Temporal and spatial regulation of anthocyanin biosynthesis provide diverse flower colour intensities and patterning in <Emphasis Type="Italic">Cymbidium</Emphasis> orchid

Main conclusion

This study confirmed pigment profiles in different colour groups, isolated key anthocyanin biosynthetic genes and established a basis to examine the regulation of colour patterning in flowers of Cymbidium orchid. Cymbidium orchid (Cymbidium hybrida) has a range of flower colours, often classified into four colour groups; pink, white, yellow and green. In this study, the biochemical and molecular basis for the different colour types was investigated, and genes involved in flavonoid/anthocyanin synthesis were identified and characterised. Pigment analysis across selected cultivars confirmed cyanidin 3-O-rutinoside and peonidin 3-O-rutinoside as the major anthocyanins detected; the flavonols quercetin and kaempferol rutinoside and robinoside were also present in petal tissue. β-carotene was the major carotenoid in the yellow cultivars, whilst pheophytins were the major chlorophyll pigments in the green cultivars. Anthocyanin pigments were important across all eight cultivars because anthocyanin accumulated in the flower labellum, even if not in the other petals/sepals. Genes encoding the flavonoid biosynthetic pathway enzymes chalcone synthase, flavonol synthase, flavonoid 3′ hydroxylase (F3′H), dihydroflavonol 4-reductase (DFR) and anthocyanidin synthase (ANS) were isolated from petal tissue of a Cymbidium cultivar. Expression of these flavonoid genes was monitored across flower bud development in each cultivar, confirming that DFR and ANS were only expressed in tissues where anthocyanin accumulated. Phylogenetic analysis suggested a cytochrome P450 sequence as that of the Cymbidium F3′H, consistent with the accumulation of di-hydroxylated anthocyanins and flavonols in flower tissue. A separate polyketide synthase, identified as a bibenzyl synthase, was isolated from petal tissue but was not associated with pigment accumulation. Our analyses show the diversity in flower colour of Cymbidium orchid derives not from different individual pigments but from subtle variations in concentration and pattern of pigment accumulation.

     

Molecular characterization of an anthocyanin-related glutathione S-transferase gene in cyclamen

Anthocyanins are a subclass of flavonoids and are a major contributor to flower colors ranging from red to blue and purple. Previous studies in model and ornamental plants indicate a member of the glutathione S-transferase (GST) gene family is involved in vacuolar accumulation of anthocyanins. In order to identify the anthocyanin-related GST in cyclamen, degenerate PCR was performed using total RNA from immature young petals. Four candidates of GSTs (CkmGST1 to CkmGST4) were isolated. Phylogenetic analysis indicated that CkmGST3 was closely related to PhAN9, an anthocyanin-related GST of petunia, and this clade was clustered with other known anthocyanin-related GSTs. Expression analysis at different developmental stages of petals revealed that CkmGST3 was strongly expressed in paler pigmented petals than in fully pigmented petals, in contrast to the constitutive expression of the other three candidates during petal development. This expression pattern of CkmGST3 was correlated with those of other anthocyanin biosynthetic genes such as CkmF3'5'H and CkmDFR2. Molecular complementation of Arabidopsis tt19, a knockout mutant of an anthocyanin-related GST gene, demonstrated that CkmGST3 could complement the anthocyanin-less phenotype of tt19. Transgenic plants that expressed the other three CkmGSTs did not show anthocyanin accumulation. These results indicate CkmGST3 functions in anthocyanin accumulation in cyclamen.     

The expression level of anthocyanidin synthase determines the anthocyanin content of crabapple (<Emphasis Type="Italic">Malus</Emphasis> sp.) petals

In addition to contributing to the coloration of plant organs and their defense against herbivores, the consumption of anthocyanins in the human diet has a number of health benefits. Crabapple (Malus sp.) represents a valuable experimental model system to research the mechanisms and regulation of anthocyanin accumulation, in part due to the often vivid and varied petal and leaf coloration that is exhibited by various cultivars. The enzyme anthocyanidin synthase (ANS) plays a pivotal role in anthocyanin biosynthesis; however, the relationship between ANS expression and petal pigmentation has yet to be established in crabapple. To illuminate the mechanism of anthocyanin accumulation in crabapple petals, we evaluated the expression of two crabapple ANS allelic genes (McANS-1 and McANS-2) and the levels of anthocyanins in petals from cultivars with dark red (‘Royalty’) and white (‘Flame’) petals, as well as another (‘Radiant’) whose petals have an intermediate pink color. We determined that the expression of McANS in the three cultivars correlated with the variation of anthocyanin accumulation during different petal developmental stages. Furthermore, transgenic tobacco plants constitutively overexpressing one of the two McANS genes, McANS-1, had showed elevated anthocyanin accumulation and a deeper red coloration in their petals than those from untransformed control lines. In conclusion, we propose that McANS are responsible for anthocyanin accumulation during petal coloration in different crabapple cultivars.     

