Acylated anthocyanins and flavonols from purple flowers of Dendrobium cv. ‘Pompadour’

Two rare anthocyanins, cyanidin 3-(6-malonylglucoside)-7,3′-di(6-sinapylglucoside) and the demalonyl derivative, were characterised as the purple floral pigments of Dendrobium cv. ‘Pompadour’. Nine known flavonol glycosides were also identified, including the 3-rutinoside-7-glucosides of kaempferol and quercetin. One new glycoside was detected: the ferulyl ester of quercetin 7-rutinoside-7-glucoside. These flavonoid patterns are typical for plants in the family Orchidaceae.     

Anthocyanins of grasses

The anthocyanin content of 23 grass species (Poaceae) belonging to five subfamilies has been determined. Altogether 11 anthocyanins were identified; the 3-(6″-malonylglucosides) and 3-glucosides of cyanidin, peonidin and delphinidin, the 3-(3″,6″-dimalonylglucoside), 3-(6″-rhamnosylglucoside) and 3-(6″-glucosylglucoside) of cyanidin, in addition to peonidin 3-(dimalonylglucoside) and delphinidin 3-(6″-rhamnosylglucoside). Anthocyanins acylated with one and/or two malonic acid moieties dominated the anthocyanin profiles of all the species in the subfamilies Pooideae and Panicoideae. On the other hand, the 3-glucoside and 3-rutinoside of cyanidin were the major anthocyanins in Sinarundinaria murielae (subfamily Bambusoideae) and Molinia caerulea (subfamily Arundinoideae), while the 3-glucosides of cyanidin and peonidin were the principal anthocyanins in rice, Oryza sativum (subfamily Oryzoideae). Pelargonidin derivatives and free anthocyanidins have previously been reported to occur in several Poaceae species, however, not identified in any of the species included in this survey.     

A rationale for the shift in colour towards blue in transgenic carnation flowers expressing the flavonoid 3',5'-hydroxylase gene

Recently marketed genetically modified violet carnations cv. Moondust and Moonshadow (Dianthus caryophyllus) produce a delphinidin type anthocyanin that native carnations cannot produce and this was achieved by heterologous flavonoid 3',5'-hydroxylase gene expression. Since wild type carnations lack a flavonoid 3',5'-hydroxylase gene, they cannot produce delphinidin, and instead accumulate pelargonidin or cyanidin type anthocyanins, such as pelargonidin or cyanidin 3,5-diglucoside-6"-O-4, 6"'-O-1-cyclic-malyl diester. On the other hand, the anthocyanins in the transgenic flowers were revealed to be delphinidin 3,5-diglucoside-6"-O-4, 6"'-O-1-cyclic-malyl diester (main pigment), delphinidin 3,5-diglucoside-6"-malyl ester, and delphinidin 3,5-diglucoside-6",6"'- dimalyl ester. These are delphinidin derivatives analogous to the natural carnation anthocyanins. This observation indicates that carnation anthocyanin biosynthetic enzymes are versatile enough to modify delphinidin. Additionally, the petals contained flavonol and flavone glycosides. Three of them were identified by spectroscopic methods to be kaempferol 3-(6"'-rhamnosyl-2"'-glucosyl-glucoside), kaempferol 3-(6"'-rhamnosyl-2"'-(6-malyl-glucosyl)-glucoside), and apigenin 6-C-glucosyl-7-O-glucoside-6"'-malyl ester. Among these flavonoids, the apigenin derivative exhibited the strongest co-pigment effect. When two equivalents of the apigenin derivative were added to 1 mM of the main pigment (delphinidin 3,5-diglucoside-6"-O-4,6"'-O-1-cyclic-malyl diester) dissolved in pH 5.0 buffer solution, the lambda(max) shifted to a wavelength 28 nm longer. The vacuolar pH of the Moonshadow flower was estimated to be around 5.5 by measuring the pH of petal. We conclude that the following reasons account for the bluish hue of the transgenic carnation flowers: (1). accumulation of the delphinidin type anthocyanins as a result of flavonoid 3',5'-hydroxylase gene expression, (2). the presence of the flavone derivative strong co-pigment, and (3). an estimated relatively high vacuolar pH of 5.5.     

