Variations in the carotenoid content of Chlamydomonas reinhardii throughout the cell cycle.

Synchronous cultures of Chlamydomonas reinhardii have been examined for the total amounts of carotenoid and chlorophyll present throughout a 12 hrs light -- 4 hrs dark life cycle. Variations in the carotenoid distribution at different points within the cell cycle have been found. During the greater part of the light period all major carotenoids increased at a proportionally similar rate. However, the increases in lutein and violaxanthin preceded those in beta-carotene and neoxanthin by some 2 hrs and that in loroxanthin, and algal xanthophyll, by abour 3 hrs. A marked drop in total carotenoid accumulation, corresponding to similar temporary falling away in the accumulation of beta-carotene, lutein and violaxanthin occurred at 9 hrs. The correspondence of this with the established drop in RNA accumulation and the break-up of the nucleolus was pointed out. Considerable redistribution among the carotenoids occurred during the dark period, notably the amount of beta-carotene increased relative to the total xanthophylls. The full significance of these results can not be estimated in the absence of comparative data on related organisms.     

Regulatory control of carotenoid accumulation in winter squash during storage

Main conclusion

Storage promotes carotenoid accumulation and converts amylochromoplasts into chromoplasts in winter squash. Such carotenoid enhancement is likely due to continuous biosynthesis along with reduced turnover and/or enhanced sequestration. Postharvest storage of fruits and vegetables is often required and frequently results in nutritional quality change. In this study, we investigated carotenoid storage plastids, carotenoid content, and its regulation during 3-month storage of winter squash butternut fruits. We showed that storage improved visual appearance of fruit flesh color from light to dark orange, and promoted continuous accumulation of carotenoids during the first 2-month storage. Such an increased carotenoid accumulation was found to be concomitant with starch breakdown, resulting in the conversion of amylochromoplasts into chromoplasts. The butternut fruits contained predominantly β-carotene, lutein, and violaxanthin. Increased ratios of β-carotene and violaxanthin to total carotenoids were noticed during the storage. Analysis of carotenoid metabolic gene expression and PSY protein level revealed a decreased expression of carotenogenic genes and PSY protein following the storage, indicating that the increased carotenoid level might not be due to increased biosynthesis. Instead, the increase likely resulted from a continuous biosynthesis with a possibly reduced turnover and/or enhanced sequestration, suggesting a complex regulation of carotenoid accumulation during fruit storage. This study provides important information to our understanding of carotenogenesis and its regulation during postharvest storage of fruits.     

Carotenoids of Eriobotrya japonica

The carotenoids of the loquat fruit Eriobotrya japonica Golden Nugget variety, were investigated. They were identified according to their chromatographic, spectrophotometric and chemical properties and compared with standard pigments. For some of the carotenoids, MS were determined. Pulp and peels were investigated separately. The main pattern of the pulp carotenoids was β-carotene (33%), γ-carotene (6%), cryptoxanthin (22%), lutein, violaxanthin and neoxanthin, each about 3–4%. The peel, with a carotenoid content 5 times as high, had a similar pattern, but the ratio between the main pigments differed: β-carotene (50%); γ-carotene (5%); cryptoxanthin (5%); lutein (13%); violaxanthin, neoxanthin, 3–4%. The carotenoids of the loquat (subfamily Maloideae) were very similar to those of the apricot (Prunus armeniaca-subfamily Prunoideae) both of the family of Rosaceae. The intergeneric differences are more pronounced, which is of possible taxonomic significance. The lower concentration of cryptoxanthin and the high concentration of lutein in the peels is noteworthy and of biosynthetic interest.     

Changes in the Carotenoid Pattern During the Synchronous Life Cycle of Scenedesmus

The wild type (WT) of Scenedesmus obliquus and a mutant lacking chlorophyll b and the light-harvesting complexes (WT-LHC₁) were synchronized by a light-dark regime. Both cultures contained the same type of carotenoids. However, concentrations and patterns of carotenoids were different during their synchronous life cycles. The concentration of total carotenoids followed more or less that of chlorophyll. The WT contained more carotenoids per cell mass, but slightly less per chlorophyll. It is discussed that part of the carotenoids of the mutant, lacking the peripheral antenna of PSII, might be located in the chlorophyll b-less apoprotein or in an enlarged core antenna of PSII. During the life cycle of Scenedesmus the carotenes are initially synthesized and most of the α-carotene is immediately oxidized to lutein which is inserted in the antennae systems of PSII and PSI. The further oxidation of lutein to loroxanthin seems to depend on both the change from dark to light, and on stages of the life cycle itself. Although the major part of β-carotene appears to be inserted in the reaction centers, a fraction of the total pool is rapidly converted to violaxanthin, following the onset of illumination. The conversion may serve to protect against photooxidation. Further conversion of violaxanthin to neoxanthin occurs to a greater extent in the mutant, WT-LHC₁. The results demonstrate (1) the close connection between the carotenoid pattern and the modulation of the photosynthetic apparatus during the life cycle of Scenedesmus and (2) the flexibility of the organism in compensating for the absence of the light-harvesting complexes of photosystems II by adjusting the carotenoid distribution.     

