Role of hexagonal structure-forming lipids in diadinoxanthin and violaxanthin solubilization and de-epoxidation

In this study, we have examined the influence of different lipids on the solubility of the xanthophyll cycle pigments diadinoxanthin (Ddx) and violaxanthin (Vx) and on the efficiency of Ddx and Vx de-epoxidation by the enzymes Vx de-epoxidase (VDE) from wheat and Ddx de-epoxidase (DDE) from the diatom Cyclotella meneghiniana, respectively. Our results show that the lipids MGDG and PE are able to solubilize both xanthophyll cycle pigments in an aqueous medium. Substrate solubilization is essential for de-epoxidase activity, because in the absence of MGDG or PE Ddx and Vx are present in an aggregated form, with limited accessibility for DDE and VDE. Our results also show that the hexagonal structure-forming lipids MGDG and PE are able to solubilize Ddx and Vx at much lower lipid concentrations than bilayer-forming lipids DGDG and PC. We furthermore found that, in the presence of MGDG or PE, Ddx is much more solubilizable than Vx. This substantial difference in Ddx and Vx solubility directly affects the respective de-epoxidation reactions. Ddx de-epoxidation by the diatom DDE is saturated at much lower MGDG or PE concentrations than Vx de-epoxidation by the higher-plant VDE. Another important result of our study is that bilayer-forming lipids DGDG and PC are not able to induce efficient xanthophyll de-epoxidation. Even in the presence of high concentrations of DGDG or PC, where Ddx and Vx are completely solubilized, a strongly inhibited Ddx de-epoxidation is observed, while Vx de-epoxidation by VDE is completely absent. This indicates that the inverted hexagonal phase domains provided by lipid MGDG or PE are essential for de-epoxidase activity. We conclude that in the natural thylakoid membrane MGDG serves to solubilize the xanthophyll cycle pigments and furthermore provides inverted hexagonal structures associated with the membrane bilayer, which are essential for efficient xanthophyll de-epoxidase activity.     

Unusual pH-dependence of diadinoxanthin de-epoxidase activation causes chlororespiratory induced accumulation of diatoxanthin in the diatom Phaeodactylum tricornutum

Based on our recent findings that in the diatom Phaeodactylum tricornutum, chlororespiration in periods of prolonged darkness leads to the accumulation of diatoxanthin (DT), we have elaborated in detail the interdependence between the chlororespiratory proton gradient and the activation of diadinoxanthin de-epoxidase (DDE). The data clearly demonstrates that activation of DDE in Phaeodactylum occurs at higher pH-values compared to activation of violaxanthin de-epoxidase (VDE) in higher plants. In thylakoid membranes as well as in enzyme assays with isolated DDE, the de-epoxidation of diadinoxanthin (DD) is efficiently catalyzed at pH 7.2. In comparison, de-epoxidation of violaxanthin (Vx) in spinach thylakoids is observed below pH 6.5. Phaeodactylum thylakoids isolated from high light grown cells, that also contain the pigments of the violaxanthin cycle, show violaxanthin de-epoxidation at higher pH-values, thus suggesting that in Phaeodactylum, one de-epoxidase converts both diadinoxanthin and violaxanthin. We conclude that the activation of DDE at higher pH-values can explain how the low rates of chlororespiratory electron flow, that lead to the build-up of a rather small proton gradient, can induce the observed accumulation of diatoxanthin in the dark. Furthermore, we show that dark activation of diadinoxanthin de-epoxidation is not restricted to Phaeodactylum tricornutum but was also found in another diatom, Cyclotella meneghiana     

Localization of the xanthophyll-cycle enzyme violaxanthin de-epoxidase within the thylakoid lumen and abolition of its mobility by a (light-dependent) pH decrease

