Supramolecular organization of photosystem II and its light-harvesting antenna in partially solubilized photosystem II membranes.

We present an extended analysis of the organization of green plant photosystem II and its associated light-harvesting antenna using electron microscopy and image analysis. The analysis is based on a large dataset of 16 600 projections of negatively stained PSII-LHCII supercomplexes and megacomplexes prepared by means of three different pretreatments. In addition to our previous work on this system [Boekema, E.J., van Roon, H., Calkoen, F., Bassi, R. and Dekker, J.P. (1999) Biochemistry 38, 2233-2239], the following results were obtained. The rotational orientation of trimeric LHCII at the S, M and L binding positions was determined. It was found that compared to the S trimer, the M and L trimers are rotationally shifted by about -20 degrees and -50 degrees, respectively. The number of projections with empty CP29, CP26 and CP24 binding sites was found to be about 0, 18 and 4%, respectively. We suggest that CP26 and CP24 are not required for the binding of trimeric LHCII at any of the three binding positions. A new type of megacomplex was observed with a characteristic windmill-like shape. This type III megacomplex consists of two C2S2 supercomplexes connected at their CP26 tips. Structural variation in the region of the central dimeric photosystem II complex was found to occur at one specific position near the periphery of the complex. We attribute this variation to the partial absence of an extrinsic polypeptide or one or more small intrinsic membrane proteins.     

Multiple types of association of photosystem II and its light-harvesting antenna in partially solubilized photosystem II membranes

Photosystem II is a multisubunit pigment-protein complex embedded in the thylakoid membranes of chloroplasts. It utilizes light for photochemical energy conversion, and is heavily involved in the regulation of the energy flow. We investigated the structural organization of photosystem II and its associated light-harvesting antenna by electron microscopy, multivariate statistical analysis, and classification procedures on partially solubilized photosystem II membranes from spinach. Observation by electron microscopy shortly after a mild disruption of freshly prepared membranes with the detergent n-dodecyl-alpha,D-maltoside revealed the presence of several large supramolecular complexes. In addition to the previously reported supercomplexes [Boekema, E. J., van Roon, H., and Dekker, J. P. (1998) FEBS Lett. 424, 95-99], we observed complexes with the major trimeric chlorophyll a/b protein (LHCII) in a third, L-type of binding position (C2S2M0-2L1-2), and two different types of megacomplexes, both identified as dimeric associations of supercomplexes with LHCII in two types of binding sites (C4S4M2-4). We conclude that the association of photosystem II and its associated light-harvesting antenna is intrinsically heterogeneous, and that the minor CP26 and CP24 proteins play a crucial role in the supramolecular organization of the complete photosystem. We suggest that different types of organization form the structural basis for photosystem II to specifically react to changing light and stress conditions, by providing different routes of excitation energy transfer.     

Proteomic approach to characterize the supramolecular organization of photosystems in higher plants

A project to investigate the supramolecular structure of photosystems was initiated, which is based on protein solubilizations by digitonin, protein separations by Blue native (BN)-polyacrylamide gel electrophoresis (PAGE) and protein identifications by mass spectrometry (MS). Under the conditions applied, nine photosystem supercomplexes could be described for chloroplasts of Arabidopsis, which have apparent molecular masses between 600 and 3200 kDa on BN gels. Identities of the supercomplexes were determined on the basis of their subunit compositions as documented by 2D BN/SDS-PAGE and BN/BN-PAGE. Two supercomplexes of 1060 and approximately 1600 kDa represent dimeric and trimeric forms of photosystem I (PSI), which include tightly bound LHCI proteins. Compared to monomeric PSI, these protein complexes are of low abundance. In contrast, photosystem II mainly forms part of dominant supercomplexes of 850, 1000, 1050 and 1300 kDa. According to our interpretation, these supercomplexes contain dimeric PSII, 1-4 LHCII trimers and additionally monomeric LHCII proteins. The 1300-kDa PSII supercomplex (containing four LHCII trimers) is partially converted into the 1000-kDa PSII supercomplex (containing two LHCII trimers) in the presence of dodecylmaltoside on 2D BN/BN gels. Analyses of peptides of the trypsinated 1300-kDa PSII supercomplex by mass spectrometry allowed to identify known subunits of the PSII core complex and additionally LHCII proteins encoded by eight different genes in Arabidopsis. Further application of this experimental approach will allow new insights into the supermolecular organization of photosystems in plants.     

Structural variability of plant photosystem II megacomplexes in thylakoid membranes

Plant photosystem II (PSII) is organized into large supercomplexes with variable levels of membrane‐bound light‐harvesting proteins (LHCIIs). The largest stable form of the PSII supercomplex involves four LHCII trimers, which are specifically connected to the PSII core dimer via monomeric antenna proteins. The PSII supercomplexes can further interact in the thylakoid membrane, forming PSII megacomplexes. So far, only megacomplexes consisting of two PSII supercomplexes associated in parallel have been observed. Here we show that the forms of PSII megacomplexes can be much more variable. We performed single particle electron microscopy (EM) analysis of PSII megacomplexes isolated from Arabidopsis thaliana using clear‐native polyacrylamide gel electrophoresis. Extensive image analysis of a large data set revealed that besides the known PSII megacomplexes, there are distinct groups of megacomplexes with non‐parallel association of supercomplexes. In some of them, we have found additional LHCII trimers, which appear to stabilize the non‐parallel assemblies. We also performed EM analysis of the PSII supercomplexes on the level of whole grana membranes and successfully identified several types of megacomplexes, including those with non‐parallel supercomplexes, which strongly supports their natural origin. Our data demonstrate a remarkable ability of plant PSII to form various larger assemblies, which may control photochemical usage of absorbed light energy in plants in a changing environment.     

