1000 resultados para violaxanthin
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Plants need to avoid or dissipate excess light energy to protect photosystem II (PSII) from photoinhibitory damage. Higher plants have a conserved system that dissipates excess energy as heat in the light-harvesting complexes of PSII that depends on the transthylakoid delta pH and violaxanthin de-epoxidase (VDE) activity. To our knowledge, we report the first cloning of a cDNA encoding VDE and expression of functional enzyme in Escherichia coli. VDE is nuclear encoded and has a transit peptide with characteristic features of other lumen-localized proteins. The cDNA encodes a putative polypeptide of 473 aa with a calculated molecular mass of 54,447 Da. Cleavage of the transit peptide results in a mature putative polypeptide of 348 aa with a calculated molecular mass of 39,929 Da, close to the apparent mass of the purified enzyme (43 kDa). The protein has three interesting domains including (i) a cysteine-rich region, (ii) a lipocalin signature, and (iii) a highly charged region. The E. coli expressed enzyme de-epoxidizes violaxanthin sequentially to antheraxanthin and zeaxanthin, and is inhibited by dithiothreitol, similar to VDE purified from chloroplasts. This confirms that the cDNA encodes an authentic VDE of a higher plant and is unequivocal evidence that the same enzyme catalyzes the two-step mono de-epoxidation reaction. The cloning of VDE opens new opportunities for examining the function and evolution of the xanthophyll cycle, and possibly enhancing light-stress tolerance of plants.
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This work describes the evaluation of the effect of saponification process in the carotenoid's content of three species of passion fruit. The results indicated the saponification of the extract was necessary to obtain cis-violaxanthin, trans-violaxanthin and β-cryptoxanthin hydrolyzed. These compounds were found in fruits of commercial P. edulis and yellow wild P. edulis. However, the extract saponification did not permitted to obtain free carotenes in fruits of wild purple P. edulis and P. setacea, and to trans-violaxanthin of P. cincinnata, therefore saponification was not indicated in the carotenoid analysis of these three accessions of passion fruit.
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Changes in carotenoid pigment content of Brazilian Valencia orange juices due to thermal pasteurization and concentration were studied. Total carotenoid pigment content loss was not significant after thermal pasteurization and concentration. However, thermal effects on carotenoid pigment contents, especially violaxanthin and lutein, were clearly observed and significant (P < 0.05). Pasteurization reduced the content of violaxanthin by 38% and lutein by 20%. The concentration process resulted in loss of lutein (17%). With the loss of lutein, beta-cryptoxanthin became the major carotenoid in the pasteurized and concentrated juices. The provitarnin A content of the juice (beta-carotene, alpha-carotene and beta-cryptoxanthin) and the amount of zeaxanthin, which are considered to be active against age-related macular degeneration and cataracts, did not significantly decrease after pasteurization and concentration. (c) 2006 Elsevier Ltd. All rights reserved.
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The carotenoid composition of Brazilian Valencia orange juice was determined by open column chromatography (OCC) and high-performance liquid chromatography. Carotenoid pigments were extracted using acetone and saponified using 10% methanolic potassium hydroxide. Sixteen pigments were isolated by OCC and identified as alpha-carotene, zeta-carotene, beta-carotene, alpha-cryptoxanthin, beta-cryptoxanthin, lutein-5,6-epoxide, violaxanthin, lutein, antheraxanthin, zeaxanthin, luteoxanthin A, luteoxanthin B, mutatoxanthin A, mutatoxanthin B, auroxanthin B and trollichrome B. Thirteen carotenoid pigments were separated using a ternary gradient (acetonitrile-methanol-ethyl acetate) elution on a C-18 reversed-phase column. Among these, violaxanthin, lutein, zeaxanthin, beta-cryptoxanthin, zeta-carotene, alpha-carotene, and beta-carotene were quantified. The total carotenoid content was 12 +/- 6.7 mg/1, and the major carotenoids were lutein (23%), beta-cryptoxanthin (21%), and zeaxanthin (20%). 2005 Elsevier Ltd. All rights reserved.