The formation of zeaxanthin (Zea) from violaxanthin (Vio) in chloroplasts of leaves and algae upon strong illumination is currently suggested to play a role in the photoprotection of plants. Properties and location of the enzyme Vio de-epoxidase, which is responsible for the transformation of Vio to Zea, were studied using thylakoid membrane vesicles isolated from leaves of Spinacia oleracea L. Without using detergents a repeated freeze-thaw treatment of thylakoid vesicles was sufficient to release the enzyme into the medium. With the same procedure the mobile electron carrier plastocyanin, known to occur in the thylakoid lumen, was also released. The enzyme was demonstrated by its activity in the supernatant of the pelleted thylakoid vesicles in the presence of the added substrates Vio and ascorbic acid, as well as by staining of the released proteins after polyacrylamide gel electrophoresis. The release of the deepoxidase from the vesicles was pH-dependent, declined below pH 6.5 and ceased in the pH range around 5, which corresponds to the pH optimum of the enzyme activity. By using thylakoid vesicles isolated from pre-illuminated and therefore Zea-containing leaves the release by freeze-thaw cycles of both the de-epoxidase and plastocyanin was diminished compared with the dark control. However, the reason for this effect was not the Zea content but an unknown effect of the illumination on the thylakoid membrane properties. The de-epoxidase collected at pH 7 was able to re-bind to thylakoid membranes at pH 5.5 and to transform intrinsic Vio to Zea in the presence of ascorbate. The isolated de-epoxidase, as well as the endogenous membrane-bound de-epoxidase, was inhibited by dithiothreitol. From these results it is concluded that Vio de-epoxidase, like plastocyanin, is mobile within the thylakoid lumen at neutral pH values which occur under in-vivo conditions in the dark. However, upon strong illumination, when the lumen pH drops (pH < 6.5) due to the formation of a proton gradient, the properties of the de-epoxidase are altered and the enzyme becomes tightly bound to the membrane (in contrast to plastocyanin) thus gaining access to its substrate Vio. These findings corroborate the assumption of a transmembrane opposite location of the two enzymes of the xanthophyll cycle, the ascorbate-dependent Vio deepoxidase at the lumenal side and the NADPH-dependent Zea epoxidase at the stromal side. Indications in favour of a location of Vio within the lipid bilayer of the thylakoid membrane and of a binding of the active deepoxidase to these areas are discussed.     

Role of histidines in the binding of violaxanthin de-epoxidase to the thylakoid membrane as studied by site-directed mutagenesis

Regulation of violaxanthin de-epoxidase (VDE) involves a conformational change at low lumenal pH, followed by binding of the enzyme to the thylakoid membrane. The role of histidine residues in this process was studied by release of unbound enzyme from thylakoids upon sonication, on a pH scale from 4.7 to 7.1. The co-operativity for binding of spinach VDE (four histidines) to the membrane was found to be 3.8, with respect to protons, and had an inflexion point at pH 6.6, whereas VDE from wheat (three histidines) showed a co-operativity of 2.9 and had an inflexion point at pH 6.2. Mutant forms of VDE were constructed and probed for their binding to the outside of thylakoid membranes. With one or two histidines substituted for alanine or arginine, a lower co-operativity (1.6–2.3) was found, compared with the wild type. Based on these findings, and that the pKa value for histidine is within the range where the VDE binding takes place, we propose that protonation of the histidine residues at low pH induces the conformational change of VDE, and hence indirectly regulates binding of the enzyme to the thylakoid membrane.     

A Structural Basis for the pH-Dependent Xanthophyll Cycle in Arabidopsis thaliana

Plants adjust their photosynthetic activity to changing light conditions. A central regulation of photosynthesis depends on the xanthophyll cycle, in which the carotenoid violaxanthin is converted into zeaxanthin in strong light, thus activating the dissipation of the excess absorbed energy as heat and the scavenging of reactive oxygen species. Violaxanthin deepoxidase (VDE), the enzyme responsible for zeaxanthin synthesis, is activated by the acidification of the thylakoid lumen when photosynthetic electron transport exceeds the capacity of assimilatory reactions: at neutral pH, VDE is a soluble and inactive enzyme, whereas at acidic pH, it attaches to the thylakoid membrane where it binds its violaxanthin substrate. VDE also uses ascorbate as a cosubstrate with a pH-dependent K_m that may reflect a preference for ascorbic acid. We determined the structures of the central lipocalin domain of VDE (VDE_cd) at acidic and neutral pH. At neutral pH, VDE_cd is monomeric with its active site occluded within a lipocalin barrel. Upon acidification, the barrel opens up and the enzyme appears as a dimer. A channel linking the two active sites of the dimer can harbor the entire carotenoid substrate and thus may permit the parallel deepoxidation of the two violaxanthin β-ionone rings, making VDE an elegant example of the adaptation of an asymmetric enzyme to its symmetric substrate.     

