Effects of Nano-anatase on Spectral Characteristics and Distribution of LHCII on the Thylakoid Membranes of Spinach

In the article, we report that effects of nano-anatase on the spectral characteristics and content of light-harvesting complex II (LHCII) on the thylakoid membranes of spinach were investigated. The results showed that nano-anatase treatment could increase LHCII content on the thylakoid membranes of spinach and the trimer of LHCII; nano-anatase could enter the spinach chloroplasts and bind to PSII. Meanwhile, spectroscopy assays indicated that the absorption intensity of LHCII from nano-anatase-treated spinach was obviously increased in the red and the blue region, fluorescence quantum yield near 685 nm of LHCII was enhanced, the fluorescence excitation intensity near 440 and 480 nm of LHCII significantly rose and F ₄₈₀/F ₄₄₀ ratio was reduced. Oxygen evolution rate of PSII was greatly improved. Together, nano-anatase promoted energy transferring from chlorophyll (chl) b and carotenoid to chl a, and nano-anatase TiO₂ was photosensitized by chl of LHCII, which led to enhance the efficiency of absorbing, transferring, and converting light energy.     

Isolation and Characterization of Phosphatase from Thylakoid Membranes of Spinach Chloroplasts

A phosphatase from thylakoid membrane of spinach (Spinacia oleracea L. ) chloroplasts was isolated with the methods of extraction with n-ButanoL centrifugation at 100000 g for 30 min and chromatographic separation through DEAE-Cellulose (DE 52) column.The phosphatase catalyzed hydrolysis of phosphate monoesters (4-nitrophenyl phosphate). The optimal pH for enzyme catalysis was below 7. The peak rate of the enzyme reaction was obtained when it was incubated at 60℃ for 15 min. The phosphatase was inhibited by ATP and phosphate. The results from SDS-PAGE showed that the preparation of enzyme was composed of two proteins.     

The Effects of Illumination on the Xanthophyll Composition of the Photosystem II Light-Harvesting Complexes of Spinach Thylakoid Membranes

The xanthophyll composition of the light-harvesting chlorophyll a/b proteins of photosystem II (LHCII) has been determined for spinach (Spinacia oleracea L.) leaves after dark adaptation and following illumination under conditions optimized for conversion of violaxanthin into zeaxanthin. Each of the four LHCII components was found to have a unique xanthophyll composition. The major carotenoid was lutein, comprising 60% of carotenoid in the bulk LHCIIb and 35 to 50% in the minor LHCII components LHCIIa, LHCIIc, and LHCIId. The percent of carotenoid found in the xanthophyll cycle pigments was approximately 10 to 15% in LHCIIb and 30 to 40% in LHCIIa, LHCIIc, and LHCIId. The xanthophyll cycle was active for the pigments bound to all of the LHCII components. The extent of deepoxidation for complexes prepared from light-treated leaves was 27, 65, 69, and 43% for LHCIIa, -b, -c, and -d, respectively. These levels of conversion of violaxanthin to zeaxanthin were found in LHCII prepared by three different isolation procedures. It was estimated that approximately 50% of the zeaxanthin associated with photosystem II is in LHCIIb and 30% is associated with the minor LHCII components.     

Localization of Cytochrome b-559 in the Chloroplast Thylakoid Membranes in Spinach

Cytochrome b-559 was purified from spinach leaves and antibodies were made against it in rabbit. Using affinity-purified, monospecific antibodies, we have found that cytochrome b-559, which is closely associated with the primary photochemical activity of photosystem II, is localized exclusively in the grana thylakoids.     

