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W2897782255 endingPage "67" @default.
W2897782255 startingPage "55" @default.
W2897782255 abstract "Taxol is a blockbuster anticancer drug that commercially synthesized from 10-decaetylbaccatin III intermediate of Taxus baccata, however, this technology has been challenged by reproducibility and association of unwanted compounds. Recently, endophytic fungi with fast growing and feasibility of molecular engineering raise the hope for sustainable production of Taxol, unfortunately the loss of their productivity with multiple subculturing is the main challenge to authenticate this approach industrially. Thus, searching for novel fungal isolates with molecular and metabolic functional stability for Taxol production was the objective of this work. Among the experimented fungal isolates, Aspergillus flavipes, a soil-dwelling saprophyte, gave the highest Taxol yield (185 μg/l). Metabolically, A. flavipes had a strong stability for Taxol production till the 10th subcultures (185-160 μg/l) on the same cultural conditions. The yield of Taxol by A. flavipes was increased by 5 folds (850 μg/ L) with fluconazole (1.0 μg/ml) addition to 5 days old culture. The expression of Taxol biosynthetic genes ts, dbat, bapt and transcriptional factor pbcR was significantly increased by 8–10 folds upon fluconazole addition that correlates with Taxol yield. HSP70 was induced by 13 folds with addition of fluconazole to cultures of A. flavipes. Thus, Taxol biosynthesis could be transcriptionally regulated by pbcR and post-translationally modified by HSP70 chaperones. To the best of knowledge, this is the first report exploring the potency of saprophytic A. flavipes for Taxol production with metabolic stability with multiple subculturing." @default.
W2897782255 created "2018-10-26" @default.
W2897782255 creator A5021105458 @default.
W2897782255 creator A5027976287 @default.
W2897782255 creator A5050040054 @default.
W2897782255 creator A5065519829 @default.
W2897782255 creator A5068395471 @default.
W2897782255 date "2019-01-01" @default.
W2897782255 modified "2023-09-27" @default.
W2897782255 title "Sterol inhibitor “Fluconazole” enhance the Taxol yield and molecular expression of its encoding genes cluster from Aspergillus flavipes" @default.
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W2897782255 doi "https://doi.org/10.1016/j.procbio.2018.10.008" @default.
W2897782255 hasPublicationYear "2019" @default.
W2897782255 type Work @default.
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