Bioactive diterpenoid metabolism and cytotoxic activities of genetically transformed Euphorbia lathyris roots

Plants in the genus Euphorbia produce a wide variety of pharmacologically active diterpenoids with anticancer, multidrug resistance reversal, and antiviral properties. Some are the primary industrial source of ingenol mebutate, which is approved for treatment of the precancerous skin condition actin...

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Bibliographic Details
Published in:Phytochemistry (Oxford) 2020-11, Vol.179, p.112504-112504, Article 112504
Main Authors: Ricigliano, Vincent A., Sica, Vincent P., Knowles, Sonja L., Diette, Nicole, Howarth, Dianella G., Oberlies, Nicholas H.
Format: Article
Language:English
Subjects:
Agrobacterium
Anticancer
Diterpene
Diterpenes - pharmacology
Euphorbia
Humans
Ingenol
Plant Roots
Specialized metabolism
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Summary:Plants in the genus Euphorbia produce a wide variety of pharmacologically active diterpenoids with anticancer, multidrug resistance reversal, and antiviral properties. Some are the primary industrial source of ingenol mebutate, which is approved for treatment of the precancerous skin condition actinic keratosis. Similar to other high value phytochemicals, Euphorbia diterpenoids accumulate at low concentrations in planta and chemical synthesis produces similarly low yields. We established genetically transformed root cultures of Euphorbia lathryis as a strategy to gain greater access to diterpenoids from this genus. Transformed roots produced via stem explant infection with Agrobacterium rhizogenes strain 15834 recapitulated the metabolite profiles of field-grown plant roots and aerial tissues. Several putative diterpenoids were present in transformed roots, including ingenol and closely related structures, indicating that root cultures are a promising approach to Euphorbia-specific diterpenoid production. Treatment with methyl jasmonate led to a significant, albeit transient increase in mRNA levels of early diterpenoid biosynthetic enzymes (farnesyl pyrophosphate synthase, geranylgeranyl pyrophosphate synthase, and casbene synthase), suggesting that elicitation could prove useful in future pathway characterization and metabolic engineering efforts. We also show the potential of transformed E. lathyris root cultures for natural product drug discovery applications by measuring their cytotoxic activities using a panel of human carcinoma cell lines derived from prostate, cervix, breast, and lung. [Display omitted] •Genetically transformed E. lathryis roots are a sustainable source of the diterpenoid ingenol.•Hairy root cultures can be used to probe Euphorbia-specific diterpenoid metabolism.•Transformed E. lathyris roots have potential for drug discovery applications.
ISSN:0031-9422
1873-3700
DOI:10.1016/j.phytochem.2020.112504