Selective Photoinhibition of Photosystem I in Isolated Thylakoid Membranes from Cucumber and Spinach

The site of photoinhibition at low temperatures in leaves ofa chilling-sensitive plant, cucumber, is photosystem I [Terashimaet al. (1994) Planta 193: 300]. As described herein, selectivephotoinhibition of PSI can also be induced in isolated thylakoidmembranes in vitro. Inhibition was observed both at chillingtemperatures and at 25°C, and not only in the thylakoidmembranes isolated from cucumber, but also in those isolatedfrom a chilling-tolerant plant, spinach. Comparison of theseobservations in vitro to the earlier results in vivo indicatesthat (1) photoinhibition of PSI is a universal phenomenon; (2)a mechanism exists to protect PSI in vivo; and (3) the protectivemechanism is chilling-sensitive in cucumber. The chilling-sensitivecomponent seems to be lost during the isolation of thylakoidmembranes. Very weak light (10–20µmol m^-2 s^-1) wassufficient to cause the inhibition of PSI. About 80% of theoxygen-evolving activity by PSII was maintained even after theactivity of PSI had decreased by more than 70%. This is thefirst report of the selective photoinhibition of PSI in vitro. (Received March 1, 1995; Accepted April 26, 1995)     

Ion Channel Permeable for Divalent and Monovalent Cations in Native Spinach Thylakoid Membranes

A cation-selective channel was characterized in isolated patches from osmotically swollen thylakoids of spinach (Spinacea oleracea). This channel was permeable for K⁺ as well as for Mg²⁺ and Ca²⁺ but not for Cl⁻. When K⁺ was the main permeant ion (symmetrical 105 mm KCl) the conductance of the channel was about 60 pS. The single channel conductance for different cations followed a sequence K⁺ > Mg²⁺≥ Ca²⁺. The permeabilities determined by reversal potential measurements were comparable for K⁺, Ca²⁺, and Mg²⁺. The cation channel displayed bursting behavior. The total open probability of the channel increased at more positive membrane potentials. Kinetic analysis demonstrated that voltage dependence of the total open probability was determined by the probability of bursts formation while the probability to find the channel in open state within a burst of activity was hardly voltage-dependent. The cation permeability of intact spinach thylakoids can be explained on the single channel level by the data presented here. Received: 26 December 1995/Revised: 17 April 1996     

The FAD-Enzyme Monodehydroascorbate Radical Reductase Mediates Photoproduction of Superoxide Radicals in Spinach Thylakoid Membranes

The photoreduction of dioxygen in spinach thylakoid membraneswas enhanced about 10-fold by the FAD-enzyme monodehydroascorbateradical (MDA) reductase at 1µM. The primary photoreducedproduct of dioxygen catalyzed by MDA reductase was the superoxideradical, as evidenced by the inhibition of photoreduction ofCytc by superoxide dismutase. The apparent K_m for dioxygen ofthe MDA reductase-dependent photoreduction of dioxygen was 100µM,higher by one order of magnitude than that observed with thylakoidmembranes only. Glutathione reductase, ferredoxin-NADP⁺ reductase,and glycolate oxi-dase also mediated the photoproduction ofsuperoxide radicals in thylakoid membranes at rates similarto those with MDA reductase. Among these flavoenzymes, MDA reductaseis the most likely mediator stimulating the photoreduction ofdioxygen in chloroplasts; its function in the protection fromphotoinhibition under excess light is discussed. (Received February 24, 1998; Accepted May 19, 1998)     

Nanodomains of Cytochrome b6f and Photosystem II Complexes in Spinach Grana Thylakoid Membranes

The cytochrome b₆f (cytb₆f) complex plays a central role in photosynthesis, coupling electron transport between photosystem II (PSII) and photosystem I to the generation of a transmembrane proton gradient used for the biosynthesis of ATP. Photosynthesis relies on rapid shuttling of electrons by plastoquinone (PQ) molecules between PSII and cytb₆f complexes in the lipid phase of the thylakoid membrane. Thus, the relative membrane location of these complexes is crucial, yet remains unknown. Here, we exploit the selective binding of the electron transfer protein plastocyanin (Pc) to the lumenal membrane surface of the cytb₆f complex using a Pc-functionalized atomic force microscope (AFM) probe to identify the position of cytb₆f complexes in grana thylakoid membranes from spinach (Spinacia oleracea). This affinity-mapping AFM method directly correlates membrane surface topography with Pc-cytb₆f interactions, allowing us to construct a map of the grana thylakoid membrane that reveals nanodomains of colocalized PSII and cytb₆f complexes. We suggest that the close proximity between PSII and cytb₆f complexes integrates solar energy conversion and electron transfer by fostering short-range diffusion of PQ in the protein-crowded thylakoid membrane, thereby optimizing photosynthetic efficiency.     

