A chloroplast membrane lacking Photosystem II. Thylakoid stacking in the absence of the Photosystem II particle

The polypeptide composition and membrane structure of a variegated mutant of tobacco have been investigated. The pale green mutant leaf regions contain chloroplasts in which the amount of membrane stacking has been reduced (although not totally eliminated). The mutant membranes are almost totally deficient in Photosystem II when compared to wild-type chloroplast membranes, but still show near-normal levels of Photosystem I activity. The pattern of membrane polypeptides separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows several differences between mutant and wild-type membranes, although the major chlorophyll-protein complexes described in many other plant species are present in both mutant and wild-type samples. Freeze-fracture analysis of the internal structure of these photosynthetic membranes shows that the Photosystem II-deficient membranes lack the characteristic large particle associated with the E fracture face of the thylakoid. These membranes also lack a tetramer-like particle visible on the inner (ES) surface of the membrane. The other characteristics of the photosynthetic membrane, including the small particles observed on the P fracture faces in both stacked and unstacked regions, and the characteristic changes in the background matrix of the E fracture face which accompany thylakoid stacking, are unaltered in the mutant. From these and other observations we conclude that the large (EF and ES) particle represents an amalgam of many components comprising the Photosystem II reaction complex, that the absence of one or more of its components may prevent the structure from assembling, and that in its absence, Photosystem II activity cannot be observed.     

A chloroplast membrane lacking photosystem II. Thylakoid stacking in the absence of the photosystem II particle.

The polypeptide composition and membrane structure of a variegated mutant of tobacco have been investigated. The pale green mutant leaf regions contain chloroplasts in which the amount of membrane stacking has been reduced (although not totally eliminated). The mutant membranes are almost totally deficient in Photosystem II when compared to wild-type chloroplast membranes, but still show near-normal levels of Photosystem I activity. The pattern of membrane polypeptides separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows several differences between mutant and wild-type membranes, although the major chlorophyll-protein complexes described in many other plant species are present in both mutant and wild-type samples. Freeze-fracture analysis of the internal structure of these photosynthetic membranes shows that the Photosystem II-deficient membranes lack the characteristic large particle associated with the E fracture face of the thylakoid. These membranes also lack a tetramer-like particle visible on the inner (ES) surface of the membrane. The other characteristics of the photosynthetic membrane, including the small particles observed on the P fracture faces in both stacked and unstacked regions, and the characteristic changes in the background matrix of the E fracture face which accompany thylakoid stacking, are unaltered in the mutant. From these and other observations we conclude that the large (EF and ES) particle represents an amalgam of many components comprising the Photosystem II reaction complex, that the absence of one or more of its components may prevent the structure from assembling, and that in its absence, Photosystem II activity cannot be observed.     

Evidence for thylakoid membrane fusion during zygote formation in Chlamydomonas reinhardtii

To understand whether fusions of thylakoid membranes from the parental chloroplasts occurred during zygote formation in Chlamydomonas reinhardtii, we performed an ultrastructural analysis of the zygotes produced by crossing mutants lacking photosystem I or II protein complexes, in the absence of de novo chloroplast protein synthesis. Thylakoid membranes from each parent could be distinguished on thin sections due to their organization in "supergrana" in mutants lacking photosystem I centers, by freeze-fracturing due to the absence of most of the exoplasmic-face (EF) particles in mutants lacking photosystem II centers, by immunocytochemistry using antibodies directed against photosystem II subunits. We demonstrate that a fusion of the thylakoid membranes occurred during zygote formation approximately 15 h after mating. These fusions allowed a lateral redistribution of the thylakoid membrane proteins. These observations provide the structural basis for the restoration of photosynthetic electron flow in the mature zygote that we observed in fluorescence induction experiments.     

