THE DIFFERENTIATION OF PIGMENTATION IN FLOWER PARTS. I. THE FLAVONOID PIGMENTS OF IMPATIENS BALSAMINA,GENOTYPE IIHHPrPr,AND THEIR DISTRIBUTION WITHIN THE PLANT

Chromatographic analysis of stems, sepals and petals of inbred Impatiens balsamina of the red-flowered genotype llHHP^rP^r has revealed a characteristic assemblage of flavonoid pigments in each organ. The more conspicuous compounds have been identified or partially characterized. The stems possess 3-monoglucosides of kaempferol, quercetin, pelargonidin, cyanidin and, presumably, delphinidin. The variety of pigments is less in flower parts than in stems, and less in petals than in sepals, but the flower parts exhibit a greater elaboration of substituents on the aromatic nuclei. The paired petals of mature flowers are pigmented by p-coumaroyl and feruloyl esters of pelargonidin-3, 5-diglucoside supplemented by more highly substituted derivatives of pelargonidin and by large amounts of kaempferol as the aglycone and two glucosides. The distribution of pigments has significance in the biology of the plant as well as providing an approach to studies of factors which control flower differentiation.     

High pressure liquid chromatographic analysis of flavonoid chemical markers in petals from Gerbera flowers as an adjunct for cultivar and germplasm identification

Flavonoids present in petals from Gerbera flowers were resolved and quantitated by high pressure liquid chromatography (HPLC). The anthocyanins isolated from 18 cultivars, ranging in color from orange through lavender, were pelargonidin and cyanidin 3-malonylglucosides accompanied by smaller amounts of pelargonidin and cyanidin 3-glucosides. Related flavonoid copigments were apigenin and luteolin 4′-glucosides and 7-glucosides, apigenin 7-malonylglucoside, kaempferol and quercetin 3-glucosides, 4′-glucosides and 3-malonylglucosides. Both qualitative and quantitative differences in these flavonoid chemical markers distinguished cultivars with very similar colors. Malonyl esters of anthocyanins are easily degraded by HCl and conventional extraction and purification procedures were adjusted to preserve their natural state.     

Variability of flavonol contents during floral morphogenesis in Papaver somniferum L

We studied the contents of flavonols (kaempferol and quercetin) in the meristem of vegetative and generative apices of the main plant shoot in floral Papaver somniferum mutants, as well as in the normal plants at successive stages of flower development. Five stages of flower development were distinguished. Flavonols (kaempferol and quercetin) were present in all flower organs at all stages of floral morphogenesis we studied. However, their contents and distribution in different organs and at different stages of flower development markedly varied. No significant differences were found in the contents of flavonols in the meristems of vegetative and generative apices of the main shoot in the lines of floral mutants, as well as between the lines with different amounts of vegetative phytomeres. In the plants with normal flower structure, the contents of flavonols (kaempferol + quercetin) sharply increased with the beginning of differentiation of flower organs, i.e. from stage 3, to reach a maximum in the open flower, when gametogenesis is terminated and fertilization takes place. The level of flavonol contents in the petals (upper part) and stamen was at a maximum at all stages of flower development, while that in the gynaecium was at a minimum. The kaempferol: quercetin ratio shifted towards quercetin at successive stages of flower development, most significantly in the stamens. The involvement of flavonols in the regulation of floral morphogenesis at stages of flower organs differentiation and functioning is discussed.     

Variability of Flavonol Contents during Floral Morphogenesis in the Poppy Papaver somniferum L.

We studied the contents of flavonols (kaempferol and quercetin) in the meristem of vegetative and generative apices of the main plant shoot in floral Papaver somniferum L. mutants, as well as in the normal plants at successive stages of flower development. Five stages of flower development were distinguished. Flavonols (kaempferol and quercetin) were present in all flower organs at all stages of floral morphogenesis we studied. However, their contents and distribution in different organs and at different stages of flower development markedly varied. No significant differences were found in the contents of flavonols in the meristems of vegetative and generative apices of the main shoot in the lines of floral mutants, as well as between the lines with different amounts of vegetative phytomeres. In the plants with normal flower structure, the contents of flavonols (kaempferol + quercetin) sharply increased with the beginning of differentiation of flower organs, i.e. from stage 3, to reach a maximum in the open flower, when gametogenesis is terminated and fertilization takes place. The level of flavonol contents in the petals (upper part) and stamen was at a maximum at all stages of flower development, while that in the gynaecium was at a minimum. The kaempferol : quercetin ratio was shifted towards quercetin at successive stages of flower development, most significantly in the stamens. The involvement of flavonols in the regulation of floral morphogenesis at stages of flower organs differentiation and functioning is discussed.     

