Molecular Cloning and Characterization of a Xanthone Prenyltransferase from Hypericum calycinum Cell Cultures

Fiesel, Tobias; Gaid, Mariam; Müller, Andreas; Bartels, Joana; El‐Awaad, Islam; Beuerle, Till; Ernst, Ludger; Behrends, Sönke; Beerhues, Ludger

doi:10.3390/molecules200915616

Cited by 29 publications

(36 citation statements)

References 50 publications

(67 reference statements)

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“…Most recently isolated xanthones are prenylated (60 %), followed by simple (25 %) and glycosylated (11 %) xanthones ( Figure ). Simple xanthones can commonly be prenylated by aromatic‐prenyltransferase enzymes, which are responsible for linking acetate and/or shikimate to the mevalonate pathway and catalyzing the binding of the isoprene unit . This prenylation is quite usual for the Clusiaceae and Hypericaceae Juss .…”

Section: Plant Sourcessupporting

confidence: 56%

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Xanthones and Cancer: from Natural Sources to Mechanisms of Action

Klein‐Júnior

Campos

Niero

et al. 2020

Chemistry & Biodiversity

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Xanthones are a class of heterocyclic natural products that have been widely studied for their pharmacological potential. In fact, they have been serving as scaffolds for the design of derivatives focusing on drug development. One of the main study targets of xanthones is their anticancer activity. Several compounds belonging to this class have already demonstrated cytotoxic and antitumor effects, making it a promising group for further exploration. This review therefore focuses on recently published studies, emphasizing their natural and synthetic sources and describing the main mechanisms of action responsible for the anticancer effect of promising xanthones.

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Section: Plant Sourcessupporting

confidence: 56%

“…Simple xanthones can commonly be prenylated by aromatic-prenyltransferase enzymes, which are responsible for linking acetate and/or shikimate to the mevalonate pathway and catalyzing the binding of the isoprene unit. [14,15] This prenylation is quite usual for the Clusiaceae and Hypericaceae JUSS. families.…”

Section: Plant Sourcesmentioning

confidence: 97%

Xanthones and Cancer: from Natural Sources to Mechanisms of Action

Klein‐Júnior

Campos

Niero

et al. 2020

Chemistry & Biodiversity

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“…Investigation of Hypericum calycinum (Great St. John’s Wort), a source of pharmacologically active specialized metabolites, led to the identification of a membrane-bound aPTase that elaborates xanthone polyketides [17]. This aPTase transfers a 5-carbon dimethylallyl moiety onto 1,2,6,7-tetrahydroxyxanthone to redirect polyketide biosynthesis to tailored natural products such as hyperxanthone E (Figure 1), a compound exhibiting anti-inflammatory properties [18].…”

Section: Natural Products Arising From Aromatic Prenyltransferases (Amentioning

confidence: 99%

Harvesting the biosynthetic machineries that cultivate a variety of indispensable plant natural products

Vickery

Clair

Burkart

et al. 2016

Current Opinion in Chemical Biology

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Plants are a sustainable resource for valuable natural chemicals best illustrated by large-scale farming centered on specific products. Here, we review recent discoveries of plant metabolic pathways producing natural products with unconventional biomolecular structures. Prenylation of polyketides by aromatic prenyltransferases (aPTases) ties together two of the major groups of plant specialized chemicals, terpenoids and polyketides, providing a core modification leading to new bioactivities and downstream metabolic processing. Moreover, PTases that biosynthesize Z-terpenoid precursors for small molecules such as lycosantalene have recently been found in the tomato family. Gaps in our understanding of how economically important compounds such as cannabinoids are produced are being identified using next-generation ‘omics’ to rapidly advance biochemical breakthroughs at an unprecedented rate. For instance, olivetolic acid cyclase, a polyketide synthase (PKS) co-factor from Cannabis sativa, directs the proper cyclization of a polyketide intermediate. Elucidations of spatial and temporal arrangements of biosynthetic enzymes into metabolons, such as those used to control the efficient production of natural polymers such as rubber and defensive small molecules such as linamarin and lotaustralin, provide blueprints for engineering streamlined production of plant products.

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“…Subsequent 3 0 -hydroxylation is catalysed by two bifunctional CYP81AA proteins, which in addition convert the resulting 2,3 0 ,4,6-tetrahydroxybenzophenone to either 1,3,5-or 1,3,7-trihydroxyxanthones via alternative regioselective C-O phenol coupling reactions (El-Awaad et al, 2016). The two trihydroxyxanthone products are likely to be the precursors of all plant xanthones El-Seedi et al, 2010;Fiesel et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Exodermis and endodermis are the sites of xanthone biosynthesis in Hypericum perforatum roots

et al. 2017

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Xanthones are specialized metabolites with antimicrobial properties, which accumulate in roots of Hypericum perforatum. This medicinal plant provides widely taken remedies for depressive episodes and skin disorders. Owing to the array of pharmacological activities, xanthone derivatives attract attention for drug design. Little is known about the sites of biosynthesis and accumulation of xanthones in roots. Xanthone biosynthesis is localized at the transcript, protein, and product levels using in situ mRNA hybridization, indirect immunofluorescence detection, and high lateral and mass resolution mass spectrometry imaging (AP-SMALDI-FT-Orbitrap MSI), respectively. The carbon skeleton of xanthones is formed by benzophenone synthase (BPS), for which a cDNA was cloned from root cultures of H. perforatum var. angustifolium. Both the BPS protein and the BPS transcripts are localized to the exodermis and the endodermis of roots. The xanthone compounds as the BPS products are detected in the same tissues. The exodermis and the endodermis, which are the outermost and innermost cell layers of the root cortex, respectively, are not only highly specialized barriers for controlling the passage of water and solutes but also preformed lines of defence against soilborne pathogens and predators.

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Molecular Cloning and Characterization of a Xanthone Prenyltransferase from Hypericum calycinum Cell Cultures

Cited by 29 publications

References 50 publications

Xanthones and Cancer: from Natural Sources to Mechanisms of Action

Xanthones and Cancer: from Natural Sources to Mechanisms of Action

Harvesting the biosynthetic machineries that cultivate a variety of indispensable plant natural products

Exodermis and endodermis are the sites of xanthone biosynthesis in Hypericum perforatum roots

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