Elisabeth Moyano

Biotechnological production of taxol and related taxoids: current state and prospects.

Taxol is one of the most effective anti-cancer drugs ever developed. The natural source of taxol is the inner bark of several Taxus species, but it accumulates at a very low concentration and with a prohibitively high cost of extraction. Another problem is that the use of inner bark for taxol production implies the destruction of yew trees. For all these reasons, the growing demand for taxol greatly exceeds the supply that can be sustained by isolation from its natural source and alternative sources of the drug are being sought. Although taxol has been prepared by total synthesis, the process is not commercially viable. Taxol can also be semisynthetically produced via the conversion of baccatin III or 10-deacethylbaccatinIII found in Taxus needles but the cost and difficulty of the extraction process of the semisynthetic precursors are also very high. The most promising approach for the sustainable production of taxol and related taxoids is provided by plant cell cultures at an industrial level. Taxol is currently being clinically used against different tumour processes but due to the difficulty of its extraction and formulation, as well as the growing demand for the compound, new taxol analogues with improved properties are being studied. In this revision we discuss current research in the design of new taxol-related compounds, the chemical structure/anti-cancer activity relationship and new formulations of the drug. We also consider the optimizing strategies to improve taxol and related taxoid production in cell cultures, as well as the current knowledge of taxol metabolism, all of which are illustrated with examples, some of them from our own research.

Alkaloid production in Duboisia hybrid hairy root cultures overexpressing the pmt gene

Putrescine:SAM N-methyltransferase (PMT) catalyses the N-methylation of the diamine putrescine to form N-methylputrescine, the first specific precursor of both tropane and pyridine-type alkaloids, which are present together in the roots of Duboisia plants. The pmt gene of Nicotiana tabacum was placed under the regulation of the CaMV 35S promoter and introduced into the genome of a scopolamine-rich Duboisia hybrid by a binary vector system using the disarmed Agrobacterium tumefaciens strain C58C1 carrying the rooting plasmid pRiA4. The presence of the foreign gene in kanamycin-resistant hairy roots and its overexpression were confirmed by polymerase chain reaction and Northern blot analysis respectively. The N-methylputrescine levels of the resulting engineered hairy roots increased (2-4-fold) compared to wild type roots, but there was no significant increase in either tropane or pyridine-type alkaloids.

Elicitation, an Effective Strategy for the Biotechnological Production of Bioactive High-Added Value Compounds in Plant Cell Factories

Plant in vitro cultures represent an attractive and cost-effective alternative to classical approaches to plant secondary metabolite (PSM) production (the “Plant Cell Factory” concept). Among other advantages, they constitute the only sustainable and eco-friendly system to obtain complex chemical structures biosynthesized by rare or endangered plant species that resist domestication. For successful results, the biotechnological production of PSM requires an optimized system, for which elicitation has proved one of the most effective strategies. In plant cell cultures, an elicitor can be defined as a compound introduced in small concentrations to a living system to promote the biosynthesis of the target metabolite. Traditionally, elicitors have been classified in two types, abiotic or biotic, according to their chemical nature and exogenous or endogenous origin, and notably include yeast extract, methyl jasmonate, salicylic acid, vanadyl sulphate and chitosan. In this review, we summarize the enhancing effects of elicitors on the production of high-added value plant compounds such as taxanes, ginsenosides, aryltetralin lignans and other types of polyphenols, focusing particularly on the use of a new generation of elicitors such as coronatine and cyclodextrins.

Metabolic responses of Taxus media transformed cell cultures to the addition of methyl jasmonate.

Dedifferentiated Taxus media cell cultures presenting the same genetic characteristics as the parent culture were established from transformed roots. Two transformed cell lines were studied: Rol C, carrying the T‐DNA of A. rhizogenes 9,402 and TXS, carrying both the T‐DNA of A. rhizogenes and the txs transgene of T. baccata under the control of the 35S CaMV promoter. In the second part of a previously optimized two‐stage system, the transformed cell lines were cultured in a production medium supplemented with the elicitor methyl jasmonate. Taxane production in the transformed cultures was compared with an untransformed T. media cell line cultured in the same conditions. The highest taxane production was observed in the TXS cell line when cultured in the optimized production medium with methyl jasmonate, being 265% greater than in the untransformed control and 170% greater than in the Rol C cell line. However, txs expression and the activity of the enzyme taxadiene synthase in the TXS cells were lower than in the line carrying only the rol genes (Rol C). It is also noteworthy that the taxane production as well as the txs gene expression and TXS activity in all the cell lines, both transformed and untransformed, were clearly dependent on the elicitor action.

Podophyllotoxin: current approaches to its biotechnological production and future challenges.

Many plant‐derived agents are being used to treat cancer, including taxol, vinblastine, vincristine, or camptothecin and podophyllotoxin derivatives, among others. Plant biotechnology can provide a new tool for the production of anticancer agents but in spite of considerable efforts to produce vinblastine and vincristine in cell cultures and knowledge of the biosynthetic pathway of Catharanthus roseus alkaloids, the biotechnological production of taxol has only been achieved at an industrial level by companies such as Phyton Biotech and Cytoclonal Pharmaceutics. Podophyllotoxin was isolated as the active antitumor agent from the roots of Podophyllum species and more recently from the genus Linum and others. Etoposide, teniposide, and etophos are semi‐synthetic derivatives of podophyllotoxin and are used in the treatment of cancer. Biotechnological approaches, including the use of cell cultures, biotransformation, or metabolic engineering techniques to manipulate the biosynthetic pathway, represent an alternative for the production of podophyllotoxin and are discussed in this review.