Flavonoids in flowers of 16 Kalanchoë blossfeldiana varieties

Kalancho? blossfeldiana varieties with orange, pink, red and magenta flowers were found to contain 3,5-O-beta-D-diglucosides of pelargonidin, cyanidin, peonidin, delphinidin, petunidin and malvidin. Pink, red and magenta varieties contained relatively high amounts of quercetin based flavonols. Four distinct quercetin flavonols were identified, namely quercetin 3-O-beta-D-glucoside and three that were quercetin 3-O-alpha-L-rhamnoside based, with either glucose, xylose or arabinose attached to position 2 of the rhamnose. In addition, the presence of at least three kaempferol based diglycosides was suggested from LC-MS analyses. Orange varieties contained very low amounts of flavonol co-pigments and of delphinidin derivatives. The flower extracts of the varieties 'Diva' (magenta) and 'Molly' (red) had identical anthocyanin ratios but differed significantly in flavonol content. The magenta variety contained four times as much quercetin relative to anthocyanidin as the red variety. This difference was mainly due to a larger content of quercetin 3-O-(2'-O-beta-D-glucopyranosyl-alpha-L-rhamnopyranoside). Based on pigment and co-pigment analyses, approaches for molecular breeding towards blue flower colour are discussed.     

Properties and genetic control of udp-l-rhamnose: anthocyanidin 3-O-glucoside, 6″-O-rhamnosyl-transferase from petals of red campion,Silene dioica

In petals of Silene dioica plants the presence of a glycosyltransferase has been demonstrated, which catalyses the transfer of the rhamnosyl moiety of UDP-l-rhamnose to the glucose of cyanidin 3-O-glucoside. This enzyme can also use pelargonidin 3-O-glucoside as a substrate. The enzyme activity is controlled by a single dominant gene N; no rhamnosyltransferase activity is found in petals of n/n plants. The rhamnosyltransferase exhibits an optimum of pH 8.1 and is stimulated by the divalent metal ions Mg, Mn and Co. The biosynthetic pathway for the synthesis of cyanidin 3-rhamnosylglucoside-5-glucoside in petals of S. dioica is discussed.     

Genetic control of the conversion of dihydroflavonols into flavonols and anthocyanins in flowers of Petunia hybrida

Petunia hybrida mutants, homozygous recessive for one of the genes An1, An2, An6, or An9 do not show anthocyanin synthesis in in vitro complementation experiments per se (see also Kho et al. 1977). Extracts of flowers of these mutants all provoke anthocyanin synthesis in isolated petals of an an3an3 mutant. Mutants homozygous recessive for one of the genes An1, An2, An6, or An9 and homozygous recessive for F1 accumulate dihydroflavonols in comparable amounts. The synthesis of dihydromyricetin is blocked in an1an1 mutants, which indicates a regulating effect of the gene An1 on the gene Hfl. Similar mutants, but dominant for F1, accumulate flavonols (kaempferol and quercetin) instead of dihydroflavonols. Myricetin is accumulated in minor amounts and not at all in an1an1 mutant. Furthermore, the synthesis of this flavonol is not controlled by the gene F1. The synthesis of cyanidin (derivatives) is greatly reduced when flavonols are synthesized (F1 dominant). In mutants dominant for Ht1 and Hf1 and thus able to synthesize cyanidin (derivatives) and delphinidin (derivatives), predominantly delphinidin (derivatives) are synthesized. The results indicate that kaempferol (derivatives), quercetin (derivatives), and delphinidin (derivatives) are the main endproducts of flavonoid biosynthesis in Petunia hybrida.     

