Carotenogenesis and chromoplast development during ripening of yellow, orange and red colored Physalis fruit.

MAIN CONCLUSION: Formation of specific ultrastructural chromoplastidal elements during ripening of fruits of three different colored Physalis spp. is closely related to their distinct carotenoid profiles. The accumulation of color-determining carotenoids within the chromoplasts of ripening yellow, orange, and red fruit of Physalis pubescens L., Physalis peruviana L., and Physalis alkekengi L., respectively, was monitored by high-performance liquid chromatography/diode array detector/tandem mass spectrometry (HPLC-DAD-MS/MS) as well as light and transmission electron microscopy. Both yellow and orange fruit gradually accumulated mainly ß-carotene and lutein esters at variable levels, explaining their different colors at full ripeness. Upon commencing ß-carotene biosynthesis, large crystals appeared in their chromoplasts, while large filaments protruding from plastoglobules were characteristic elements of chromoplasts of orange fruit. In contrast to yellow and orange fruit, fully ripe red fruit contained almost no ß-carotene, but esters of both ß-cryptoxanthin and zeaxanthin at very high levels. Tubule bundles and unusual disc-like crystallites were predominant carotenoid-bearing elements in red fruit. Our study supports the earlier hypothesis that the predominant carotenoid type might shape the ultrastructural carotenoid deposition form, which is considered important for color, stability and bioavailability of the contained carotenoids.

HPLC-DAD-APCI-MSn analysis of the genuine carotenoid pattern of pineapple (Ananas comosus [L.] Merr.) infructescence.

The genuine carotenoid pattern of pineapple infructescence was assessed by HPLC-DAD-APCI-MSn analysis. Prevailing pigments in the shell of 'MD2' (syn. "Extra Sweet") fruit were (all-E)-lutein and (all-E)-ß-carotene, in addition to chlorophylls a and b. The edible flesh contained (all-E)-violaxanthin, (all-E)-ß-carotene, and diverse esters of (9Z)-violaxanthin with caprylic, capric, lauric, and myristic acid. The latter esters have been reported for the first time as pineapple constituents. Total carotenoid concentrations in the edible fractions of the four varieties 'Sugar Loaf', 'Smooth Cayenne', 'MD2', and 'Queen Victoria' cultivated in Ghana ranged between 29 and 565 µg/100 g of fresh weight (FW). Total carotenoids in the flesh of fully ripe 'MD2' fruit exported by air freight amounted to 302 µg/100 g of FW, those in green ripe samples dispatched by sea freight to 359-432 µg/100 g of FW. All yellow fleshed cultivars exhibited a highly similar qualitative carotenoid profile.

Genuine Carotenoid Profiles in Sweet Orange [Citrus sinensis (L.) Osbeck cv. Navel] Peel and Pulp at Different Maturity Stages.

The carotenogenesis in the endocarp and flavedo of Navel oranges over four consecutive maturity stages was assessed by high-performance liquid chromatography-diode array detection-atmospheric pressure chemical ionization-multistage mass spectrometry. After optimization of the extraction method, 77 carotenoids, including 26 monoesters and 33 diesters of violaxanthin, ß-citraurin, and antheraxanthin, were characterized. Whereas chloroplast-specific pigments, such as (all-E)-lutein and (all-E)-ß-carotene, predominated in the flavedo of green-ripe fruit, a highly complex pattern of xanthophyll esters was found in the mature oranges. Total carotenoid contents of flavedo were approximately 9-fold higher [12 605 µg/100 g of fresh weight (FW)] than those in the endocarp (1354 µg/100 g of FW) at the fully mature stage. The mature endocarp abundantly contained violaxanthin mono- and diesters, in addition to diverse antheraxanthin esters, which were exclusively detected in this fruit fraction. Likewise, ß-citraurin esters were found to be unique flavedo constituents of mature fruit. Therefore, they may support the detection of fraudulent use of peel fractions during orange juice production.

Characterization of carotenoid profiles in goldenberry (Physalis peruviana L.) fruits at various ripening stages and in different plant tissues by HPLC-DAD-APCI-MSn.