Fine structure of granal thylakoid membrane organization using cryo electron tomography

The architecture of grana membranes from spinach chloroplasts was studied by cryo electron tomography. Tomographic reconstructions of ice-embedded isolated grana stacks enabled to resolve features of photosystem II (PSII) in the native membrane and to assign the absolute orientation of individual membranes of granal thylakoid discs. Averaging of 3D sub-volumes containing PSII complexes provided a 3D structure of the PSII complex at 40 ? resolution. Comparison with a recently proposed pseudo-atomic model of the PSII supercomplex revealed the presence of unknown protein densities right on top of 4 light harvesting complex II (LHCII) trimers at the lumenal side of the membrane. The positions of individual dimeric PSII cores within an entire membrane layer indicates that about 23% supercomplexes must be of smaller size than full C(2)S(2)M(2) supercomplexes, to avoid overlap.     

Unique organization of photosystem II supercomplexes and megacomplexes in Norway spruce

Photosystem II (PSII) complexes are organized into large supercomplexes with variable amounts of light‐harvesting proteins (Lhcb). A typical PSII supercomplex in plants is formed by four trimers of Lhcb proteins (LHCII trimers), which are bound to the PSII core dimer via monomeric antenna proteins. However, the architecture of PSII supercomplexes in Norway spruce[Picea abies (L.) Karst.] is different, most likely due to a lack of two Lhcb proteins, Lhcb6 and Lhcb3. Interestingly, the spruce PSII supercomplex shares similar structural features with its counterpart in the green alga Chlamydomonas reinhardtii [Kou?il et al. (2016) New Phytol. 210 , 808–814]. Here we present a single‐particle electron microscopy study of isolated PSII supercomplexes from Norway spruce that revealed binding of a variable amount of LHCII trimers to the PSII core dimer at positions that have never been observed in any other plant species so far. The largest spruce PSII supercomplex, which was found to bind eight LHCII trimers, is even larger than the current largest known PSII supercomplex from C. reinhardtii. We have also shown that the spruce PSII supercomplexes can form various types of PSII megacomplexes, which were also identified in intact grana membranes. Some of these large PSII supercomplexes and megacomplexes were identified also in Pinus sylvestris, another representative of the Pinaceae family. The structural variability and complexity of LHCII organization in Pinaceae seems to be related to the absence of Lhcb6 and Lhcb3 in this family, and may be beneficial for the optimization of light‐harvesting under varying environmental conditions.     

PHOTOSYSTEM II SUBUNIT R Is Required for Efficient Binding of LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 to Photosystem II-Light-Harvesting Supercomplexes in Chlamydomonas reinhardtii

