Resonance Raman study of reconstituted carotenoproteins incorporating astaxanthin and 15,15'-didehydroastaxanthin

Two reconstituted carotenoproteins have been studied by resonance Raman spectroscopy. They were prepared from the apoprotein of the Asterias rubens carotenoprotein, asteriarubin and either astaxanthin or 15,15'-didehydroastaxanthin. Spectral properties of dehydrocarotenoids are first discussed. The spectral properties of the complexes are compared to those of the free carotenoids and of other carotenoproteins containing astaxanthin, and possible protein-carotenoid interactions are discussed. Greater delocalisation of the pi-electron system in the central part of the polyene chain, and the role of lateral methyl groups in binding is emphasised.     

Egg carotenoproteins in neotropical Ampullariidae (Gastropoda: Arquitaenioglossa)

Carotenoid-binding proteins are commonly found in invertebrates. Their carotenoids form non-covalent complexes with proteins giving tissues a variety of colors. In molluscs they have been described in only a few species. In particular, the egg perivitellin fluid of those Ampullariid species which deposit eggs above the waterline is provided with carotenoproteins playing several roles ranging from photoprotection, antioxidant or antitrypsin actions to nutrient provision for development. These molecules form complex glyco-lipo-carotenoproteins of high molecular weight where either free astaxanthin (3,3'-dihydroxy-beta, beta'-carotene- 4,4'dione) or astaxanthin esterified with fatty acids, occur more frequently. This review compiles the current knowledge on the biochemical composition and biophysical data on the chemical and thermal stability of egg carotenoproteins in ampullariid. In addition, recent data on their metabolism, their cellular site of biosynthesis during perivitellogenesis, as well as their carotenoid binding properties are reviewed, highlighting the physiological significance of carotenoproteins in the context of the reproductive biology of these molluscs.     

Alternative ligands as probes for the carotenoid-binding site of lobster carapace crustacyanin.

The apoproteins of the lobster carotenoprotein, crustacyanin, show single high-affinity binding sites for the hydrophobic fluorescence probes 8-anilo-1-naphthalenesulphonic acid and cis-parinaric acid, and exhibit fluorescence transfer from tryptophan to the ligands. These results, together with information from the amino acid sequences, infer that the native carotenoid, astaxanthin, is bound to each apoprotein within an internal hydrophobic pocket, or calyx.     

Carotenoid-binding proteins; accessories to carotenoid function

Understanding of the widespread biological importance of carotenoids is increasing. Accompanying this is the developing recognition that the interaction of carotenoids with other molecules, such as proteins, is also essential. Here the significance of carotenoid-protein interactions with respect to biological function is reviewed for three well characterised carotenoprotein complexes; crustacyanin, the orange carotenoid protein and glutathione-S-transferase P1. In addition a preliminary report is made on the recent partial purification of an echinenone-binding protein extracted from a New Zealand sea urchin, Evechinus chloroticus.     

Adaptative role of carotenoids and carotenoproteins in Cyclops kolensis Lilljeborg (Crustacea: Copepoda) specimens to extremely eutrophical conditions

The authors, using column, thin-layer, and ion-exchange chromatography, investigated carotenoid and carotenoprotein complex content in Cyclops kolensis specimens from an extremely eutrophic pond. The following carotenoids were found to be present: beta-carotene, beta-cryptoxanthin, lutein epoxide, crustaxanthin, 4'-hydroxyechinenone, canthaxanthin, and astaxanthin. Carotenoprotein complex containing astaxanthin as the prosthetic group name gamma-crustacyanine was purified from Cyclops kolensis individuals examined. The authors justify the adaptative role of these pigments in Cyclops kolensis specimens in extremely eutrophical conditions.     

