Cell cycle analysis of Taxus suspension cultures at the single cell level as an indicator of culture heterogeneity

Single cell growth and division was measured via flow cytometry in order to characterize the metabolic variability of Taxus cuspidata suspension cultures, which produce the valuable secondary metabolite Taxol. Good agreement was observed between the cell cycle distribution and biomass accumulation over the batch culture period. Specific growth rates of 0.13 days(-1) by fresh weight and 0.15 days(-1) by dry weight were measured. Elicitation with methyl jasmonate (MJ) significantly decreased both cell cycle progression and biomass accumulation, as the specific growth rate decreased to 0.027 days(-1) by fresh and dry weight. Despite the decrease in biomass accumulation for MJ elicited cultures, sucrose utilization was not significantly different from control cultures. MJ elicitation also increased the accumulation of paclitaxel and other taxanes. The accumulation of upstream taxanes (baccatin III and 10-deactylbaccatin III) increased during exponential growth, reached a maximum around day 12, and then declined throughout the stationary phase. The paclitaxel concentration increased during both exponential growth and stationary phase, reaching a maximum around days 20-25. Throughout the culture period, greater than 70% of the cells were in G(0)/G(1) phase of the cell cycle. Studies using bromodeoxyuridine (BrdU) incorporation showed that approximately 65% of the Taxus cells are noncycling, even during exponential growth. Although the role of these cells is currently unknown, the presence of a large, noncycling subpopulation can have a significant impact on the utilization of plant cell culture technology for the large-scale production of paclitaxel. These results demonstrate that there is a high degree of metabolic heterogeneity in Taxus cuspidata suspension cultures. Understanding this heterogeneity is important for the optimization of plant cell cultures, particularly the reduction of production variability.     

Elicitation kinetics of taxane production in suspension cultures of Taxus baccata Pendula

Methyl jasmonate increased taxane production in suspension cultures of Taxus baccata Pendula. Time course changes of taxane production after methyl jasmonate addition were different from normal kinetics without elicitation. Baccatin III and 10-deacetyl baccatin III were detected first and paclitaxel, 10-deacetyl taxol and cephalomanine followed each other in sequence. Paclitaxel was not a dead-end metabolite.     

Manipulation by culture mixing and elicitation of paclitaxel and baccatin III production in Taxus baccata suspension cultures

Summary Experiments were carried out with Taxus baccata cell lines showing different paclitaxel-producing capacities (between 1.74 and 19.91 mgl^−1) when growing in a selected product-formation medium that specifically stimulated the production of taxane to the detriment of cell growth. Through mixing low-, medial- and high-producing lines, it could be observed that paclitaxel productivity in the resulting mixed lines was clearly higher than the mean productivity of the individual lines before mixing. This suggests that culture components generated by high-producing individual lines within the population might induce paclitaxel production. Although the accumulation of paclitaxel and baccatin III was higher when 100 μM methyl jasmonate was added to the subcultures of the mixed lines, the results indicate that exogenously applied methyl jasmonate was not the first factor to stimulate taxane production. The possible effects of methyl jasmonate elicitation and paclitaxel accumulation on cell viability are also considered.     

Relationship of viability and apoptosis to taxol production in Taxus sp. suspension cultures elicited with methyl jasmonate

Taxus cuspidata P991 in plant cell suspension culture is capable of producing the important anticancer agent Taxol (paclitaxel) and related taxanes. High-level production is obtained by elicitation with methyl jasmonate, but successful elicitation leads to loss of cell viability that cannot be recovered by subculture. Here, we test whether the loss of viability is due to a direct effect of methyl jasmonate. Upon subculture, the reduced viability continued in methyl jasmonate elicited cultures, but not in nonelicited control cultures. The growth reduction in elicited T. cuspidata P991 suspension cultures was evaluated by viability reduction measurements using phenosafranin and fluorescein diacetate. The viability reduction does not appear to be related to apoptosis based on DNA laddering analysis because it occurred very late (at day 35) in the culture period. DNA laddering was also found only after day 28 in T. canadensis C93AD (a Taxol-producing cell line) elicited with methyl jasmonate, implying that apoptosis is not the major death mechanism after elicitation. As compared to Taxol-producing cell lines, the viability of a nonproducing cell line, T. canadensis CO93D, was not severely affected by methyl jasmonate, indicating that methyl jasmonate itself is not the primary factor for viability reduction. Based on Northern analysis of taxadiene synthase mRNA from both elicited and nonelicited T. cuspidata P991, methyl jasmonate directly induces the production of this enzyme, which is the first committed step in the biosynthetic pathway for Taxol. As a result, both viability reduction and growth reduction appear related to a high production level of Taxol (and related taxanes) upon methyl jasmonate elicitation, rather than to the direct effect of methyl jasmonate.     