The FAD-Enzyme Monodehydroascorbate Radical Reductase Mediates Photoproduction of Superoxide Radicals in Spinach Thylakoid Membranes

The photoreduction of dioxygen in spinach thylakoid membraneswas enhanced about 10-fold by the FAD-enzyme monodehydroascorbateradical (MDA) reductase at 1 µM. The primary photoreducedproduct of dioxygen catalyzed by MDA reductase was the superoxideradical, as evidenced by the inhibition of photoreduction ofCyt c by superoxide dismutase. The apparent K_m for dioxygenof the MDA reductase-dependent photoreduction of dioxygen was100 µM, higher by one order of magnitude than that observedwith thylakoid membranes only. Glutathione reductase, ferredoxin-NADP⁺reductase, and glycolate oxidase also mediated the photoproductionof superoxide radicals in thylakoid membranes at rates similarto those with MDA reductase. Among these flavoenzymes, MDA reductaseis the most likely mediator stimulating the photoreduction ofdioxygen in chloroplasts; its function in the protection fromphotoinhibition under excess light is discussed. (Received February 24, 1998; Accepted May 19, 1998)     

Glycinebetaine Stabilizes Photosystem 1 and Photosystem 2 Electron Transport in Spinach Thylakoid Membranes Against Heat Inactivation

Glycinebetaine, a compatible osmolyte of halotolerant plants and bacteria, partially protected photosystem (PS) 1 and PS2 electron transport reactions against thermal inactivation but with different efficiencies. In its presence, the temperature for half-maximal inactivation (t_1/2) was generally shifted downward by 3–12 °C. Glycinebetaine stabilized photoinduced oxygen evolving reactions of PS2 by protecting the tetranuclear Mn cluster and the extrinsic proteins of this complex. A weaker, although noticeable, stabilizing effect was observed in photoinduced PS2 electron transport reactions that did not originate in the oxygen-evolving complex (OEC). This weaker protection by glycinebetaine was probably exerted on the PS2 reaction centre. Glycinebetaine protected also photoinduced electron transport across PS1 against thermal inactivation. The protective effect was exerted on plastocyanin, the mobile protein in the lumen that carries electrons from the integral cytochrome b ₆ f complex to the PS1 complex. This revised version was published online in June 2006 with corrections to the Cover Date.     

盐酸胍对大麦类囊体膜能量分配和电子传递的影响

本文以大麦叶片为实验材料,研究了盐酸胍修饰对类囊体膜能量分配及电子传递的影响。结果表明：盐酸胍处理类囊体膜,室温下Ｆ６８５荧光强度,随着盐酸胍浓度的增加而逐渐下降。盐酸胍处理导致类囊体膜在低温（７７Ｋ）下Ｆ６８５／Ｆ７８６比值下降,并随着盐酸胍浓度的增加而加剧。盐酸胍处理抑制类囊体膜以Ｈ２Ｏ为电子供体的ＤＣＩＰ光还原速度和Ｃｈｌａ诱导荧光产率,这种抑制作用可分别为加入ＰＳＩＩ的人工电子供体ＤＰＣ和     

Effects of Nano-anatase TiO<Subscript>2</Subscript> on Absorption,Distribution of Light,and Photoreduction Activities of Chloroplast Membrane of Spinach