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Total and individual carotenoid concentrations were determined by spectro photometry and HPLC, in raw tubers of a sample of 23 accessions of Solanum phureja potatoes taken at random from the world germplasm collection following its stratification on tuber flesh color. Lutein, zeaxanthin, violaxanthin, antheraxanthin and beta-carotene were detected in all accessions and three distinct patterns of carotenoid accumulation were evidenced by cluster analysis. Accessions in group 1 showed the highest concentrations of total carotenoids (1258-1840 mu g 100 g(-1) FW) comprised largely of zeaxanthin (658-1290 mu g 100 g(-1) FW) with very low or no presence of beta-carotene (below 5.4 mu g 100 g(-1) FW). Accessions in group 2 presented moderate total carotenoid concentrations with violaxanthin, antheraxanthin, lutein and zeaxanthin as the major carotenoids. Accessions in group 3 showed low concentrations of total carotenoids (97-262 mu g 100 g(-1) FW) and very low or no zeaxanthin, with lutein and violaxanthin as the predominant carotenoids and relatively high concentrations of beta-carotene(up to 27 mu g 100 g(-1) FW). Five accessions with significant concentrations of zeaxanthin were identified with the accession 703566 showing the highest concentration (1290 p g 100 g(-1) FW). This value is to our knowledge higher than any value previously reported for potatoes, including those achieved through genetic modification. For the 23 S. phureja accessions, total carotenoid concentration was positively and significantly correlated with antheraxanthin and zeaxanthin concentrations, and negatively and significantly correlated with beta-carotene concentration. (C) 2008 Elsevier B.V. All rights reserved.
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Because hydroponic production of vegetables is becoming more common, the carotenoid composition of hydroponic leafy vegetables commercialized in Campinas, Brazil, was determined. All samples were collected and analyzed in winter. Lactucaxanthin was quantified for the first time and was found to have concentrations similar to that of neoxanthin in the four types of lettuce analyzed. Lutein predominated in cress, chicory, and roquette (75.4 ± 10.2, 57.0 ± 10.3, and 52.2 ± 12.6 μg/g, respectively). In the lactucaxanthin-containing lettuces, β-carotene and lutein were the principal carotenoids (ranging from 9.9 ± 1.5 to 24.6 ± 3.1 μg/g and from 10.2 ± 1.0 to 22.9 ± 2.6 μg/g, respectively). Comparison of hydroponic and field-produced curly lettuce, taken from neighboring farms, showed that the hydroponic lettuce had significantly lower lutein, β-carotene, violaxanthin, and neoxanthin contents than the conventionally produced lettuce. Because the hydroponic farm had a polyethylene covering, less exposure to sunlight and lower temperatures may have decreased carotenogenesis.
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Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES)
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Gracilaria domingensis (Kützing) Sonder ex Dickie and Gracilaria birdiae (Plastino & Oliveira) (Gracilariales, Rhodophyta) are seaweeds that occur on the Brazilian coast. Based on their economic and pharmaceutical importance, we investigated the antioxidant activity of the methanolic, ethyl acetate and hexane extracts of both species. The hexane extracts display a high antioxidant activity and comparative analyses indicated G. birdiae as the most active species. Chemical investigation of these fractions showed several carotenoids and fatty acids, as well as cholesterol and sitosterol derivatives. HPLC-DAD analysis of G. birdiae showed violaxanthin (0.04 μg.mg-1 of dry material), antheraxanthin (5.31 μg.mg-1), aloxanthin (0.09 μg.mg-1), zeaxanthin (0.45 μg.mg-1) and β-carotene (0.37 μg.mg-1) as the major carotenoids. G. domingensis showed a similar carotenoid profile, however, with much lower concentration than G. birdiae. Gas chromatography coupled to mass spectrometry was used to determine other nonpolar compounds of these seaweeds. The main compounds detected in both studied species were the fatty acids 16:0; 18:1 Δ9; 20:3 Δ6,9,12, 20:4 Δ5,8,11,14. We found no specificity of compounds in either species. However, G. birdiae, presented higher contents of carotenoids and arachidonic acid than G. domingensis.
