Absolute configuration of β,γ-carotene and biosynthetic implications

Racemic γ-ionone, partly resolved via its menthydrazone, was used for total synthesis of β,γ-carotene enriched in the 6′R and 6′S enantiomers. By CD correlation with natural β,γ-carotene isolated from Caloscypha fulgens 6′S-chirality is demonstrated for the natural carotene. Biosynthetic implications regarding the cyclization reaction are discussed.     

Chemical induction of β-carotene biosynthesis

Marsh white seedless grapefruit were treated with the 2-diethylaminoethanol esters of the following acids: benzoic, phenylacetic, hydrocinnamic, 4-phenylbutyric, 5-phenylvaleric, valeric, hexanoic, heptanoic, octanoic, nonanoic, 5-chlorovaleric, cyclohexanecarboxylic, phenoxyacetic, p-chlorophenoxyacetic, 3-phenoxypropionic, cinnamic and p-chlorocinnamic. Several of these esters, in particular the hexanoate, 4-phenylbutyrate and cinnamate, caused the accumulation of large amounts of β-carotene. The effects of the hexanoate and of 2-phenoxytriethylamine, which causes only lycopene accumulation, were studied as functions of time. The hexanoate caused the rapid accumulation of lycopene during the first day. The amount of lycopene then began to decrease and that of β-carotene increased until, after 14 days, β-carotene was the major pigment. 2-Phenoxytriethylamine caused rapid lycopene accumulation during the first day and a slow steady increase afterwards. Thus, the mode of action of the β-carotene inducers may be similar to that of the lycopene inducers except that the former are probably rapidly hydrolysed by the esterase(s) in the flavedo, so that they no longer inhibit the cyclase(s), and β-carotene is accumulated at the expanse of lycopene.     

Effective production of retinal from β-carotene using recombinant mouse β-carotene 15,15′-monooxygenase

The gene encoding β-carotene 15,15′-monooxygenase from Mus musculus (house mouse), which cleaves β-carotene into two molecules of retinal, was cloned and expressed in Escherichia coli. The expressed enzyme was purified by His-tag affinity and resource Q ion exchange chromatography columns to a final specific activity of 0.51 U mg⁻¹. The optimum pH, temperature, substrate and detergent concentrations, and enzyme amount for effective retinal production were determined to be 9.0, 37°C, 200 mg l⁻¹ β-carotene, 5% (w/v) Tween 40, and 0.2 U ml⁻¹ enzyme, respectively. Under optimum conditions, the recombinant enzyme produced 72 mg l⁻¹ retinal in a 15-h reaction time, with a conversion yield of 36% (w/w). The specific activity of the purified enzyme and retinal production obtained in the present study were the highest results ever reported.     

MIT1, encoding a 15-cis-ζ-carotene isomerase,regulates tiller number and stature in rice

正Lateral branching is an important determinant of shoot architecture and crop yield. The plant hormone strigolactone (SL) inhibits lateral bud outgrowth in various plant species. Deficiencies in SL biosynthesis and signal transduction result in excessive outgrowth of lateral buds (Stirnberg et al., 2002; Sorefan et al., 2003).     

Phytoene,phytofluene and ζ-carotene isomers from a Scenedesmus obliquus mutant

A number of mutant strains of the green alga, Scenedesmus obliquus, when grown in the dark, accumulated ζ-carotene as their major carotenoid together with appreciable concentrations of phytoene and phytofluene. The phytoene was almost entirely the 15-cis isomer, and phytofluene was also present mainly as the 15-cis form, whereas the ζ-carotene could be separated into three isomers, predominantly all-trans ζ-carotene accompanied by the 15-cis and an unidentified cis isomer. All the ζ-carotene isomers, when illuminated in the presence of iodine, gave the same equilibrium mixture of stereo-isomers, including a product with unusual spectroscopic and chromatographic properties, which may be a cyclic compound. The pathway of carotenoid biosynthesis in S. obliquus is discussed. On illumination, most of the ζ-carotenic strains were killed, but PGI strain survived, due to the production of cyclic carotenoids with chromophores long enough to protect chlorophyll from photosensitized oxidation.     

Production of β-carotene by aRhodotorula strain

Summary The production of -carotene by the biomass ofRhodotorula strain var.glutinis, during the stationary phase of growth and in non-proliferating conditions was assayed. When the cells were transferred to distilled water, the fraction of -carotene produced increased from 130 to 630 g per gram of dried cells.     