A chemotaxonomic study of flavonoids in the leaves of six Trichosanthes species

The 7-, 3′- and 4′-glucosides of luteolin, the 7-glucoside and 6,8-di-C-glucoside of apigenin were isolated from Trichosanthes kirilowii var. japonica. Kaempferol 3,7-di-rhamnoside and 3-glucoside-7-rhamnoside were identified from T. cucumeroides, kaempferol 3-galactoside and 3-sophoroside were also identified from T. anguina. Quercetin-3-rutinoside was detected from T. multiloba and T. rostrata. T. bracteata afforded luteolin 3′-glucoside and kaempferol 3-rutinoside, and T. kirilowii afforded luteolin 7-, 3′- and 4′-glucosides and apigenin 7-glucoside.     

Anthocyanin content of Tulipa species and cultivars and its impact on tepal colours

Flowers of tulips (17 species and 25 cultivars) were subjected to qualitative and relative quantitative examination for anthocyanins. Altogether five anthocyanins were identified as the 3-O-(6″-O-α-rhamnopyranosyl-β-glucopyranoside) of delphinidin (1), cyanidin (2) and pelargonidin (3), and the 3-O-[6″-O-(2‴-O-acetyl-α-rhamnopyranosyl)-β-glucopyranoside] of cyanidin (4) and pelargonidin (5). The pigments 1–5 represented 7%, 43%, 12%, 2% and 31%, respectively, of the total anthocyanin amount in the tepals of the Tulipa species, and 20%, 37%, 30%, 6% and 4%, respectively, in the cultivar tepals. Nearly 50% of the samples contained acetylated anthocyanins. The colours of the freeze-dried tepals described by the CIELab coordinates, hue angle (h_ab), saturation (C*), and lightness (L*) together with the anthocyanin content were subjected to multivariate analysis. All tepals classified with hue angles described as “blue nuances” were from cultivars. They contained 1 as the major anthocyanin, and no or just traces of pelargonidin derivatives. The species and cultivars having “magenta nuances” showed similar anthocyanin content with increased relative proportions of 2 at the expense of 1. Orange coloured tepals were to a large extent correlated with high relative proportions of the pelargonidin derivatives, 3 and 5. Acetylation of anthocyanins furnished a weak colour effect opposite to the bluing effect previously reported for anthocyanins with aromatic acyl groups. All six species belonging to the section Eichleres (subgenus Tulipa) were after principal component analysis grouped closely together. They were characterized by high concentrations of the pelargonidin derivatives 3 and 5, and orange petal nuances. However, within section Tulipa (subgenus Tulipa), considerable anthocyanin variation was observed. Species in the subgenus Eriostemones were generally characterized by the two anthocyanins 1 and 2, and no pelargonidin derivatives.     

The identification of flavonoids and the expression of genes of anthocyanin biosynthesis in the chrysanthemum flowers

In order to provide additional information on the coloration of chrysanthemum flowers, the flavonoid composition and the expression of six structural genes involved in anthocyanin pathway in the ray florets of a pink flowering (cv. H5) and two white flowering (cvs. Keikai and Jinba) Chrysanthemum grandiflorum cultivars were examined. HPLCDAD/ESI-MSⁿ analysis showed that cyanidin 3-O-(6″-O-malonylglucoside) and cyanidin 3-O-(3″,6″-O-dimalonylglucoside) were the two major flavonoids presented in H5, while white flowering cultivars contained flavones instead of anthocyanins. Nine flavone derivatives were detected in the three cultivars, the amount of each flavone varied upon cultivars, and seven of these were identified as luteolin 7-O-arabinosylglucuronide, apigenin 7-O-glucoside, luteolin 7-O-malonylglucoside, apigenin 7-O-malonylglucoside, chrysoeriol 7-O-malonylglucoside, acacetin 7-O-rutinoside and acacetin 7-O-malonylglucoside. The two white flowering cultivars showed similar total flavonoid content, which was about two fold higher than that in H5. A high expression of the genes encoding dihydroflavonol 4-reductase and 3-O-glucosyltransferase was detected only in H5 but not in Keikai or Jinba. Chalcone synthase, chalcone isomerase, flavanone 3-hydroxylase, and flavonoid 3′-hydroxylase were expressed in all flowers, suggesting that the lack of anthocyanin in white flowering cultivars cannot be due to any blockage of their expression.     