In Chlamydomonas reinhardtii, the LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 (LHCSR3) protein is crucial for efficient energy-dependent thermal dissipation of excess absorbed light energy and functionally associates with photosystem II-light-harvesting complex II (PSII-LHCII) supercomplexes. Currently, it is unknown how LHCSR3 binds to the PSII-LHCII supercomplex. In this study, we investigated the role of PHOTOSYSTEM II SUBUNIT R (PSBR) an intrinsic membrane-spanning PSII subunit, in the binding of LHCSR3 to PSII-LHCII supercomplexes. Down-regulation of PSBR expression diminished the efficiency of oxygen evolution and the extent of nonphotochemical quenching and had an impact on the stability of the oxygen-evolving complex as well as on PSII-LHCII-LHCSR3 supercomplex formation. Its down-regulation destabilized the PSII-LHCII supercomplex and strongly reduced the binding of LHCSR3 to PSII-LHCII supercomplexes, as revealed by quantitative proteomics. PHOTOSYSTEM II SUBUNIT P deletion, on the contrary, destabilized PHOTOSYSTEM II SUBUNIT Q binding but did not affect PSBR and LHCSR3 association with PSII-LHCII. In summary, these data provide clear evidence that PSBR is required for the stable binding of LHCSR3 to PSII-LHCII supercomplexes and is essential for efficient energy-dependent quenching and the integrity of the PSII-LHCII-LHCSR3 supercomplex under continuous high light.Plant photosynthetic electron transfer is conducted by a series of reactions at the chloroplast thylakoid membrane, resulting in light-dependent water oxidation, NADP reduction, and ATP formation (Whatley et al., 1963). Two separate photosystems (PSI and PSII) and an ATP synthase catalyze these reactions. PSI and PSII are multiprotein complexes that are mainly embedded in unstacked and stacked regions of the thylakoid membrane, respectively. PSI consists of more than 10 subunits and a number of cofactors such as chlorophyll a, β-carotene, phylloquinone, and three iron-sulfur (4Fe-4S) clusters (Busch and Hippler, 2011). PSI catalyzes light-driven electron transfer from luminal plastocyanin to stromal ferredoxin. The latter reduces the ferredoxin-NADP reductase that, in turn, leads to the formation of NADPH. PSII catalyzes light-induced electron transfer from water to the plastoquinone pool by using chlorophyll a, carotenoids, as well as redox-active cofactors, causing the release of oxygen and protons (Pagliano et al., 2013). The core complex is organized as a dimer. Monomers are composed of the reaction center subunits PSBA (D1) and PSBD (D2), the inner antenna proteins PSBB (CP47) and PSBC (CP43), the α- and β-subunits (PSBE and PSBF) of cytochrome b₅₅₉, as well as a number of intrinsic low-molecular-mass subunits. The core monomer is further associated with an inorganic Mn₄O₅Ca cluster and a few chloride ions (Rivalta et al., 2011; Umena et al., 2011) required for photosynthetic water oxidation. To optimize this process, the oxygen-evolving complex is formed at the luminal side by the extrinsic polypeptides PSBO, PSBP, PSBQ, and PSBR (for review, see Pagliano et al., 2013).To enhance the light-harvesting capacity of PSII, various light-harvesting proteins bind to dimeric PSII core complexes (Dekker and Boekema, 2005). A common structure found for vascular plants and green algae is the C₂S₂ supercomplex, where two copies of monomeric Lhcb4 and Lhcb5 and two LHCII trimers (S-trimer; Boekema et al., 1995) bind to the dimeric PSII core. In vascular plants, larger but less stable PSII supercomplexes, known as C₂S₂M₂, are composed of two extra copies of the monomeric Lhcb6 with two additional LHCII trimers (M-trimer) bound through Lhcb4 and Lhcb5 (Dekker and Boekema, 2005; Caffarri et al., 2009). Even larger complexes containing two additional LHCII trimers (L-trimer), bound via Lhcb6, are found and are known as C₂S₂M₂L_1–2 (Boekema et al., 1999). A recent study in Chlamydomonas reinhardtii identified PSII-LHCII supercomplexes with three LHCII trimers attached to each side of the core (C₂S₂M₂L₂; Tokutsu et al., 2012). Interestingly, such PSII-LHCII supercomplexes associate with LIGHT-HARVESTING COMPLEX STRESS-RELATED PROTEIN3 (LHCSR3; Tokutsu and Minagawa, 2013), an ancient light-harvesting protein required for efficient energy-dependent (qE) quenching in the alga (Peers et al., 2009). The qE component of nonphotochemical quenching (NPQ) is an energy-dependent constituent of NPQ and regulates the thermal dissipation of excess absorbed light energy (Li et al., 2000; Peers et al., 2009). The qE capacity in C. reinhardtii increases proportionally to the light-dependent accumulation of the LHCSR3 protein (Peers et al., 2009). In contrast, in vascular plants, qE is constitutively active and dependent on PSBS, a PSII polypeptide (Li et al., 2000). Mass spectrometric analyses of isolated C₂S₂M₂ PSII supercomplexes revealed the presence of extrinsic subunits PSBP, PSBQ, and PSBR, while PSBS was not identified, suggesting that PSBS does not influence the association of the PSII core with the outer light-harvesting complex system (Pagliano et al., 2014). In line with the proteomic findings, recent data suggest that subunits PSBP, PSBQ, and PSBR contribute to the stability of PSII-LHCII supercomplexes in vascular plants (Caffarri et al., 2009; Ifuku et al., 2011; Allahverdiyeva et al., 2013). A recent quantitative proteomic study performed with C. reinhardtii identified PSBR as the only PSII subunit to be induced upon the shift from photoheterotrophic to photoautotrophic growth conditions similar to LHCSR3 (Höhner et al., 2013).In vascular plants and green algae, PSBR is nucleus encoded and has a mass of about 10 kD. The mature protein has a predicted 70-amino acid luminal N-terminal part and a C-terminal transmembrane span (Ljungberg et al., 1986; Lautner et al., 1988; Webber et al., 1989). An association of PSBR with the oxygen-evolving complex has been suggested, as its presence is required for the stable assembly of PSBP with the PSII core and its absence also impacts the binding of PSBQ to the core (Suorsa et al., 2006; Liu et al., 2009). For stable association with the PSII core complex, PSBR needs the presence of PSBJ (Suorsa et al., 2006). Functionally, the depletion of PSBR protein expression decreased rates of oxygen evolution (Allahverdiyeva et al., 2007, 2013) and quinone reoxidation (Allahverdiyeva et al., 2007). PSBR phosphorylation is known for Arabidopsis (Arabidopsis thaliana; Reiland et al., 2009, 2011; Nakagami et al., 2010) and in the green alga C. reinhardtii (Turkina et al., 2006), although phosphorylation sites are not conserved between the alga and the vascular plant.In this work, we addressed the question of whether down-regulation of PSBR expression would affect LHCSR3 binding to the PSII-LHCII supercomplex in C. reinhardtii. To this end, we took advantage of artificial microRNA (amiRNA) technology to down-regulate PSBR expression and investigated the impact of PSBR down-regulation on photosynthetic performance as well as on PSII-LHCII-LHCSR3 supercomplex formation. Our data provide evidence that PSBR is required for the stable binding of LHCSR3 to PSII-LHCII supercomplexes.     