Enhancement of carotenoid biosynthesis in the green microalga Dunaliella salina with light-emitting diodes and adaptive laboratory evolution

There is a particularly high interest to derive carotenoids such as β-carotene and lutein from higher plants and algae for the global market. It is well known that β-carotene can be overproduced in the green microalga Dunaliella salina in response to stressful light conditions. However, little is known about the effects of light quality on carotenoid metabolism, e.g., narrow spectrum red light. In this study, we present UPLC-UV-MS data from D. salina consistent with the pathway proposed for carotenoid metabolism in the green microalga Chlamydomonas reinhardtii. We have studied the effect of red light-emitting diode (LED) lighting on growth rate and biomass yield and identified the optimal photon flux for D. salina growth. We found that the major carotenoids changed in parallel to the chlorophyll b content and that red light photon stress alone at high level was not capable of upregulating carotenoid accumulation presumably due to serious photodamage. We have found that combining red LED (75 %) with blue LED (25 %) allowed growth at a higher total photon flux. Additional blue light instead of red light led to increased β-carotene and lutein accumulation, and the application of long-term iterative stress (adaptive laboratory evolution) yielded strains of D. salina with increased accumulation of carotenoids under combined blue and red light.     

DIEL CHANGES IN THE COMPOSITION OF PHOTOSYNTHETIC PIGMENTS AND CELLULAR CARBON AND NITROGEN IN CHATTONELLA ANTIQUA (RAPHIDOPHYCEAE)1

An axenic clonal culture of Chattonella antiqua (Hada) Ono was grown on a 12: 12 h LD cycle in a laboratory culture tank containing 1 m³ of f/2 medium. Diel changes in mean cell volume, cellular carbon (carbon content per cell), C/N ratio, cellular Chl a, Chl a/c ratio and carotenoid composition were observed. Mean cell volume and cellular C, N and pigments increased during the light period as a result of photosynthesis and decreased with increase of cell concentration by phased cell division during the dark period. These changes indicated that carbon assimilation and pigment synthesis occurred together during the light period. However, the patterns of increase were not the same since different diel patterns were also found in the ratios of C/N and chl a/c. Photosynthetic pigments were analyzed by reversed-phase high-performance liquid chromatography with ion-pairing solution. This analysis showed that the dominant carotenoids in C. antiqua were fucoxanthin, violaxanthin and β-carotene. Diel patterns of Chls a and c were similar to that of fucoxanthin but different from those of violaxanthin and β-carotene. The cellular contents of Chl a, fucoxanthin and carbon increased in a parallel manner during the light period. On the other hand, the increase of violaxanthin was restricted to only a few hours at the beginning of the light period during cell division cycles.     

The effects of temperature and light on the carotenoids of seedlings grown from three corn hybrids

Seedlings of three corn hybrids, U. S. 13, Indiana 252, and Indiana 909, were subjected to eight different sets of environmental conditions, and the relative proportions of lutein, β-carotene, violaxanthin, neoxanthin, and zeaxanthin were determined. No significant differences occurred between hybrids, but markedly significant differences were observed between environmental conditions. High light intensity and low temperatures tended to favor the accumulation of zeaxanthin. Changes in this pigment were often approximately equal and opposite to simultaneous changes in β-carotene. This suggested that these two pigments were either interconvertible or formed from a common precursor. Similar interrelationships were observed between lutein and violaxanthin. The results obtained support the interesting possibility that the carotenoids are chemically involved in metabolic functions in green leaves. It is suggested that the techniques developed provide a useful approach for future investigations on the physiological role of the carotenoids in leaves.     

Characterization of the Xanthophyll Cycle and Other Photosynthetic Pigment Changes Induced by Iron Deficiency in Sugar Beet (Beta vulgaris L.)