The effects of nano-anatase TiO₂ on light absorption, distribution, and conversion, and photoreduction activities of spinach chloroplast were studied by spectroscopy. Several effects of nano-anatase TiO₂ were observed: (1) the absorption peak intensity of the chloroplast was obviously increased in red and blue region, the ratio of the Soret band and Q band was higher than that of the control; (2) the great enhancement of fluorescence quantum yield near 680 nm of the chloroplast was observed, the quantum yield under excitation wavelength of 480 nm was higher than the excitation wavelength of 440 nm; (3) the excitation peak intensity near 440 and 480 nm of the chloroplast significantly rose under emission wavelength of 680 nm, and F ₄₈₀ / F ₄₄₀ ratio was reduced; (4) when emission wavelength was at 720 nm, the excitation peaks near 650 and 680 nm were obviously raised, and F ₆₅₀ / F ₆₈₀ ratio rose; (5) the rate of whole chain electron transport, photochemical activities of PSII DCPIP photoreduction and oxygen evolution were greatly improved, but the photoreduction activities of PSI were a little changed. Together, the studies of the experiments showed that nano-anatase TiO₂ could increase absorption of light on spinach chloroplast and promote excitation energy to be absorbed by LHCII and transferred to PSII and improve excitation energy from PSI to be transferred to PSII, thus, promote the conversion from light energy to electron energy and accelerate electron transport, water photolysis, and oxygen evolution.     

A Fluorescence Detected Magnetic Resonance Investigation of the Carotenoid Triplet States Associated with Photosystem II of Isolated Spinach Thylakoid Membranes

The carotenoid triplet populations associated with the fluorescence emission chlorophyll forms of Photosystem II have been investigated in isolated spinach thylakoid membranes by means of fluorescence detected magnetic resonance in zero field (FDMR). The spectra collected in the 680–690 nm emission range, have been fitted by a global analysis procedure. At least five different carotenoid triplet states coupled to the terminal emitting chlorophyll forms of PS II, peaking at 682 nm, 687 nm and 692 nm, have been characterised. The triplets associated with the outer antenna emission forms, at 682 nm, have zero field splitting parameters |D| = 0.0385 cm⁻¹, |E| = 0.00367 cm⁻¹; |D| = 0.0404 cm⁻¹, |E| = 0.00379 cm⁻¹ and |D| = 0.0386 cm⁻¹, |E| = 0.00406 cm⁻¹ which are very similar to those previously reported for the xanthophylls of the isolated LHC II complex. Therefore the FDMR spectra recorded in this work provide insights into the organisation of the LHC II complex in the unperturbed environment represented by thylakoid membranes. The additional carotenoid triplet populations, detected by monitoring the chlorophyll emission at 687 and 692 nm, are assigned to carotenoids bound to inner antenna complexes and hence attributed to β-carotene molecules.     

Role of Plastid Transglutaminase in LHCII Polyamination and Thylakoid Electron and Proton Flow

Transglutaminases function as biological glues in animal cells, plant cells and microbes. In energy producing organelles such as chloroplasts the presence of transglutaminases was recently confirmed. Furthermore, a plastidial transglutaminase has been cloned from maize and the first plants overexpressing tgz are available (Nicotiana tabacum TGZ OE). Our hypothesis is that the overexpression of plastidal transglutaminase will alter photosynthesis via increased polyamination of the antenna of photosystem II. We have used standard analytical tools to separate the antenna from photosystem II in wild type and modified plants, 6 specific antibodies against LHCbs to confirm their presence and sensitive HPLC method to quantify the polyamination level of these proteins. We report that bound spermidine and spermine were significantly increased (～80%) in overexpressors. Moreover, we used recent advances in in vivo probing to study simultaneously the proton and electron circuit of thylakoids. Under physiological conditions overexpressors show a 3-fold higher sensitivity of the antenna down regulation loop (qE) to the elicitor (luminal protons) which is estimated as the ΔpH component of thylakoidal proton motive force. In addition, photosystem (hyper-PSIIα) with an exceptionally high antenna (large absorption cross section), accumulate in transglutaminase over expressers doubling the rate constant of light energy utilization (Kα) and promoting thylakoid membrane stacking. Polyamination of antenna proteins is a previously unrecognized mechanism for the modulation of the size (antenna absorption cross section) and sensitivity of photosystem II to down regulation. Future research will reveal which peptides and which residues of the antenna are responsible for such effects.     