Paclitaxel and baccatin III production induced by methyl jasmonate in free and immobilized cells of Taxus baccata

The effects of 100 and 200 μM methyl jasmonate (MJA) on cell proliferation and paclitaxel and baccatin III production were investigated in free and alginate immobilized cells of Taxus baccata growing in a selected product formation culture medium. The greatest accumulation of paclitaxel (13.20 mg dm⁻³) and baccatin III (4.62 mg dm⁻³) occurred when 100 μM MJA was added to the culture medium of cells entrapped using a 1.5 and 2.5 % alginate solution. The effects of different treatments on the viability of cultured cells and their capacity to excrete both taxanes into the surrounding medium were considered.     

Taxus metabolomics: methyl jasmonate preferentially induces production of taxoids oxygenated at C-13 in Taxus x media cell cultures

Cells from suspension cultures of Taxus cuspidata were extracted with pentane as a source of relatively non-polar taxoids. Of the 13 taxoids identified in this fraction, eight were oxygenated at C-14 and two had not been previously described. These taxoids, along with existing taxoid standards, were employed to profile the metabolites of Taxus x media cv. Hicksii cell suspension cultures induced with methyl jasmonate to produce paclitaxel (Taxol). The majority of the taxoid metabolites produced in these induced cultures were oxygenated at C-13, and not C-14.     

Kinetic studies of paclitaxel production by Taxus canadensis cultures in batch and semicontinuous with total cell recycle

Suspension cultures of Taxus canadensis were elicited with methyl jasmonate (MJ) under defined headspace ethylene concentrations. Kinetic studies of growth, nutrient consumption, pH variation, and paclitaxel accumulation were conducted in batch cultures and semicontinuous culture with total cell recycle. A dramatic increase of paclitaxel was obtained when the cultures were elicited with 100 microM MJ, but cell growth was thereby arrested. Supplementation of acetyl-CoA and MJ to the culture proved to be another way to improve paclitaxel yields. Using semicontinuous culture with total cell recycle, paclitaxel accumulation was increased by a factor of 4.0 relative to that in the batch culture during 35 days of cultivation.     

Effect of subculture and elicitation on instability of taxol production in Taxus sp. suspension cultures

The production of secondary metabolites through plant cell suspension cultures is challenging because the level and pattern of production is often unstable and unpredictable. To investigate the factors affecting instability of secondary metabolite production, high Taxol (paclitaxel)-producing Taxus cultures induced by methyl jasmonate elicitation and their low Taxol-producing counterparts were compared with respect to growth and Taxol production kinetics. With Taxus subcultures we observe alternating states of high and low productivity. Parental cultures and their subcultures from five different cell lines were used to test whether a high-producing culture grows more slowly or dies more rapidly than a low-producing one. These cell lines were of three types: (1) Taxol-producing with and without methyl jasmonate, (2) Taxol-producing only upon elicitation, and (3) nonproducing. High-producing cultures show growth inhibition upon subculture, whereas nonproducing elicited cultures show little growth inhibition. Thus, growth inhibition is primarily due to Taxol or taxane accumulation and not a direct result of methyl jasmonate treatment. Through media exchange between high- and low-producing cultures, it appears that culture components generated by cells alter culture properties. To assess variability as a function of culture lineage, two groups of replicate cultures were generated either with a mixing of the parental flasks or segregation of parental flasks at each subculture. Although parental culture mixing did not reduce flask-to-flask variation, the production level of Taxol in subcultures resulting from mixing inocula was sustained at a higher level relative to segregated subcultures. The results are consistent with the possibility of cell signaling within the population that can induce Taxol production.     