Exploitation of Dunaliella for β-carotene production

Halotolerant microalga Dunaliella, which is exploited for the production of dried biomass or cell extract, is used as a medicinal food. With the advancement in this field in recent years, the production of bio-organic compounds such as β-carotene is established in many countries. Large-scale production of β-carotene is controlled by numerous stress factors like high light intensity, high salinity, temperature and availability of nutrients. The state-of-the-art strategies in industries in closed systems under new set of inductive factors will additionally promote the ease of commercial production of β-carotene. This review mainly focuses on the different methodologies employed recently for the optimum production of β-carotene from Dunaliella species.     

Copper status in rats fed diets supplemented with either vitamin E,vitamin A,or β-carotene

Copper status was measured in rats fed copper-adequate, purified diets supplemented with either vitamin E (250 IU/kg), vitamin A (40,000 IU/kg), or β-carotene (2 g/kg). It was hypothesized that the extra intake of the antioxidants would spare vitamin C resulting in a decreased copper status as shown previously after supplementation with vitamin C. A significant increase in plasma ascorbate concentration was observed after β-carotene supplementation, but not after supplemental vitamin E or vitamin A. Extra intake of either β-carotene or vitamin A slightly, but significantly, raised plasma copper concentrations. β-carotene also slightly raised liver copper concentration. Supplemental vitamin E had no effect on plasma and liver copper concentrations. It is concluded that the observed relatively small effects of supplemental vitamin A and β-carotene on copper status in rats are not mediated by changes in plasma vitamin C concentration.     

Seasonal variation in the lipid content of culturedLaminaria japonica: fatty acids,sterols, β-carotene and tocopherol

Seasonal variation in major lipid constituents of nutritional importance in culturedLaminaria japonica Aresch., such as fatty acids, sterols, -carotene and tocopherol, were investigated from December to October, the growing season. The total and saturated fatty acid contents were minimal in midsummer. Mono-unsaturated fatty acids gradually increased from late summer to autumn. The polyunsaturated fatty acid content (PUFA, (n-6) family) was maximal during warm months, while (n-3) PUFAs were most abundant during the cold months when algal thalli were very young, and decreased gradually toward October when sori had developed. Fucosterol content was maximum from February to June, but decreased steeply by nearly a half toward October, when 24-methylene cholesterol was highest although much less than fucosterol. The -carotene and tocopherol contents were maximal from July to September and slight during the winter.     

Strain selection for β-carotene production by Dunaliella

Four strains of Dunaliella were grown at 25°C and pH 8±0.5, with continous illumination at 200 W/m². Their maximum specific growth rates ranged from 0.093 day^-1 to 0.234 day^-1, nitrate yields from 3.0 to 7.8 g cells/g NaNO₃ and lipid contents from 3% to 6% of the dry wt, with carotenes 50 to 80% of the lipids. Of the carotenes, -carotene made up 7 to 19%; all-trans--carotene 32 to 52% and 9-cis--carotene 29 to 55%. There are, therefore, considerable intra-specific differences between strains of Dunaliella.     

Serum levels of vitamins A, C, and E, β-carotene, selenium, and zinc in patients with behçet’s disease

Behçet’s disease is a multisystemic disease characterized by activation and remission periods. The etiopathogenesis is not exactly known; a genetic defect in the immunoregulatory system induced by infectious agents, like viruses and bacteria, is thought to cause the disease. In this study, we examine the serum levels of vitamins A, C, and E, β-carotene, selenium, and zinc in Behçet’s disease patients and investigate the relationship between these serum levels and the activation of the disease. We conclude that adding vitamin E to the treatment of Behçet’s disease patients and its effects on the prognosis of the disease need to be further investigated by controlled studies.     

Iron-induced oxidation of (all-E)-β-carotene under model gastric conditions: kinetics,products, and mechanism

The stability of (all-E)-β-carotene toward dietary iron was studied in a mildly acidic (pH 4) micellar solution as a simple model of the postprandial gastric conditions. The oxidation was initiated by free iron (Fe^II, Fe^III) or by heme iron (metmyoglobin, MbFe^III). Fe^II and metmyoglobin were much more efficient than Fe^III at initiating β-carotene oxidation. Whatever the initiator, hydrogen peroxide did not accumulate. Moreover, β-carotene markedly inhibited the conversion of Fe^II into Fe^III. β-Carotene oxidation induced by Fe^II or MbFe^III was maximal with 5–10 eq Fe^II or 0.05–0.1 eq MbFe^III and was inhibited at higher iron concentrations, especially with Fe^II. UPLC/DAD/MS and GC/MS analyses revealed a complex distribution of β-carotene-derived products including Z-isomers, epoxides, and cleavage products of various chain lengths. Finally, the mechanism of iron-induced β-carotene oxidation is discussed. Altogether, our results suggest that dietary iron, especially free (loosely bound) Fe^II and heme iron, may efficiently induce β-carotene autoxidation within the upper digestive tract, thereby limiting its supply to tissues (bioavailability) and consequently its biological activity.     

