Anthocyanin, Carotenoid, and Chlorophyll Changes in the Peel of Cox's Orange Pippin Apples during Ripening on and off the Tree

The concentrations of various peel pigments of Cox’s OrangePippin apples have been measured during ripening on the treeand during storage at 12 °C. Total chlorophyll decreased and total carotenoid increased atthe time of the respiration climacteric. These changes weremore pronounced in fruit maturing on the tree where a significantincrease of anthocyanin occurred; it did not occur in storedfruit. There was no consistent or marked difference in the ratesof destruction of chlorophylls a and b. The carotenoids found in the unripe fruit were those characteristicof photosynthetic tissue, ß-carotene, lutein, violaxanthin,and neoxanthin. These decreased to a greater or lesser extent,and at different rates, on and off the tree. Other carotenoidswhich increased greatly during ripening were identified as esters,mainly of violaxanthin. During the climacteric there is a transition from an assemblageof pigments associated with the chloroplast to that typicalof a chromoplast.     

Consequences of chlorophyll deficiency for leaf carotenoid composition in tobacco synthesizing glutamate 1-semialdehyde aminotransferase antisense RNA: dependency on developmental age and growth light

Transgenic tobacco (Nicotiana tabacum), with a reduced chlorophyll content of up to less than 10% of the wild-type level due to a different expression of antisense RNA coding for glutamate 1-semialdehyde aminotransferase, were used to study the relationship between chlorophyll accumulation and changes in carotenoid composition in developing and mature leaves grown either under low (30 mol photons m^-2 s^-1) or high light (300 mol photons m^-2 s^-1). Regardless of the extent to which chlorophyll synthesis was reduced, under low light the ratios of total chlorophyll to carotenoids remained constant. In contrast, under high light the content of carotenoids was elevated relative to chlorophyll and increased further with progressive inhibition in chlorophyll synthesis. The xanthophyll-cycle pigment pool was most strongly increased (up to 18-fold) upon suppression of chlorophyll synthesis. Concurrently to the higher pool sizes a higher extent of violaxanthin was converted into antheraxanthin and zeaxanthin and this was found to be correlated with a decrease in the quantum yield of photosystem II photochemistry. While lutein increased (up to 3-fold) with decreasing chlorophyll contents in high light transformants, neoxanthin remained rather constant in all plants analysed. Based on the present results, two different levels for the regulation of carotenoid synthesis are proposed depending on (I) the chlorophyll synthesizing capacity, and (ii) the photosynthetic light utilization efficiency. The first point suggests a co-regulation between carotenoid and chlorophyll synthesis; the second emphasizes the special role of carotenoids for protection against light stress.     

In vivo chlorophyll forms in higher plants and algae sensitive to treatment with lutein

Lamella preparations of spinach, Chlorella, Phaeodactylum, Anabatnaand Porphyra were treated with a hydrophobic reagent, lutein,and the absorption and fluorescence spectra in the red regionbefore and after treatment were compared for changes causedby the treatment. Absorption spectra of all these preparationsunderwent the same spectral change, transformation of a bandat 684 nm into a band at 666 nm. The longer the maximum wavelengthof the red peak, the greater was the fractional absorbance decreaseat 684 nm. The content of C684 (the chlorophyll form responsiblefor the 684 nm band) in the lamellae was estimated from thefractional decreases as being progressively higher in the orderof Phaeodactylum, Porphyra, Anabatna, Chlorella and spinach.The fluorescence spectra at liquid nitrogen temperature beforetreatment showed two bands. The longer wavelength band was transformedby the treatment into a shorter wavelength band(s), as describedbelow, according to the maximum wavelengths: spinach, F735F695(or F686); Chlorella, F715F700 (or F686); Phaeodactylum, anunidentified componentF690; Anabaena, F732F685 (or F695); Porphyra,F726F683. These chlorophyll forms with fluorescence maxima between715 and 735 nm were, therefore, designated C684 based on absorptionspectrophotometry, and are considered to play a role in photosystemII. (Received August 15, 1972; )     

Effects of light quality on chlorophyll-forms Ca 684, Ca 690 and Ca 699 of the diatom Phaeodactylum tricornutum

