line selection, culture conditions, elicitation, up-scaling, etc.) and out-put factors (growth, production, yields, etc.), but also to carry out molecular biological studies. The latter can provide valuable insight into how the enhancement of taxane biosynthesis and accumulation affects metabolic profiles and gene expression in Taxus spp. cell cultures.     

Development of an <Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated transformation method for <Emphasis Type="Italic">Taxus</Emphasis> suspension cultures

The FDA-approved anti-cancer compound paclitaxel is currently produced commercially by Taxus plant cell suspension cultures. One major limitation to the use of plant cell culture as a production platform is the low and variable product yields. Therefore, methods to increase and stabilize paclitaxel production are necessary to ensure product security, especially as the demand for paclitaxel continues to rise. Although a stable transformation method for Taxus suspension cultures has been developed, stable transformant yields are low (around 1% of experiments) and the method does not translate to the Taxus cuspidata Siebold and Zucc. and Taxus canadensis Marshall cell lines utilized in this study. Therefore, a new method for Agrobacterium-mediated transformation of Taxus callus and suspension cultures was developed through identification of the optimal Agrobacterium strain, inclusion of an anti-necrotic cocktail (silver nitrate, cysteine, and ascorbic acid) and increased recovery time for cells after cocultivation, the time following infection with Agrobacterium tumefaciens. Application of the increased recovery time to transformation of T. cuspidata line PO93XC resulted in 200 calluses staining positive for GUS. Additionally, two transgenic lines have been maintained with stable transgene expression for over 5 yr. This method represents an improvement over existing transformation methods for Taxus cultures and can be applied for future metabolic engineering efforts.     

Involvement of nitric oxide in cerebroside-induced defense responses and taxol production in <Emphasis Type="Italic">Taxus yunnanensis</Emphasis> suspension cells

This work was to characterize the generation of nitric oxide (NO) in Taxus yunnanensis cells induced by a fungal-derived cerebroside and the signal role of NO in the elicitation of plant defense responses and taxol production. (2S,2′R,3R,3′E,4E,8E)-1-O-β-d-glucopyranosyl-2-N-(2′-hydroxy-3′-octadecenoyl)-3-hydroxy-9-methyl-4,8-sphingadienine at 10 μg/ml induced a rapid and dose-dependent NO production in the Taxus cell culture, reaching a maximum within 5 h of the treatment. The NO donor sodium nitroprusside (SNP) potentiated cerebroside-induced H₂O₂ production and cell death. Inhibition of nitric oxide synthase activity by phenylene-1,3-bis(ethane-2-isothiourea) dihydrobromide or scavenging NO by 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide partially blocked the cerebroside-induced H₂O₂ production and cell death. Moreover, NO enhanced cerebroside-induced activation of phenylalanine ammonium-lyase and accumulation of taxol in cell cultures. These results are suggestive of a role for NO as a new signal component for activating the cerebroside-induced defense responses and secondary metabolism activities of plant cells. Taxol is a trademark of Bristol-Myers Squibb, Madison, NJ.     

Culture of Isolated Single Cells from <Emphasis Type="Italic">Taxus</Emphasis> Suspensions for the Propagation of Superior Cell Populations

Single cells isolated from aggregated Taxus cuspidata cultures via enzymatic digestion were grown in suspension culture. High seeding density (4×10⁵ cells/ml) and the addition of cell-free conditioned medium were essential for growth. Doubling the concentration of the nutrients [ascorbic acid (150 g/l), glutamine (6.25 mm), and citric acid (150 g/l)] had no effect on single cell growth or viability. A specific growth rate of 0.11 days⁻¹ was achieved, which is similar to the observed growth rate of aggregated Taxus suspensions. The biocide, Plant Preservative Mixture, added at 0.2% (v/v) to all single cell cultures to prevent microbial contamination, had no significant effect on growth or viability. Following cell sorting, single cell cultures can be used to establish new cell lines for biotechnology applications or provide cells for further study.