Membrane barriers and Mehler-peroxidase reaction limit the ascorbate available for violaxanthin de-epoxidase activity in intact chloroplasts

The presence of an acidic lumen and the xanthophylls, zeaxanthin and antheraxanthin, are minimal requirements for induction of non-radiative dissipation of energy in the pigment bed of Photosystem II. We recently reported that ascorbate, which is required for formation for these xanthophylls, also can mediate the needed lumen acidity through the Mehler-peroxidase reaction [Neubauer and Yamamoto (1992) Plant Physiol 99: 1354–1361]. It is demonstrated that in non-CO₂-fixing intact chloroplasts and thylakoids of Lactuca sativa, L. c.v. Romaine, the ascorbate available to support de-epoxidase activity is influenced by membrane barriers and the ascorbate-consuming Mehler-peroxidase reaction. In intact chloroplasts, this results in biphasic kinetic behavior for light-induced de-epoxidation. The initial relatively high activity is due to ascorbate preloaded into the thylakoid before light-induction and the terminal low activity due to limiting ascorbate from the effects of chloroplast membranes barriers and a light-dependent process. A five-fold difference between the initial and final activities was observed for light-induced de-epoxidation in chloroplasts pre-incubated with 120 mM ascorbate for 40 min. The light-dependent activity is ascribed to the competitive use of ascorbic acid by ascorbate peroxidase in the Mehler-peroxidase reaction. Thus, stimulating ascorbic peroxidase with H₂O₂ transiently inhibited de-epoxidase activity and concomitantly increased photochemical quenching. Also, the effects inhibiting ascorbate peroxidase with KCN, and the K_M values for ascorbate peroxidase and violaxanthin de-epoxidase of 0.36 and 3.1 mM, respectively, support this conclusion. These results indicate that regulation of xanthophyll-dependent non-radiative energy dissipation in the pigment bed of Photosystem II is modulated not only by lumen acidification but also by ascorbate availability.Abbreviations APO ascorbate peroxidase - MP Mehler ascorbate-peroxidase - NIG nigericin - NPQ non-photochemical quenching - F_o dark fluorescence - F fluorescence at any time - F_M maximal fluorescence of the (dark) non-energized state - F_M maximal fluorescence of the energized state - q_P coefficient for photochemical fluorescence quenching - VDE violaxanthin de-epoxidase - k first-order rate constant for violaxanthin de-epoxidase activity     

The de-epoxidase and epoxidase reactions of Mantoniella squamata (Prasinophyceae) exhibit different substrate-specific reaction kinetics compared to spinach

In vivo the prasinophyceaen alga Mantoniella squamata Manton et Parke uses an incomplete violaxanthin (Vx) cycle, leading to a strong accumulation of antheraxanthin (Ax) under conditions of high light. Here, we show that this zeaxanthin (Zx)-depleted Vx/Ax cycle is caused by an extremely slow second de-epoxidation step from Ax to Zx, and a fast epoxidation from Ax back to Vx in the light. The rate constant of Ax epoxidation is 5 to 6 times higher than the rate constant of Zx formation, implying that Ax is efficiently converted back to Vx before it can be de-epoxidated to Zx. It is, however, only half the rate constant of the first de-epoxidation step from Vx to Ax, thus explaining the observed net accumulation of Ax during periods of strong illumination. When comparing the rate constant of the second de-epoxidation step in M. squamata with Zx formation in spinach (Spinacia oleracea L.) thylakoids, we find a 20-fold reduction in the reaction kinetics of the former. This extremely slow Ax de-epoxidation, which is also exhibited by the isolated Mantoniella violaxanthin de-epoxidase (VDE), is due to a reduced substrate affinity of M. squamata VDE for Ax compared with the VDE of higher plants. Mantoniella VDE, which has a similar Km value for Vx, shows a substantially increased Km for the substrate Ax in comparison with spinach VDE. Our results furthermore explain why Zx formation in Mantoniella cells can only be found at low pH values that represent the pH optimum of VDE. A pH of 5 blocks the epoxidation reaction and, consequently, leads to a slow but appreciable accumulation of Zx.     