Ultrastructure of thylakoid membranes in C. reinhardtii: Evidence for variations in the partition coefficient of the light-harvesting complex-containing particles upon membrane fracture

The ultrastructure of the thylakoid membranes of Chlamydomonas reinhardtii was investigated using cell cultures grown under light intensities of 200 and 4000 lx, respectively. A significant difference in the size distribution of the exoplasmic fracture face (EF) particles appears upon Mg²⁺ treatment of broken cell preparations from the two light growth conditions. Particles larger than 150 Å are seen at 4000 lx only. However neither the absorption spectra of chlorophyll at 77 °K, nor the chlorophyll a/chlorophyll b ratios differ in the two cell batches. In addition, the polypeptide composition of the thylakoid membranes and the Mg²⁺ effect (spillover) on the photochemical rate of Photosystem II are the same in both conditions. We conclude that the partition coefficient between the two fracture faces of light-harvesting complex-containing particles is variable. It depends on Mg²⁺ ion concentration in the incubating medium of the membranes and on the light growth conditions of the cell cultures. Our results suggest that 60- to 80-Å protoplasmic fracture face (PF) particles containing the light-harvesting complexes can aggregate either in larger PF particles (100–120 Å) or in EF particles larger than 120 Å which also contain the Photosystem II centers. That some light-harvesting complexes are located on the PF faces is confirmed by the analysis of the BF4 mutant of C. reinhardtii lacking in chlorophyll-protein complex II. The PF faces of the BF4 thylakoids display a reduced number of particles as compared to that in the wild type.     

Inside-out membrane vesicles isolated from spinach thylakoids

Inside-out thylakoid vesicles have been separated from right-side-out material after press disruption of chloroplast lamellae. The separation was obtained by partition in an aqueous dextran-polyethylene glycol two-phase system, a method which utilizes differences in surface properties for separation of membrane particles. The isolated thylakoid vesicles showed the following inside-out properties: (1) light-induced reversible proton extrusion into the surrounding medium when supplied with the Photosystem II electron acceptor phenyl-p-benzoquinone; (2) a pH rise in the internal phase accompanying the external proton release, (3) sensitivity to trypsin treatment different from that of thylakoid membranes of normal orientation; (4) concave EF and convex PF freeze-fracture faces.     

FREEZE-FRACTURED CHLOROPLAST MEMBRANES OF GONYAULAX POLYEDRA (PYRROPHYTA)1

The chloroplast membranes of Gonyaulax polyedra Stein were studied in replicas of rapidly frozen and fractured cells. The thylakoid EF_s face lacked the large 15–16 nm particles characteristic of plants with the light-harvesting chlorophyll a/b protein, presumably because the principal light-harvesting protein of Gonyaulax is the small water-soluble peridinin-chlorophyll-protein and the chlorophyll a/b protein is absent. As in other plants, the EF_s thylakoid fracture face carried more particles (4 ×) than EF_uface. The PF faces of the thylakoid showed twice as many particles as did the EF_s faces. No circadian differences in the number or size of thylakoid membrane particles could be detected. Three membranes comprise the chloroplast envelope in Gonyaulax. They could be clearly differentiated in freeze-fractured cells. The middle envelope membrane carried many fewer particles on both the EF and PF faces than did the other two envelope membranes. The PF faces of both the outer and inner envelope membranes showed more particles than the EF faces, as do many other membranes which have been examined.     

The Supramolecular Organization of Photosynthetic Membranes of the Thallus Stage of Porphyra leucosticta Thuret. (Bangiales,Rhodophyta) Visualized by Freeze-Fracture

The supramolecular organization of the thylakoid membranes of the thallus stage in the red alga Porphyra leucosticta is studied in replicas of rapidly frozen and fractured cells. Freeze-fractured thylakoid membranes exhibit only two types of fracture faces (EF and PF), because the lamellae in red algal chloroplasts are not stacked. The PF reveals numerous, tightly packed, but randomly distributed particles (density range from 2970 to 3550 particles/μm²). In contrast, the EF particles appear organized into parallel rows, the spacing of which is about 60–70 nm (about 8–9 particles occur along 100 nm of the line that is formed). Significant numbers of single EF particles are randomly distributed between the EF particle rows. The particles on both fracture faces (PF and EF) fall into two size classes: 10 to 11 nm (major size class) and 14 to 15 nm (minor size class).     