Isolation and structural determination of 13 flavonoid glycosides in Hibiscus esculentus (okra)

Eleven flavonol glycosides and two anthocyanins, only one of which was previously identified, were isolated from the flower petals of okra, Hibiscus esculentus L. On the basis of chromatographic, spectral, and degradative evidence, the following structural assignments were made: quercetin 4′-glucoside, quercetin 7-glucoside, quercetin 5-glucoside, quercetin 3-diglucoside, quercetin 4′-diglucoside, quercetin 3-triglucoside, quercetin 5-rhamnoglucoside, gossypetin 8-glucoside, gossypetin 8-rhamnoglucoside, gossypetin 3-glucosido-8-rhamnoglucoside, cyanidin 4′-glucoside, and cyanidin 3-glucosido-4′ glucoside. Some evidence was obtained of a pentahy-droxy, monomethoxy-flavone glycoside. The total flavonoid content in the red portion of the petal was 0.48% of fresh weight; that in the white portion was 2.51%. The two anthocyanins comprised 28.5% of the flavonoid content of the red flower but only a trace of the content of the white.     

Anthocyanins in flowers of genus Rosa, sections Cinnamomeae (=Rosa), Chinenses, Gallicanae and some modern garden roses

Forty-four taxa of three sections (Cinnamomeae (=Rosa) 26, Chinenses 8 and Gallicanae 10) and eight modern garden roses in the genus Rosa were surveyed for their floral anthocyanins. Eleven anthocyanins: 3-glucosides and 3,5-diglucosides of cyanidin (Cy), pelargonidin (Pg) and peonidin (Pn), 3-rutinosides and 3-rho-coumaroylglucoside-5-glucosides of Cy and Pn, and Cy 3-sophoroside, were isolated from flowers of these taxa and identified by chemical and spectroscopic techniques. Four anthocyanins: Cy 3-rutinoside, Pn 3-rutinoside, Pn 3-rho-coumaroylglucoside-5-glucoside and Cy 3-sophoroside were found for the first time in Rosa flowers.Investigated sections of wild roses showed characteristic distribution of anthocyanins. Cy 3,5-diglucoside was the dominant anthocyanin detected in all three sections, but accumulation of Pn 3,5-diglucoside distinguished sections Cinnamomeae from other sections, and the occurrence of Cy 3-glucoside separates section Chinenses from others.Cy 3-sophoroside was detected in large amount in some taxa of section Cinnamomeae: e.g., R. moyesii and its related cultivars, and R. rugosa cv. Salmon Pink. The acylated Cy glycoside was found in all sections and also in some modern garden roses, while the acylated Pn glycoside was detected in the section Cinnamomeae, but not in sections Chinenses and Gallicanae. According to anthocyanin distribution patterns, eight groups were classified chemotaxonomically in genus Rosa.     