Regulation of violaxanthin de-epoxidase activity by pH and ascorbate concentration

The activity of violaxanthin de-epoxidase has been studied both in isolated thylakoids and after partial purification, as a function of pH and ascorbate concentration. We demonstrate that violaxanthin de-epoxidase has a K_m for ascorbate that is strongly dependent on pH, with values of 10, 2.5, 1.0 and 0.3 mM at pH 6.0, 5.5, 5.0 and 4.5, respectively. These values can be expressed as a single K_m±0.1±0.02 mM for the acid form of ascorbate. Release of the protein from the thylakoids by sonication was also found to be strongly pH dependent with a cooperativity of 4 with respect to protons and with an inflexion point at pH 6.7. These results can explain some of the discrepancies reported in the literature and provide a more consistent view of zeaxanthin formation in vivo.     

The influence of phase transitions in phosphatidylethanolamine models on the activity of violaxanthin de-epoxidase

In the present study, the influence of the phospholipid phase state on the activity of the xanthophyll cycle enzyme violaxanthin de-epoxidase (VDE) was analyzed using different phosphatidylethanolamine species as model lipids. By using (31)P NMR spectroscopy, differential scanning calorimetry and temperature dependent enzyme assays, VDE activity could directly be related to the lipid structures the protein is associated with. Our results show that the gel (L beta) to liquid-crystalline (L alpha) phase transition in these single lipid component systems strongly enhances both the solubilization of the xanthophyll cycle pigment violaxanthin in the membrane and the activity of the VDE. This phase transition has a significantly stronger impact on VDE activity than the transition from the L alpha to the inverted hexagonal (HII) phase. Especially at higher temperatures we found increased VDE reaction rates in the presence of the L alpha phase compared to those in the presence of HII phase forming lipids. Our data furthermore imply that the HII phase is better suited to maintain high VDE activities at lower temperatures.     

pH-dependent reversible inhibition of violaxanthin de-epoxidase by pepstatin related to protonation-induced structural change of the enzyme

The redox enzyme violaxanthin de-epoxidase (VDE) was found to be sensitive to pepstatin, a specific inhibitor of aspartic protease. The inhibition was similar to that of aspartic protease in that it was reversible and accompanied by the protonation of the enzyme. Of the two peaks of VDE appearing on anion exchange chromatography, VDE-I predominated at pH 7.2. On lowering the pH of the chromatography, VDE-I decreased and VDE-II increased. Furthermore, re-chromatography of either peak yielded both peaks. These results suggest that VDE-I and VDE-II are interconvertible depending on pH, and thus, they represent the de-protonated and protonated forms of the enzyme, respectively. Presumably the protonation-induced structural change of the enzyme is responsible for the interaction with pepstatin, and also with substrate.     

Ascorbate deficiency can limit violaxanthin de-epoxidase activity in vivo

As a response to high light, plants have evolved non-photochemical quenching (NPQ), mechanisms that lead to the dissipation of excess absorbed light energy as heat, thereby minimizing the formation of dangerous oxygen radicals. One component of NPQ is pH dependent and involves the formation of zeaxanthin from violaxanthin. The enzyme responsible for the conversion of violaxanthin to zeaxanthin is violaxanthin de-epoxidase, which is located in the thylakoid lumen, is activated by low pH, and has been shown to use ascorbate (vitamin C) as its reductant in vitro. To investigate the effect of low ascorbate levels on NPQ in vivo, we measured the induction of NPQ in a vitamin C-deficient mutant of Arabidopsis, vtc2-2. During exposure to high light (1,500 micromol photons m(-2) s(-1)), vtc2-2 plants initially grown in low light (150 micromol photons m(-2) s(-1)) showed lower NPQ than the wild type, but the same quantum efficiency of photosystem II. Crosses between vtc2-2 and Arabidopsis ecotype Columbia established that the ascorbate deficiency cosegregated with the NPQ phenotype. The conversion of violaxanthin to zeaxanthin induced by high light was slower in vtc2-2, and this conversion showed saturation below the wild-type level. Both the NPQ and the pigment phenotype of the mutant could be rescued by feeding ascorbate to leaves, establishing a direct link between ascorbate, zeaxanthin, and NPQ. These experiments suggest that ascorbate availability can limit violaxanthin de-epoxidase activity in vivo, leading to a lower NPQ. The results also demonstrate the interconnectedness of NPQ and antioxidants, both important protection mechanisms in plants.     