The configuration of methyl jasmonate affects paclitaxel and baccatin III production in Taxus cells

All stereoisomers of methyl jasmonate (MJA) were prepared, and their effects on cell yield and promotion of paclitaxel (Taxol) and baccatin III production investigated in cell suspension cultures of Taxus media. (3R,7S)-MJA showed the strongest cell growth inhibition, followed by (3R,7R)-MJA. In contrast, (3S,7R)- and (3S,7S)-MJA had very low inhibitory effects, indicating that this inhibition depends largely on the (3R)-configuration. In terms of the promotion of paclitaxel and baccatin III production, (3R,7R)-MJA had the highest activity. Although it showed considerable activity at low concentration, at higher concentrations the activity was decreased due to strong inhibition of cell growth. Interestingly, paclitaxel and baccatin III contents increased even at a high (3S,7R)-MJA concentration, whereas the other isomers had the opposite effects. These findings are interpreted to suggest that the optimum configuration is (3R,7R), the (3R)-configuration not being indispensable, and that the (7R)-configuration is suitable for the promotion of paclitaxel and baccatin III production.     

Effect of the culture medium and biotic stimulation on taxane production in Taxus globosa Schltdl in vitro cultures

Taxus globosa is the only species of the Taxus genus that grows in Mexico. In this study, callus cultures from leaves and young shoots of T. globosa were established in Gamborg’s B5 medium supplemented with 2,4-dichlorophenoxiacetic acid (2 mg/L), kinetin (0.5 mg/L) and gibberellic acid (0.25 mg/L). Callus growth and taxane production were evaluated using two culture media: Woody Plant Medium and Gamborg’s B5 supplemented with picloram (2 mg/L), kinetin (0.1 mg/L) and gibberellic acid (0.5 mg/L). The effect of the inoculum size (50, 100 and 150 g FW/L) and culture media (Woody Plant Medium and Gamborg’s B5) with and without the presence of methyl jasmonate (100 μM) on T. globosa cell suspensions was assessed. Taxane analysis revealed that the calli in Gamborg’s B5 produced taxol (50 μg/g DW), baccatin III, 10-deacetyl baccatin III and 10-deacetyl taxol. Woody Plant Medium also induced the production of taxol, although to a lesser extent. The optimum inoculum size was 50 g FW/L. In cell suspension cultures, both media had a significant effect on taxane production when supplemented with methyl jasmonate. In Woody Plant Medium, at day 14, a total concentration of 197.999 μg/L of taxol, 160.622 μg/L of baccatin III, 633.724 μg/L of 10-deacetyl baccatin III and 229.611 μg/L 10-deacetyl taxol were obtained, with total excretion of baccatin III and 10-deacetyl taxol to the culture medium. In Gamborg’s B5, cephalomanine was obtained at a concentration of 91.428 μg/L without elicitation, and all taxanes were excreted to the medium to a variable extent.     

中国红豆杉细胞经重复诱导和蔗糖饲喂后云南紫杉烷C生产的相应基因表达变化

红豆杉悬浮培养细胞具有可持续生产抗癌药物紫杉醇及其他紫杉烷的潜力。在中国红豆杉悬浮培养细胞中,云南紫杉烷 C(Tc) 是主要的次生代谢产物。为促使代谢前体由生成其他紫杉烷的代谢支路转到生产紫杉醇,实验采用实时定量PCR技术 (RQ-PCR) 揭示细胞培养过程中紫杉醇及紫杉烷合成关键基因的动态变化。在细胞培养的第7天和第12天,以100 μmol/L 2,3-二羟丙基茉莉酸 (DHPJA) 进行诱导,同时在第7天饲喂20 g/L的蔗糖,在此过程中考察6个关键基因 (TASY,TDAT,T5αH,TαH,T10βH和T14βH) 的表达变化。上述联合调控手段使得Tc产量在第1次诱导8 d后达 (554.46±21.28) mg/L,第2次诱导9 d后高达 (997.72±1.51) mg/L。代谢早期基因TASY和TDAT在第1次诱导后表达量分别提高了182和98倍,在第2次诱导后表达量分别提高了208和131倍。在每次诱导后基因表达量提高约持续24 h,之后下降。其他4个基因 (T5αH、TαH、T10βH和T14βH) 的情况有所不同。基因TαH在2次诱导后表达量分别提高了3 061和1 016倍。其他3个基因T5αH、T10βH、T14βH在第1次诱导后表达量分别提高13、38、20倍,在第2次诱导后分别提高7、16、6倍。RQ-PCR结果表明基因表达和Tc积累之间存在紧密相关性：基因表达的变化与Tc产量的变化相一致,诱导可提高6个基因的表达量。基因的高表达随着培养过程逐渐衰减,再次诱导可再次促使基因的高表达。     