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Photosynthetic organisms have sought out the delicate balance between efficient light harvesting under limited irradiance and regulated energy dissipation under excess irradiance. One of the protective mechanisms is the thermal energy dissipation through the xanthophyll cycle that may transform harmlessly the excitation energy into heat and thereby prevent the formation of damaging active oxygen species (AOS). Violaxanthin deepoxidase (VDE) converts violaxanthin (V) to antheraxanthin (A) and zeaxanthin (Z) defending the photosynthetic apparatus from excess of light. Another important biological pathway is the chloroplast water-water cycle, which is referred to the electrons from water generated in PSII reducing atmospheric O2 to water in PSI. This mechanism is active in the scavenging of AOS, when electron transport is slowed down by the over-reduction of NADPH pool. The control of the VDE gene and the variations of a set of physiological parameters, such as chlorophyll florescence and AOS content, have been investigated in response to excess of light and drought condition using Arabidopsis thaliana and Arbutus unedo.. Pigment analysis showed an unambiguous relationship between xanthophyll de-epoxidation state ((A+Z)/(V+A+Z)) and VDE mRNA amount in not-irrigated plants. Unexpectedly, gene expression is higher during the night when xanthophylls are mostly epoxidated and VDE activity is supposed to be very low than during the day. The importance of the water-water cycle in protecting the chloroplasts from light stress has been examined through Arabidopsis plant with a suppressed expression of the key enzyme of the cycle: the thylakoid-attached copper/zinc superoxide dismutase. The analysis revealed changes in transcript expression during leaf development consistent with a signalling role of AOS in plant defence responses but no difference was found any in photosynthesis efficiency or in AOS concentration after short-term exposure to excess of light. Environmental stresses such as drought may render previously optimal light levels excessive. In these circumstances the intrinsic regulations of photosynthetic electron transport like xanthophyll and water-water cycles might modify metabolism and gene expression in order to deal with increasing AOS.
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The relation between the intercepted light and orchard productivity was considered linear, although this dependence seems to be more subordinate to planting system rather than light intensity. At whole plant level not always the increase of irradiance determines productivity improvement. One of the reasons can be the plant intrinsic un-efficiency in using energy. Generally in full light only the 5 – 10% of the total incoming energy is allocated to net photosynthesis. Therefore preserving or improving this efficiency becomes pivotal for scientist and fruit growers. Even tough a conspicuous energy amount is reflected or transmitted, plants can not avoid to absorb photons in excess. The chlorophyll over-excitation promotes the reactive species production increasing the photoinhibition risks. The dangerous consequences of photoinhibition forced plants to evolve a complex and multilevel machine able to dissipate the energy excess quenching heat (Non Photochemical Quenching), moving electrons (water-water cycle , cyclic transport around PSI, glutathione-ascorbate cycle and photorespiration) and scavenging the generated reactive species. The price plants must pay for this equipment is the use of CO2 and reducing power with a consequent decrease of the photosynthetic efficiency, both because some photons are not used for carboxylation and an effective CO2 and reducing power loss occurs. Net photosynthesis increases with light until the saturation point, additional PPFD doesn’t improve carboxylation but it rises the efficiency of the alternative pathways in energy dissipation but also ROS production and photoinhibition risks. The wide photo-protective apparatus, although is not able to cope with the excessive incoming energy, therefore photodamage occurs. Each event increasing the photon pressure and/or decreasing the efficiency of the described photo-protective mechanisms (i.e. thermal stress, water and nutritional deficiency) can emphasize the photoinhibition. Likely in nature a small amount of not damaged photosystems is found because of the effective, efficient and energy consuming recovery system. Since the damaged PSII is quickly repaired with energy expense, it would be interesting to investigate how much PSII recovery costs to plant productivity. This PhD. dissertation purposes to improve the knowledge about the several strategies accomplished for managing the incoming energy and the light excess implication on photo-damage in peach. The thesis is organized in three scientific units. In the first section a new rapid, non-intrusive, whole tissue and universal technique for functional PSII determination was implemented and validated on different kinds of plants as C3 and C4 species, woody and herbaceous plants, wild type and Chlorophyll b-less mutant and monocot and dicot plants. In the second unit, using a “singular” experimental orchard named “Asymmetric orchard”, the relation between light environment and photosynthetic performance, water use and photoinhibition was investigated in peach at whole plant level, furthermore the effect of photon pressure