Revisiting the Supramolecular Organization of Photosystem II in Chlamydomonas reinhardtii

Photosystem II (PSII) is a multiprotein complex that splits water and initiates electron transfer in photosynthesis. The central part of PSII, the PSII core, is surrounded by light-harvesting complex II proteins (LHCIIs). In higher plants, two or three LHCII trimers are seen on each side of the PSII core whereas only one is seen in the corresponding positions in Chlamydomonas reinhardtii, probably due to the absence of CP24, a minor monomeric LHCII. Here, we re-examined the supramolecular organization of the C. reinhardtii PSII-LHCII supercomplex by determining the effect of different solubilizing detergents. When we solubilized the thylakoid membranes with n-dodecyl-β-d-maltoside (β-DM) or n-dodecyl-α-d-maltoside (α-DM) and subjected them to gel filtration, we observed a clear difference in molecular mass. The α-DM-solubilized PSII-LHCII supercomplex bound twice more LHCII than the β-DM-solubilized supercomplex and retained higher oxygen-evolving activity. Single-particle image analysis from electron micrographs of the α-DM-solubilized and negatively stained supercomplex revealed that the PSII-LHCII supercomplex had a novel supramolecular organization, with three LHCII trimers attached to each side of the core.     

The mobile thylakoid phosphoprotein TSP9 interacts with the light-harvesting complex II and the peripheries of both photosystems

The localization of the plant-specific thylakoid-soluble phosphoprotein of 9 kDa, TSP9, within the chloroplast thylakoid membrane of spinach has been established by the combined use of fractionation, immunoblotting, cross-linking, and mass spectrometry. TSP9 was found to be exclusively confined to the thylakoid membranes, where it is enriched in the stacked grana membrane domains. After mild solubilization of the membranes, TSP9 migrated together with the major light-harvesting antenna (LHCII) of photosystem II (PSII) and with PSII-LHCII supercomplexes upon separation of the protein complexes by either native gel electrophoresis or sucrose gradient centrifugation. Studies with a cleavable cross-linking agent revealed the interaction of TSP9 with both major and minor LHCII proteins as identified by mass spectrometric sequencing. Cross-linked complexes that in addition to TSP9 contain the peripheral PSII subunits CP29, CP26, and PsbS, which form the interface between LHCII and the PSII core, were found. Our observations also clearly suggest an interaction of TSP9 with photosystem I (PSI) as shown by both immunodetection and mass spectrometry. Sequencing identified the peripheral PSI subunits PsaL, PsaF, and PsaE, originating from cross-linked protein complexes of around 30 kDa that also contained TSP9. The distribution of TSP9 among the cross-linked forms was found to be sensitive to conditions such as light exposure. An association of TSP9 with LHCII as well as the peripheries of the photosystems suggests its involvement in regulation of photosynthetic light harvesting.     

Structural organization of photosynthetic apparatus in agranal chloroplasts of maize

We investigated the organization of photosystem II (PSII) in agranal bundle sheath thylakoids from a C(4) plant maize. Using blue native/SDS-PAGE and single particle analysis, we show for the first time that PSII in the bundle sheath (BS) chloroplasts exists in a dimeric form and forms light-harvesting complex II (LHCII).PSII supercomplexes. We also demonstrate that a similar set of photosynthetic membrane complexes exists in mesophyll and agranal BS chloroplasts, including intact LHCI.PSI supercomplexes, PSI monomers, PSII core dimers, PSII monomers devoid of CP43, LHCII trimers, LHCII monomers, ATP synthase, and cytochrome b(6)f complex. Fluorescence functional measurements clearly indicate that BS chloroplasts contain PSII complexes that are capable of performing charge separation and are efficiently sensitized by the associated LHCII. We identified a fraction of LHCII present within BS thylakoids that is weakly energetically coupled to the PSII reaction center; however, the majority of BS LHCII is shown to be tightly connected to PSII. Overall, we demonstrate that organization of the photosynthetic apparatus in BS agranal chloroplasts of a model C(4) plant is clearly distinct from that of the stroma lamellae of the C(3) plants. In particular, supramolecular organization of the dimeric LHCII.PSII in the BS thylakoids strongly suggests that PSII in the BS agranal membranes may donate electrons to PSI. We propose that the residual PSII activity may supply electrons to poise cyclic electron flow around PSI and prevent PSI overoxidation, which is essential for the CO(2) fixation in BS cells, and hence, may optimize ATP production within this compartment.     