Reaction System for Violaxanthin De-Epoxidase with PSII Membranes

PSII membranes were used as a substrate for violaxanthin de-epoxidase(VDE) that had been solubilized from spinach thylakoids by sonication.Inclusion of Tween 20 in the assay mixture was essential, althoughthe detergent apparently inhibited the activity in the conventionalassay with purified violaxanthin and lipid as substrate. Themaximum enhancing effect of the detergent was observed nearits critical micellar concentration. It is likely that the monomerof the detergent helped VDE react with the substrate in themembranes. Dependence of the activity on the substrate concentrationsuggested that VDE functions at least at two sites in the membranes,probably on both their lumenal and stromal surfaces. The abilityof the enzyme to function on the stromal surface in in vitroassays was demonstrated by using intact thylakoids as the substrate.Under such conditions where the endogenous VDE was functioningin the lumen, the exogenously added VDE converted an-theraxanthinto zeaxanthin in the absence of Tween 20. This result suggeststhat, in the reaction with PSII membranes, the detergent wasrequired for VDE to react with violaxanthin but not with antheraxanthin.Otherwise, the detergent was necessary for the reaction on thelumenal surface. (Received September 5, 1997; Accepted October 19, 1997)     

Alternative Electron Transports Participate in the Maintenance of Violaxanthin De-Epoxidase Activity of Ulva sp. under Low Irradiance

The xanthophyll cycle (Xc), which involves violaxanthin de-epoxidase (VDE) and the zeaxanthin epoxidase (ZEP), is one of the most rapid and efficient responses of plant and algae to high irradiance. High light intensity can activate VDE to convert violaxanthin (Vx) to zeaxanthin (Zx) via antheraxanthin (Ax). However, it remains unclear whether VDE remains active under low light or dark conditions when there is no significant accumulation of Ax and Zx, and if so, how the ΔpH required for activation of VDE is built. In this study, we used salicylaldoxime (SA) to inhibit ZEP activity in the intertidal macro-algae Ulva sp. (Ulvales, Chlorophyta) and then characterized VDE under low light and dark conditions with various metabolic inhibitors. With inhibition of ZEP by SA, VDE remained active under low light and dark conditions, as indicated by large accumulations of Ax and Zx at the expense of Vx. When PSII-mediated linear electron transport systems were completely inhibited by SA and DCMU, alternative electron transport systems (i.e., cyclic electron transport and chlororespiration) could maintain VDE activity. Furthermore, accumulations of Ax and Zx decreased significantly when SA, DCMU, or DBMIB together with an inhibitor of chlororespiration (i.e., propyl gallate (PG)) were applied to Ulva sp. This result suggests that chlororespiration not only participates in the build-up of the necessary ΔpH, but that it also possibly influences VDE activity indirectly by diminishing the oxygen level in the chloroplast.     

The influence of phase transitions in phosphatidylethanolamine models on the activity of violaxanthin de-epoxidase

In the present study, the influence of the phospholipid phase state on the activity of the xanthophyll cycle enzyme violaxanthin de-epoxidase (VDE) was analyzed using different phosphatidylethanolamine species as model lipids. By using ³¹P NMR spectroscopy, differential scanning calorimetry and temperature dependent enzyme assays, VDE activity could directly be related to the lipid structures the protein is associated with. Our results show that the gel (L_β) to liquid-crystalline (L_α) phase transition in these single lipid component systems strongly enhances both the solubilization of the xanthophyll cycle pigment violaxanthin in the membrane and the activity of the VDE. This phase transition has a significantly stronger impact on VDE activity than the transition from the L_α to the inverted hexagonal (H_II) phase. Especially at higher temperatures we found increased VDE reaction rates in the presence of the L_α phase compared to those in the presence of H_II phase forming lipids. Our data furthermore imply that the H_II phase is better suited to maintain high VDE activities at lower temperatures.     