Identification of carotenoid pigments and their fatty acid esters in an avian integument combining HPLC-DAD and LC-MS analyses

Yellow-orange-red ornaments present in the integuments (feathers, bare parts) of birds are often produced by carotenoid pigments and may serve to signal the quality of the bearer. Although carotenoid esterification in tissues is a common phenomenon, most of the work on avian carotenoids has been focused on the identification of free forms or have been done after sample saponification. Here we determined free and esterified carotenoid composition in a bird species with red ornaments: the red-legged partridge (Alectoris rufa). Carotenoids from leg integument were extracted and processed by TLC to separate three major carotenoid groups (free form, mono- and diesters with fatty acids), whereas saponified extracts gave only free forms of carotenoids. TLC fractions were then analyzed by HPLC-DAD with C18 phase column for a preliminary identification of carotenoid groups. The final characterization of free carotenoids and its esters with fatty acids was performed with direct extracts analyzed by LC-MS and LC-MS/MS with a C30 phase, always with a system coupled to DAD. The main carotenoid (λ(max) 478 nm and [M+H](+) at m/z 597.2) was identified as astaxanthin by comparison with standards. A second carotenoid (λ(max) between 440 and 480 nm and [M+H](+) at m/z 581.3) was not identified among any of the commercially available carotenoid standards, although it could correspond to pectenolone according to its fragmentation pattern. Both the unidentified carotenoid and astaxanthin formed monoesters with fatty acids, but only astaxanthin was in its diesterified form. Monoesters were mainly formed with palmitic, stearic, oleic and linoleic acids. Complementary analyses of fatty acid composition in partridge integument by GC-MS revealed high amounts of these and other fatty acids, such as myristic, arachidic and docosanoic acids. The combination of HPLC-DAD and LC-MS/MS spectra was especially useful to identify the carotenoids present in the esterified forms and the probable masses of the fatty acids included in them, respectively.     

Purification and characterization of the blue carotenoprotein from the caparace of the crayfish Procambarus clarkii (Girard)

The isolation, purification and characterization of a blue carotenoprotein isolated from the carapace of the crayfish Procambarus clarkii (Girard) are reported. The molecular weight of the complex has been determined by polyacrylamide gradient gel electrophoresis and gel filtration. Under unfavourable conditions the natural blue complex, designated the α-form (approx. M_r 246 000), dissociated to a purple dimer, the β-form (approx. 41 600). Sodium dodecyl sulphate polyacrylamide gel electrophoresis indicated the β-form to contain two polypeptides, of molecular weight 19 200 and 21 400. The amino-acid composition of the natural protein is described and compared with those of similar carotenoproteins from other crustaceans. The complex contains six carotenoid molecules per molecule of protein (α-form) and the carotenoid has been identified by thin-layer chromatography, light-absorption spectroscopy, HPLC and mass spectrometry as all-trans-astaxanthin (3,3′-dihydroxy-β,β-carotene-4,4′-dione), the three optical isomeric forms, (3R,3′R)-, (3R,3′S) and (3S,3′S), being present in the ratio 20:21:58. The binding of the carotenoid, astaxanthin (absorption maximum in acetone at 470 nm) to the apoprotein results in a marked red spectral shift of about 165 nm, giving rise to absorption maxima at 635 nm and 585 nm for the α- and β-forms, respectively, in 50 mM phosphate buffer (pH 7.5). The λ_max of any sample is dependent upon the relative ratio of α and β forms present.     

Structure and function of the genes involved in the biosynthesis of carotenoids in the mucorales

Carotenoids are widely distributed natural pigments which are in an increasing demand by the market, due to their applications in the human food, animal feed, cosmetics, and pharmaceutical industries. Although more than 600 carotenoids have been identified in nature, only a few are industrially important (β-carotene, astaxanthin, lutein or lycopene). To date chemical processes manufacture most of the carotenoid production, but the interest for carotenoids of biological origin is growing since there is an increased public concern over the safety of artificial food colorants. Although much interest and effort has been devoted to the use of biological sources for industrially important carotenoids, only the production of biological β-carotene and astaxanthin has been reported. Among fungi, several Mucorales strains, particularlyBlakeslea trispora, have been used to develop fermentation process for the production of β-carotene on almost competitive cost-price levels. Similarly, the basidiomycetous yeastXanthophyllomyces dendrorhous (the perfect state ofPhaffia rhodozyma), has been proposed as a promising source of astaxanthin. This paper focuses on recent findings on the fungal pathways for carotenoid production, especially the structure and function of the genes involved in the biosynthesis of carotenoids in the Mucorales. An outlook of the possibilities of an increased industrial production of carotenoids, based on metabolic engineering of fungi for carotenoid content and composition, is also discussed.     