Proteomic characterization of hierarchical megacomplex formation in Arabidopsis thylakoid membrane

Conversion of solar energy into chemical energy in plant chloroplasts concomitantly modifies the thylakoid architecture and hierarchical interactions between pigment–protein complexes. Here, the thylakoids were isolated from light‐acclimated Arabidopsis leaves and investigated with respect to the composition of the thylakoid protein complexes and their association into higher molecular mass complexes, the largest one comprising both photosystems (PSII and PSI) and light‐harvesting chlorophyll a/b‐binding complexes (LHCII). Because the majority of plant light‐harvesting capacity is accommodated in LHCII complexes, their structural interaction with photosystem core complexes is extremely important for efficient light harvesting. Specific differences in the strength of LHCII binding to PSII core complexes and the formation of PSII supercomplexes are well characterized. Yet, the role of loosely bound L‐LHCII that disconnects to a large extent during the isolation of thylakoid protein complexes remains elusive. Because L‐LHCII apparently has a flexible role in light harvesting and energy dissipation, depending on environmental conditions, its close interaction with photosystems is a prerequisite for successful light harvesting in vivo. Here, to reveal the labile and fragile light‐dependent protein interactions in the thylakoid network, isolated membranes were subjected to sequential solubilization using detergents with differential solubilization capacity and applying strict quality control. Optimized 3D‐lpBN‐lpBN‐sodium dodecyl sulfate–polyacrylamide gel electrophoresis system demonstrated that PSII–LHCII supercomplexes, together with PSI complexes, hierarchically form larger megacomplexes via interactions with L‐LHCII trimers. The polypeptide composition of LHCII trimers and the phosphorylation of Lhcb1 and Lhcb2 were examined to determine the light‐dependent supramolecular organization of the photosystems into megacomplexes.     

Phosphorylation of the Light-Harvesting Complex II Isoform Lhcb2 Is Central to State Transitions

Light-harvesting complex II (LHCII) is a crucial component of the photosynthetic machinery, with central roles in light capture and acclimation to changing light. The association of an LHCII trimer with PSI in the PSI-LHCII supercomplex is strictly dependent on LHCII phosphorylation mediated by the kinase STATE TRANSITION7, and is directly related to the light acclimation process called state transitions. In Arabidopsis (Arabidopsis thaliana), the LHCII trimers contain isoforms that belong to three classes: Lhcb1, Lhcb2, and Lhcb3. Only Lhcb1 and Lhcb2 can be phosphorylated in the N-terminal region. Here, we present an improved Phos-tag-based method to determine the absolute extent of phosphorylation of Lhcb1 and Lhcb2. Both classes show very similar phosphorylation kinetics during state transition. Nevertheless, only Lhcb2 is extensively phosphorylated (>98%) in PSI-LHCII, whereas phosphorylated Lhcb1 is largely excluded from this supercomplex. Both isoforms are phosphorylated to different extents in other photosystem supercomplexes and in different domains of the thylakoid membranes. The data imply that, despite their high sequence similarity, differential phosphorylation of Lhcb1 and Lhcb2 plays contrasting roles in light acclimation of photosynthesis.Light capture and its conversion to chemical energy occur in a set of transmembrane protein complexes of the thylakoid membrane. PSII, the cytochrome b₆f complex, and PSI drive photosynthetic electron flow and the creation of a proton gradient across the thylakoid membrane. ATP synthase couples the dissipation of this gradient to the synthesis of ATP. The light-harvesting antennae play an important role in collecting light and transferring energy to the photosystems. Light-Harvesting Complex I (LHCI) exclusively transfers light energy to PSI, with which it is tightly associated (Croce and van Amerongen, 2014). In contrast, LHCII, which is the most abundant complex of the thylakoid membrane, can transfer energy to PSI or PSII (Grieco et al., 2015). Light is highly variable in natural environments, and plants experience continuous changes in both the spectrum and intensity of light on timescales as short as seconds. Changes in light quality may unbalance the activity of the two photosystems since their absorption spectra differ, whereas high light intensity can lead to overexcitation and induce photodamage. At low or moderate light intensities, the LHCII complex differentially associates with PSII or PSI, in a phosphorylation-dependent process known as state transitions, to rapidly respond to changes in the spectrum of light. In brief, under light quality that activates PSII more than PSI (e.g. blue light), LHCII is phosphorylated, and as a consequence, its binding to PSI is favored (state 2). Conversely, under light that preferentially excites PSI (enriched in far-red), this association can be reverted by dephosphorylation of the LHCII antenna, which favors its binding to PSII (state 1; Goldschmidt-Clermont and Bassi, 2015; Kim et al., 2015). A protein kinase, STATE TRANSITION7 (STN7), and a protein phosphatase, PROTEIN PHOSPHATASE1 (PPH1)/THYLAKOID-ASSOCIATED PHOSPHATASE38 (TAP38), are essential for the rapid phosphorylation and dephosphorylation of the LHCII antenna that regulates its differential association to PSI or PSII (Bellafiore et al., 2005; Pribil et al., 2010; Shapiguzov et al., 2010). Only a relatively small fraction of the LHCII antenna (<20%) is estimated to participate in state transitions in Arabidopsis (Arabidopsis thaliana; Allen, 1992). However, the process is conserved across the green eukaryotes and is relevant to plant fitness (Frenkel et al., 2007). Under high light, energy-dependent quenching of LHCII predominates, and furthermore, this antenna can uncouple from PSII (Wientjes et al., 2013b).The differential association of photosystems, LHCII, and other components of the thylakoid membrane gives rise to a set of supercomplexes that are central in ensuring photosynthetic efficiency and a rapid response to environmental cues (Caffarri et al., 2009; Duffy et al., 2013; Pietrzykowska et al., 2014; Fristedt et al., 2015). Fine tuning the dynamic assembly of these supercomplexes involves the association of antennae containing specific sets of Lhcb proteins. The major LHCII antenna comprises homo- and heterotrimers of Lhcb1 to Lhcb3 (Jackowski et al., 2001), whereas the minor LHCII isoforms (Lhcb4–Lhcb6) are monomeric (de Bianchi et al., 2008). Lhcb1 and Lhcb2 share a very similar primary structure and associated pigments (Formaggio et al., 2001; Zhang et al., 2008), whereas Lhcb3 appears to have slightly different features (Standfuss and Kühlbrandt, 2004). In Arabidopsis, five genes encode Lhcb1 isoforms, three genes encode Lhcb2 isoforms, and a single gene encodes Lhcb3. The principal discriminant between these classes is a short stretch of residues at the N-terminal end, which is of particular importance since it contains the Thr that is reversibly phosphorylated during light-acclimation processes (Goldschmidt-Clermont and Bassi, 2015). During evolution, land plants have maintained a major LHCII composed of different classes of Lhcb subunits. The phosphorylated N terminus of Lhcb2 was particularly well conserved (Alboresi et al., 2008; Zhang et al., 2008).PSII-LHCII supercomplexes have been isolated from Arabidopsis with up to four LHCII trimers bound to a PSII dimer, as well as the three minor monomeric antennae (Lhcb4–Lhcb6; Caffarri et al., 2009; Kouřil et al., 2012). In the LHCII trimers of these supercomplexes, different classes of Lhcb subunits are distributed differently, suggesting a specific role in light acclimation for each of them (Damkjaer et al., 2009; Pietrzykowska et al., 2014). In the stably bound S trimer, Lhcb1 and Lhcb2 are more abundant, whereas the moderately bound M trimer contains mostly Lhcb1 and Lhcb3 (Galka et al., 2012). PSII supercomplexes isolated from spinach (Spinacia oleracea) showed the presence of an extra LHCII trimer (L trimer); therefore, it is possible that, in Arabidopsis, other trimers are associated with the PSII dimer in a more labile supercomplex that cannot be isolated (Boekema et al., 1999). A single LHCII trimer, containing Lhcb1 and Lhcb2, stably associates with PSI to constitute the PSI-LHCII supercomplex, whose formation is dependent on LHCII phosphorylation by STN7 in state 2 (Kouřil et al., 2005; Galka et al., 2012).Previous reports have shown that the relative phosphorylation of Lhcb1 and Lhcb2 isoforms differs among thylakoid supercomplexes (Galka et al., 2012; Leoni et al., 2013). Here, we address the specific roles of Lhcb1 and Lhcb2 phosphorylation in photosynthetic acclimation. The improved protocol for SDS-PAGE in the presence of Phos-tag (Wako Chemicals) that we present allows quantification of the extent of phosphorylation for each class of antenna isoforms. We report that, in the PSI-LHCII supercomplex that is assembled in state 2, only the phosphorylated form of Lhcb2 is present, whereas the phosphorylated form of Lhcb1 is excluded. In contrast, both Lhcb1 and Lhcb2 are phosphorylated to different levels in other supercomplexes. This quantitative information on the level of phosphorylation of Lhcb1 and Lhcb2 offers new insights into the specific roles of the two classes of LHCII isoforms in light acclimation and supercomplex formation.     

