Anthocyanins of holly fruits

Anthocyanin distribution in the fruits of Ilex closely followed an accepted taxonomic classification. Within the evergreen subgenus Aquifolium, species belonging to section Lioprinus produced only cyanidin pigments while in section Aquifolium, pelargonidin was the major anthocyanin. Likewise, in the deciduous subgenus Prinos, species of section Prinoides contained cyanidin pigments and those of section Euprinus had pelargonidin compounds. Exceptions to this pattern and the bearing of pigment studies on breeding are discussed.     

A Unique pattern of anthocyanins in Daucus carota and other umbelliferae

Three cyanidin glycosides have been identified in the black carrot: the known 3-lathyroside and two new pigments, a 3-xylosylglucosylgalactoside and its ferulyl derivative. The same pigments, together with the sinapyl derivative of the triglycoside, occur variously in other tissues of Daucus carota. Ferulyl and sinapyl derivatives of cyanidin 3-glucosylgalactoside occur exceptionally in stem of one subspecies, maritimus. One or other of the same pigments have been found to occur variously in 20 of 22 other umbellifer species surveyed. Both ferulyl and sinapyl derivatives occur in stem of Conium maculatum and Foeniculum vulgare. A further novel acylated pigment based on p-coumaric acid was found in wild celery, Apiurn graveolens. The systematic significance of these various findings is discussed.     

Chemotaxonomic value of anthocyanins in Podalyria and Virgilia (tribe Podalyrieae: Fabaceae)

Anthocyanin pigments responsible for purple and pink flower colours in the tribe Podalyrieae have been identified. The considerable variation in flower colour is not reflected in the chemical variation and the flower pigments are surprisingly conservative. Virgilia flowers always have the acetic acid esters of cyanidin-3-glucoside and peonidin-3-glucoside as major compounds, together with trace amounts of the coumaroyl ester of cyanidin-3-glucoside. Podalyria flowers invariably have the rather more stable coumaroyl ester of cyanidin. The data support a close affinity between the two genera but also show that flower colour is only partially homologous.     

Chemosystematics in the Rutaceae: A chemotaxonomic survey of flavonoids and monoterpenes in leaves of Acmadenia species

By means of thin layer chromatography and gas liquid chromatography the distribution of monoterpenes and flavonoid aglycones in the leaves of 19 samples of 15 species of Acmadenia has been investigated. The distribution of flavonol and flavone aglycones shows a close agreement with recently proposed taxonomic divisions within the genus. It is proposed that these patterns may be of importance in interpreting the evolutionary development of the genus.     

Flavonol and dihydroflavonol glycosides of echinocereus triglochidiatus var. Gurneyi

Perianth parts, in particular, tepals of Echinocereus triglochidiatus var. gurneyi yielded a complex mixture of dihydroflavonols and dihydroflavonol 7-O-glucosides. Dihydroquercetin and its 7-O-glucoside were the predominant compounds while dihydrokaempferol and dihydromyricetin and their 7-O-glycosides were present in lesser amounts. Quercetin 7-O-glucoside was the principal flavonol glycoside: others present were quercetin and kaempferol 3-O-glucosides and 3-O-rhamnosylglucosides. The epidermis and spines yielded only traces of presumed flavonols as determined by two-dimensional TLC. No flavonoids were detected in the cortex tissue. This is the first report of dihydroflavonol derivatives from the Cactaceae and constitutes the first record of flavonoids from Echinocereus.     

Pollenkitt formation in Ilex paraguariensis A.St.Hil. (Aquifoliaceae)

 We investigated the cellular and organelle transformations during the formation of the pollenkitt in the secretory tapetum of Ilex paraguariensis. After the dissolution of the callose surrounding the young microspores, the elaioplasts of the tapetum produce many globules of saturated and unsaturated lipids (plastoglobules). Further on, oleosomes with unsaturated lipids, synthesized in the endoplasmic reticulum, accumulate in the tapetal cytoplasm. In contrast to other species, the plastoglobule production seems to precede the oleosome synthesis. The tapetum shows signs of cellular maturation in the late vacuolated microspore stage, when the plastoglobules and oleosomes coalesce and form the pollenkitt mass. In mature stages of the tapetum the pollenkitt is released into the loculus. Finally, it is mainly deposited on the exine, according to the entomophilous character of this species. The mode of pollenkitt formation in Ilex para guariensis and its transfer to the pollen surface is slightly dissimilar to other Angiosperms. Received October 24, 2002; accepted December 2, 2002 Published online: March 20, 2003     

Chemiluminescence of anthocyanins in the presence of acetaldehyde and tert-butyl hydroperoxide