A comparative approach towards thylakoid membrane proteome analysis of unicellular green alga Scenedesmus obliquus

The chlorophyll (Chl)-containing membrane protein complexes from the green alga Scenedesmus obliquus have been isolated from the thylakoid membranes by solubilization with dodecyl-β-maltoside and fractionation using a sucrose density gradient. The Chl-containing protein fractions were characterized by absorption spectroscopy, tricine SDS PAGE, BN-PAGE, and dynamic light scattering (DLS). BN-PAGE showed the presence of seven protein complexes with molecular weights in the range of 68, 118, 157, 320, 494, 828 and 955 kDa, respectively. Furthermore, light scattering reveals the simultaneous presence of particles of different sizes in the 3-4 nm and 6.0-7.5 nm range, respectively. The smaller size is related to the hydrodynamic radius of the trimer Light Harvesting Complex (LHCII), whereas the larger size is associated with the presence of photosystem I and photosystem II reaction centers. Additionally, functional information regarding protein-protein interactions was deconvoluted using coupling 2-D BN-PAGE, MALDI-TOF MS and a detailed mapping of S. obliquus photosynthetic proteome of the solubilized thylakoid membranes is therefore presented.     

Characteristic temperature dependences of respiratory and photosynthetic electron-transport activities in membrane preparations from Anacystis nidulans grown at different temperatures

Electron-transport activities supported by seven different electron donor/acceptor couples in the light and in the dark, respectively, were measured in particle preparations of the cyanobacterium (blue-green alga) Anacystis nidulans after growth at 40, 30 and 25°C. The Arrhenius plots of the photosynthetic electron-transport reactions between ascorbate (plus 2,6-dichlorophenolindophenol (DCIP)) and NADP⁺, diphenylcarbazide and DCIP, diaminodurene and benzyl viologen (O₂), and the plot of the photooxidation of reduced horse heart cytochrome c showed a single discontinuity at approx. 24–25, 15–17 and 10–13°C in membranes derived from cells grown at 40, 30 and 25°C, respectively. By contrast, the dark respiratory electron-transport reactions between NADPH, ascorbate (plus DCIP) or reduced horse heart cytochrome c and oxygen, and the reduction by horse heart cytochrome c of the aa₃-type terminal oxidase as followed directly by dual-wavelength spectrophotometry, all gave Arrhenius plots distinguished by two distinct breaks: The break at the higher temperature corresponded to the break also found in the Arrhenius plots of the photosynthetic reactions while an additional discontinuity was observed at 17–18, 8–9 and 5–6°C in membranes prepared from cells grown at 40, 30 and 25°C, respectively. The temperatures at which the discontinuities in the Arrhenius plots occurred depended on the temperature at which the cells had been grown; they were independent, however, of the specific electron donors and acceptors employed. The characteristic features in the Arrhenius plots of respiratory and photosynthetic electron-transport reactions are discussed in terms of lipid-phase transitions in the cytoplasmic and the intracytoplasmic (thylakoid) membranes of A. nidulans. Implications for possibly distinct sites of the respiratory and photosynthetic electron-transport systems in A. nidulans will be mentioned.     

Gross morphological changes in thylakoid membrane structure are associated with photosystem I deletion in Synechocystis sp. PCC 6803

Cells of Synechocystis sp. PCC 6803 lacking photosystem I (PSI-less) and containing only photosystem II (PSII) or lacking both photosystems I and II (PSI/PSII-less) were compared to wild type (WT) cells to investigate the role of the photosystems in the architecture, structure, and number of thylakoid membranes. All cells were grown at 0.5μmol photons m(-2)s(-1). The lumen of the thylakoid membranes of the WT cells grown at this low light intensity were inflated compared to cells grown at higher light intensity. Tubular as well as sheet-like thylakoid membranes were found in the PSI-less strain at all stages of development with organized regular arrays of phycobilisomes on the surface of the thylakoid membranes. Tubular structures were also found in the PSI/PSII-less strain, but these were smaller in diameter to those found in the PSI-less strain with what appeared to be a different internal structure and were less common. There were fewer and smaller thylakoid membrane sheets in the double mutant and the phycobilisomes were found on the surface in more disordered arrays. These differences in thylakoid membrane structure most likely reflect the altered composition of photosynthetic particles and distribution of other integral membrane proteins and their interaction with the lipid bilayer. These results suggest an important role for the presence of PSII in the formation of the highly ordered tubular structures.     