The effect of zeaxanthin as the only xanthophyll on the structure and function of the photosynthetic apparatus in Arabidopsis thaliana

In green plants, the xanthophyll carotenoid zeaxanthin is synthesized transiently under conditions of excess light energy and participates in photoprotection. In the Arabidopsis lut2 npq2 double mutant, all xanthophylls were replaced constitutively by zeaxanthin, the only xanthophyll whose synthesis was not impaired. The relative proportions of the different chlorophyll antenna proteins were strongly affected with respect to the wild-type strain. The major antenna, LHCII, did not form trimers, and its abundance was strongly reduced as was CP26, albeit to a lesser extent. In contrast, CP29, CP24, LHCI proteins, and the PSI and PSII core complexes did not undergo major changes. PSII-LHCII supercomplexes were not detectable while the PSI-LHCI supercomplex remained unaffected. The effect of zeaxanthin accumulation on the stability of the different Lhc proteins was uneven: the LHCII proteins from lut2 npq2 had a lower melting temperature as compared with the wild-type complex while LHCI showed increased resistance to heat denaturation. Consistent with the loss of LHCII, light-state 1 to state 2 transitions were suppressed, the photochemical efficiency in limiting light was reduced and photosynthesis was saturated at higher light intensities in lut2 npq2 leaves, resulting in a photosynthetic phenotype resembling that of high light-acclimated leaves. Zeaxanthin functioned in vivo as a light-harvesting accessory pigment in lut2 npq2 chlorophyll antennae. As a whole, the in vivo data are consistent with the results obtained by using recombinant Lhc proteins reconstituted in vitro with purified zeaxanthin. While PSII photoinhibition was similar in wild type and lut2 npq2 exposed to high light at low temperature, the double mutant was much more resistant to photooxidative stress and lipid peroxidation than the wild type. The latter observation is consistent with an antioxidant and lipid protective role of zeaxanthin in vivo.     