In this work we characterize the changes induced by iron deficiency in the pigment composition of sugar beet (Beta vulgaris L.) leaves. When sugar beet plants were grown hydroponically under limited iron supply, neoxanthin and β-carotene decreased concomitantly with chlorophyll a, whereas lutein and the carotenoids within the xanthophyll cycle were less affected. Iron deficiency caused major increases in the lutein/chlorophyll a and xanthophyll cycle pigments/chlorophyll a molar ratios. Xanthophyll cycle carotenoids in Fe-deficient plants underwent epoxidations and de-epoxidations in response to ambient light conditions. In dark adapted Fe-deficient plants most of the xanthophyll cycle pigment pool was in the epoxidated form violaxanthin. We show, both by HPLC and by in vivo 505 nanometers absorbance changes, that in Fe deficient plants and in response to light, the de-epoxidated forms antheraxanthin and zeaxanthin were rapidly formed at the expense of violaxanthin. Several hours after returning to dark, the xanthophyll cycle was shifted again toward violaxanthin. The ratio of variable to maximum chlorophyll fluorescence from intact leaves was decreased by iron deficiency. However, in iron deficient leaves this ratio was little affected by light conditions which displace the xanthophyll cycle toward epoxidation or de-epoxidation. This suggests that the functioning of the xanthophyll cycle is not necessarily linked to protection against excess light input.     

Changes in the pigment patterns and the photosynthetic activity during a light-induced cell cycle of the green alga Scenedesmus armatus

The photosynthetic oxygen evolution as well as the chlorophyll and carotenoid patterns were studied during the light phase (14 h) of the Scenedesmus armatus cell cycle. The alga was synchronised by the light/dark regime (14/10 h). In this publication, the term “cell cycle” refers to this period of light only. The oxygen evolution measured by a Clark-type electrode and expressed per cell, gradually increased from the beginning of the cell cycle, reaching its maximum at 12 h and then slowly declined towards the end of the cell cycle. This pattern reflects the final reproductive events of the cell cycle consisting of the third mitotic division, chloroplast and protoplast fission, followed by the formation of the autospores. When the same amount of oxygen was expressed per chlorophyll a content, we observed a rapid increase just after the onset of light, which reached a maximum at the third hour, after which, this slowly declined until the end of the cell cycle. A similar pattern for the relative quantum yield of oxygen evolution was obtained when a photobaric component of a photoacoustic signal was analysed by the photoacoustic spectroscopy method. The most abundant carotenoid was lutein. Much smaller amounts of α-carotene, β-carotene, loroxanthin, violoxanthin and neoxanthin were noted; traces of zeaxanthin and antheraxanthin were also identified. The photosynthetic efficiency and the ratio of lutein/α-carotene followed the same patterns during the cell cycle and similar relationships were also observed in the ratio changes of violoxanthin/β-carotene and violoxanthin/neoxanthin. The most photosynthetic-efficient cells contained the highest level of lutein, and had a much lower violoxanthin content. The content of neoxanthin and β-carotene found was lower, with both pigments still being present in similar amounts. These results suggest that the molecular organisation of LHC IIb mainly determined the photosynthetic efficiency of algae during its light-induced cell cycle.     

Carotenoid Synthesis in Leaves of Etiolated Wheat Seedlings after Varying Light and Dark Treatments

A short impulse of red light has a varying effect on carotenoid synthesis in dark-grown wheat seedlings. Except for β-carotene, which remains unchanged in the dark (it increases in continuous light), the carotenoid synthesis shows the same tendency as during constant irradiation. Thus, lutein and neoxanthin slowly increases, while violaxanthin decreases. During a period of constant light following various periods of darkness after the short impulse of light, the pigment changes correspond to those occurring in the dark, but are much more pronounced. The changes are discussed on the basis of phytochrome action.     

Photosynthetic Characteristics and the Ratios of Chlorophyll, β-Carotene,and the Components of the Xanthophyll Cycle Upon a Sudden Increase in Growth Light Regime in Several Plant Species*

Among three species, Gossypium hirsutum, Rhizophora mangle, and Monstera deliciosa, which were transferred from low to high growth PFD, only small decreases in the efficiency of photochemical energy conversion were observed in those plants which exhibited an increase in photosynthetic capacity. Leaves of plants which showed no increase in photosynthetic capacity experienced a continuous decrease in photochemical efficiency, accompanied by a more pronounced loss of chlorophyll than that observed in the former group. In all species marked increases in the xanthophyll/β-carotene ratio resulted from small increases in lutein, and several-fold increases in the sum of the three components of the xanthophyll cycle, zeaxanthin, antheraxanthin, and violaxanthin. A strong increase in the level of zeaxanthin was only partially matched by a decrease of violaxanthin to zero, and was further paralleled by a decrease in β-carotene. Antiparallel changes in the sum of zeaxanthin + antheraxanthin + violaxanthin and β-carotene between morning and evening were observed in all species. These diel changes were overlaid on a net increase in β-carotene as well as total carotenoid content in those plants in which photosynthetic capacity increased. In those, however, which exhibited no photosynthetic acclimation upon transfer to high light, a decrease in both β-carotene and total carotenoid content was observed. Rhizophora mangle grown at 100 % seawater exhibited a particularly high capacity for increasing the level of zeaxanthin in response to high light.     

