Project description:Taxol is one of the most effective anticancer drugs in the world that is widely used in the treatments of breast, lung and ovarian cancer. The elucidation of the taxol biosynthetic pathway is the key to solve the problem of taxol supply. So far, the taxol biosynthetic pathway has been reported to require an estimated 20 steps of enzymatic reactions, and sixteen enzymes involved in the taxol pathway have been well characterized, including a novel taxane-10β-hydroxylase (T10βOH) and a newly putative β-phenylalanyl-CoA ligase (PCL). Moreover, the source and formation of the taxane core and the details of the downstream synthetic pathway have been basically depicted, while the modification of the core taxane skeleton has not been fully reported, mainly concerning the developments from diol intermediates to 2-debenzoyltaxane. The acylation reaction mediated by specialized Taxus BAHD family acyltransferases (ACTs) is recognized as one of the most important steps in the modification of core taxane skeleton that contribute to the increase of taxol yield. Recently, the influence of acylation on the functional and structural diversity of taxanes has also been continuously revealed. This review summarizes the latest research advances of the taxol biosynthetic pathway and systematically discusses the acylation reactions supported by Taxus ACTs. The underlying mechanism could improve the understanding of taxol biosynthesis, and provide a theoretical basis for the mass production of taxol.

Project description:A cDNA clone encoding a taxane 2alpha-O-benzoyltransferase has been isolated from Taxus cuspidata. The recombinant enzyme catalyzes the conversion of 2-debenzoyl-7,13-diacetylbaccatin III, a semisynthetic substrate, to 7,13-diacetylbaccatin III, and thus appears to function in a late-stage acylation step of the Taxol biosynthetic pathway. By employing a homology-based PCR cloning strategy for generating acyltransferase oligodeoxynucleotide probes, several gene fragments were amplified and used to screen a cDNA library constructed from mRNA isolated from methyl jasmonate-induced Taxus cells, from which several full-length acyltransferases were obtained and individually expressed in Escherichia coli. The functionally expressed benzoyltransferase was confirmed by radio-HPLC, (1)H-NMR, and combined HPLC-MS verification of the product, 7, 13-diacetylbaccatin III, derived from 2-debenzoyl-7, 13-diacetylbaccatin III and benzoyl-CoA as cosubstrates in the corresponding cell-free extract. The full-length cDNA has an open reading frame of 1,320 base pairs and encodes a protein of 440 residues with a molecular weight of 50,089. The recombinant benzoyltransferase has a pH optimum of 8.0, K(m) values of 0.64 mM and 0.30 mM for the taxoid substrate and benzoyl-CoA, respectively, and is apparently regiospecific for acylation of the 2alpha-hydroxyl group of the functionalized taxane nucleus. This enzyme may be used to improve the production yields of Taxol and for the semisynthesis of drug analogs bearing modified aroyl groups at the C2 position.

Project description:BackgroundTaxol from Taxus species is a precious drug used for the treatment of cancer and can effectively inhibit the proliferation of cancer cells. However, the growth of Taxus plants is very slow and the content of taxol is quite low. Therefore, it is of great significance to improve the yield of taxol by modern biotechnology without destroying the wild forest resources. Endophytic fungus which symbiosis with their host plants can promote the growth and secondary metabolism of medicinal plants.ResultsHere, an endophytic fungus KL27 was isolated from T. chinensis, and identified as Pseudodidymocyrtis lobariellae. The fermentation broth of KL27 (KL27-FB) could significantly promote the accumulation of taxol in needles of T. chinensis, reaching 0.361 ± 0.082 mg/g·DW (dry weight) at 7 days after KL27-FB treatment, which is 3.26-fold increase as compared to the control. The RNA-seq and qRT-PCR showed that KL27-FB could significantly increase the expression of key genes involved in the upstream pathway of terpene synthesis (such as DXS and DXR) and those in the taxol biosynthesis pathway (such as GGPPS, TS, T5OH, TAT, T10OH, T14OH, T2OH, TBT, DBAT and PAM), especially at the early stage of the stimulation. Moreover, the activation of jasmonic acid (JA) biosynthesis and JA signal transduction, and its crosstalk with other hormones, such as gibberellin acid (GA), ethylene (ET) and salicylic acid (SA), explained the elevation of most of the differential expressed genes related to taxol biosynthesis pathway. Moreover, TF (transcriptional factor)-encoding genes, including MYBs, ethylene-responsive transcription factors (ERFs) and basic/helix-loop-helix (bHLH), were detected as differential expressed genes after KL27-FB treatment, further suggested that the regulation of hormone signaling on genes of taxol biosynthesis was mediated by TFs.ConclusionsOur results indicated that fermentation broth of endophytic fungus KL27-FB could effectively enhance the accumulation of taxol in T. chinensis needles by regulating the phytohormone metabolism and signal transduction and further up-regulating the expression of multiple key genes involved in taxol biosynthesis. This study provides new insight into the regulatory mechanism of how endophytic fungus promotes the production and accumulation of taxol in Taxus sp.