The Photosystem II Light-Harvesting Protein Lhcb3 Affects the Macrostructure of Photosystem II and the Rate of State Transitions in Arabidopsis

The main trimeric light-harvesting complex of higher plants (LHCII) consists of three different Lhcb proteins (Lhcb1-3). We show that Arabidopsis thaliana T-DNA knockout plants lacking Lhcb3 (koLhcb3) compensate for the lack of Lhcb3 by producing increased amounts of Lhcb1 and Lhcb2. As in wild-type plants, LHCII-photosystem II (PSII) supercomplexes were present in Lhcb3 knockout plants (koLhcb3), and preservation of the LHCII trimers (M trimers) indicates that the Lhcb3 in M trimers has been replaced by Lhcb1 and/or Lhcb2. However, the rotational position of the M LHCII trimer was altered, suggesting that the Lhcb3 subunit affects the macrostructural arrangement of the LHCII antenna. The absence of Lhcb3 did not result in any significant alteration in PSII efficiency or qE type of nonphotochemical quenching, but the rate of transition from State 1 to State 2 was increased in koLhcb3, although the final extent of state transition was unchanged. The level of phosphorylation of LHCII was increased in the koLhcb3 plants compared with wild-type plants in both State 1 and State 2. The relative increase in phosphorylation upon transition from State 1 to State 2 was also significantly higher in koLhcb3. It is suggested that the main function of Lhcb3 is to modulate the rate of state transitions.     

The oligomeric states of the photosystems and the light-harvesting complexes in the Chl b-less mutant

The reversible associations between the light-harvesting complexes (LHCs) and the core complexes of PSI and PSII are essential for the photoacclimation mechanisms in higher plants. Two types of Chls, Chl a and Chl b, both function in light harvesting and are required for the biogenesis of the photosystems. Chl b-less plants have been studied to determine the function of the LHCs because the Chl b deficiency has severe effects specific to the LHCs. Previous studies have shown that the amounts of the LHCs, especially the LHCII trimer, were decreased in the mutants; however, it is still unclear whether Chl b is required for the assembly of the LHCs and for the association of the LHCs with PSI and PSII. Here, to reveal the function of Chl b in the LHCs, we investigated the oligomeric states of the LHCs, PSI and PSII in the Arabidopsis Chl b-less mutant. A two-dimensional blue native-PAGE/SDS-PAGE demonstrated that the PSI-LHCI supercomplex was fully assembled in the absence of Chl b, whereas the trimeric LHCII and PSII-LHCII supercomplexes were not detected. The PSI-NAD(P)H dehydrogenase (NDH) supercomplexes were also assembled in the mutant. Furthermore, we detected two forms of monomeric LHC proteins. The faster migrating forms, which were detected primarily in the mutant, were probably apo-LHC proteins, whereas the slower migrating forms were probably the LHC proteins that contained Chl a. These findings increase our understanding of the Chl b function in the assembly of LHCs and the association of the LHCs with PSI, PSII and NDH.     

Protein assembly of photosystem II and accumulation of subcomplexes in the absence of low molecular mass subunits PsbL and PsbJ.

The protein assembly and stability of photosystem II (PSII) (sub)complexes were studied in mature leaves of four plastid mutants of tobacco (Nicotiana tabacum L), each having one of the psbEFLJ operon genes inactivated. In the absence of psbL, no PSII core dimers or PSII-light harvesting complex (LHCII) supercomplexes were formed, and the assembly of CP43 into PSII core monomers was extremely labile. The assembly of CP43 into PSII core monomers was found to be necessary for the assembly of PsbO on the lumenal side of PSII. The two other oxygen-evolving complex (OEC) proteins, PsbP and PsbQ, were completely lacking in Delta psbL. In the absence of psbJ, both intact PSII core monomers and PSII core dimers harboring the PsbO protein were formed, whereas the LHCII antenna remained detached from the PSII dimers, as demonstrated by 77 K fluorescence measurements and by the lack of PSII-LHCII supercomplexes. The Delta psbJ mutant was characterized by a deficiency of PsbQ and a complete lack of PsbP. Thus, both the PsbL and PsbJ subunits of PSII are essential for proper assembly of the OEC. The absence of psbE and psbF resulted in a complete absence of all central PSII core and OEC proteins. In contrast, very young, vigorously expanding leaves of all psbEFLJ operon mutants accumulated at least traces of D2, CP43 and the OEC proteins PsbO and PsbQ, implying developmental control of the expression of the PSII core and OEC proteins. Despite severe problems in PSII assembly, the thylakoid membrane complexes other than PSII were present and correctly assembled in all psbEFLJ operon mutants.     