The effect of light on gene expression and podophyllotoxin biosynthesis in Linum album cell culture

Podophyllotoxin (PTOX) is a naturally occurring phenolic compound isolated as an active anti-tumor agent. The stimulatory influence of light on the formation of phenolic compounds has been reported, but the molecular mechanism underlying the effect of light on the expression of genes involved in phenolic biosynthesis, especially of lignans, is still not fully understood. A series of experiments was carried out using ordinary fluorescent lamps to study the influence of light irradiation on growth and PTOX accumulation in Linum album cell cultures by varying the type of light and periods of exposure. The biosynthesis of PTOX was variably affected according to the quality of light. The enhancing effects of red light on PTOX production was correlated with increased activities of the enzyme phenylalanine ammonia-lyase (PAL), and the expression of some key genes involved in the biosynthesis of this compound, including the PAL gene itself and the cinnamoyl-CoA reductase (CCR) gene. Blue light was found to have similar effects but mainly on the expression level of CCR and pinoresinol lariciresinol reductase (PLR) genes.

Overexpression of the Arabidopsis thaliana squalene synthase gene in Withania coagulans hairy root cultures

Squalene synthase (SS) dimerizes two molecules of farnesyl diphosphate to synthesize squalene, a shared precursor in steroid and triterpenoid biosynthesis in plants. The SS1 gene encoding SS from Arabidopsis thaliana was introduced in Withania coagulans under the control of the CaMV35S promoter together with the T-DNA of Agrobacterium rhizogenes A4. The engineered hairy roots were studied for withanolide production and phytosterol accumulation and the results were compared with those obtained from control roots harbouring only the T-DNA from pRiA4. The increased capacity of the engineered roots for biosynthesizing phytosterols and withanolides was strongly related with the expression level of the transgene, showing the effectiveness of overexpressing 35SS1 to increase triterpenoid biosynthesis.

Synergistic effect of cyclodextrins and methyl jasmonate on taxane production in Taxus x media cell cultures

Methyl jasmonate and cyclodextrins are proven effective inducers of secondary metabolism in plant cell cultures. Cyclodextrins, which are cyclic oligosaccharides, can form inclusion complexes with nonhydrophilic secondary products, thus increasing their excretion from the producer cells to the culture medium. In the present work, using a selected Taxus x media cell line cultured in a two-stage system, the relationship between taxane production and the transcript profiles of several genes involved in taxol metabolism was studied to gain more insight into the mechanism by which these two elicitors regulate the biosynthesis and excretion of taxol and related taxanes. Gene expression was not clearly enhanced by the presence of cyclodextrins in the culture medium and variably induced by methyl jasmonate, but when the culture was supplemented with both elicitors, a synergistic effect on transcript accumulation was observed. The BAPT and DBTNBT genes, which encode the last two transferases involved in the taxol pathway, appeared to control limiting biosynthetic steps. In the cell cultures treated with both elicitors, the produced taxanes were found mainly in the culture medium, which limited retroinhibition processes and taxane toxicity for the producer cells. The expression level of a putative ABC gene was found to have increased, suggesting it played a role in the taxane excretion. Taxol biosynthesis was clearly increased by the joint action of methyl jasmonate and cyclodextrins, reaching production levels 55 times higher than in nonelicited cultures.

MANIPULATION BY CULTURE MIXING AND ELICITATION OF PACLITAXEL AND BACCATIN III PRODUCTION IN TAXUS BACCATA SUSPENSION CULTURES

SummaryExperiments 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.

Transcript profiling of jasmonate-elicited Taxus cells reveals a β-phenylalanine-CoA ligase.

Plant cell cultures constitute eco-friendly biotechnological platforms for the production of plant secondary metabolites with pharmacological activities, as well as a suitable system for extending our knowledge of secondary metabolism. Despite the high added value of taxol and the importance of taxanes as anticancer compounds, several aspects of their biosynthesis remain unknown. In this work, a genomewide expression analysis of jasmonate-elicited Taxus baccata cell cultures by complementary DNA-amplified fragment length polymorphism (cDNA-AFLP) indicated a correlation between an extensive elicitor-induced genetic reprogramming and increased taxane production in the targeted cultures. Subsequent in silico analysis allowed us to identify 15 genes with a jasmonate-induced differential expression as putative candidates for genes encoding enzymes involved in five unknown steps of taxane biosynthesis. Among them, the TB768 gene showed a strong homology, including a very similar predicted 3D structure, with other genes previously reported to encode acyl-CoA ligases, thus suggesting a role in the formation of the taxol lateral chain. Functional analysis confirmed that the TB768 gene encodes an acyl-CoA ligase that localizes to the cytoplasm and is able to convert β-phenylalanine, as well as coumaric acid, into their respective derivative CoA esters. β-phenylalanyl-CoA is attached to baccatin III in one of the last steps of the taxol biosynthetic pathway. The identification of this gene will contribute to the establishment of sustainable taxol production systems through metabolic engineering or synthetic biology approaches.