Project description:BackgroundTaxus cuspidata is well known worldwide for its ability to produce Taxol, one of the top-selling natural anticancer drugs. However, current Taxol production cannot match the increasing needs of the market, and novel strategies should be considered to increase the supply of Taxol. Since the biosynthetic mechanism of Taxol remains largely unknown, elucidating this pathway in detail will be very helpful in exploring alternative methods for Taxol production.ResultsHere, we sequenced Taxus cuspidata transcriptomes with next-generation sequencing (NGS) and third-generation sequencing (TGS) platforms. After correction with Illumina reads and removal of redundant reads, more than 180,000 nonredundant transcripts were generated from the raw Iso-Seq data. Using Cogent software and an alignment-based method, we identified a total of 139 cytochrome P450s (CYP450s), 31 BAHD acyltransferases (ACTs) and 1940 transcription factors (TFs). Based on phylogenetic and coexpression analysis, we identified 9 CYP450s and 7 BAHD ACTs as potential lead candidates for Taxol biosynthesis and 6 TFs that are possibly involved in the regulation of this process. Using coexpression analysis of genes known to be involved in Taxol biosynthesis, we elucidated the stem biosynthetic pathway. In addition, we analyzed the expression patterns of 12 characterized genes in the Taxol pathway and speculated that the isoprene precursors for Taxol biosynthesis were mainly synthesized via the MEP pathway. In addition, we found and confirmed that the alternative splicing patterns of some genes varied in different tissues, which may be an important tissue-specific method of posttranscriptional regulation.ConclusionsA strategy was developed to generate corrected full-length or nearly full-length transcripts without assembly to ensure sequence accuracy, thus greatly improving the reliability of coexpression and phylogenetic analysis and greatly facilitating gene cloning and characterization. This strategy was successfully utilized to elucidate the Taxol biosynthetic pathway, which will greatly contribute to the goals of improving the Taxol content in Taxus spp. using molecular breeding or plant management strategies and synthesizing Taxol in microorganisms using synthetic biological technology.

Project description:The structural pharmacophore of Taxol, responsible for binding the N terminus of the beta-subunit of tubulin to arrest cell proliferation, comprises, in part, the 13-O-(N-benzoyl-3-phenylisoserinoyl) side chain. To identify the side chain transferase of Taxol biosynthesis, a set of transacylases obtained from an enriched cDNA library (constructed from mRNA isolated from Taxus cuspidata cells induced with methyl jasmonate for Taxol production) was screened. A cDNA clone (designated TAX7) encoding a taxoid C-13 O-phenylpropanoyltransferase was isolated which yielded a recombinant enzyme that catalyzes the selective 13-O-acylation of baccatin III with beta-phenylalanoyl CoA as the acyl donor to form N-debenzoyl-2'-deoxytaxol. This enzymatic product was converted to 2'-deoxytaxol by chemical N-benzoylation, and the identity of this derivative was confirmed by spectrometric analyses. The full-length cDNA has an ORF of 1,335 bases and encodes a 445-aa protein with a calculated molecular weight of 50,546. Evaluation of kinetic parameters revealed K(m) values of 2.4 +/- 0.5 microM and 4.9 +/- 0.3 microM for baccatin III and beta-phenylalanoyl-CoA, respectively. The pH optimum for the recombinant O-(3-amino-3-phenylpropanoyl)transferase is at 6.8. Identification of this clone completes acquisition of the five aroyl/acyltransferases involved in the biosynthesis of Taxol. Application of these transacylase genes in suitable host cells can improve the production yields of Taxol and could enable the preparation of second-generation Taxol analogs possessing greater bioactivity and improved water solubility.

Project description:Biosynthesis of the anticancer drug Taxol involves 19 enzymatic steps from the universal diterpenoid progenitor geranylgeranyl diphosphate derived by the plastidial methylerythritol phosphate pathway for isoprenoid precursor supply. To gain further insight about Taxol biosynthesis relevant to the improved production of this drug and to draw inferences about the organization, regulation, and origins of this complex natural product pathway, random sequencing of a cDNA library derived from Taxus cuspidata cells (induced for taxoid biosynthesis with methyl jasmonate) was undertaken. This effort revealed surprisingly high abundances for transcripts of several of the 12 defined genes of Taxol biosynthesis, yielded cDNAs encoding two previously uncharacterized cytochrome P450 taxoid hydroxylases, and provided candidate genes for all but one of the remaining seven steps of this extended sequence of reactions.