Animal carotenoids—carotenoproteins from hydrocorals

• 1.1. The carotenoid complexes isolated from six corals of the order Hydrocorallina (Stylaster roseus, S. elegans, S. sanguineus, Distichopora coccinea, D. nitida and D. violacea) have been re-examined.
• 2.2. The yellow to violet colours of the calcareous skeletons of these hydrocorals are evoked by carotenoproteins containing astaxanthin (1) and zeaxanthin (2).
• 3.3. A preliminary characterization of these new carotenoproteins is reported.

     

Pathway engineering strategies for production of beneficial carotenoids in microbial hosts

Carotenoids, such as lycopene, β-carotene, zeaxanthin, canthaxanthin and astaxanthin have many benefits for human health. In addition to the functional role of carotenoids as vitamin A precursors, adequate consumption of carotenoids prevents the development of a variety of serious diseases. Biosynthesis of carotenoids is a complex process and it starts with the common isoprene precursors. Condensation of these precursors and subsequent modifications, by introducing hydroxyl- and keto-groups, leads to the generation of diversified carotenoid structures. To improve carotenoid production, metabolic engineering has been explored in bacteria, yeast, and algae. The success of the pathway engineering effort depends on the host metabolism, specific enzymes used, the enzyme expression levels, and the strategies employed. Despite the difficulty of pathway engineering for carotenoid production, great progress has been made over the past decade. We review metabolic engineering approaches used in a variety of microbial hosts for carotenoid biosynthesis. These advances will greatly expedite our efforts to bring the health benefits of carotenoids and other nutritional compounds to our diet.     

Novel methoxy-carotenoids from the burgundy-colored plumage of the Pompadour Cotinga Xipholena punicea

Recent advances in the fields of chromatography, mass spectrometry, and chemical analysis have greatly improved the efficiency with which carotenoids can be extracted and analyzed from avian plumage. Prior to these technological developments, Brush (1968) [1] concluded that the burgundy-colored plumage of the male pompadour Cotinga Xipholena punicea is produced by a combination of blue structural color and red carotenoids, including astaxanthin, canthaxanthin, isozeaxanthin, and a fourth unidentified, polar carotenoid. However, X. punicea does not in fact exhibit any structural coloration. This work aims to elucidate the carotenoid pigments of the burgundy color of X. punicea plumage using advanced analytical methodology. Feathers were collected from two burgundy male specimens and from a third aberrant orange-colored specimen. Pigments were extracted using a previously published technique (McGraw et al. (2005) [2]), separated by high-performance liquid chromatography (HPLC), and analyzed by UV/Vis absorption spectroscopy, chemical analysis, mass spectrometry, nuclear magnetic resonance (NMR), and comparison with direct synthetic products. Our investigation revealed the presence of eight ketocarotenoids, including astaxanthin and canthaxanthin as reported previously by Brush (1968) [1]. Six of the ketocarotenoids contained methoxyl groups, which is rare for naturally-occurring carotenoids and a novel finding in birds. Interestingly, the carotenoid composition was the same in both the burgundy and orange feathers, indicating that feather coloration in X. punicea is determined not only by the presence of carotenoids, but also by interactions between the bound carotenoid pigments and their protein environment in the barb rami and barbules. This paper presents the first evidence of metabolically-derived methoxy-carotenoids in birds.     