variation on energy management was considered on single leaf. In the third section the quenching analysis method suggested by Kornyeyev and Hendrickson (2007) was validate on peach. Afterwards it was applied in the field where the influence of moderate light and water reduction on peach photosynthetic performances, water requirements, energy management and photoinhibition was studied. Using solar energy as fuel for life plant is intrinsically suicidal since the high constant photodamage risk. This dissertation would try to highlight the complex relation existing between plant, in particular peach, and light analysing the principal strategies plants developed to manage the incoming light for deriving the maximal benefits as possible minimizing the risks. In the first instance the new method proposed for functional PSII determination based on P700 redox kinetics seems to be a valid, non intrusive, universal and field-applicable technique, even because it is able to measure in deep the whole leaf tissue rather than the first leaf layers as fluorescence. Fluorescence Fv/Fm parameter gives a good estimate of functional PSII but only when data obtained by ad-axial and ab-axial leaf surface are averaged. In addition to this method the energy quenching analysis proposed by Kornyeyev and Hendrickson (2007), combined with the photosynthesis model proposed by von Caemmerer (2000) is a forceful tool to analyse and study, even in the field, the relation between plant and environmental factors such as water, temperature but first of all light. “Asymmetric” training system is a good way to study light energy, photosynthetic performance and water use relations in the field. At whole plant level net carboxylation increases with PPFD reaching a saturating point. Light excess rather than improve photosynthesis may emphasize water and thermal stress leading to stomatal limitation. Furthermore too much light does not promote net carboxylation improvement but PSII damage, in fact in the most light exposed plants about 50-60% of the total PSII is inactivated. At single leaf level, net carboxylation increases till saturation point (1000 – 1200 μmolm-2s-1) and light excess is dissipated by non photochemical quenching and non net carboxylative transports. The latter follows a quite similar pattern of Pn/PPFD curve reaching the saturation point at almost the same photon flux density. At middle-low irradiance NPQ seems to be lumen pH limited because the incoming photon pressure is not enough to generate the optimum lumen pH for violaxanthin de-epoxidase (VDE) full activation. Peach leaves try to cope with the light excess increasing the non net carboxylative transports. While PPFD rises the xanthophyll cycle is more and more activated and the rate of non net carboxylative transports is reduced. Some of these alternative transports, such as the water-water cycle, the cyclic transport around the PSI and the glutathione-ascorbate cycle are able to generate additional H+ in lumen in order to support the VDE activation when light can be limiting. Moreover the alternative transports seems to be involved as an important dissipative way when high temperature and sub-optimal conductance emphasize the photoinhibition risks. In peach, a moderate water and light reduction does not determine net carboxylation decrease but, diminishing the incoming light and the environmental evapo-transpiration request, stomatal conductance decreases, improving water use efficiency. Therefore lowering light intensity till not limiting levels, water could be saved not compromising net photosynthesis. The quenching analysis is able to partition absorbed energy in the several utilization, photoprotection and photo-oxidation pathways. When recovery is permitted only few PSII remained un-repaired, although more net PSII damage is recorded in plants placed in full light. Even in this experiment, in over saturating light the main dissipation pathway is the non photochemical quenching; at middle-low irradiance it seems to be pH limited and other transports, such as photorespiration and alternative transports, are used to support photoprotection and to contribute for creating the optimal trans-thylakoidal ΔpH for violaxanthin de-epoxidase. These alternative pathways become the main quenching mechanisms at very low light environment. Another aspect pointed out by this study is the role of NPQ as dissipative pathway when conductance becomes severely limiting. The evidence that in nature a small amount of damaged PSII is seen indicates the presence of an effective and efficient recovery mechanism that masks the real photodamage occurring during the day. At single leaf level, when repair is not allowed leaves in full light are two fold more photoinhibited than the shaded ones. Therefore light in excess of the photosynthetic optima does not promote net carboxylation but increases water loss and PSII damage. The more is photoinhibition the more must be the photosystems to be repaired and consequently the energy and dry matter to allocate in this essential activity. Since above the saturation point net photosynthesis is constant while photoinhibition increases it would be interesting to investigate how photodamage costs in terms of tree productivity. An other aspect of pivotal importance to be further widened is the combined influence of light and other environmental parameters, like water status, temperature and nutrition on peach light, water and phtosyntate management.