Fluorescence Spectral Dynamics of Single LHCII Trimers

Single-molecule spectroscopy was employed to elucidate the fluorescence spectral heterogeneity and dynamics of individual, immobilized trimeric complexes of the main light-harvesting complex of plants in solution near room temperature. Rapid reversible spectral shifts between various emitting states, each of which was quasi-stable for seconds to tens of seconds, were observed for a fraction of the complexes. Most deviating states were characterized by the appearance of an additional, red-shifted emission band. Reversible shifts of up to 75 nm were detected. By combining modified Redfield theory with a disordered exciton model, fluorescence spectra with peaks between 670 nm and 705 nm could be explained by changes in the realization of the static disorder of the pigment-site energies. Spectral bands beyond this wavelength window suggest the presence of special protein conformations. We attribute the large red shifts to the mixing of an excitonic state with a charge-transfer state in two or more strongly coupled chlorophylls. Spectral bluing is explained by the formation of an energy trap before excitation energy equilibration is completed.     

Irradiance Effects on Thylakoid Membranes of the Red Alga Porphyridium cruentum. An Immunocytochemical Study

Immunogold labelling on ultrathin sections of the red alga Porphyridiumcruentum (ATCC 50161) was used to assess changes in the densityand distribution of polypeptide components of photosystem I,photosystem II, phycobilisomes, and ATP synthase within thethylakoid membrane as a function of growth irradiance. In cellsgrown under a low, limiting quantum flux (6 microeinsteins persquare meter per second of continuous white light) thylakoidmembrane density and total thylakoid area per cell are 2 1/2times greater than in cells grown under a high, saturating quantumflux (280 microeinsteins per square meter per second). Immunogoldlabelling data indicate that concentrations of photosystem I,photosystem II and phycobilisomes in thylakoids of low light-growncells are only slightly greater than in cells grown under highlight. In contrast, the concentration of ATP synthase withinthe thylakoid membrane is nearly ten times greater in high light-growncells. Photosystem I polypeptides were detected in those portionsof the thylakoid membrane which traverse the pyrenoid, but photosystemII and phycobilisomes appeared to be absent from these membranes.Ribulose-l,5-bisphosphate carboxylase was restricted primarilyto the pyrenoid, and its concentration in the stroma or pyrenoidwas little affected by the photon flux density. Quantitativeestimates of photosystems I and II, phycobilisomes, and ATPsynthase by spectroscopy or by immunoelectrophoresis are inaccord with the immunogold results and lend support to the useof immunogold labelling for quantifying changes in relativeamounts of membrane proteins. (Received October 29, 1990; Accepted February 4, 1991)     

Transformation of Thylakoid Membranes during Differentiation from Vegetative Cell into Heterocyst Visualized by Microscopic Spectral Imaging