Temporal and spatial control of expression of anthocyanin biosynthetic genes in developing flowers of Antirrhinum majus

The co-ordination of expression of anthocyanin biosynthetic genes was studied in developing flowers. Four genes encoding enzymes operating late in the anthocyanin biosynthetic pathway are induced together during flower development but the early steps appear to be induced more rapidly. Co-ordination of expression could imply a common regulatory mechanism controlling the expression of metabolically related genes. The data presented here show that while four genes may share such a mechanism for the control of their expression during flower development, different control processes regulate the early steps of the pathway. Spatially, gene expression is patterned across the flower and appears to be very similar for all the biosynthetic genes. However, the observed influence of the regulatory gene Delila shows that the spatial co-ordination of gene expression must involve more than one regulatory system. Delila itself appears to have a dual function, being required for activation of expression of the later genes in the flower tube but repressing chalcone synthase gene expression in the mesophyll of the corolla lobes. It is postulated that common signals induce the expression of genes in the pathway during flower development. The data presented here suggest that the same regulatory mechanism interprets these signals for four of the genes encoding the later biosynthetic enzymes, but that different or modified mechanisms interpret the signals to control expression of chalcone synthase and chalcone isomerase genes in Antirrhinum flowers.     

Engineering of flower color in forsythia by expression of two independently-transformed dihydroflavonol 4-reductase and anthocyanidin synthase genes of flavonoid pathway

Flower color was modified in forsythia (Forsythia x intermedia cv Spring Glory) by inducing anthocyanin synthesis in petals through sequential Agrobacterium-mediated transformation with dihydroflavonol 4-reductase from Antirrhinum majus (AmDFR) and anthocyanidin synthase from Matthiola incana (MiANS) genes. This is the second report of flower color modification of an ornamental shrub after rose, and the first time an ANS gene is used for this purpose. Double transformants (AmDFR+MiANS) displayed a novel bronze-orange petal color, caused by the de novo accumulation of cyanidin-derived anthocyanins over the carotenoid yellow background of wild type (wt), and intense pigmentation of vegetative organs. Transformation with single genes (either AmDFR or MiANS) produced no change in flower color, showing a multistep control of late anthocyanin pathway in petals of forsythia. Analysis of relevant late flavonoid pathway genes – an endogenous flavonoid glycosyltransferase (FiFGT) and transformed DFR and ANS genes – showed appropriate expression in flower organs. Functional characterization of FiFGT expressed in E. coli revealed its ability to metabolize both flavonols and anthocyanidin substrates, a prerequisite for effective anthocyanin accumulation in petals of plants transformed with constructs leading to anthocyanidin synthesis. Biochemical analyses of flavonoid compounds in petals and leaves showed that, besides anthocyanin induction in petals of double transformants, the accumulation pattern of flavan-3-ols was quantitatively and qualitatively modified in petals and leaves of transformants, in agreement with the most recent model proposed for flavan-3-ol synthesis. On the other hand, phenylpropanoid, flavone and flavonol pools were not quantitatively affected, indicating a tight regulation of early flavonoid pathway.     

Arctic mustard flower color polymorphism controlled by petal-specific downregulation at the threshold of the anthocyanin biosynthetic pathway

Intra- and interspecific variation in flower color is a hallmark of angiosperm diversity. The evolutionary forces underlying the variety of flower colors can be nearly as diverse as the colors themselves. In addition to pollinator preferences, non-pollinator agents of selection can have a major influence on the evolution of flower color polymorphisms, especially when the pigments in question are also expressed in vegetative tissues. In such cases, identifying the target(s) of selection starts with determining the biochemical and molecular basis for the flower color variation and examining any pleiotropic effects manifested in vegetative tissues. Herein, we describe a widespread purple-white flower color polymorphism in the mustard Parrya nudicaulis spanning Alaska. The frequency of white-flowered individuals increases with increasing growing-season temperature, consistent with the role of anthocyanin pigments in stress tolerance. White petals fail to produce the stress responsive flavonoid intermediates in the anthocyanin biosynthetic pathway (ABP), suggesting an early pathway blockage. Petal cDNA sequences did not reveal blockages in any of the eight enzyme-coding genes in white-flowered individuals, nor any color differentiating SNPs. A qRT-PCR analysis of white petals identified a 24-fold reduction in chalcone synthase (CHS) at the threshold of the ABP, but no change in CHS expression in leaves and sepals. This arctic species has avoided the deleterious effects associated with the loss of flavonoid intermediates in vegetative tissues by decoupling CHS expression in petals and leaves, yet the correlation of flower color and climate suggests that the loss of flavonoids in the petals alone may affect the tolerance of white-flowered individuals to colder environments.     

Isolation and characterization of the fragrant cyclamen O-methyltransferase involved in flower coloration

Anthocyanin O-methyltransferase (OMT) is one of the key enzymes for anthocyanin modification and flower pigmentation. We previously bred a novel red-purple-flowered fragrant cyclamen (KMrp) from the purple-flowered fragrant cyclamen 'Kaori-no-mai' (KM) by ion-beam irradiation. Since the major anthocyanins in KMrp and KM petals were delphinidin 3,5-diglucoside and malvidin 3,5-diglucoside, respectively, inactivation of a methylation step in the anthocyanin biosynthetic pathway was indicated in KMrp. We isolated and compared OMT genes expressed in KM and KMrp petals. RT-PCR analysis revealed that CkmOMT2 was expressed in the petals of KM but not in KMrp. Three additional CkmOMTs with identical sequences were expressed in petals of both KM and KMrp. Genomic PCR analysis revealed that CkmOMT2 was not amplified from the KMrp genome, indicating that ion-beam irradiation caused a loss of the entire CkmOMT2 region in KMrp. In vitro enzyme assay demonstrated that CkmOMT2 catalyzes the 3' or 3',5' O-methylation of the B-ring of anthocyanin substrates. These results suggest that CkmOMT2 is functional for anthocyanin methylation, and defective expression of CkmOMT2 is responsible for changes in anthocyanin composition and flower coloration in KMrp.