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Zusammenfassung:In Chlorophyll(Chl) a/c-haltigen Algen leisten Xanthophylle einen wesentlichen Beitrag zur Lichtsammlung. Daneben finden sich weitere Xanthophylle, die an einem Schutzmechanismus bei überoptimalem Lichtangebot beteiligt sind, dem sog. Xanthophyllzyklus. Ein Teil der Chl a/c-haltigen Algen besitzt den auch bei Höheren Pflanzen anzutreffenden Violaxanthin/Antheraxanthin/Zeaxanthin-(Vx/Ax/Zx-)Zyklus. In anderen Gruppen wie den Dinophyta, Haptophyta und den Kieselalgen (Bacillariophyceae) ist statt dessen der Diadinoxanthin/Diatoxanthin-(Ddx/Dtx-)Zyklus zu finden. Die vorliegende Arbeit zeigt, daß schwachlichtadaptierte Turbidostatkulturen der Kieselalge Phaeodactylum tricornutum unter mehrstündiger Starklichtinkubation neben den Pigmenten des Ddx/Dtx-Zyklus auch die des Vx/Ax/Zx-Zyklus akkumulieren. Außerdem läßt sich ein dritter Xanthophyllzyklus zwischen beta-Cryptoxanthin (Cx) und beta-Cryptoxanthin-Epoxid (CxE) nachweisen, doch liegen diese beiden Pigmente nur in sehr geringen Konzentrationen vor. Für die Starklichtakkumulation von Zx ist eine hohe Deepoxidase-Aktivität und die de-novo-Synthese von Carotinoiden erforderlich. Aus Zx wird im anschließenden Schwachlicht über die Intermediate Vx und Ddx das Lichtsammelxanthophyll Fucoxanthin (Fx) synthetisiert. Dies bestätigt auch ein Vergleich der Kinetiken der einzelnen Umwandlungsschritte mit den anhand eines Modells der Xanthophyllbiosynthesewege ermittelten theoretischen Ratenkonstanten. Dieser Vergleich legt jedoch nahe, daß bei der Vx-Synthese aus beta-Carotin CxE anstelle von Zx involviert sein könnte. Eine Untersuchung weiterer Chl a/c-haltiger Algen mit Ddx/Dt-Zyklus ergab, daß sie unter Starklicht ebenfalls den Vx/Ax/Zx-Zyklus akkumulieren. Weiterhin sind, mit Einschränkungen bei den Dinophyten und Xanthophyceen, alle untersuchten Algen in der Lage, die unter Starklicht akkumulierten Xanthophyllzykluspigmente im nachfolgenden Schwachlicht zur Synthese des jeweiligen Lichtsammelxanthophylls zu nutzen. Unter energetischen Gesichtspunkten stellt dieses Pigment-Recycling insbesondere für die Fx-haltigen Algen einen Vorteil dar, da ihre Lichtsammelkomplexe im Vergleich zu denen der Höheren Pflanzen etwa die doppelte Anzahl an Xanthophyllen binden.