Substrate specificity of the violaxanthin de-epoxidase of the primitive green alga<Emphasis Type="Italic"> Mantoniella squamata</Emphasis> (Prasinophyceae)

The substrate specificity of the enzyme violaxanthin de-epoxidase (VDE) of the primitive green alga Mantoniella squamata (Prasinophyceae) was tested in in vitro enzyme assays employing the following xanthophyll mono-epoxides: antheraxanthin (Ax), diadinoxanthin (Ddx), lutein-epoxide (LE), cryptoxanthin-epoxide (CxE), 9- cis neoxanthin (cNx), all- trans neoxanthin (Nx), and xanthophyll di-epoxides: 9- cis violaxanthin (cVx), all- trans violaxanthin (Vx), cryptoxanthin-di-epoxide (CxDE). The data presented in this study show that the VDE of M. squamata not only exhibits a low affinity for the mono-epoxide Ax, as has been reported by R. Frommolt et al. (2001, Planta 213:446-456), but has a reduced substrate affinity for the mono-epoxides Ddx, LE, CxE, and Nx as well. On the other hand, xanthophylls with a second epoxy-group (Vx, CxDE) can be de-epoxidized with a higher efficiency. Such a preference for xanthophyll di-epoxides cannot be observed for the higher-plant VDE, where, in general, no marked differences in the pigment de-epoxidation rates between xanthophyll mono- and di-epoxides are visible. Despite this substantial difference between the VDEs of M. squamata and S. oleracea there are also features common to both enzymes. Neither VDE is able to convert xanthophylls with a 9- cis configuration in the acyclic polyene chain and both rely on substrates in the all- trans configuration. Both enzymes furthermore exhibit a dependence of enzyme activity on the polarity of the substrate. Highly polar (Nx) or non-polar (CxE) xanthophylls are de-epoxidized with greatly reduced rates in comparison to substrates with an intermediate polarity (Vx, Ax, LE, Ddx). This dependence on substrate polarity becomes more obvious when the higher-plant VDE is examined, as the substrate affinity of the VDE of M. squamata is more strongly influenced by the existence or absence of a second epoxy-group. In summary, the data presented in this study underline the fact that different VDEs, although in general catalyzing the same reaction sequence, are functionally diverse.     

Functional roles of the major chloroplast lipids in the violaxanthin cycle

Monogalactosyldiacylglyceride (MGDG) and digalactosyldiacylglyceride (DGDG) are the major membrane lipids of chloroplasts. The question of the specialized functions of these unique lipids has received limited attention. One function is to support violaxanthin de-epoxidase (VDE) activity, an enzyme of the violaxanthin cycle. To understand better the properties of this system, the effects of galactolipids and phosphatidylcholines on VDE activity were examined by two independent methods. The results show that the micelle-forming lipid (MGDG) and bilayer forming lipids (DGDG and phosphatidylcholines) support VDE activity differently. MGDG supported rapid and complete de-epoxidation starting at a threshold lipid concentration (10 μM) coincident with complete solubilization of violaxanthin. In contrast, DGDG supported slow but nevertheless complete to nearly complete de-epoxidation at a lower lipid concentration (6.7 μM) that did not completely solubilize violaxanthin. Phosphotidylcholines showed similar effects as DGDG except that de-epoxidation was incomplete. Since VDE requires solubilized violaxanthin, aggregated violaxanthin in DGDG at low concentration must become solubilized as de-epoxidation proceeds. High lipid concentrations had lower activity possibly due to formation of multilayered structures (liposomes) that restrict accessibility of violaxanthin to VDE. MGDG micelles do not present such restrictions. The results indicate VDE operates throughout the lipid phase of the single bilayer thylakoid membrane and is not limited to putative MGDG micelle domains. Additionally, the results also explain the differential partitioning of violaxanthin between the envelope and thylakoid as due to the relative solubilities of violaxanthin and zeaxanthin in MGDG, DGDG and phospholipids. The violaxanthin cycle is hypothesized to be a linked system of the thylakoid and envelope for signal transduction of light stress.     