Colored light modifies the relative concentration of chlorophyll-forms of the diatom Phaeodactylum tricornutum compared to white-light control. No change in the ratio carotenoids/chlorophylls was observed after 4 days exposure to green light (max: 530 nm), blue light (max: 470 nm) or red light ( > 650 nm) of same intensity.However, the absorption spectra were modified, the content in Ca 684, Ca 690, Ca 699 forms increased in red and green light cultures and photosynthetic unit size of PS II decreased by 30% in green and blue light cultures.Fluorescence emission and fluorescence excitation spectra according to the Butler and Kitajima method (1975) were carried out for each culture. Ca 669 form was predominant in the two photosystems. The newly appeared far red forms fluoresce at 715 nm like PS I forms.We conclude that these new forms originated in a rearrangement of PS II forms. They do not transmit excitation energy to reaction center of PS I and are disconnected from the other chlorophyll-forms of the photosynthetic antennae.Abbreviations ABS absorption - Ca chlorophyll-complex - chla chlorophyll a - chl c chlorophyll c - chl t total chlorophylls - D.C.M.U. 3-(3, 4 dichlorophenyl) 1-diméthyl-urea - d^v division - F fluorescence - PS I and PS II photosystem I and photosystem II     

Room temperature photooxidation of β-carotene and peripheral chlorophyll in photosystem II reaction centre

Differential kinetic absorption spectra were measured during actinic illumination of photosystem II reaction centres and core complexes in the presence of electron acceptors silicomolybdate and ferricyanide. The spectra of samples with ferricyanide differ from those with both ferricyanide and silicomolybdate. Near-infrared spectra show temporary beta-carotene and peripheral chlorophyll oxidation during room temperature actinic illumination. Peripheral chlorophyll is photooxidized even after decay of beta-carotene oxidation activity and significant reduction of beta-carotene content in both reaction centres and photosystem II core complexes. Besides, new carotenoid cation is observed after about 1 s of actinic illumination in the reaction centres when silicomolybdate is present. Similar result was observed in PSII core complexes. HPLC analyses of illuminated reaction centres reveal several novel carotenoids, whereas no new carotenoid species were observed in HPLC of illuminated core complexes. Our data support the proposal that pigments of inner antenna are a sink of cations originating in the photosystem II reaction centre.     

Effects of sulfur limitation on photosystem II functioning in Chlamydomonas reinhardtii as probed by chlorophyll a fluorescence

Chlorophyll fluorescence methods were applied to probe in vivo photosystem II (PSII) function in Chlamydomonas reinhardtii grown in sulfur-depleted media under aerobic conditions. The rates of oxygen evolution and     dark reduction decreased during a 24-h incubation in sulfur-deficient medium, while the respiration rate increased. The analysis of chlorophyll fluorescence induction curves suggests that electron transport was perturbed on both the acceptor and donor sides of PSII. Light-induced violaxanthin de-epoxidation and non-photochemical fluorescence quenching were suppressed, owing to dark accumulation of zeaxanthin. Also sulfur-deprived cells showed elevated concentrations of violaxanthin and lutein. Sulfur deprivation stimulated a pronounced (three- to four-fold) increase in chlorophyll a fluorescence intensity (parameters F_o and F_m), probably due to greater light absorption by carotenoids and changes in the excitation energy transfer and deactivation in PSII of C. reinhardtii .     

Observations on pigments and morphology of Gyrodinium aureolum Hulburt, a marine dinoflagellate containing 19' -hexanoyloxyfucoxanthin as the main carotenoid

Gyrodinium aureolum, a common "red tide" dinoflagellate in Europeanwaters often associated with fish mortality, was isolated fromthe Oslofjord, Norway, and analysed for chlorophylls and carotenoids.Besides chlorophyll a and c the following carotenoids were characterizedby thin-layer chromatography, visible light spectrophotometryand mass spectrometry: ß,-carotene, ß,ß-carotene,djatoxanthin, diadinoxanthin, 19'-hexanoyloxyfucoxanthin and3 xanthophylls which could not be correlated with hitherto structurallyknown carotenoids from dinoflagellates. G. aureolum deviatesfrom most dinoflagellates by the lack of peridinin, but showsaffinity with Gyrodinium sp.-A by the possession of 19'-hexanoyloxyfucoxanthin. Preliminary light microscopical observations on the internalstructure indicate that G. aureolum is uni-nucleate with a typicaldinokaryotic nucleus containing continually condensed chromosomes.The chloroplasts seem to possess an internal pyrenoid like someother dinoflagellates with deviating carotenoid pigmentation.The similarity in carotenoid pigmentation and chloroplast structureof Emiliania huxleyi (Prymnesiophyceae) and Gyrodinium sp.-Aand G.aureolum (Dinophyceae) is pointed out. The potential chemotaxonomicvalue of the carotenoid composition in establishing identitywith morphologically similar and ichthyotoxic dinoflagellatesis briefly discussed.     