Anthocyanins with 4'-glucosidation from red onion, Allium cepa

The anthocyanins, cyanidin 3-O-(3"-O-beta-glucopyranosyl-6"-O-malonyl-beta-glucopyranoside)-4'-O-beta-glucopyranoside, cyanidin 7-O-(3"-O-beta-glucopyranosyl-6"-O-malonyl-beta-glucopyranoside)-4'-O-beta-glucopyranoside, cyanidin 3,4'-di-O-beta-glucopyranoside, cyanidin 4'-O-beta-glucoside, peonidin 3-O-(6"-O-malonyl-beta-glucopyranoside)-5-O-beta-glucopyranoside and peonidin 3-O-(6"-O-malonyl-beta-glucopyranoside) have been isolated in minor amounts from pigmented scales of red onion, Allium cepa, in addition to six known anthocyanins. The structures were established mainly by extensive use of 2D NMR spectroscopy and electrospray LC-MS. With exception of cyanidin 4'-glucoside and cyanidin 3,4'-diglucoside reported from Hibiscus esculentus with inadequate documentation, this is the first identification of anthocyanins with 4'-glycosidation. Compared to cyanidin 3-glycosides the cyanidin 4'-glucoside derivatives showed hypsochromic shifts of visible lambda(max) and hyperchromic effects on wavelengths around 440 nm, similar to pelargonidin 3-glycosides.     

Acylated anthocyanins in inflorescence of spider flower (Cleome hassleriana)

Five anthocyanins, cyanidin 3-(2′′-(6′′′-caffeoyl-β-glucopyranosyl)-6′′-(E-p-coumaroyl)-β-glucopyranoside)-5-β-glucopyranoside, cyanidin 3-(2′′-(6′′′-E-sinapoyl-β-glucopyranosyl)-6′′-(E-p-coumaroyl)-β-glucopyranoside)-5-β-glucopyranoside, cyanidin 3-(2′′-(6′′′-feroyl-β-glucopyranosyl)-6′′-(E-p-coumaroyl)-β-glucopyranoside)-5-β-glucopyranoside, pelargonidin 3-(2′′-(6′′′-E-sinapoyl-β-glucopyranosyl)-6′′-(E-p-coumaroyl)-β-glucopyranoside)-5-β-glucopyranoside, and pelargonidin 3-(2′′-(6′′′-E-p-coumaroyl-β-glucopyranosyl)-6′′-(E-p-coumaroyl)-β-glucopyranoside)-5-β-glucopyranoside, together with five known anthocyanins have been identified in flowers of Cleome hassleriana Queen line. One monoacylated and four diacylated cyanidin 3-sophoroside-5-glucosides were identified as the main anthocyanins in flowers with mauve colouration, while a homologous glycosidic pattern based on pelargonidin was found in the five main anthocyanins from flowers with pink colouration. The anthocyanins identified in C. hassleriana share the same glycosidic pattern as anthocyanins isolated from the genera Raphanus, Brassica and Iberis in the sister family Brassicaceae.     

Apigenin and amentoflavone glycosides in the psilotaceae and their phylogenetic significance

Documentation of amentoflavone O-glucosides as the predominant flavonoid glycosides in both genera of the Psilotaceae clearly distinguishes this family from all other families of vascular plants. Psilotum and Tmesipteris also possess apigenin C- and O-glycosides as common flavonoid types. Apigenin 7-O-rhamnoglucoside occurs in both genera and the previously undocumented apigenin 7-O-rhamnoglucoside-4′-O-glucoside, although identified only in Tmesipteris, may also be present in Psilotum. The existence of flavone C-glycosides in both genera may provide a phytochemical relationship between the Psilotaceae and some ferns. The phylogenetic significance of these results is discussed.     

Anthocyanins in the epacridaceae

An examination of 73 species of the family Epacridaceae resulted in the identification of the following anthocyanins: cyanidin 3-galactoside, cyanidin 3-glucoside, cyanidin 3-arabinoside, cyanidin 3-rhamnoside, cyanidin 3-rhamnosylgalactoside, cyanidin 3-rhamnosylglucoside, cyanidin 3-xylosylgalactoside, cyanidin 3-xylosylarabinoside, delphinidin 3-galactoside, delphinidin 3-arabinoside, delphinidin 3-rhamnosylgalactoside, delphinidin 3-rhamnosylglucoside and pelargonidin 3-rhamnosylglucoside. No acylated or 5-substituted anthocyanins were detected in any of the species examined. Evidence of methylated anthocyanidin was found only in one species, Woollsia pungens. The occurrence of cyanidin 3-galactoside and cyanidin 3-arabinoside forms a chemical link between this family and the related Ericaceae.     