Cooperativity in the dopamine beta-monooxygenase reaction. Evidence for ascorbate regulation of enzyme activity

The steady-state kinetic behavior of dopamine beta-monooxygenase (D beta M) has been examined over a 1000-fold range of ascorbate concentrations. Kinetic plots exhibit extreme curvature indicative of apparent negative cooperativity in the interaction of D beta M with ascorbate, with a calculated Hill coefficient of 0.15-0.30. The observed cooperativity is found to be independent of enzyme concentration and tyramine and oxygen concentrations, as well as the pH employed for the assay. Similar kinetic data have been obtained with both soluble and purified membrane-derived forms of enzyme. An investigation of the effect of the anion activator fumarate upon the observed kinetic patterns has demonstrated a conversion to a less cooperative kinetic pattern at low pH and high concentrations of fumarate. This phenomenon is attributed to an inhibitory binding of the structurally similar monoanionic species of fumarate to the ascorbate reductant site. A simple model has been used to assess the change in apparent Vmax and Km parameters with increased ascorbate concentrations. At all pH values examined, there is a dramatic decrease in the affinity of D beta M for ascorbate from a Km of approximately 0.05-0.10 mM (ascorbate concentration less than 1 mM) to Km greater than 10 mM at limiting ascorbate; at the same time there is a 3- to 4-fold increase in the limiting Vmax value. Several models have been considered to explain the observed activation of D beta M by high levels of ascorbic acid.     

The main thylakoid membrane lipid monogalactosyldiacylglycerol (MGDG) promotes the de-epoxidation of violaxanthin associated with the light-harvesting complex of photosystem II (LHCII)

In higher plants, the major part of the xanthophyll cycle pigment violaxanthin (Vx) is non-covalently bound to the main light-harvesting complex of PSII (LHCII). Under saturating light conditions Vx has to be released from its binding site into the surrounding lipid phase, where it is converted to zeaxanthin (Zx) by the enzyme Vx de-epoxidase (VDE). In the present study we investigated the influence of thylakoid lipids on the de-epoxidation of Vx, which was still associated with the LHCII. We isolated LHCII with different concentrations of native, endogenous lipids and Vx by sucrose gradient centrifugation or successive cation precipitation. Analysis of the different LHCII preparations showed that the concentration of LHCII-associated Vx was correlated with the concentration of the main thylakoid lipid monogalactosyldiacylglycerol (MGDG) associated with the complexes. Decreases in the MGDG content of the LHCII led to a diminished Vx concentration, indicating that a part of the total Vx pool was located in an MGDG phase surrounding the LHCII, whereas another part was bound to the LHCII apoproteins. We further studied the convertibility of LHCII-associated Vx in in-vitro enzyme assays by addition of isolated VDE. We observed an efficient and almost complete Vx conversion in the LHCII fractions containing high amounts of endogenous MGDG. LHCII preparations with low concentrations of MGDG exhibited a strongly reduced Vx de-epoxidation, which could be increased by addition of exogenous, pure MGDG. The de-epoxidation of LHCII-associated Vx was saturated at a much lower concentration of native, endogenous MGDG compared with the concentration of isolated, exogenous MGDG, which is needed for optimal VDE activity in in-vitro assays employing pure isolated Vx.     

Violaxanthin de-epoxidase.

Violaxanthin de-epoxidase catalyzes the de-epoxidation of violaxanthin to antheraxanthin and zeaxanthin in the xanthophyll cycle. Its activity is optimal at approximately pH 5.2 and requires ascorbate. In conjunction with the transthylakoid pH gradient, the formation of antheraxanthin and zeaxanthin reduces the photochemical efficiency of photosystem II by increasing the nonradiative (heat) dissipation of energy in the antennae. Previously, violaxanthin de-epoxidase had been partially purified. Here we report its purification from lettuce (Lactuca sativa var Romaine) to one major polypeptide fraction, detectable by two-dimensional isoelectic focusing/sodium dodecyl sulfate-polyacrylamide gel electrophoresis, using anion-exchange chromatography on Mono Q and a novel lipid-affinity precipitation step with monogalactosyldiacylglyceride. The association of violaxanthin de-epoxidase and monogalactosyldiacyglyceride at pH 5.2 is apparently specific, since little enzyme was precipitated by eight other lipids tested. Violaxanthin de-epoxidase has an isoelectric point of 5.4 and an apparent molecular mass of 43 kD. Partial amino acid sequences of the N terminus and tryptic fragments are reported. The peptide sequences are unique in the GenBank data base and suggest that violaxanthin de-epoxidase is nuclear encoded, similar to other chloroplast proteins localized in the lumen.