Flow cytometric identification of Paclitaxel-accumulating subpopulations

An immunofluorescence procedure was developed for paclitaxel quantification at the single cell level via flow cytometry in Taxus cuspidata suspension cultures. Intracellular staining was validated via fluorescence microscopy. Paclitaxel content of isolated cells and protoplasts was compared to total paclitaxel levels measured via HPLC. Paclitaxel accumulation was significantly increased by elicitation with methyl jasmonate (100 microM) on day 7 post-transfer as compared to unelicited cultures. Maximum accumulation was observed by day 12 post-transfer in both total paclitaxel (approximately 0.25 mg/L) and the percentage of paclitaxel-accumulating cells (approximately 95%). A similar trend was observed with isolated protoplasts, although protoplasts accumulated only ca. 40-75% of the paclitaxel present in single cells. In unelicited cell cultures, a small subpopulation (ca. 3-5%) of single cells was shown to accumulate paclitaxel. Although nearly all cells were observed to accumulate paclitaxel in methyl jasmonate-elicited cell cultures, a high degree of cell-to-cell variation was observed in paclitaxel content. The identified subpopulations represent targets for cell sorting, which may be applied to develop higher-accumulating cell lines. The quantification of single cell paclitaxel content is useful for characterizing production variability in cell cultures and can be utilized to develop rational strategies to increase paclitaxel production.     

Analysis of aggregate size as a process variable affecting paclitaxel accumulation in Taxus suspension cultures

Plant cell aggregates have long been implicated in affecting cellular metabolism in suspension culture, yet the rigorous characterization of aggregate size as a process variable and its effect on bioprocess performance has not been demonstrated. Aggregate fractionation and analysis of biomass-associated product is commonly used to assess the effect of aggregation, but we establish that this method is flawed under certain conditions and does not necessarily agree with comprehensive studies of total culture performance. Leveraging recent advances to routinely measure aggregate size distributions, we developed a simple method to manipulate aggregate size and evaluate its effect on the culture as a whole, and found that Taxus suspension cultures with smaller aggregates produced significantly more paclitaxel than cultures with larger aggregates in two cell lines over a range of aggregate sizes, and where biomass accumulation was equivalent before elicitation with methyl jasmonate. Taxus cuspidata (T. cuspidata) P93AF cultures with mean aggregate sizes of 690 and 1,100 μm produced 22 and 11 mg/L paclitaxel, respectively, a twofold increase for smaller aggregates, and T. cuspidata P991 cultures with mean aggregate sizes of 400 and 840 μm produced 6 and 0.3 mg/L paclitaxel, respectively, an increase of 20-fold for smaller aggregates. These results demonstrate the importance of validating experiments aimed at a specific phenomenon with total process studies, and provide a basis for treating aggregate size as a targeted process variable for rational control strategies.     

Effects of immobilization by entrapment in alginate and scale-up on paclitaxel and baccatin III production in cell suspension cultures of Taxus baccata

Paclitaxel and baccatin III-producing cells of Taxus baccata were immobilized within Ca(2+)-alginate beads. Under established optimum conditions for the biosynthesis of both taxanes, the yields of paclitaxel and baccatin III in shake-flask cultures of free cells increased by factors of up to 3 and 2, respectively, in the corresponding cultures of immobilized cells. Although the scale-up from shake-flask to bioreactor culture usually results in reduced productivities when both free and immobilized cells were grown in the same optimum conditions in three different bioreactor types (Stirred, Airlift, and Wave) running for 24 days in a batch mode and with the system optimized in each case, there was a considerable increase in the yields of paclitaxel and baccatin III. Among the reactors, the Stirred bioreactor was the most efficient in promoting immobilized cell production of paclitaxel, giving a content of 43.43 mg.L(-1) at 16 days of culture, equivalent to a rate of 2.71 mg.L(-1).day(-1). To our knowledge, the paclitaxel productivity obtained in this study is one of the highest reported so far by academic laboratories for Taxus species cultures in bioreactors.     