Light emission (chemiluminescence; CL) was observed in the reaction of anthocyanins with tert-butyl hydroperoxide (t-BuOOH) in the presence of acetaldehyde. The intensity of the CL of the anthocyanins was in the order of nasunin > rubrobrassicin > delphinidin > malvin = cyanidin > malvidin, indicating that glucosylation at C-3 and C-5 of the anthocyanin skeleton enhances the CL of the parent compound. CL intensity was enhanced at alkaline pH. The results suggest that the antioxidant effect of anthocyanins on lipid peroxidation, which is observed in the linoleic acid-β-carotene-lipoxcygenase system, is at least partly due to their strong reactivity with hydroperoxides.     

Conversion of hydroxylated and methylated dihydroflavonols into anthocyanins in a white flowering mutant of Petunia hybrida

A 3′, 4′-dihydroxy or a 3′, 4′, 5′-trihydroxy substitution pattern of dihydroflavonols is required for their conversion into the corresponding anthocyanins in a white flower of Petunia hybrida. The presence of a 5-hydroxyl group is not required. B-ring methylated dihydroflavonols were not converted into the corresponding anthocyanins. In case of a 4′-methoxy substituted dihydroflavonol a 4′-hydroxyanthocyanin is obtained, suggesting demethylation of this compound. The conversion of synthetic (±)-trans-2,3-dihydroflavonols into anthocyanins proceeded almost as well as with natural compounds. The results demonstrate that the cinnamic acid starter hypothesis for the origin of B-ring substituents is not correct for B-ring methylation.     

The sterol and fatty acid compositions of seven tropical seagrasses from North Queensland,Australia

The sterol and fatty acid compositions of fresh leaves of the seagrasses Cymodocea serrulata, Enhalus acoroides, Halodule uninervis, Halophila ovalis, H. ovata, H. spinulosa and Thalassia hemprichii are reported. The major fatty acids were palmitic acid, linoleic acid and linolenic acid as expected. H. ovalis and H. ovata were characterized by the relatively high abundance (ca 5%) of the acid hexadeca-7,10,13-trienoic acid (16:3<7 > ). The sterol compositions were typical of higher plants, with sitosterol and stigmasterol accounting for 60–90% of the observed sterols. 28-Isofucosterol was a major sterol (20–30%) only in the Halophila spp. Cluster analysis of the sterol composition data clearly separated the Halophila spp. from the other seagrasses and enabled the distinction of Enhalus sp. from Cymodocea, Halodule and Thalassia spp. The seagrass species were clearly separated into five chemical groups using the combined fatty acid and sterol composition data and the need for a reappraisal of the taxonomic position of Halophila was indicated.     

Anthocyanin pigments and leaf flavonoids in the family araceae

Anthocyanins, variously identified in inflorescence, fruit, leaf or petiole of 59 representative species of the Araccae, are of a simple type. The most common pigment is cyanidin 3-rutinoside, while pelargonidin 3-rutinoside and cyanidin 3-glucoside are regularly present. Two rare pigments are: cyanidin 3-gentiobioside in Anchomanes and Rhektophyllum, both in the subfamily Lasioideae; and delphinidin 3-rutinoside in Schismatoglottis concinna. In a leaf survey of 144 species from 58 genera, flavone C-glycosides (in 82%) and proanthocyanidins (in 35–45%) were found as the major flavonoids. In the subfamily Calloideae, subtribe Symplocarpeae, flavonols replace glycoflavones as the major leaf components but otherwise flavonols are uncommon in the family (in 27% of the sample) and more usually co-occur with flavone C-glycosides. Two new flavonol glycosides were characterized from Lysichiton camtschatcense: kaempferol 3-(6-arabinosylgalactoside)and kaempferol 3-xylosylgalactoside. Simple flavones, luteolin and chrysoeriol (in 6%) were found only in the subtribes Arinae and Cryptocoryninae, subfamily Aroideae. Flavonoid sulphates were identified in only four taxa: glycoflavone sulphates in two Culcasia species and Philodendron ornatum and a mixture of flavone and flavonol sulphates in Scindapsus pictus. Caffeic ester sulphates were more common and their presence in Anthurium hookeri was confirmed. These results show that the Araceae are unusual amongst the monocots in their simple and relatively uniform flavonoid profile; no one subfamily is clearly distinguished, although at tribal level some significant taxonomic patterns are observed. The best defined groups are the subfamilies Lasioideae and Monsteroideae, and the tribes Symplocarpeae and Arophyteae, and the subtribe Arinae. The greatest chemical diversity occurs in Anthurium and Philodendron, but this may only reflect the fact that these are the two largest genera in the family. The origin and relationship of the Araccae to other monocot groups are discussed in the light of the flavonoid evidence.     