Carotenoid profiles of goldenberry (Physalis peruviana L.) fruits differing in ripening states and in different fruit fractions (peel, pulp, and calyx of ripe fruits) were investigated by HPLC-DAD-APCI-MSn. Out of the 53 carotenoids detected, 42 were tentatively identified. The carotenoid profile of unripe fruits is dominated by (all-E)-lutein (51%), whereas in ripe fruits, (all-E)-ß-carotene (55%) and several carotenoid fatty acid esters, especially lutein esters esterified with myristic and palmitic acid as monoesters or diesters, were found. In overripe fruits, carotenoid conversion products and a higher proportion of carotenoid monoesters to diesters compared to ripe fruits were observed. Overripe fruits showed a significant decrease in total carotenoids of about 31% due to degradation. The observed conversion and degradation processes included epoxidation, isomerization, and deesterification. The peel of ripe goldenberries showed a 2.8 times higher total carotenoid content of 332.00 µg/g dw compared to the pulp.

Carotenoids and Carotenoid Esters of Red and Yellow Physalis (Physalis alkekengi L. and P. pubescens L.) Fruits and Calyces.

Carotenoid profiles of fruits and calyces of red (Physalis alkekengi L.) and yellow (P. pubescens L.) Physalis were characterized by HPLC-DAD-APCI-MSn. Altogether 69 carotenoids were detected in red Physalis, thereof, 45 were identified. In yellow Physalis, 40 carotenoids were detected and 33 were identified. Zeaxanthin esters with various fatty acids were found to be the most abundant carotenoids in red Physalis, accounting for 51-63% of total carotenoids, followed by ß-cryptoxanthin esters (16-24%). In yellow Physalis, mainly free carotenoids such as lutein and ß-carotene were found. Total carotenoid contents ranged between 19.8 and 21.6 mg/100 g fresh red Physalis fruits and 1.28-1.38 mg/100 g fresh yellow Physalis fruits, demonstrating that Physalis fruits are rich sources of dietary carotenoids. Yellow Physalis calyces contained only 153-306 µg carotenoids/g dry weight, while those of red Physalis contained substantially higher amounts (14.6-17.6 mg/g dry weight), thus possibly exhibiting great potential as a natural source for commercial zeaxanthin extraction.

Xanthophyll esters are found in human colostrum.

SCOPE: Carotenoids in human milk are associated with other lipid counterparts in several metabolic processes. One interesting association that has not been demonstrated to date is the presence of xanthophyll esters. Colostrum and mature milk samples were analyzed to determine the occurrence of xanthophyll esters and identify the compounds. Thus, the association of the amounts of these compounds with lactation and whether they are significant contributors to the carotenoid profile of human milk was assessed. METHODS AND RESULTS: Pre-term and term delivering mothers were included in the study to donate colostrum at 3-5 days postpartum and mature milk at 15 days postpartum. Carotenoids extracts were subjected to a clean-up procedure to remove the triacylglycerol fraction and then analyzed by HPLC-MSn . Identification of xanthophyll esters was achieved by considering their chromatographic behaviour, UV-visible characteristics and MSn features. CONCLUSION: Xanthophyll esters are significant contributors to the carotenoid profile in the colostrum, while mature milk does not contain these compounds. Therefore, fatty acid acylation to xanthophylls is activated during the accumulation of carotenoids in the human mammary gland. The sharp decline in the amount of xanthophyll esters in mature milk indicates that the lipophilic components are those recently incorporated in the mammary epithelium.

Carotenoid composition of strawberry tree (Arbutus unedo L.) fruits.

The carotenoid composition of strawberry tree (Arbutus unedo) fruits has been characterised in detail and quantified for the first time. According to the total carotenoid content (over 340 µg/g dw), mature strawberry tree berries can be classified as fruits with very high carotenoid content (>20 µg/g dw). (all-E)-Violaxanthin and 9Z-violaxanthin were found to be the major carotenoid pigments, accounting for more than 60%, responsible for the bright colour of the flesh of ripe fruits. In addition other 5,6-epoxide carotenoids, such as (all-E)-neoxanthin, (9'Z)-neoxanthin (all-E)-antheraxanthin and lutein 5,6-epoxide, together with (all-E)-lutein, (all-E)-zeaxanthin and (all-E)-ß-carotene were found at high levels (>5-20 µg/g dw). The LC-MS (APCI+) analysis of the xanthophyll fraction in their native state (direct extract) revealed that most of them (>90%) were totally esterified with saturated fatty acids (capric, lauric, myristic, palmitic and stearic). Monoesters, homodiesters and heterodiesters of (all-E)-violaxanthin and 9Z-violaxanthin were the major pigments.