The interaction of dietary carotenoids with radical species

Dietary carotenoids react with a wide range of radicals such as CCl3O2*, RSO2*, NO2*, and various arylperoxyl radicals via electron transfer producing the radical cation of the carotenoid. Less strongly oxidizing radicals, such as alkylperoxyl radicals, can lead to hydrogen atom transfer generating the neutral carotene radical. Other processes can also arise such as adduct formation with sulphur-centered radicals. The oxidation potentials have been established, showing that, in Triton X-100 micelles, lycopene is the easiest carotenoid to oxidize to its radical cation and astaxanthin is the most difficult. The interaction of carotenoids and carotenoid radicals with other antioxidants is of importance with respect to anti- and possibly pro-oxidative reactions of carotenoids. In polar environments the vitamin E (alpha-tocopherol) radical cation is deprotonated (TOH*+ --> TO* + H+) and TO* does not react with carotenoids, whereas in nonpolar environments such as hexane, TOH*+ is converted to TOH by hydrocarbon carotenoids. However, the nature of the reaction between the tocopherol and various carotenoids shows a marked variation depending on the specific tocopherol homologue. The radical cations of the carotenoids all react with vitamin C so as to "repair" the carotenoid.     

Response of serum carotenoid levels to dietary astaxanthin and canthaxanthin in immature rainbow trout Oncorhynchus mykiss

Rainbow trout were fed a diet supplemented with astaxanthin (89 mg/kg) or canthaxanthin (116 mg/kg) in two different experiments: experiment 1 was designed to measure the kinetics of the appearance and disappearance of carotenoids in the serum; experiment 2 was undertaken to establish the serum dose-response to synthetic astaxanthin and canthaxanthin for immature rainbow trout. The serum carotenoid concentrations of immature rainbow trout increased when fish were fed carotenoid supplemented feed and then reached a plateau after 1 day of intake for astaxanthin and after 2 days for canthaxanthin. Circulating astaxanthin represented a value 2.3 times that of canthaxanthin. After dietary supplementation was discontinued, the serum carotenoid concentrations decreased within 3 days for both carotenoids. The average decreasing slopes for the two carotenoid pigments were parallel, indicating a similarity in the rate of which astaxanthin and canthaxanthin are utilized by rainbow trout. The serum dose-response of trout that received dietary keto-carotenoids increased with increasing pigment levels. The hypothesis that absorption of dietary carotenoids in 12.5–200 mg/kg range of concentration across the gut wall may be by passive diffusion is proposed.     

The effects of dietary carotenoid intake on carotenoid accumulation in the retina of a wild bird, the house finch (Carpodacus mexicanus)

Carotenoid pigments accumulate in the retinas of many animals, including humans, where they play an important role in visual health and performance. Recently, birds have emerged as a model system for studying the mechanisms and functions of carotenoid accumulation in the retina. However, these studies have been limited to a small number of domesticated species, and the effects of dietary carotenoid access on retinal carotenoid accumulation have not been investigated in any wild animal species. The purpose of our studies was to examine how variation in dietary carotenoid types and levels affect retinal accumulation in house finches (Carpodacus mexicanus), a common and colorful North American songbird. We carried out three 8-week studies with wild-caught captive birds: (1) we tracked the rate of retinal carotenoid depletion, compared to other body tissues, on a very low-carotenoid diet, (2) we supplemented birds with two common dietary carotenoids (lutein + zeaxanthin) and measured the effect on retinal accumulation, and (3) we separately supplemented birds with high levels of zeaxanthin - an important dietary precursor for retinal carotenoids - or astaxanthin - a dominant retinal carotenoid not commonly found in the diet (i.e. a metabolic derivative). We found that carotenoids depleted slowly from the retina compared to other tissues, with a significant (∼50%) decline observed only after 8 weeks on a very low-carotenoid diet. Supplementation with lutein + zeaxanthin or zeaxanthin alone significantly increased only retinal galloxanthin and ε-carotene levels, while other carotenoid types in the retina remained unaffected. Concentrations of retinal astaxanthin were unaffected by direct dietary supplementation with astaxanthin. These results suggest highly specific mechanisms of retinal carotenoid metabolism and accumulation, as well as differential rates of turnover among retinal carotenoid types, all of which have important implications for visual health maintenance and interventions.     