Resonance Raman spectroscopy of carotenoids in Photosystem I particles

Low-temperature resonance Raman (RR) spectroscopy was used for the first time to study the spectral properties, binding sites and composition of major carotenoids in spinach Photosystem I (PSI) particles. Excitation was provided by an argon ion laser at 457.9, 476.5, 488, 496.5, 502 and 514.5 nm. Raman spectra contained the four known groups of bands characteristic for carotenoids (called from nu(1) to nu4). Upon 514.5, 496.5 and 476.5 nm excitations, the nu(1)-nu(3) frequencies coincided with those established for lutein. Spectrum upon 502-nm excitation could be assigned to originate from violaxanthin, at 488 nm to 9-cis neoxanthin, and at 457.9 nm to beta-carotene and 9-cis neoxanthin. The overall configuration and composition of these bound carotenoid molecules in Photosystem I particles were compared with the composition of pigment extracts from the same PSI particles dissolved in pyridine, as well as to configuration in the main chlorophyll a/b light-harvesting protein complex of photosystem II. The absorption transitions for lutein, violaxanthin and 9-cis neoxanthin in spinach photosystem I particles are characterized, and the binding sites of lutein and neoxanthin are discussed. Resonance Raman data suggest that beta-carotene molecules are also present in all-trans and, probably, in 9-cis configurations.     

Herbicides which inhibit photosystem II or produce chlorosis and their effect on production and transformation of pigments in etiolated radish seedlings (Raphanus sativus)

Abstract The herbicides DCMU, bentazon, amitrole, and SAN 6706 were tested for their ability to influence the carotenoid and pro-tochlorophyll(ide) composition as well as the protochloro-phyll(ide) phototransformation and the Shibata shift in dark-grown radish seedlings (Raphanus sativus L. cv. Saxa Treib). Bentazon enhanced the formation of lutein and carotenes, while SAN 6706 suppressed the biosynthesis of carotenoids. Amitrole led to a reduced accumulation of phototransformable pro-tochlorophyll(ide). The phototransformation of pro-tochlorophyll(ide) and the Shibata shift were not affected by any of the tested herbicides, irrespective of the presence or absence of activated phytochrome. From this we conclude that herbicides inhibiting photosystem II or producing chlorosis partly affect, but do not block, carotenoid and chlorophyll biosynthesis in dark-grown plants. The main herbicide effect becomes visible only after prolonged illumination.     

Photosynthetic enhancement spectra in higher plants

Enhancement spectra for photosynthesis of intact leaves of higherplants were investigated by means of the rate of CO₂ absorptionunder atmospheric conditions. Enhancement spectra for photosystem(system)II measured with a reference beam of 700 nm had twopronounced peaks at about 480 and 650 nm and lower humps at540–600 nm in all of the nine species tested. By the useof a rice mutant which lacks chlorophyll b, it was revealedthat the 650-nm peak and the middle humps in the spectrum canbe attributed mostly to chlorophyll b absorption, whereas the480-nm peak must be due to the absorption of carotenoids andchlorophyll b. Enhancement for system I in wheat had a peakat about 715 nm, and the maximum was much higher than that ofthe enhancement for system II. Enhancement between a red anda farred light for wheat was much greater for the farred lightthan for the red light in the presence of an excess amount ofthe other light. These results demonstrate that the enhancementphenomenon in higher plants is essentially the same as thatin green algae. (Received November 30, 1977; )     

Changes in the carotenoid composition of chloroplast membranes from Chlamydomonas reinhardtii double mutants with alterations of various sites in photosystem II