Effects of light intensity and quality on the growth rate and photosynthetic pigment content of Spirulina platensis

The quantitative and qualitative effects of light on carotenoid production by Spirulina were studied. Maximum total carotenoid production was measured in cells grown under white light at an irradiance of 432 μmol photon m^?2 s^?1, the onset of light saturation for this organism as determined by growth rates. A true maximum may exist at irradiances above 1500 μmol photon m^?2 s^?1 under white light. Individual carotenoids responded differently to light conditions. Under white light, β-carotene and echinenone were most abundant at the lowest and highest irradiance levels tested. Myxoxanthophyll and lutein/zeaxanthin did not change over the same irradiance range. Under red and blue light, we found decreased values of myxoxanthophyll, while β-carotene increased and lutein/zeaxanthin and echinenone showed little change. In general, maximum carotenoid production requires optimization of the culture conditions that favor growth.     

Changes in the chlorophylls and carotenoids of leaves of Nicotiana tabacum during senescence

In addition to chlorophylls a and b, β-carotene, lutein, violaxanthin and neoxanthin, leaves of tobacco (Nicotiana tabacum L. cv. Virginia Gold) contain antheraxanthin in some harvests. In lower leaves, chlorophylls decreased more rapidly than carotenoids during senescence, but both types of pigment decreased at equal rates in upper leaves. The chlorophyll a:b ratio decreased only in post-mature leaves. Total carotenoid decreased with age, with the relative proportion of β-carotene increasing in lower leaves. Seasonal influences rather than age of leaf determines whether antheraxanthin is present. No esterified xanthophylls were found in senescent leaves.     

Effects of light and nitrogen starvation on the content and composition of carotenoids of the green microalga <Emphasis Type="Italic">Parietochloris incisa</Emphasis>

The changes in pigment content and composition of the unicellular alga Parietochloris incisa comb. nov (Trebouxiophyceae, Chlorophyta) were studied. This alga is unique in its ability to accumulate high amounts of arachidonic acid in the cell during cultivation under different irradiances and nitrogen availability in the medium. Under low irradiance of 35 μE/(m₂ s) photosynthetically active radiation the P. incisa cultures possessed slow growth and a relatively low carotenoid-to-chlorophyll ratio. At higher irradiances (200 and 400 μE/(m₂ s)) on complete medium, the alga displayed higher growth rate and an increase in the carotenoid content, especially that of β-carotene and lutein. Both on nitrogen-free (regardless of illumination intensity) and nitrogen-replete medium (under high light), a considerable increase in the ratio of carotenoid and chlorophyll contents was recorded. Predominant accumulation of xanthophylls took place in thylakoid membranes, whereas β-carotene deposition occurred mainly in the cytoplasmic lipid globules (oil bodies); lower amounts of carotenoids were accumulated in the absence of nitrogen. Under high light and nitrogen-deficiency conditions, an increase in violaxanthin de-epoxidation and nonphotochemical quenching was recorded together with a decline in variable chlorophyll fluorescence (F _v/F _m) level. A possible photoprotective role of carotenoids in adaptation of P. incisa to high light under nitrogen starvation conditions is discussed.     

Die rolle der Carotinoide und des Gallenfarbstoffs bei der Farbmodifikation der Puppen von Pieris brassicae

The carotenoids and the bile pigment in larvae and pupae of Pieris brassicae were analysed. Their rôle in the morphological colour adaptation of the pupae was studied by quantitative measurements.The carotenoids are β-carotene, lutein mono-ester, free lutein, and zeaxanthin. Metabolized carotenoids were not found. There are no differences between pupae showing different grades of melanization in the quality of the carotenoids, or in the total amounts, or in the relative portions of each carotenoid fraction. However, the carotenoid content of the integument alone is twofold in the light pupae as compared to dark ones. The integumental carotenoids are deposited mainly in the epidermis. β-Carotene, lutein, and zeaxanthin are selectively absorbed by the larvae from the diet. β-Carotene and lutein ester are localized mainly in the fat body, whereas lutein is predominant in the haemolymph and in the integument.The pupal bile pigment is protobiliverdin-IXγ (pterobilin), which is also known to be the larval pigment. The bile pigment is synthesized mainly during the last larval instar up to the pharate pupal stage. In the pupae the bile pigment content is related to the melanization: pupae exposed to the same light conditions contain less bile pigment the more melanized they are (negative correlation). On the whole there is a strong enhancement by blue light of the bile pigment content besides the known stimulation of melanization (positive correlation). But within such a sample the negative correlation between the amounts of bile pigment and melanin is maintained.     