Complete sequence and model for the C1 subunit of the carotenoprotein, crustacyanin, and model for the dimer, beta-crustacyanin, formed from the C1 and A2 subunits with astaxanthin

The complete sequence has been determined for the C1 subunit of crustacyanin, an astaxanthin-binding protein from the carapace of the lobster Homarus gammarus (L.). The polypeptide, 181 residues long, is similar (38% identity) to the other main subunit, A2 and to plasma retinol-binding protein. The tertiary structure of the C1 subunit has been modelled on that derived for the A2 subunit from the coordinates of retinol-binding protein. Residues lining the putative binding cavities and at the putative carotenoid binding sites of the two subunits are highly conserved. The carotenoid environments are characterized by a preponderance of aromatic and polar residues and the absence of charged side-chains. A tentative model for the dimer, beta-crustacyanin, formed between the two subunits with their associated carotenoid ligands, is discussed. The model is based on the crystal structure of the dimer of bilin-binding protein, a member of the same superfamily. This structure has enabled us to examine mechanisms for the bathochromic spectral shift of the protein-bound carotenoid and to identify likely contact regions between dimers in octameric alpha-crustacyanin.     

The carotenoids of wild and blue disease affected farmed tiger shrimp (Penaeus monodon, Fabricus)

1. The main carotenoids in wild Penaeus monodon exoskeleton were astaxanthin di- and mono-esters, astaxanthin, and beta-carotene. 2. Wild P. monodon exoskeleton contained on average 26.3 ppm total carotenoid; normally pigmented farmed shrimp had a similar concentration (25.3 ppm). 3. Exoskeletons of farmed "blue" P. monodon (i.e. blue-coloured, as opposed to the normally red-blue/black banded shrimp) contained significantly less total carotenoid (4.3-7 ppm). The only major carotenoid being astaxanthin. 4. Commercially available diets contained only trace quantities of canthaxanthin. 5. Nutritional deficiency with respect to carotenoids is suggested as the cause of blue disease in farmed P. monodon.     

Evolution of carotenoid metabolic capabilities during the early development of the European lobster Homarus gammarus (Linné, 1758)

The quantification of carotenoids during the early developmental stages of the European lobster Homarus gammarus, indicates a rapid decrease of pigment concentration, occurring immediately after hatching. Conversely, the carotenoid amount of the individual increases progressively at the end of larval stage I, as a result of an enhanced feeding activity. Free astaxanthin represents the bulk of carotenoids of the unhatched embryo (metanauplius), whereas larval, post-larval and juvenile stages exhibit the typical adult carotenoid pattern, in which astaxanthin esterified forms (diester and monoester) appear preponderant. The Artemia strain used as food material is not found to contain astaxanthin, while important amounts of canthaxanthin are observed; nevertheless, this carotenoid is not detected in the larvae, indicating that metabolic transformation capabilities are already occurring in freshly hatched individuals.     

One-electron reduction potentials of dietary carotenoid radical cations in aqueous micellar environments

The one-electron reduction potentials of the radical cations of five dietary carotenoids (β-carotene, canthaxanthin, zeaxanthin, astaxanthin and lycopene) in aqueous micellar environments have been obtained from a pulse radiolysis study of electron transfer between the carotenoids and tryptophan radical cations as a function of pH, and lie in the range of 980–1060 mV. These values are consistent with our observation that the carotenoid radical cations oxidise tyrosine and cysteine. The decays of the carotenoid radical cations in the absence of added reactants suggest a distribution of exponential lifetimes. The radicals persist for up to about 1 s, depending on the medium.     

Reduction of oxidized guanosine by dietary carotenoids: A pulse radiolysis study

Time-resolved pulse radiolysis investigations reported herein show that the carotenoids β-carotene, lycopene, zeaxanthin and astaxanthin (the last two are xanthophylls - oxygen containing carotenoids) are capable of both reducing oxidized guanosine as well as minimizing its formation. The reaction of the carotenoid with the oxidized guanosine produces the radical cation of the carotenoid. This behavior contrasts with the reactions between the amino acids and dietary carotenoids where the carotenoid radical cations oxidized the amino acids (tryptophan, cysteine and tyrosine) at physiological pH.