The variable fluorescence and polypeptide and carotenoid compositions of the chlorophyll b-deficient mutant C-48 of the unicellular green alga Chlamydomonas reinhardtii and its double mutants without chlorophyll b and with inactive photosystem II were compared with those of the wild-type algal cells. Studying variable fluorescence demonstrated the alterations at the donor side (AC-121), the acceptor side (AC-234) or immediately in the photosystem II reaction centre (AC-184, AC-864). Gel electrophoresis showed that the absence of chlorophyll b in all mutants was due to the lack of 26, 28 and 31 kDa polypeptides in the light-harvesting chlorophyll a/b-protein complex II (LHC II). As a result of the second mutation, the chlorophyll a-protein complex of photosystem II did not form in chloroplast membranes. The disassembly of this complex in the mutants AC-121, AC-234 and AC-864 was related to the deficiency of both polypeptides of the reaction centre (30 and 32 kDa) and polypeptides of the water-oxidizing system (18, 23 and 34 kDa). Besides the loss of these polypeptides, the contents of polypeptides with molecular masses of 47 and 51 kDa decreased in the double mutant AC-184. Substantial changes were revealed in the carotenoid composition of the double mutants. We observed the considerable accumulation of carotenes that accompanied alterations in the donor (mutant AC-121) or acceptor (mutant AC-234) sides of PS II. In the first case, beta-carotene predominantly accumulated (87%); in the second case, it was alpha-carotene (52%). Alterations in the PS II reaction centre (mutants AC-184, AC-864) caused accumulation of xanthophylls, mainly lutein (38-41%). We suppose that alterations in different parts of the PS II chloroplast membrane lead to substantial changes in the carotenoid composition.     

The functional significance of the monomeric and trimeric states of the photosystem II light harvesting complexes

The main light harvesting complex of photosystem II in plants, LHCII, exists in a trimeric state. To understand the biological significance of trimerization, a comparison has been made been LHCII trimers and LHCII monomers prepared by treatment with phospholipase. The treatment used caused no loss of chlorophyll, but there was a difference in carotenoid composition, together with the previously observed alterations in absorption spectrum. It was found that, when compared to monomers, LHCII trimers showed increased thermal stability and a reduced structural flexibility as determined by the decreased rate and amplitude of fluorescence quenching in low-detergent concentration. It is suggested that LHCII should be considered as having two interacting domains: the lutein 1 domain, the site of fluorescence quenching [Wentworth et al. (2003) J. Biol. Chem. 278, 21845-21850], and the lutein 2 domain. The lutein 2 domain faces the interior of the trimer, the differences in absorption spectrum and carotenoid binding in trimers compared to monomers indicating that the trimeric state modulates the conformation of this domain. It is suggested that the lutein 2 domain controls the conformation of the lutein 1 domain, thereby providing allosteric control of fluorescence quenching in LHCII. Thus, the pigment configuration and protein conformation in trimers is adapted for efficient light harvesting and enhanced protein stability. Furthermore, trimers exhibit the optimum level of control of energy dissipation by modulating the development of the quenched state of the complex.     

Effects of chlorophyll a, chlorophyll b, and xanthophylls on the in vitro assembly kinetics of the major light-harvesting chlorophyll a/b complex, LHCIIb

The major light-harvesting chlorophyll a/b complex (LHCIIb) of photosystem II in higher plants can be reconstituted with pigments in lipid-detergent micelles. The pigment-protein complexes formed are functional in that they perform efficient internal energy transfer from chlorophyll b to chlorophyll a. LHCIIb formation in vitro, can be monitored by the appearance of energy transfer from chlorophyll b to chlorophyll a in time-resolved fluorescence measurements. LHCIIb is found to form in two apparent kinetic steps with time constants of about 30 and 200 seconds. Here we report on the dependence of the LHCIIb formation kinetics on the composition of the pigment mixture used in the reconstitution. Both kinetic steps slow down when the concentration of either chlorophylls or carotenoids is reduced. This suggests that the slower 200 seconds formation of functional LHCIIb still includes binding of both chlorophylls and carotenoids. LHCIIb formation is accelerated when the chlorophylls in the reconstitution mixture consist predominantly of chlorophyll a although the complexes formed are thermally less stable than those reconstituted with a chlorophyll a:b ratio < or = 1. This indicates that although chlorophyll a binding is more dominant in the observed rate of LHCIIb formation, the occupation of (some) chlorophyll binding sites with chlorophyll b is essential for complex stability. The accelerating effect of various carotenoids (lutein, zeaxanthin, violaxanthin, neoxanthin) on LHCIIb formation correlates with their affinity to two lutein-specific binding sites. We conclude that the occupation of these two carotenoid binding sites but not of the third (neoxanthin-specific) binding site is an essential step in the assembly of LHCIIb in vitro.     

