violaxanthin and capsanthin

The orange color of tiger lily (Lolium lancifolium 'Splendens') flowers is due, primarily, to the accumulation of two κ-xanthophylls, capsanthin and capsorubin. An enzyme, known as capsanthin-capsorubin synthase (CCS), catalyzes the conversion of antheraxanthin and violaxanthin into capsanthin and capsorubin, respectively. We cloned the gene for capsanthin-capsorubin synthase (Llccs) from flower tepals of L. lancifolium by the rapid amplification of cDNA ends (RACE) with a heterologous non-degenerate primer that was based on the sequence of a gene for lycopene β-cyclase (lcyB). The full-length cDNA of Llccs was 1,785 bp long and contained an open reading frame of 1,425 bp that encoded a polypeptide of 474 amino acids with a predicted N-terminal plastid-targeting sequence. Analysis by reverse transcription-PCR (RT-PCR) revealed that expression of Llccs was spatially and temporally regulated, with expression in flower buds and flowers of L. lancifolium but not in vegetative tissues. Stable overexpression of the Llccs gene in callus tissue of Iris germanica, which accumulates several xanthophylls including violaxanthin, the precursor of capsorubin, resulted in transgenic callus whose color had changed from its normal yellow to red-orange. This novel red-orange coloration was due to the accumulation of two non-native κ-xanthophylls, capsanthin and capsorubin, as confirmed by HPLC and ultraperformance liquid chromatography-tandem mass spectrometry (UPLC-MS/MS) analysis with authentic standards. Cloning of the Llccs gene should advance our understanding of the molecular and genetic mechanisms of the biosynthesis of κ-carotenoids in general and in the genus Lilium in particular, and will facilitate transgenic alterations of the colors of flowers and fruits of many plant species.

Topics: Amino Acid Sequence; Chromatography, High Pressure Liquid; Cloning, Molecular; Color; DNA, Complementary; Flowers; Gene Expression Regulation, Enzymologic; Gene Expression Regulation, Plant; Genes, Plant; Intramolecular Lyases; Iris Plant; Lilium; Molecular Sequence Data; Open Reading Frames; Oxidoreductases; Phylogeny; Plant Proteins; Plants, Genetically Modified; Reverse Transcriptase Polymerase Chain Reaction; Sequence Homology, Amino Acid; Tandem Mass Spectrometry; Xanthophylls

The carotenoid patterns of fully ripe fruits from 12 Bolivian accessions of the Andean peppers Capsicum baccatum (ají) and C. pubescens (rocoto) were determined by high-performance liquid chromatography (HPLC)-photodiode array detector (PDA)-mass spectrometry (MS). We include 2 California Wonder cultivars as C. annuum controls. A total of 16 carotenoids were identified and differences among species were mostly found at the quantitative level. Among red-fruited genotypes, capsanthin was the main carotenoid in the 3 species (25% to 50% contribution to carotenoid fraction), although ajíes contained the lowest contribution of this carotenoid. In addition, the contribution of capsanthin 5,6-epoxide to total carotenoids in this species was high (11% to 27%) in comparison to rocotos and red C. annuum. Antheraxanthin and violaxanthin were, in general, the next most relevant carotenoids in the red Andean peppers (6.1% to 10.6%). Violaxanthin was the major carotenoid in yellow-/orange-fruited genotypes of the 3 species (37% to 68% total carotenoids), although yellow rocotos were characterized by lower levels (<45%). Cis-violaxanthin, antheraxanthin, and lutein were the next most relevant carotenoids in the yellow/orange Andean peppers (5% to 14%). As a whole, rocotos showed the highest contributions of provitamin A carotenoids to the carotenoid fraction. In terms of nutritional contribution, both ajíes and rocotos provide a remarkable provitamin A activity, with several accessions showing a content in retinol equivalents higher than California Wonder controls. Furthermore, levels of lutein in yellow/orange ajíes and rocotos were clearly higher than California Wonder pepper (≥1000 μg·100/g). Finally, the Andean peppers, particularly red ajíes, can be also considered as a noticeable source of capsanthin, the most powerful antioxidant compound among pepper carotenoids. Practical Application: Capsicum peppers are known for their content in carotenoids, although there is no information about 2 species with Andean origin: ajíes and rocotos. Due to their relevance for the Andean cuisine and increasing importance in ethnic restaurants in Europe, we studied their carotenoid pattern and vitamin A contribution.

Topics: Antioxidants; Bolivia; Capsicum; Carotenoids; Chromatography, High Pressure Liquid; Fruit; Mass Spectrometry; Pigmentation; Species Specificity; Vitamin A; Xanthophylls

The relationship between the degradation rate and structure of each pigment of the pepper carotenoid profile was studied in mixtures of dehydrated fruit with lipid substrates of differing degrees of unsaturation and in different proportions (20 and 40%). The differences in structural nature of the carotenoids present in the pepper fruit produce a variable rate of oxidation, resulting in nonuniform degradation. The yellow xanthophylls and beta-carotene have the highest rates of oxidation, with the ketocarotenoids and violaxanthin degrading at lower rates. Autoxidation is greater or lesser depending on the functional groups, which stabilize the radical intermediaries of the reaction. The behavior of capsanthin and capsorubin is that expected of carotenoids having structures that include keto groups: a markedly greater stability to autoxidation processes. This increases their antioxidant capacity, adding to their beneficial impact by reducing the proliferation of radical processes, which are detrimental to health.

Topics: beta Carotene; Capsicum; Carotenoids; Chromatography, High Pressure Liquid; Cryptoxanthins; Esterification; Kinetics; Molecular Structure; Oxidation-Reduction; Structure-Activity Relationship; Xanthophylls; Zeaxanthins