Enhancing the carotenoid content of <Emphasis Type="Italic">Brassica napus</Emphasis> seeds by downregulating lycopene epsilon cyclase

The accumulation of carotenoids in higher plants is regulated by the environment, tissue type and developmental stage. In Brassica napus leaves, beta-carotene and lutein were the main carotenoids present while petals primarily accumulated lutein and violaxanthin. Carotenoid accumulation in seeds was developmentally regulated with the highest levels detected at 35-40 days post anthesis. The carotenoid biosynthesis pathway branches after the formation of lycopene. One branch forms carotenoids with two beta rings such as beta-carotene, zeaxanthin and violaxanthin, while the other introduces both beta- and epsilon-rings in lycopene to form alpha-carotene and lutein. By reducing the expression of lycopene epsilon-cyclase (epsilon-CYC) using RNAi, we investigated altering carotenoid accumulation in seeds of B. napus. Transgenic seeds expressing this construct had increased levels of beta-carotene, zeaxanthin, violaxanthin and, unexpectedly, lutein. The higher total carotenoid content resulting from reduction of epsilon-CYC expression in seeds suggests that this gene is a rate-limiting step in the carotenoid biosynthesis pathway. epsilon-CYC activity and carotenoid production may also be related to fatty acid biosynthesis in seeds as transgenic seeds showed an overall decrease in total fatty acid content and minor changes in the proportions of various fatty acids.     

Carotenoids in sixty-six representatives of the Pteridophyta

The presence of 27 carotenoids was determined in the Pteridophyta. The carotenoids characteristic of club-moss and horsetail species are β-carotene, β-cryptoxanthin, lutein epoxide and zeaxanthin, and fern species are β-cryptoxanthin, lutein epoxide, zeaxanthin, violaxanthin and rhodoxanthin.     

Control of Light-Induced Carotenoid Synthesis in Raphanus Seedlings by Phytochrome

The effect of short pulses of red and or far-red light on the formation of individual carotenoids was tested in etiolated radish seedlings (Raphanus sativus L.). Red light induces an enhanced synthesis of β-carotene, lutein. violaxanthin and neoxanthin, while the level of antheraxanthin is decreased. Far-red light reverses the red light effects to the level of the far-red light control. The data indicate that in radish seedlings active phytochrome P_fr initiates the light-induced carotenoid synthesis, which is bound to thylakoid formation.     

Primary and Secondary Carotenoids of Spongiochloris typica

A qualitative and quantitative investigation was made of the pigments of Spongiochloris typica over an 8 week period. The pigments were chromatographed on thin layers of sucrose and measured spectrophotometrically. Pigments present after 1 week of growth were identified as chlorophylls a and b, β-carotene, lutein, zeaxanthin, violaxanthin, trollein, and neoxanthin. In cultures 2 weeks or more old, secondary carotenoids appeared. These were echinenone, canthaxanthin, astacene, and an unidentified ketocarotenoid. Carotenoids comprised nearly 100 percent of the total pigment composition on the 8th week. About 75 percent of the carotenoid fraction on the 8th week consisted of secondary carotenoids.     

Relationships between carotenoid composition and growth habit in British plant species

The pigment composition of leaves from a number of different plant species collected from field sites in the region of Sheffield, UK, have been compared using high-performance liquid chromatography. Expression of pigment content per unit leaf area was dominated by variation in the total leaf chlorophyll. Neither chlorophyll per unit area nor the chlorophyll a/b ratio were found to be correlated with the habitat from which the plants originated. When the amounts of different carotenoids were expressed relative to the total carotenoid pool, it was found that whilst neither total carotene (α- +β-carotene) nor neoxanthin correlated with ability to grow in shade, the leaf content of both lutein and the total xanthophyll cycle carotenoids (zeaxanthin, anther-axanthin and violaxanthin) did, with lutein content being high in shade species and xanthophyll cycle intermediates low. There was a strong negative correlation between the relative amounts of each of these groups of carotenoids. The ratio of lutein to xanthophyll cycle carotenoids was strongly correlated to an index of shade tolerance.