Phenolic compounds of the subfamily pomoideae: A chemotaxonomic survey

The subfamily Pomoideae has been surveyed for leaf phenolics and it has been shown that flavone glycosides are present in the genera Sorbus, Aronia, Chaenomeles and Hesperomeles in addition to the previously reported occurrences in Crataegus, Malus and Pyrus. The dihydrochalcone phloridzin, a typical constituent of Malus, has also been found in Docynia. Arbutin and phenolic acid-calleryanin esters are apparently restricted to Pyrus. Naringenin and eriodictyol glucosides have been detected in Pyracantha, Sorbus, Photinia, Chaenomeles and Hesperomeles. A number of Pomoideae phenolics have been found in two Spiraeoideae genera; luteolin 7-glucoside,] luteolin 7-diglucoside, luteolin 7-rhamnosylglucoside and apigenin 7-glucoside in Exochorda and the dihydrochalcone trilobatin in Sorbaria. The chemotaxonomic evidence is consistent with the hypothesis that the Pomoideae evolved through a process of allopolyploidy from primitive members of the Spiracoideae and Prunoideae.     

Pigments and fatty acids of marine raphidophytes: A chemotaxonomic re-evaluation

The patterns of occurrence of photosynthetic pigments and fatty acids among seven available species (11 strains) of marine raphidophytes were determined and used as chemotaxonomic markers. All currently recognized genera of marine raphidophytes were included for analysis: that is, Chattonella, Fibrocapsa, Heterosigma, Olisthodiscus and Haramonas. The characteristic pigment composition was shown to be chlorophyll a, chlorophylls c₁ and/or c₂, fucoxanthin as the major carot-enoid, β,β-carotene and any or all of zeaxanthin, violaxanthin and an auroxanthin-like pigment as the minor carotenoids. The carotenoid composition of all marine raphidophyte genera investigated was virtually the same, except in Fibrocapsa and Haramonas, which differed due to the occurrence of fucoxanthinol and 19′-butanoyloxyfucoxanthin, respectively. These fucoxanthin derivatives, in addition to fucoxanthin, have potential chemotaxonomic use for differentiating the two species. In all 11 strains, 15 fatty acids (saturated, mono-unsaturated and polyunsaturated) were determined. Significant taxonomic distinctions between genera were reflected by their fatty acid profiles. A rapid key for the differentiation of genera, in addition to morphological features, may be the absence of the 18:4 fatty acid in Olisthodiscus; presence of 18:5 in Heterosigma; the presence of fucoxanthinol in Fibrocapsa and presence of 19′-butanoyloxyfucoxanthin in Haramonas.     

l-3-(3′-Carboxy-4′-hydroxyphenyl)alanine (3-carboxytyrosine) in seeds of Neonotonia wightii (Glycine wightii) and its possible systematic significance

l-3-(3′-Carboxy-4′-hydroxyphenyl)alanine (3-carboxytyrosine) constitutes 3% of the seeds of Neonotonia wightii (Glycine wightii); it has also been detected in the seeds of 3 species belonging to 2 other genera of the Glycineae. The systematic significance of these findings is discussed.     

A red orange and lemon by-products extract rich in anthocyanins inhibits the progression of diabetic nephropathy

The major cause of end-stage renal disease is the diabetic nephropathy. Oxidative stress contributes to the development of type II diabetes mellitus (T2DM). In this study we have evaluated the effect of a diet with a new standardized of red orange and lemon extract (RLE) rich in anthocyanins (ANT) in the progression of the kidney disease on Zucker diabetic fatty rats. Oxidative stress and renal function were analyzed. In diabetic rats, the RLE restored the blood glucose levels, body weight, and normalized the reactive oxygen species (ROS) total pathways. The kidney inflammation, in diabetic rats, has not shown significant change, showing that the oxidative stress rather than to inflammatory processes is a triggering factor in the renal complication associated with T2DM. Therefore, the administration of the RLE prevents this complication and this effect could be related to the inhibition of ROS production.     

Tulip allergens in Alstroemeria and some other liliiflorae

A study has been made of the occurrence of tulip allergens (tuliposides) among several plant genera belonging to the Liliiflorae. All species of the genera Alstroemeria, Erythronium and Tulipa can be considered potentially allergenic (tuliposide-A). Tuliposide-B is more generally distributed and occurs in Lilium, Notholirion and Calochortus as well. Small amounts of both tuliposides are found in Fritillaria. A brief discussion is given of the systematic implications of the results.