Some filamentous cyanobacteria carry out oxygenic photosynthesis in vegetative cells and nitrogen fixation in specialized cells known as heterocysts. Thylakoid membranes in vegetative cells contain photosystem I (PSI) and PSII, while those in heterocysts contain predominantly PSI. Therefore, the thylakoid membranes change drastically when differentiating from a vegetative cell into a heterocyst. The dynamics of these changes have not been sufficiently characterized in situ. Here, we used time-lapse fluorescence microspectroscopy to analyze cells of Anabaena variabilis under nitrogen deprivation at approximately 295 K. PSII degraded simultaneously with allophycocyanin, which forms the core of the light-harvesting phycobilisome. The other phycobilisome subunits that absorbed shorter wavelengths persisted for a few tens of hours in the heterocysts. The whole-thylakoid average concentration of PSI was similar in heterocysts and nearby vegetative cells. PSI was best quantified by selective excitation at a physiological temperature (approximately 295 K) under 785-nm continuous-wave laser irradiation, and detection of higher energy shifted fluorescence around 730 nm. Polar distribution of thylakoid membranes in the heterocyst was confirmed by PSI-rich fluorescence imaging. The findings and methodology used in this work increased our understanding of how photosynthetic molecular machinery is transformed to adapt to different nutrient environments and provided details of the energetic requirements for diazotrophic growth.The most essential pigment-protein complexes for oxygenic photosynthesis are PSI and PSII, which are embedded in the thylakoid membranes of chloroplasts and cyanobacteria. Cooperation between PSI and PSII achieves light-driven noncyclic electron transport from the oxidative splitting of water to the reduction of ferredoxin and is accompanied by the generation of a proton gradient for ATP synthesis. Phycobilisomes (PBS), another pigment-protein complex, are attached to the stromal side of the thylakoid membrane in cyanobacteria and red algae; they work as light-harvesting antennae to transfer electronic excitation energy mainly to PSII and, in some cases, to PSI (Gantt 1994). The integration of these pigment-protein complexes changes in response to light conditions, nutrient status, and developmental stage (Fujita et al., 1994; Grossman et al., 1994; Wolk et al., 1994).Some cyanobacteria, including Anabaena variabilis, are able to grow diazotrophically using the nitrogen-fixing enzyme nitrogenase. Because nitrogenase is sensitive to oxygen, oxygenic photosynthesis is not readily compatible with diazotrophic growth. When this filamentous cyanobacterium is grown under fixed nitrogen-deficient conditions, approximately 1 in 10 to 20 vegetative cells differentiates into a heterocyst, in which oxygenic photosynthesis is suppressed and nitrogenase becomes operative (Haselkorn, 1978; Wolk et al., 1994). The other vegetative cells continue oxygenic photosynthesis. The differentiation of heterocysts from chains of vegetative cells has been studied extensively (Golden and Yoon, 2003; Toyoshima et al., 2010). The abundances of PSII and PBS decrease during the transition. PSI appears to persist in the heterocyst to produce ATP by cyclic electron transport, because nitrogen fixation demands a large amount of ATP (Wolk et al., 1994). However, the mechanisms by which PBS and PSII are degraded during heterocyst differentiation remain unclear, and whether the amount of PSI per cell changes is unknown.The PBS of A. variabilis contain three types of phycobiliproteins, pigment-protein complexes with distinct absorption and fluorescence spectra. The core PBS contains allophycocyanin (APC), which absorbs around 654 nm (Ying and Xie, 1998); the core is most closely connected to PSII. More peripherally in the PBS, the so-called rod contains phycoerythrocyanin (PEC) and phycocyanin (PC), which absorb maximally around 575 and 604 to 620 nm, respectively (Switalski and Sauer, 1984; Zhang et al., 1998). Photon energy is absorbed by PEC, then transferred downhill through PC and APC and finally to PSII. The structure of PBS is probably optimized not only for efficient energy transfer to PSII and/or PSI but also for transformation and/or degradation under various nutrient conditions. However, the order in which these subunits degrade during heterocyst differentiation remains unknown. One strategy to address this question is to isolate heterocysts at several stages during differentiation and quantify their proteomes via mass spectrometry. However, such isolation procedures work well only when there is a good understanding of the properties of cells at different stages. Ideally, noninvasive methods should be used to understand changes in the integrity of PSII and PBS in intact cells in filaments.In principle, time-lapse microscopic observations can clarify the process of differentiation from a vegetative cell into a mature heterocyst. Spectral microscopy is an ideal tool to analyze physiological state and/or amounts of pigment-protein complexes under various conditions. Acquiring microscopic fluorescence spectra of individual cells is a natural extension of laser scanning confocal fluorescence microscopy, which has been applied to several types of cyanobacterial cells, including heterocysts (Peterson et al., 1981; Ying et al., 2002; Wolf and Schüssler, 2005; Kumazaki et al., 2007; Vermaas et al., 2008; Sukenik et al., 2009; Bordowitz and Montgomery, 2010; Collins et al., 2012, Sugiura and Itoh, 2012). Microscopic fluorescence spectra reflect the concentration of pigment-protein complexes and the energy transfer dynamics between photosynthetic pigments. However, to date, there have been no thorough time-lapse investigations of the fluorescence spectra of heterocysts and vegetative cells during the differentiation process.In this study, we investigated the dynamic changes in thylakoid membranes of A. variabilis during heterocyst differentiation. Our unique microscopic system can acquire fluorescence spectra from an entire linearly illuminated region with about 2-nm wavelength resolution in a single exposure (Kumazaki et al., 2007). Heterocyst formation was induced by transferring vegetative cell filaments from fixed-nitrogen-sufficient incubation medium to nitrogen-deprived medium. We conducted long-term observations (60–96 h) on identical filaments. Another unique feature of our setup is that it uses a near-infrared (NIR) excitation laser source. Our previous microspectroscopic study of chloroplasts of a higher plant, maize (Zea mays), and a green alga (Parachlorella kessleri) showed that continuous wave (CW) laser light emitting at 785 to 820 nm excited PSI with high selectivity under the one-photon excitation (OPE) mode. This enabled us to observe highly PSI-rich fluorescence spectra and images with signals around 710 to 740 nm, even at approximately 295 K (Hasegawa et al., 2010, 2011). We used this technique to quantify PSI in individual heterocysts compared with its parental and contiguous vegetative cells. Pigment fluorescence under OPE qualitatively differed from that under two-photon excitation (TPE) using a pulsed NIR laser (typically achieved with picosecond or femtosecond pulses), because TPE using 800 to 830 nm resulted in spectra with contributions from PBS, PSII, and PSI, as typically observed by visible light excitation (Kumazaki et al., 2007; Hasegawa et al., 2010, 2011). The advantages of our microscopic system are the high wavelength resolution and coverage of the entire fluorescence spectrum, the availability of fluorescence spectra at several differentiation stages, and the multiple excitation modes with different selectivities for pigment-protein complexes. Together, these analyses allowed us to characterize spectral decomposition and to understand the time dependence of different pigment-protein complexes, even at a physiological temperature. Microscopic absorption spectra were also obtained from single cells. These data were tentatively used to estimate the absolute concentrations of PSI and PSII in heterocysts and vegetative cells.     