Pleiotropic effect of a pelargonidin-hydroxylation gene in Silene dioica?

In petals of Silene dioica a gene P has been identified, which controls the 3′-hydroxylation of the B-ring of pelargonidin to cyanidin. Another gene Ac controls the acylation of the terminal sugar at the 3-position of anthocyanin 3-rhamnosylglucoside-5-glucosides. In p/p plants the bound acyl group is p-coumaric acid; in P/P plants, however, it is caffeic acid. Gene P seems to exert a pleiotropic effect: it not only controls the hydroxylation of the B-ring of pelargonidin but also that of the acyl group.     

1H NMR spectral analysis of the malylated anthocyanins from Dianthus

The structures of malylated anthocyanins from carnation Dianthus caryophyllus flowers were confirmed as the 3-O-(6-O-malyl-β-D-glucopyranosides) of pelargonidin and cyanidin by 400 MHz FT-NMR.     

Anthocyanins in fruits of Vaccinium Japonicum

Cyanidin-3-arabinoside (54%) and pelargonidin-3-arabinoside (39%) were the main anthocyanins isolated from berries of Vaccinium japonicum. In addition smaller amounts of 3-galactosides of cyanidin (5%) and pelargonidin (2%) were found. The total anthocyanin content in the fruit averaged 113 mg/100 g fresh fruit. This is the first report of pelargonidin derivatives in the genus Vaccinium.     

Identification and distribution of malonated anthocyanins in plants of the compositae

A survey of 31 species from 28 genera in the Compositae showed the presence of zwitterionic anthocyanins in petals or stems of 27 species. Detailed investigations, including the use of FAB-MS, showed that mono- and dimalonated esters of pelargonin and cyanin occurred in Dahlia variabilis cultivars. The corresponding delphin mono- and dimalonates occur in blue flowers Cichorium intybus. A cyanidin 3-dimalonylglucoside was identified in stems of Coleostephus myconis while pelargonidin 3-(6″-malonylg]ucoside) was found in Callistephus petals. A further malonated cyanidin derivative in flowers of Helenium cv. Bruno was found to be the 3-glucuronosylglucoside; this is the first report of an anthocyanin with glucuronic acid. Overall, the results confirm that malonated anthocyanins are widespread in the family and that many pigments previously reported in the Compositae as being unacylated probably contain these labile organic acid attachments.     

Chemical taxonomy of the Xibei tree peony from China by floral pigmentation

Petal flavonoid compositions of 39 tree peony cultivars from Xibei (northwest China) were investigated in order to study the chemotaxonomic relationship among tree peony species. Six anthocyanins, the 3-O-glucosides and 3,5-di-O-glucosides of three anthocyanidins—pelargonidin (Pg), cyanidin (Cy), and peonidin (Pn)—exist in petals without a blotch at the base. The flowers are classified into three anthocyanidin phenotypes: Pn, Pg>Cy; Pn, Cy; and Pn, Cy>Pg. Furthermore, the yellow pigments are identified as three flavones and three flavonols: apigenin, luteolin, chrysoeriol, and kaempferol, quercetin, and isorhamnetin, respectively. Wards minimum-variance cluster analysis with principal component analysis produced a dendrogram using standardized scores of 20 pigment variables. Of 39 cultivars, 11 clustered with white flowered Paeonia rockii and 17 with pink flowered P. rockii. The other 11 cultivars matched either P. delavayi or P. potaninii. The result suggests that the Xibei tree peony originated mainly from P. rockii.     

