Browsing by Subject "Coronatine"
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- PublicationRestrictedA rational approach to improving the biotechnological production of taxanes in plant cell cultures of Taxus spp.(Elsevier, 2014-03-27) Cusido, Rosa M.; Onrubia, Miriam; Sabater Jara, Ana Belén; Moyano, Elisabeth; Bonfill, Mercedes; Goossens, Alain; Palazón, Javier; Pedreño García, María Ángeles; Sabater Jara, Ana Belén; Biología VegetalTaxol 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. Several rational approaches have focused on studying the transcriptomic profiles of key genes in the taxol biosynthetic pathway in Taxus spp. cell cultures treated with elicitors such as methyl jasmonate, coronatine and cyclodextrins in relation with the taxane pattern, production and excretion to the culture medium. These studies have provided new insights into the taxol biosynthetic pathway and its regulation. Additionally, identifying genes with low levels of expression even in the presence of elicitors, together with metabolomics studies, has shed light on the limiting steps in taxol biosynthesis and could help define suitable metabolic targets for engineering with the main aim of obtaining highly productive Taxus cultured cells. In this review, we have summarized the latest endeavors to enhance the molecular understanding of the action mechanism of elicitors in Taxus spp. cell cultures. Developments in the ongoing search for new and more effective elicitation treatments and the application of metabolic engineering to design new transgenic cell lines of Taxus with an improved capacity for taxane production are described.
- PublicationRestrictedEnhanced bioactive compound production in broccoli cells due to coronatine and methyl jasmonate is linked to antioxidative metabolism(Elsevier, 2020-02-22) Sánchez-Pujante, Pedro Joaquín; Gionfriddo, Matteo; Díaz-Vivancos, Pedro; Almagro Romero, Lorena; Pedreño García, María Ángeles; Sabater Jara, Ana Belén; Biología VegetalElicited broccoli suspension-cultured cells (SCC) provide a useful system for obtaining bioactive compounds, including glucosinolates (GS) and phenolic compounds (PCs). In this work, coronatine (Cor) and methyl jas monate (MJ) were used to increase the bioactive compound production in broccoli SCC. Although the use of Cor and MJ in secondary metabolite production has already been described, information concerning how elicitors affect cell metabolism is scarce. It has been suggested that Cor and MJ trigger defence reactions affecting the antioxidative metabolism. In the current study, the concentration of 0.5 μM Cor was the most effective treatment for increasing both the total antioxidant capacity (measured as ferulic acid equivalents) and glucosinolate content in broccoli SCC. The elicited broccoli SCC also showed higher polyphenol oxidase activity than the control cells. Elicitation altered the antioxidative metabolism of broccoli SCC, which displayed biochemical changes in antioxidant enzymes, a decrease in the glutathione redox state and an increase in lipid peroxidation levels. Furthermore, we studied the effect of elicitation on the protein profile and observed an induction of defence-related proteins. All of these findings suggest that elicitation not only increases bioactive compound production, but it also leads to mild oxidative stress in broccoli SCC that could be an important factor triggering the production of these compounds.
- PublicationOpen AccessImproved biotechnological production of paclitaxel in Taxus media cell cultures by the combined action of coronatine and calix[8]arenes(Elsevier, 2021-06) Escrich, Ainoa; Moyano, Elisabeth; Cusido, Rosa M.; Bonfill, Mercedes; Hosseini, Bahman; Palazón, Javier; Almagro Romero, Lorena; Biología VegetalPaclitaxel (PTX), a widely used anticancer agent, is found in the inner bark of several Taxus species, although at such low levels that its extraction is ecologically unsustainable. Biotechnological platforms based on Taxus sp. cell cultures offer an eco-friendlier approach to PTX production, with yields that can be improved by elicitation. However, the also limited excretion of target compounds from the producer cells to the medium hampers their extraction and purification. In this context, we studied the effect of treating T. media cell cultures with the elicitor coronatine (COR) and calix[8]arenes (CAL), nanoparticles that can host lipophilic compounds within their macrocyclic scaffold. The highest taxane production (103.5 mg.L−1), achieved after treatment with COR (1 μM) and CAL (10 mg.L−1), was 15-fold greater than in the control, and PTX represented 82% of the total taxanes analyzed. Expression levels of the flux-limiting PTX biosynthetic genes, BAPT and DBTNBT, increased after the addition of COR, confirming its elicitor action, but not CAL. The CAL treatment significantly enhanced taxane excretion, especially when production levels were increased by COR; 98% of the total taxanes were found in the culture medium after COR + CAL treatment. By forming complexes with PTX, the nanoparticles facilitated its excretion to the medium, and by protecting cells from PTX toxicity, its intra-and extra-cellular degradation may have been avoided. The addition of COR and CAL to T. media cell cultures is therefore a bio-sustainable and economically viable system to improve the yield of this important anticancer compound.
- PublicationEmbargoIncreased glucosinolate production in Brassica oleracea var. italica cell cultures due to coronatine activated genes involved in glucosinolate biosynthesis(American Chemical Society, 2018-12-19) Sánchez Pujante, P.J.; Almagro Romero, Lorena; Belchí Navarro, Sarai; Pedreño García, María Ángeles; Sabater Jara, Ana Belén; Biología VegetalIn this work, the effect of different elicitors and culture conditions on the production of glucosinolates in broccoli cell cultures was studied. The results showed that 0.5 μM coronatine was the best elicitor for increasing glucosinolate production (205-fold increase over untreated cells after 72 h of treatment). Furthermore, the expression levels of some genes related to the biosynthetic pathway of glucosinolates as well as three Myb transcription factors also have been studied. The highest glucosinolate levels found in coronatine-treated cells were closely correlated with the highest gene expression levels of Cyp79b2, Cyp83b1, St5a, Myb51, and Myb122 after 6 h of treatment. The data shown in this study provide new insight into the key metabolic steps involved in the biosynthesis of glucosinolates, which will be of use for future applications of metabolic engineering techniques in broccoli.