Redox functions of carotenoids in photosynthesis

Carotenoids are well-known as light-harvesting pigments. They also play important roles in protecting the photosynthetic apparatus from damaging reactions of chlorophyll triplet states and singlet oxygen in both plant and bacterial photosynthesis. Recently, it has been found that beta-carotene functions as a redox intermediate in the secondary pathways of electron transfer within photosystem II and that carotenoid cation radicals are transiently formed after photoexcitation of bacterial light-harvesting complexes. The redox role of beta-carotene in photosystem II is unique among photosynthetic reaction centers and stems from the very strongly oxidizing intermediates that form in the process of water oxidation. Because of the extended pi-electron-conjugated system of carotenoid molecules, the cation radical is delocalized. This enables beta-carotene to function as a "molecular wire", whereby the centrally located oxidizing species is shuttled to peripheral redox centers of photosystem II where it can be dissipated without damaging the system. The physiological significance of carotenoid cation radical formation in bacterial light-harvesting complexes is not yet clear, but may provide a novel mechanism for excitation energy dissipation as a means of photoprotection. In this paper, the redox reactions of carotenoids in photosystem II and bacterial light-harvesting complexes are presented and the possible roles of carotenoid cation radicals in photoprotection are discussed.     

On the role of ß-carotene in the reaction center chlorophyll a antennae of photosystem I

Absorption and low temperature fluorescence emission spectra were measured on chloroplast thylakoids and on purified reaction center chlorophyll a-protein complexes of photosystem I, CP-a₁. A clear association between the presence of ß-carotene and the occurrence of far red absorbing and emitting chlorophyll a components of the reaction center antennae of photosystem I was demonstrated. For this study chloroplasts and CP-a₁ were obtained from normal and carotenoid deficient plant material of various sources. The experimental material included 1) lyophilized pea chloroplasts extracted with petroleum ether, 2) the carotenoid deficient mutant C-6E of Scenedesmus obliquus and 3) wheat chloroplasts derived from normal and SAN-9789 treated plants. Removal of carotenoids, most likely principally ß-carotene, caused a loss of long wavelength absorbing chlorophylls in chloroplasts and purified CP-a₁, and the loss or diminution of the long wavelength peak seen in the low temperature fluorescence emission spectrum. This association between ß-carotene and special chlorophyll a forms may explain both the photoprotective and antenna functions ascribed to ß-carotene. In the absence of carotenoids in wheat and in the Scenedesmus mutant, the chlorophyll a antenna of photosystem I was extremely photosensitive. A triplet-triplet resonance energy transfer from chlorophyll a to ß-carotene and a singlet-singlet energy transfer from excited ß-carotene to chlorophyll would explain the photoprotective and antenna functions, respectively. The role of this association in determining some of the fluorescence properties of photosystem I is also discussed.     

Carotenoid S(1) state in a recombinant light-harvesting complex of Photosystem II.

The carotenoid species lutein, violaxanthin, and zeaxanthin are crucial in the xanthophyll-dependent nonphotochemical quenching occurring in photosynthetic systems of higher plants, since they are involved in dissipation of excess energy and thus protect the photosynthetic machinery from irreversible inhibition. Nonetheless, important properties of the xanthophyll cycle carotenoids, such as the energy of their S(1) electronic states, are difficult to study and were only recently determined in organic solvents [Polívka, T. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 4914. Frank, H. A. (2000) Biochemistry 39, 2831]. In the present study, we have determined the S(1) energies of three carotenoid species, violaxanthin, lutein, and zeaxanthin, in their LHCII (peripheral light-harvesting complex of photosystem II) protein environment by constructing recombinant Lhcb1 (Lhc = light-harvesting complex) proteins containing single carotenoid species. Within experimental error the S(1) energy is the same for all three carotenoids in the monomeric LHCII, 13,900 +/- 300 cm(-1) (720 +/- 15 nm), thus well below the Q(y)() transitions of chlorophylls. In addition, we have found that, although the S(1) lifetimes of violaxanthin, lutein, and zeaxanthin differ substantially in solution, when incorporated into the LHCII protein, their S(1) states have in fact the same lifetime of about 11 ps. Despite the similar spectroscopic properties of the carotenoids bound to the LHCII, we observed a maximal fluorescence quenching when zeaxanthin was present in the LHCII complex. On the basis of these observations, we suggest that, rather than different photochemical properties of individual carotenoid species, changes in the protein conformation induced by binding of carotenoids with distinct molecular structures are involved in the quenching phenomena associated with Lhc proteins.     