The role of lipophilic and polar flavonoids in the classification of temperate members of the Anthemideae

Lipophilic and vacuolar flavonoids were separately identified in representative temperate species of the genera Anthemis, Chrysanthemum, Cotula, Ismelia, Leucanthemum and Tripleurospermum. The four Anthemis species investigated variously produced four main surface constituents, in leaf and flower: santin, quercetagetin 3,6,3′-trimethyl ether, scutellarein 6,4′-dimethyl ether and 6-hydroxyluteolin 6,3′-dimethyl ether. By contrast, surface extracts of disc and ray florets of the species of Chrysanthemum, Cotula, Ismelia, Leucanthemum and Tripleurospermum surveyed yielded five common flavones in the free state: apigenin, luteolin, acacetin, apigenin 7-methyl ether and chrysoeriol. Polar flavonoids were isolated and identified in leaf, ray floret and disc floret of all the above plants. Anthemis species were distinctive in having flavonol glycosides in the leaves, whereas the leaf flavonoids of the other taxa were generally flavone O-glycosides. The 3-glucoside and 3-rutinoside of patuletin were characterised for the first time from Anthemis tinctoria ssp. subtinctoria. Two new flavonol glycosides, the 5-glucuronides of quercetin and kaempferol, were obtained from the leaf of Leucanthemum vulgare, where they co-occur with the related 5-glucosides and with several flavone glycosides. The ray florets of these Anthemideae generally contain apigenin and/or luteolin 7-glucoside and 7-glucuronide, whereas disc florets have additional flavonol glycosides, notably the 7-glucosides of quercetin and patuletin and the 7-glucuronide of quercetin. A comparison of the flavonoid pattern encountered here with those previously recorded for Tanacetum indicate some chemical affinity between Anthemis and Tanacetum. Flavonoid patterns of the other five genera are more distinct from those of Tanacetum and suggest that those genera form a related group. All 14 species surveyed for their flavonoid profiles have distinctive constituents and the chemical data are in harmony with modern taxonomic treatments of the “Chrysanthemum complex” as a series of separate genera.     

A survey of anthocyanins in fruits of some angiosperms,I

The anthocyanin pigments in the fruits of fifty-two species belonging to seventeen families of angiosperms were investigated paper-chromatographicallly. They were identified as cyanidin 3-monoglucoside, pelargonidin 3-monoglucoside, cyanidin 3-rutinoside, pelargonidin 3-rutinoside, cyanidin 3-xylosylglucoside, cyanidin 3-xylosylgalactoside, delphinidin 3-xylosylglucoside and delphinidin 3-sophorosido-5-monoglucoside. Of those anthocyanins detected, the most common was cyanidin 3-monoglucoside. In general, the plants belonging to a certain genus contained the same anthocyanin.     

The B-ring hydroxylation pattern of intermediates of anthocyanin synthesis in pelargonidin-and cyanidin-producing lines of Matthiola incana

In flowers of Matthiola incana, the B-ring hydroxylation pattern of anthocyanins is controlled by the locus b. Recessive genotypes produce pelargonidin and genotypes with wild-type alleles cyanidin as the aglycone. Supplementation experiments on acyanic flowers using extracts of pelargonidin-and cyanidin-producing flowers, respectively, showed not only the presence of compounds with a precursor function for anthocyanin synthesis in the cyanic flowers but also differences in the B-ring hydroxylation pattern of these compounds. Chromatographic investigations proved that flavanones and dihydroflavonols occur in extracts of cyanic flowers. Naringenin, dihydrokaempferol, and their 7-glucosides could be demonstrated in all flower extracts, but in extracts of cyanidin-producing flowers, dihydroquercetin and a further 3, 4-hydroxylated dihydroflavonol, tentatively identified as dihydroquercetin 3-glycoside, were additionally found. In no case, however, could eriodictyol be detected. From these results and from the ready hydroxylation of dihydrokaempferol to dihydroquercetin in a white mutant line of Matthiola incana, it can be concluded that introduction of the 3-hydroxyl group of anthocyanins is not achieved by specific incorporation of caffeic acid during synthesis of the flavonoid skeleton, but by hydroxylation at the dihydroflavonol stage.