Role of Plastid Protein Phosphatase TAP38 in LHCII Dephosphorylation and Thylakoid Electron Flow

Short-term changes in illumination elicit alterations in thylakoid protein phosphorylation and reorganization of the photosynthetic machinery. Phosphorylation of LHCII, the light-harvesting complex of photosystem II, facilitates its relocation to photosystem I and permits excitation energy redistribution between the photosystems (state transitions). The protein kinase STN7 is required for LHCII phosphorylation and state transitions in the flowering plant Arabidopsis thaliana. LHCII phosphorylation is reversible, but extensive efforts to identify the protein phosphatase(s) that dephosphorylate LHCII have been unsuccessful. Here, we show that the thylakoid-associated phosphatase TAP38 is required for LHCII dephosphorylation and for the transition from state 2 to state 1 in A. thaliana. In tap38 mutants, thylakoid electron flow is enhanced, resulting in more rapid growth under constant low-light regimes. TAP38 gene overexpression markedly decreases LHCII phosphorylation and inhibits state 1→2 transition, thus mimicking the stn7 phenotype. Furthermore, the recombinant TAP38 protein is able, in an in vitro assay, to directly dephosphorylate LHCII. The dependence of LHCII dephosphorylation upon TAP38 dosage, together with the in vitro TAP38-mediated dephosphorylation of LHCII, suggests that TAP38 directly acts on LHCII. Although reversible phosphorylation of LHCII and state transitions are crucial for plant fitness under natural light conditions, LHCII hyperphosphorylation associated with an arrest of photosynthesis in state 2 due to inactivation of TAP38 improves photosynthetic performance and plant growth under state 2-favoring light conditions.