Changes in Carotenoid Composition and Function of the Photosynthetic Apparatus during Light-dependent Chloroplast Differentiation in Mutant C-6D of Scenedesmus obliquus*

Changes in pigment composition during light-dependent chloroplast differentiation in mutant C-6D of Scenedesmus obliquus were followed by HPLC. The system used enables the separation and quantitative determination of five xanthophylls (neoxanthin, violaxanthin, antheraxanthin, lutein and zeaxanthin), α- and β-carotene and chlorophyll a and b (and their epimeric forms). Dark-grown cells of the mutant contain only chlorophyll a, traces of chlorophyll b and acyclic precursors of carotenoids. During subsequent illumination, precursors decrease and high amounts of xanthophylls, carotenes and chlorophyll a and b are formed. Dark-grown cultures of mutant C-6D show high photosystem I-activity and contain the photosystem I-complex CP I, but lack photosystem II-activity, the photosystem II-complex CPa and the LHCP. Immediately after transfer to light, photosystem II-activity increases rapidly, as also do the amounts of CPa and lutein. Under anaerobiosis no lutein and PS II-activity can be detected. This indicates a role of lutein in the assembly of an active photosystem II-complex. All other xanthophylls and the LHCP exhibit high rates of synthesis only after a delay of about 1 hour. Thus, our results reveal an asynchronous fashion of formation of CPa and LHCP.     

Carotenoid production and change of photosynthetic functions in Scenedesmus sp. exposed to nitrogen limitation and acetate treatment

Under stress conditions, some microalgae up-regulate certain biosynthetic pathways, leading to the accumulation of specific compounds. For example, changing nutrient composition can induce stress in algae’s physiological activities, which may trigger an intense increase in carotenoid production. In this study, the change of photosynthetic functions and carotenoid production in the green microalga Scenedesmus sp. was investigated when algal cultures were exposed to conditions including limited nitrogen content with the addition of sodium acetate. Microalgal cultures were treated for 18 days under higher irradiance conditions. We observed a decrease of chlorophyll content induced concomitantly with a decline of photosystem II and I photochemistry. At the same time, an important increase in carotenoid content was detected. By using high-performance liquid chromatographic analysis, we found that the secondary carotenoids astaxanthin and canthaxanthin were accumulated compared to controls. During the process of carotenoid accumulation, chlorophyll degradation was found in addition to a strong decrease in photosynthetic electron transport. Such changes may be associated with the structural reorganization of the photosynthetic apparatus and can be a useful indicator of secondary carotenoid accumulation in algal cultures.     

Accumulation of Pigments during the Greening of Etiolated Seedlings of Hordeum vulgare L.

The pigment changes that occur during transformation of etioplaststo fully developed chloroplasts have been studied in seedlingsof barley (Hordeum vulgare L.) by greening with white lightof low (15–25 µmol m^–2 s^–1) and medium(150 µmol m^–2 s^–1) intensity. At least 24h longer was required in the low light regime for the same concentrationof pigment to be accumulated in the seedlings. The increasein pigment content was mainly due to the synthesis of chlorophyllsa and b. Of the carotenoids present, the increases in the levelsof neoxanthin and, especially, ß-carotene were muchgreater than those observed for the other carotenoids. Levelsof lutein also increased but this change was small by comparisonto those observed for neoxanthin and ß-carotene. Inthe long-term the concentration of violaxanthin remained unalteredalthough significant transient changes were recorded. The levelsof antheraxanthin and zeaxanthin were markedly reduced duringgreening. The rate of pigment synthesis decreased with increasingcell age, i.e. from the base to the tip of the primary leaf.Overall, carotenoid levels increased by approximately 100% atthe base of the seedling but hardly at all at the tip. Key words: Hordeum vulgare, carotenoids, violaxanthin-cycle, etiolation     

Carotenoid photooxidation in photosystem II

Carotenoids are known to function as light-harvesting pigments and they play important roles in photoprotection in both plant and bacterial photosynthesis. These functions are also important for carotenoids in photosystem II. In addition, beta-carotene recently has been found to function as a redox intermediate in an alternate pathway of electron transfer within photosystem II. This redox role of a carotenoid in photosystem II is unique among photosynthetic reaction centers and stems from the very highly oxidizing intermediates that form in the process of water oxidation. In this minireview, an overview of the electron-transfer reactions in photosystem II is presented, with an emphasis on those involving carotenoids. The carotenoid composition of photosystem II and the physical methods used to study the structure of the redox-active carotenoid are reviewed. Possible roles of carotenoid cations in photoprotection of photosystem II are discussed.