Inhibition of paclitaxel and baccatin III accumulation by mevinolin and fosmidomycin in suspension cultures of Taxus baccata

To achieve a better understanding of the metabolism and accumulation of paclitaxel and baccatin III in cell cultures of Taxus, inhibitors of the early steps in the terpenoid pathway were applied to a cell suspension culture of Taxus baccata: fosmidomycin as an inhibitor of the non-mevalonate branch of the pathway, and mevinolin as an inhibitor of the mevalonate branch. Synthesis of both taxanes in the cell suspension was first increased when cultured in the product formation medium supplemented with methyljasmonate (100 microM). The product formation medium was selected after assaying 24 different culture media. When fosmidomycin (200 microM) was added to the product formation medium together with the elicitor, the accumulation of paclitaxel and baccatin III was reduced by up to 3.0 and 1.5 times, respectively, whereas the inhibitory effect of mevinolin (1 microM) was only clearly exerted in the case of paclitaxel. Under the conditions of our experiment, we conclude that in the synthesis of both taxanes, the non-mevalonate pathway is the main source of the universal terpenoid precursor isopentenyl diphosphate (IPP).     

Isolation of an endophytic fungus producing baccatin III from Taxus wallichiana var. mairei

The objective of this study was to isolate endophytic fungi producing baccatin III from yew for the purpose of baccatin III and paclitaxel manufacture. Surface sterilized bark of Taxus wallichiana var. mairei was used as source material with potato dextrose agar culture medium for isolation of endophytic fungi. Fungal cultures were extracted with a mixture of chloroform/methanol (1:1, v/v) and the baccatin III in the extracts was determined and authenticated with LC–MS. An endophytic fungus that produced baccatin III was identified by ITS rDNA and 26S D1/D2 rDNA sequencing. A total of 192 endophytic fungal strains were isolated from T. wallichiana var. mairei. Only one of the 192 strains produced baccatin III and it was identified as Diaporthe phaseolorum. The productivity of this strain cultured in PDA culture medium was 0.219 mg/l. The isolated endophytic fungus produced baccatin III at a relatively high level and shows promise as a producing strain for baccatin III and paclitaxel manufacture after strain improvement.     

Preparation of single cells from aggregated Taxus suspension cultures for population analysis

A method for the isolation of single plant cells from Taxus suspension cultures has been developed for the analysis of single cells via rapid throughput techniques such as flow cytometry. Several cell wall specific enzymes, such as pectinase, pectolyase Y-23, macerozyme, Driselase(R), and cellulase were tested for efficacy in producing single cell suspensions. The method was optimized for single cell yield, viability, time, and representivity of aggregated cell cultures. The best combination for single cell isolation was found to be 0.5% (w/v) pectolyase Y-23 and 0.04% (w/v) cellulase. High viability (>95%) and high yields of single cell aggregates (>90%) were obtained following 4 hours of digestion for four separate Taxus cell lines. In addition, methyl jasmonate elicitation (200 microM) was found to have no effect on three of the four tested Taxus lines. Isolated single cells were statistically similar to untreated cell cultures for peroxidase activity (model cell wall protein) and paclitaxel content (secondary metabolite produced in Taxus cell cultures). In comparison, protoplasts showed marked changes in both peroxidase activity and paclitaxel content as compared to untreated cultures. The use of flow cytometry was demonstrated with isolated cells that were found to have > 99% viability upon staining with fluorescein diacetate. The development of a method for the isolation of single plant cells will allow the study of population dynamics and culture variability on a single cell level for the development of population models of plant cell cultures and secondary metabolism.     

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.