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In der vorliegenden Arbeit wird der Vx-Zyklus und der Ddx-Zyklus unterschiedlicher Pflanzen hinsichtlich ihrer Regulation untersucht. Es konnte an Hand von in vivo Messungen gezeigt werden, dass bei zwei Kieselalgen unterschiedlicher Ordnung (Pennales bzw. Centrales) und einer Haptophyte mit Ddx-Zyklus die Dtx-Epoxidase delta-pH-reguliert ist. Im Gegensatz dazu steht die nicht-regulierte Zx-Epoxidase des Vx-Zyklus einer Raphidophyceae, einer Grünalge und einer aquatischen Höheren Pflanze. Es konnte gezeigt werden, dass der Grund für diese unterschiedliche Regulation der beiden Epoxidasen die verschiedenen Quench-Eigenschaften der Pigmente Dtx bzw. Zx ist. Durch parallele Messungen des NPQ und des De-Epoxidierungsgrads wurde deutlich, dass Zx zum Aufbau eines Quenching direkt den im Licht aufgebauten delta-pH benötigt, während Dtx alleine ausreichend ist, um ein Quenching zu verursachen. Bei diesen in vivo Messungen wurde außerdem deutlich, dass die Aktivitäten der untersuchten Epoxidasen große Unterschiede aufweisen. Diese sind abhängig von der entsprechenden Pigmentierung des jeweiligen Lichtsammelsystems, stehen also in Zusammenhang mit den Carotinoidbiosynthesen. Es konnte gezeigt werden, dass bei allen untersuchten Organismen, die eine Xanthophyll-dominierte Antenne mit Fx als Massenpigment enthielten, die Umsatzraten der Epoxidase sehr hoch waren, im Gegensatz zu Chl-dominierten Antennen. Nach diesen Erkenntnissen wurde die Dtx-Epoxidase weiter untersucht und so erstmalig durch Western-Blotting identifiziert. Es ergaben sich, allerdings erst nach zusätzlicher Proteinstabilisierung, zwei Signale, eins bei 60 kDa, das andere bei 57 kDa. Hierbei ist nach wie vor unklar, warum das Antiserum zwei Signale lieferte und ob es sich dabei um Isoformen, um anderweitige Modifizierungen, oder um eine Kreuzreaktion handelt. Auch der Mechanismus der delta-pH-Regulation der Dtx-Epoxidase konnte trotz in vivo und in vitro durchgeführter Studien nicht endgültig geklärt werden. Allerdings konnten verschiedene Mechanismen, wie z.B. eine direkte pH-Abhängigkeit des Enzyms, eine Regulation durch Reduktion und Oxidation oder durch Phosphorylierung und Dephosphorylierung, auf Grund der Daten falsifiziert werden. Es konnte schließlich die Regulation mit Hilfe eines transmembranen Rezeptors als das einzige, mit allen Daten konsistente Regulationsmodell vorgeschlagen werden.
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Die Lichtsammelantenne des PSI (LHCI) ist hinsichtlich ihrer Protein- und Pigmentzusammensetzung weniger gut untersucht als die des PSII. Im Rahmen dieser Arbeit wurde deshalb zunächst die Isolation von nativen LHCI-Subkomplexen optimiert und deren Pigmentzusammensetzung untersucht. Zusätzlich wurde die Pigmentbindung analysiert sowie das Pigment/Protein-Verhältnis bestimmt. Die Analyse der Proteinzusammensetzung des LHCI erfolgte mittels einer Kombination aus ein- oder zweidimensionaler Gelelektrophorese mit Westernblotanalysen mit Lhca-Protein-spezifischen Antikörpern und massenspektrometrischen Untersuchungen. Dabei stellte sich heraus, dass der LHCI mehr Proteine bzw. Proteinisoformen enthält als bisher vermutet. So gelang durch die massenspektrometrischen Untersuchungen die Identifizierung zweier bisher noch nicht nachgewiesener Lhca-Proteine. Bei diesen handelt es sich um eine Isoform des Lhca4 und ein zusätzliches Lhca-Protein, das Tomaten-Homolog des Lhca5 von Arabidopsis thaliana. Außerdem wurden in 1D-Gelen Isoformen von Lhca-Proteinen mit unterschiedlichem elektrophoretischen Verhalten beobachtet. In 2D-Gelen trat zusätzlich eine große Anzahl