Photosynthetic characteristics of Dunaliella salina (Chlorophyceae,Dunaliellales) in relation to β-carotene content

Photosynthetic characteristics of Dunaliella salina with high (red form) and low β-carotene (green form) concentrations were studied. D. salina growing in brine saltworks exhibited a high level of β-carotene (15 pg cell⁻¹). The rate of oxygen evolution as a function of irradiance was higher in the red than in the green form (on chlorophyll basis). Photosynthetic inhibition of the green form was observed above 500 μmol m⁻² s⁻¹. The red form appeared more resistant to high irradiance and no inhibition in O₂ evolution was observed up 2000 μmol m⁻² s⁻¹. However, when these results are expressed on a cell number basis the rate of oxygen evolution was significantly higher in the green form. Carbonic anhydrase (CA) activity (total, soluble, membrane bound) was found in red and green forms. CA was higher in the red form on a chlorophyll basis, but lower if expressed on a protein basis. The light dependent rate of oxygen evolution and photoinhibition depends on the concentration of β-carotene in D. salina cells.     

Addition of lutein, lycopene, or β-carotene to LDL or serum in vitro: Effects on carotenoid distribution, LDL composition, and LDL oxidation

Carotenoids are dietary antioxidants transported with plasma lipoproteins, primarily low-density lipoprotein (LDL). In this study in vitro methods were used to increase the amounts of specific, individual carotenoids in LDL. By addition of carotenoid to isolated LDL or to serum, followed by (re)isolation of the lipoproteins, samples of LDL were enriched 4- to 150-fold with lutein, 2- to 15-fold with lycopene, or 3- to 25-fold with β-carotene. Enrichment with specific carotenoids was achieved without affecting the electrophoretic mobility of the lipoprotein, its cholesterol to protein ratio, or the levels of other cartenoids or -tocopherol. The distributions among lipoproteins of carotenoid added to serum were similar, but not identical, to the distributions of the endogenous carotenoids. In particular, for added lutein, a greater proportion was found in HDL, and for added β-carotene, more was found in very low-density lipoprotein (VLDL). We then studied the effect of enriching LDL with specific carotenoids on its susceptibility to oxidation by copper ions. Lutein, β-cryptoxanthin, lycopene, and β-carotene, the four major plasma carotenoids, and -tocopherol were destroyed before the formation of lipid peroxidation products. The rates of destruction of the individual carotenoids differed; lycopene was destroyed most rapidly and lutein most slowly. Upon oxidation of β-carotene-enriched LDL, the rates of destruction of β-carotene, lycopene, and lutein were slowed and the lag times before the initiation of lipid peroxidation increased from 19 to 65 min. Neither effect was observed in LDL enriched with lutein or lycopene. Thus, β-carotene was unique among the carotenoids studied in having a small, but significant effect on LDL oxidation in vitro.     

Cyclization of lycopene in the biosynthesis of β-carotene

Mycobacterium marinum produces carotenoids when exposed to light or when antimycin A is added. Although the major pigment synthesized is β-carotene, lycopene is accumulated when the induced bacteria are incubated in the presence of nicotine (5 mM) or 2-(4-chlorophenylthio)-triethylamine hydrochloride (CPTA) (50 μM). Both of these compounds inhibit β-carotene synthesis by blocking the cyclization of lycopene. When nicotine is removed by washing the cells, the accumulated lycopene is cyclized to form β-carotene. The cyclization of lycopene is not an energy-requiring reaction and, furthermore, does not require oxygen or any other electron acceptor. Chloramphenicol addition also does not inhibit the conversion of lycopene to β-carotene indicating that no de novo protein synthesis is involved. Nicotine appears to act by inhibiting the activity of the enzyme required for the cyclization of lycopene.Although the mode of action of CPTA is similar to nicotine, it cannot be removed by washing once the cells have been incubated in its presence, suggesting that the molecule is tightly bound to the enzyme. The possible active molecular sites of nicotine and CPTA are discussed.     

Biosynthesis of plastoquinone and β-carotene in isolated chloroplasts

Intact, isolated spinach chloroplasts incorporated ¹⁴C from ¹⁴CO₂ into plastoquinone and β-carotene under photosynthetic conditions. Addition of unlabelled l-tyrosine, p-hydroxyphenylpyruvate, or homogentisate increased the incorporation of ¹⁴C into plastoquinone, but decreased that into β-carotene.