A further survey of anthocyanins and other phenolics in Ilex and Euonymus

A survey of 27 plants of Ilex and Euonymus revealed that the distribution of anthocyanins and cinnamic acid esters in their fruits is correlated with accepted taxonomic classification. In the skin of the fruit, the 3-xylosylglucoside of cyanidin and pelargonidin and the 3-monoglucoside of cyanidin were identified, and the hydrolysed fruit-extracts were found to contain quercetin, kaempferol and caffeic acid. The genus Ilex has been shown to be distinguishable from the genus Euonymus by their anthocyanins; I. micrococca was exceptional in having only chrysanthemin. Additionally, chlorogenic and isochlorogenic acids and caffeylglucose occur in Ilex but not in Euonymus. The microspectrophotometric examination of the pigment cells of the black- and red-Ilex fruits revealed that the position of absorption maxima in the visible region is mainly related to the relative amounts of anthocyanin and flavonol present.     

BIOCHEMICAL BASIS OF FLORAL COLOR POLYMORPHISM IN A HETEROCYANIC POPULATION OF TRILLIUM SESSILE (LILIACEAE)

A study of flavonoids occurring within a heterocyanic population of Trillium sessile was made to determine the chemical basis of a common floral color polymorphism in this species. In the study population, three floral color phenotypes (red, pink, yellow) are determined primarily by the presence or absence of anthocyanin compounds in the petal tissue, and secondarily by quantitative differences in the concentration of several flavonol glycosides. Petals of red phenotypes contain both cyanidin 3-arabinoside and 3-diarabinoside, petals of pink phenotypes contain only cyanidin 3-arabinoside, and petals of yellow phenotypes lack cyanidin entirely. Quercetin 3-0-glucoside, quercetin 3-0-arabinoglucoside, quercetin 3–0-arabinogalactoside, and quercetin 3-0-arabinogalactosyl, 7-0-glucoside occur in petals of all three phenotypes but differ in relative amounts. Petals of the red phenotype have mostly 3-0-biosides, but lesser amounts of both quercetin 3-0-glucoside and the 3,7-0-triglycoside. Petals of the pink phenotype contain relatively equal amounts of quercetin mono-, di-, and triglycosides. Petals of the yellow phenotypes contain mostly quercetin 3,7-0-triglycosides, and less mono- and di-glycosides. Small amounts of a quercetin tetraglycoside were detected in petals of both yellow and pink phenotypes, but not in red phenotypes. The enhancement of quercetin polyglycoside biosynthesis in yellow petal phenotypes is attributed to the shunting of dihydroflavonol precursors to synthesis of quercetin compounds when their conversion to anthocyanins is blocked genetically.     

Flavonol glycosides from distilled petals of Rosa damascena Mill

Flavonol glycosides were extracted from petals of Rosa damascena Mill. after industrial distillation for essential oil recovery and characterized by high-performance liquid chromatography-electrospray ionization mass spectrometry. Among the 22 major compounds analyzed, only kaempferol and quercetin glycosides were detected. To the best of our knowledge, the presence of quercetin 3-O-galactoside and quercetin 3-O-xyloside has so far not been reported within the genus Rosa. In addition, based on their fragmentation patterns, several acylated quercetin and kaempferol glycosides, some of them being disaccharides, were identified for the first time. The kaempferol glycosides, along with the kaempferol aglycone, accounted for 80% of the total compounds that were quantified, with kaempferol 3-O-glucoside being the predominant component. The high flavonol content of approximately 16 g/kg on a dry weight basis revealed that distilled rose petals represent a promising source of phenolic compounds which might be used as functional food ingredients, as natural antioxidants or as color enhancers.     

Sepal phenolic profile during Helleborus niger flower development

Morphological changes and phenolic patterns of developing hellebore sepals and the effects of pistil removal on these parameters were studied by comparing six flower stages of Helleborus niger. Color changes were evaluated colorimetrically, chlorophyll content was measured spectrophotometrically, and anthocyanins and flavonols were identified and quantified with HPLC–MS. Pistil removal not only altered the morphological development of hellebore flower resulting in smaller flower and significant color changes but also lead to several biochemical modifications. Five cyanidin glycosides have been identified from the group of anthocyanins in hellebore. Individual and total anthocyanin content increased from bud to subsequent developmental stages. Moreover, significantly higher content levels of individual and total anthocyanins have been measured in non-pollinated flower sepals compared to sepals of pollinated flowers. From the group of flavonols eight quercetin and kaempferol compounds have been quantified in hellebore sepals. Flavonol content significantly decreased during flower development with lowest levels recorded in sepals of non-pollinated and senescent pollinated hellebore flowers. Sepals of pollinated flowers contained highest levels of chlorophyll and significantly lower amounts of chlorophyll were measured in non-pollinated flowers and in sepals of senescent stage.     