an Isoformen mit unterschiedlichen isoelektrischen Punkten auf. Es ist zu vermuten, dass zumindest ein Teil dieser Isoformen physiologischen Ursprungs ist, und z.B. durch differentielle Prozessierung oder posttranslationale Modifikationen verursacht wird, wenn auch die Spotvielfalt in 2D-Gelen wohl eher auf die Probenaufbereitung zurückzuführen ist. Mittels in vitro-Rekonstitution mit anschließenden biochemischen Untersuchungen und Fluoreszenzmessungen wurde nachgewiesen, dass Lhca5 ein funktioneller LHC mit spezifischen Pigmentbindungseigenschaften ist. Außerdem zeigten in vitro-Dimerisierungsexperimente eine Interaktion zwischen Lhca1 und Lhca5, wodurch dessen Zugehörigkeit zur Antenne des PSI gestützt wird. In vitro-Dimerisierungsexperimente mit Lhca2 und Lhca3 führten dagegen nicht zur Bildung von Dimeren. Dies zeigt, dass die Interaktion in potentiellen Homo- oder Heterodimeren aus Lhca2 und/oder Lhca3 schwächer ist als die zwischen Lhca1 und Lhca4 oder Lhca5. Die beobachtete Proteinheterogenität deutet daraufhin, dass die Antenne des PSI eine komplexere Zusammensetzung hat als bisher angenommen. Für die Integration „neuer“ LHC in den PSI-LHCI-Holokomplex werden zwei Modelle vorgeschlagen: geht man von einer festen Anzahl von LHCI-Monomeren aus, so kann sie durch den Austausch einzelner LHC-Monomere erreicht werden. Als zweites Szenario ist die Bindung zusätzlicher LHC vorstellbar, die entweder indirekt über bereits vorhandene LHC oder direkt über PSI-Kernuntereinheiten mit dem PSI interagieren. In Hinblick auf die Pigmentbindung der nativen LHCI-Subfraktionen konnte gezeigt werden, dass sie Pigmente in einer spezifischen Stöchiometrie und Anzahl binden, und sich vom LHCIIb vor allem durch eine verstärkte Bindung von Chlorophyll a, eine geringere Anzahl von Carotinoiden und die Bindung von ß-Carotin an Stelle von Neoxanthin unterscheiden. Der Vergleich von nativem LHCI mit rekonstituierten Lhca-Proteinen ergab, dass Lhca-Proteine Pigmente in einer spezifischen Stöchiometrie binden, und dass sie Carotinoidbindungsstellen mit flexiblen Bindungseigenschaften besitzen. Auch über die Umwandlung des an die einzelnen Lhca-Proteine gebundenen Violaxanthins (Vio) im Xanthophyllzyklus war nur wenig bekannt. Deshalb wurden mit Hilfe eines in vitro-Deepoxidationssystems sowohl native als auch rekonstituierte LHCI hinsichtlich ihrer Deepoxidationseigenschaften untersucht und der Deepoxidationsgrad von in vivo deepoxidierten Pigment-Protein-Komplexen bestimmt. Aus den Deepoxidationsexperimenten konnte abgeleitet werden, dass in den verschiedenen Lhca-Proteinen unterschiedliche Carotinoidbindungsstellen besetzt sind. Außerdem bestätigten diese Experimente, dass der Xanthophyllzyklus auch im LHCI auftritt, wobei jedoch ein niedrigerer Deepoxidationsgrad erreicht wird als bei LHCII. Dies konnte durch in vitro-Deepoxidationsversuchen auf eine geringere Deepoxidierbarkeit des von Lhca1 und Lhca2 gebundenen Vio zurückgeführt werden. Damit scheint Vio in diesen Lhca-Proteinen eher eine strukturelle Rolle zu übernehmen. Eine photoprotektive Funktion von Zeaxanthin im PSI wäre folglich auf Lhca3 und Lhca4 beschränkt. Damit enthält jede LHCI-Subfraktion ein LHC-Monomer mit langwelliger Fluoreszenz, das möglicherweise am Lichtschutz beteiligt ist. Insgesamt zeigten die Untersuchungen der Pigmentbindung, der Deepoxidierung und der Fluoreszenzeigenschaften, dass sich die verschiedenen Lhca-Proteine in einem oder mehreren dieser Parameter unterscheiden. Dies lässt vermuten, dass schon durch leichte Veränderungen in der Proteinzusammensetzung des LHCI eine Anpassung an unterschiedliche Licht-verhältnisse erreicht werden kann.
