4-Deoxyaurone Formation in Bidens ferulifolia (Jacq.) DC

Silvija Miosic,Ulrich S Schubert,Jürgen Greiner,Binita Kumari Shrestha,Dirk Hölscher,Christian Gosch,Bernd Schneider,Karl Stich,Katrin Knop,Marco Kai,Aleš Svatoš,Anna C Crecelius,Jana Thill,Heidi Halbwirth

doi:10.1371/journal.pone.0061766

Silvija Miosic, Ulrich S Schubert + Show 12 more

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https://doi.org/10.1371/journal.pone.0061766

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Abstract

The formation of 4-deoxyaurones, which serve as UV nectar guides in Bidens ferulifolia (Jacq.) DC., was established by combination of UV photography, mass spectrometry, and biochemical assays and the key step in aurone formation was studied. The yellow flowering ornamental plant accumulates deoxy type anthochlor pigments (6′-deoxychalcones and the corresponding 4-deoxyaurones) in the basal part of the flower surface whilst the apex contains only yellow carotenoids. For UV sensitive pollinating insects, this appears as a bicoloured floral pattern which can be visualized in situ by specific ammonia staining of the anthochlor pigments. The petal back side, in contrast, shows a faintly UV absorbing centre and UV absorbing rays along the otherwise UV reflecting petal apex. Matrix-free UV laser desorption/ionisation mass spectrometric imaging (LDI-MSI) indicated the presence of 9 anthochlors in the UV absorbing areas. The prevalent pigments were derivatives of okanin and maritimetin. Enzyme preparations from flowers, leaves, stems and roots of B. ferulifolia and from plants, which do not accumulate aurones e.g. Arabidopsis thaliana, were able to convert chalcones to aurones. Thus, aurone formation could be catalyzed by a widespread enzyme and seems to depend mainly on a specific biochemical background, which favours the formation of aurones at the expense of flavonoids. In contrast to 4-hydroxyaurone formation, hydroxylation and oxidative cyclization to the 4-deoxyaurones does not occur in one single step but is catalyzed by two separate enzymes, chalcone 3-hydroxylase and aurone synthase (catechol oxidase reaction). Aurone formation shows an optimum at pH 7.5 or above, which is another striking contrast to 4-hydroxyaurone formation in Antirrhinum majus L. This is the first example of a plant catechol oxidase type enzyme being involved in the flavonoid pathway and in an anabolic reaction in general.

Highlights

Flower colour is a result of the evolutionary development from undirected pollination by wind to directed pollination by a specific vector [1,2,3,4]
Using a combined approach of mass spectrometry, biochemical assays, and UV photography, we investigated for the first time the formation of 4-deoxyaurones in Bidens ferulifolia (Jacq.) DC
Anthochlors and flavonoids in Bidens ferulifolia petals The presence of anthochlor pigments and flavonoids in the Bidens petals was analysed by a combined approach of matrix-free UV laser desorption/ionisation mass spectrometric imaging (LDIMSI), liquid chromatography-mass spectrometry (LC-MS) and high-performance liquid chromatography (HPLC) with emphasis on identifying the chalcone and aurone core structures

Summary

Introduction

Flower colour is a result of the evolutionary development from undirected pollination by wind to directed pollination by a specific vector [1,2,3,4]. Yellow coloration appeared as an adaptation to the colour sense of insects as the prevalent pollinators in temperate zones [2]. In Bidens sp., the carotenoids are uniformly distributed across the petal whereas the anthochlors are concentrated at the petal base [5,6]. Such patterns are known as nectar guides (synonym: honey guides, pollen guides) [7]. The flowers are monochromatically yellow; for ultraviolet (UV) sensitive insects the flowers appear bicoloured because of the different UV absorbance of carotenoids and anthochlors [1,8]. Bidens ferulifolia is an interesting model plant for studying both nectar guide formation and anthochlor biosynthesis, which is not completely understood so far [9]

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