Relationship between the composition of flavonoids and flower colors variation in tropical water lily (Nymphaea) cultivars

Water lily, the member of the Nymphaeaceae family, is the symbol of Buddhism and Brahmanism in India. Despite its limited researches on flower color variations and formation mechanism, water lily has background of blue flowers and displays an exceptionally wide diversity of flower colors from purple, red, blue to yellow, in nature. In this study, 34 flavonoids were identified among 35 tropical cultivars by high-performance liquid chromatography (HPLC) with photodiode array detection (DAD) and electrospray ionization mass spectrometry (ESI-MS). Among them, four anthocyanins: delphinidin 3-O-rhamnosyl-5-O-galactoside (Dp3Rh5Ga), delphinidin 3-O-(2"-O-galloyl-6"-O-oxalyl-rhamnoside) (Dp3galloyl-oxalylRh), delphinidin 3-O-(6"-O-acetyl-β-glucopyranoside) (Dp3acetylG) and cyanidin 3- O-(2"-O-galloyl-galactopyranoside)-5-O-rhamnoside (Cy3galloylGa5Rh), one chalcone: chalcononaringenin 2'-O-galactoside (Chal2'Ga) and twelve flavonols: myricetin 7-O-rhamnosyl-(1 → 2)-rhamnoside (My7RhRh), quercetin 7-O-galactosyl-(1 → 2)-rhamnoside (Qu7GaRh), quercetin 7-O-galactoside (Qu7Ga), kaempferol 7-O-galactosyl-(1 → 2)-rhamnoside (Km7GaRh), myricetin 3-O-galactoside (My3Ga), kaempferol 7-O-galloylgalactosyl-(1 → 2)-rhamnoside (Km7galloylGaRh), myricetin 3-O-galloylrhamnoside (My3galloylRh), kaempferol 3-O-galactoside (Km3Ga), isorhamnetin 7-O-galactoside (Is7Ga), isorhamnetin 7-O-xyloside (Is7Xy), kaempferol 3-O-(3"-acetylrhamnoside) (Km3-3"acetylRh) and quercetin 3-O-acetylgalactoside (Qu3acetylGa) were identified in the petals of tropic water lily for the first time. Meanwhile a multivariate analysis was used to explore the relationship between pigments and flower color. By comparing, the cultivars which were detected delphinidin 3-galactoside (Dp3Ga) presented amaranth, and detected delphinidin 3'-galactoside (Dp3'Ga) presented blue. However, the derivatives of delphinidin and cyanidin were more complicated in red group. No anthocyanins were detected within white and yellow group. At the same time a possible flavonoid biosynthesis pathway of tropical water lily was presumed putatively. These studies will help to elucidate the evolution mechanism on the formation of flower colors and provide theoretical basis for outcross breeding and developing health care products from this plant.     

UDP-Glucose: Cyanidin 3-O-glucosyltransferase from red cabbage seedlings

An enzyme, catalysing the glucosylation of cyanidin at the 3-position using uridine diphosphate-D-glucose (UDPG) as glucosyl-donor, has been isolated and purified about 50-fold from young red cabbage (Brassica oleracea) seedlings. The pH optimum for this reaction was ca 8 and no additional cofactors were required. The reaction was inhibited by cyanidin (above 0.25 mM) and by very low concentrations of the reaction product cyanidin-3-glucoside (5 μM). The K_m values for UDPG and cyanidin were 0.51 and 0.4 mM respectively. In addition to cyanidin the enzyme could also glucosylate the following compounds at the 3-position: pelargonidin, peonidin, malvidin, kaempferol, quercetin, isorhamnetin, myricetin and fisetin. In contrast, cyanidin-3-glucoside, cyanidin-3-sophoroside, cyanidin-3,5-diglucoside, apigenin, luteolin, naringenin and dihydroquercetin were not glucosylated.     

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.     

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.     