Arrangement of photosystem II supercomplexes in crystalline macrodomains within the thylakoid membrane of green plant chloroplasts

The chloroplast thylakoid membrane of green plants is organized in stacked grana membranes and unstacked stroma membranes. We investigated the structural organization of Photosystem II (PSII) in paired grana membrane fragments by transmission electron microscopy. The membrane fragments were obtained by a short treatment of thylakoid membranes with the mild detergent n-dodecyl-alpha, d-maltoside and are thought to reflect the grana membranes in a native state. The membranes frequently show crystalline macrodomains in which PSII is organized in rows spaced by either 26.3 nm (large-spaced crystals) or 23 nm (small-spaced crystals). The small-spaced crystals are less common but better ordered. Image analysis of the crystals by an aperiodic approach revealed the precise positions of the core parts of PSII in the lattices, as well as features of the peripheral light-harvesting antenna. Together, they indicate that the so-called C(2)S(2) and C(2)S(2)M supercomplexes form the basic motifs of the small-spaced and large-spaced crystals, respectively. An analysis of a pair of membranes with a well-ordered large-spaced crystal reveals that many PSII complexes in one layer face only light-harvesting complexes (LHCII) in the other layer. The implications of this type of organization for the efficient transfer of excitation energy from LHCII to PSII and for the stacking of grana membranes are discussed.     

Characterization of PSII–LHCII supercomplexes isolated from pea thylakoid membrane by one-step treatment with α- and β-dodecyl-d-maltoside

It was the work of Jan Anderson, together with Keith Boardman, that showed it was possible to physically separate photosystem I (PSI) from photosystem II (PSII), and it was Jan Anderson who realized the importance of this work in terms of the fluid-mosaic model as applied to the thylakoid membrane. Since then, there has been a steady progress in the development of biochemical procedures to isolate PSII and PSI both for physical and structural studies. Dodecylmaltoside (DM) has emerged as an effective mild detergent for this purpose. DM is a glucoside-based surfactant with a bulky hydrophilic head group composed of two sugar rings and a non-charged alkyl glycoside chain. Two isomers of this molecule exist, differing only in the configuration of the alkyl chain around the anomeric centre of the carbohydrate head group, axial in α-DM and equatorial in β-DM. We have compared the use of α-DM and β-DM for the isolation of supramolecular complexes of PSII by a single-step solubilization of stacked thylakoid membranes isolated from peas. As a result, we have optimized conditions to obtain homogeneous preparations of the C₂S₂M₂ and C₂S₂ supercomplexes following the nomenclature of Dekker & Boekema (2005 Biochim. Biophys. Acta 1706, 12–39). These PSII–LHCII supercomplexes were subjected to biochemical and structural analyses.     

Light-harvesting complex II (LHCII) and its supramolecular organization in Chlamydomonas reinhardtii

LHCII is the most abundant membrane protein on earth. It participates in the first steps of photosynthesis by harvesting sunlight and transferring excitation energy to the core complex. Here we have analyzed the LHCII complex of the green alga Chlamydomonas reinhardtii and its association with the core of Photosystem II (PSII) to form multiprotein complexes. Several PSII supercomplexes with different antenna sizes have been purified, the largest of which contains three LHCII trimers (named S, M and N) per monomeric core. A projection map at a 13 Å resolution was obtained allowing the reconstruction of the 3D structure of the supercomplex. The position and orientation of the S trimer are the same as in plants; trimer M is rotated by 45° and the additional trimer (named here as LHCII-N), which is taking the position occupied in plants by CP24, is directly associated with the core. The analysis of supercomplexes with different antenna sizes suggests that LhcbM1, LhcbM2/7 and LhcbM3 are the major components of the trimers in the PSII supercomplex, while LhcbM5 is part of the “extra” LHCII pool not directly associated with the supercomplex. It is also shown that Chlamydomonas LHCII has a slightly lower Chlorophyll a/b ratio than the complex from plants and a blue shifted absorption spectrum. Finally the data indicate that there are at least six LHCII trimers per dimeric core in the thylakoid membranes, meaning that the antenna size of PSII of C. reinhardtii is larger than that of plants.     

Consequences of state transitions on the structural and functional organization of Photosystem I in the green alga Chlamydomonas reinhardtii

State transitions represent a photoacclimation process that regulates the light‐driven photosynthetic reactions in response to changes in light quality/quantity. It balances the excitation between photosystem I (PSI) and II (PSII) by shuttling LHCII, the main light‐harvesting complex of green algae and plants, between them. This process is particularly important in Chlamydomonas reinhardtii in which it is suggested to induce a large reorganization in the thylakoid membrane. Phosphorylation has been shown to be necessary for state transitions and the LHCII kinase has been identified. However, the consequences of state transitions on the structural organization and the functionality of the photosystems have not yet been elucidated. This situation is mainly because the purification of the supercomplexes has proved to be particularly difficult, thus preventing structural and functional studies. Here, we have purified and analysed PSI and PSII supercomplexes of C. reinhardtii in states 1 and 2, and have studied them using biochemical, spectroscopic and structural methods. It is shown that PSI in state 2 is able to bind two LHCII trimers that contain all four LHCII types, and one monomer, most likely CP29, in addition to its nine Lhcas. This structure is the largest PSI complex ever observed, having an antenna size of 340 Chls/P700. Moreover, all PSI‐bound Lhcs are efficient in transferring energy to PSI. A projection map at 20 Å resolution reveals the structural organization of the complex. Surprisingly, only LHCII type I, II and IV are phosphorylated when associated with PSI, while LHCII type III and CP29 are not, but CP29 is phosphorylated when associated with PSII in state2.