Project description:WRKY, a plant-specific transcription factor family, plays important roles in pathogen defense, abiotic cues, phytohormone signaling, and regulation of plant secondary metabolism. However, little is known about the roles, functions, and mechanisms of WRKY in taxane biosynthesis in Taxus spp. In this study, 61 transcripts were identified from Taxus chinensis transcriptome datasets by using hidden Markov model search. All of these transcripts encoded proteins containing WRKY domains, which were designated as TcWRKY1-61. After phylogenetic analysis of the WRKY domains of TcWRKYs and AtWRKYs, 16, 8, 10, 14, 5, 7, and 1 TcWRKYs were cladded into Group I, IIa-IIe, and III, respectively. Then, six representative TcWRKYs were selected to classify their effects on taxol biosynthesis. After MeJA (methyl jasmonate acid) and SA (salicylic acid) treatments, all of the six TcWRKYs were upregulated by MeJA treatment. TcWRKY44 (IId) and TcWRKY47 (IIa) were upregulated, whereas TcWRKY8 (IIc), TcWRKY20 (III), TcWRKY26 (I), TcWRKY41 (IIe), and TcWRKY52 (IIb) were downregulated by SA treatment. Overexpression experiments showed that the six selected TcWRKYs exerted different effects on taxol biosynthesis. In specific, TcWRKY8 and TcWRKY47 significantly improved the expression levels of taxol-biosynthesis-related genes. Transcriptome-wide identification of WRKY factors in Taxus not only enhances our understanding of plant WRKY factors but also identifies candidate regulators of taxol biosynthesis.

Project description:The multitherapeutic taxol, which can be obtained from Taxus spp., is the most widely used anticancer drug. Taxol biosynthesis is significantly regulated by jasmonate acid (JA), one of the most important endogenous hormones in land plants. Nevertheless, the JA-inducing mechanism remains poorly understood. MYC2 is one of the key regulators of JA signal transfer and the biosynthesis of various secondary metabolites. Here, TcMYC2a was identified to contain a basic helix-loop-helix (bHLH)-leucine zipper domain, a bHLH-MYC_N domain, and a BIF/ACT-like domain. TcMYC2a was also found to bind with TcJAZ3 in yeast, which was a homolog of Arabidopsis JASMONATE ZIM-domain JAZ proteins, indicating that TcMYC2a had a similar function to AtMYC2 of JA signal transduction. TcMYC2a was able to affect the expression of GUS reporter gene by binding with the T/G-box, G-box, and E-box, which were the key cis-elements of TASY and TcERF12/15 promoter. TcMYC2a overexpression also led to significantly increased expression of TASY, tat, dbtnbt, t13h, and t5h genes. Additionally, TcERF15, which played the positive role to regulate tasy gene, was up-regulated by TcMYC2a. All these results revealed that TcMYC2a can regulate taxol biosynthesis either directly or via ERF regulators depending on JA signaling transduction.

Project description:The last few steps in the biosynthesis of the anticancer drug Taxol in yew (Taxus) species are thought to involve the attachment of beta-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)-beta-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.

Project description:BACKGROUND:Taxol is an efficient anticancer drug; however, the accumulation of taxoids can vary hugely among Taxus species. The mechanism underlying differential accumulation of taxoids is largely unknown. Thus, comparative analysis of the transcriptomes in three Taxus species, including T. media, T. mairei and T. cuspidata, was performed. RESULTS:KEGG enrichment analysis revealed that the diterpenoid biosynthesis and cytochrome P450 pathways were significantly enriched in different comparisons. Differential expressions of these taxol biosynthesis related genes might be a potential explanation for the interspecific differential accumulation of taxol and its derivatives. Besides, the sequences of several MEP pathway-associated genes, such as DXS, DXR, MCT, CMK, MDS, HDS, HDR, IPPI, and GGPPS, were re-assembled based on independent transcriptomes from the three Taxus species. Phylogenetic analysis of these MEP pathway-associated enzymes also showed a high sequence similarity between T. media and T. cuspidata. Moreover, 48 JA-related transcription factor (TF) genes, including 10 MYBs, 5 ERFs, 4 RAPs, 3 VTCs, and 26 other TFs, were analyzed. Differential expression of these JA-related TF genes suggested distinct responses to exogenous JA applications in the three Taxus species. CONCLUSIONS:Our results provide insights into the expression pattern and sequence similarity of several taxol biosynthesis-related genes in three Taxus species. The data give us an opportunity to reveal the mechanism underlying the variations in the taxoid contents and to select the highest-yielding Taxus species.