THE DIFFERENTIATION OF PIGMENTATION IN FLOWER PARTS. VIII. THE EFFECT OF INHIBITORS OF PROTEIN AND RNA SYNTHESIS ON DEVELOPMENTAL CHANGES OF ANTHOCYANINS IN CULTURED PETALS OF IMPATIENS BALSAMINA

If inhibitors of protein or RNA synthesis are administered to flower petals of the red genotype (HHHP^rP^r) of Impatiens balsamina at a very early stage of development, an alteration in the normal pattern of anthocyanin pigmentation results. Whereas control petals are mainly pigmented with acyl pelargonidin-3,5-diglucoside and pelargonidin-3,5-diglucoside, petals cultured in the presence of inhibitors are mainly pigmented with pelargonidin-3-monoglucoside. The complete absence of the more highly substituted forms of pelargonidin in treated petals suggests that the biochemical reactions required for the addition of glucosyl and hydroxycinnamoyl residues to pelargonidin-3-monoglucoside have been prevented. The ability to block the normal developmental pattern of pigmentation with these inhibitors suggests that de novo synthesis of active enzymes is required, and as indicated by the effectiveness of actinomycin D, specific RNA synthesis is a necessary prerequisite for the synthesis of the normal anthocyanin complement in this tissue. The ability of the white flowered genotype (llhhpp) to metabolize exogenously supplied pelargonidin-3-monoglucoside was found to be prevented by prior culture of immature petals in the presence of DL-ethionine. The data indicate that the enzymes required for this ability are not products of induction by the substrate but rather their presence is a normal feature of petal development. Treatment with inhibitors has failed to produce any inhibition in the formation of specific anthocyanins found in the flower petals of some other genotypes of I. balsamina.     

Heterologous Expression of Two Gentian Cytochrome P450 Genes can Modulate the Intensity of Flower Pigmentation in Transgenic Tobacco Plants

Two different heterologous expression systems, microsomal fractions of Saccharomyces cerevisiae and transgenic tobacco plants, were used to investigate the enzymatic activities of flavonoid 3′-hydroxylase (GtF3′H) and flavone synthase II (GtFSII) homologues isolated from gentian petals. Recombinant GtF3′H expressed in yeast showed hydroxylation activities in the 3′ position with several flavonoid substrates, while recombinant GtFSII was able to produce flavone from flavanone. GtF3′ H-expressing transgenic tobacco plants showed a slight increase in anthocyanin content and flower color intensity, and conversion of the flavonol quercetin from kaempferol. On the other hand, GtFSII-expressing plants showed a remarkable reduction in anthocyanin content and flower color intensity, and additional accumulation of flavone, especially luteolin derivatives. We demonstrated that two cytochrome P450s from gentian petals have F3′H and FSII enzymatic activities both in vitro and in vivo, and might therefore be useful in modification of flower color using genetic engineering.     

Genetical study on the formation of anthocyanins and flavonols in turnip varieties. Genetical studies on anthocyanins in brassicaceae II

Genetic studies were made on the root color of turnip varieties. In the cross between the red (raphanusin, pelargonidin glucoside) and the white varieties, F₁ hybrids were all purple (rubrobrassicin, cyanidin glucoside), and F₂ progenies were segregated into three groups: purple (rubrobrassicin), red (raphanusin), and white in the ratio of 9:3:4, respectively. This indicates the presence of two pairs of conditional alleles, as previously found in the case of radish. As to the flavonols in turnip varieties, isorhamnetin and kaempferol were found in the plants forming rubrobrassicin in roots, and only kaempferol in the plants producing raphanusin in roots; whereas isorhamnetin was found together with a trace of kaempferol in the plants with white root.     

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.     

The identification of poinsettia cultivars by HPLC analysis of their flavonol content

The flavonols from each of 38 poinsettia cultivars were quantitatively resolved by HPLC. Careful selection of samples revealed significant quantitative differences in flavonol content. While all cultivars of seedling origin could be differentiated on the basis of their flavonols, several families of sports could not. Most new commercial poinsettia cultivars have been selected from among somatic mutants exhibiting different bract color. Such changes in color were usually the results of change in anthocyanin content rather than flavonol content. The flavonol content increased in color sports with less anthocyanin. Three of the flavonols were absent from a few of the cultivars but most differences between cultivars were only quantitative. Genetic data suggested independent assortment of control of quercetin 3-rhamnoside and quercetin 3-galactoside synthesis but linkage of quercetin 3-rhamnoside and kaempferol 3-rhamnoside synthesis.