The ultrastructure of plasma and thylakoid membrane vesicles from the fresh water cyanobacteriumAnacystis nidulans adapted to salinity

Summary Photoautotrophically growing cultures of the fresh water cyanobacteriumAnacystis nidulans adapted to the presence of 0.4–0.5 M NaCl (about sea water level) with a lag phase of two days after which time the growth rate reassumed 80–90% of the control. Plasma and thylakoid membranes were separated from cell-free extracts of French pressure cell treatedAnacystis nidulans by discontinuous sucrose density gradient centrifugation and purified by repeated recentrifugation on fresh gradients. Identity of the plasma and thylakoid membrane fractions was confirmed by labeling of intact cells with impermeant protein markers prior to breakage and membrane isolation. Electron microscopy revealed that each type of membrane was obtained in the form of closed and perfectly spherical vesicles. Major changes in structure and function of the plasma membranes (and, to a much lesser extent, of the thylakoid membranes) were found to accompany the adaptation process. On the average, diameters of plasma membrane vesicles from salt adapted cells were only one-third of the diameters of corresponding vesicles from control cells. By contrast, the diameters of thylakoid membrane vesicles were the same in both cases.Freeze-etching the cells and counting the number of membrane-intercalating particles on both protoplasmic and exoplasmic fracture faces of plasma and thylakoid membranes indicated a roughly 50% increase of the particle density in plasma membranes during the adaptation process while that in thylakoid membranes was unaffected. Comparison between particle densities on isolated membranes and those on corresponding whole cell membranes permitted an estimate as to the percentage of inside-out and right-side-out vesicles. Stereometric measurement of particle sizes suggested that two distinct sub-populations of the particles in the plasma membranes increased during the adaptation process, tentatively correlated to the cytochrome oxidase and sodium-proton antiporter, respectively. The effects of salt adaptation described in this paper were fully reversed upon withdrawal of the additional NaCl from the growth medium (deadaptation). Moreover, they were not observed when the NaCl was replaced by KCl.Abbreviations CM cytoplasmic or plasma membrane - ICM intracytoplasmic or thylakoid membrane - EF exoplasmic fracture face - PF protoplasmic fracture face - DABS diazobenzosulfonate; Hepes N-2-hydroxyethylpiperazine-N-2-ethane-sulfonate - PMSF phenylmethylsulfonylfluoride Dedicated to the memory of Professor Oswald Kiermayer     

A chloroplast membrane lacking Photosystem I. Changes in unstacked membrane regions

The structure and polypeptide composition of the photosynthetic membrane of a mutant of maize has been investigated. The thylakoid membranes of the mutant plants are deficient in Photosystem I activity, although Photosystem II is at near normal levels. SDS polyacrylamide gel electrophoresis of thylakoid membranes from the mutant shows them to be deficient in two polypeptide bands which have been associated with Photosystem I. Freeze-fracture studies of the membrane show that the absence of these polypeptides is associated with a measurable reduction in particle diameter on the unstacked protoplasmic fracture face. This fracture face is derived from the splitting of membranes in unstacked regions of the thylakoid membrane system. It is suggested that in membranes stacked by salts in vitro, Photosystem I activity may be confined to this region.     

Phenotypes of Alb3p and carotenoid synthesis mutants show similarities regarding light sensitivity, thylakoid structure and protein stability

Chloroplast proteins of the Alb3/YidC/Oxa1p family are necessary for assembly of photosynthetic complexes in the thylakoid membranes. Alb3p in Arabidopsis thaliana is essential for posttranslational LHCII-integration into thylakoid membranes and participates in cotranslational assembly of D1. However, the pleiotropic defects of an Alb3p mutant, albino3, suggest additional functions for Alb3p. To obtain an impression of such potential further Alb3p activities from phenotypic manifestations, properties of mutants disturbed in thylakoid membrane protein transport or carotenoid biosynthesis were compared with the albino3 mutant. Specific defects observed in albino3 were similar to those in a carotenoid synthesis mutant. While this correlation did not provide tangible evidence for Alb3p being involved in the integration of carotenoids in photosynthetic complexes, it suggests a possible avenue for future investigations.     

Analysis of the thylakoid outer surface. Coupling factor is limited to unstacked membrane regions

The structure of the spinach thylakoid outer surface has been examined by deepetching, a technique which exposes the true surfaces of biological membranes by sublimination of frozen dilute buffer. The membrane surface is covered with large (150 A average diameter) and small (90 A average diameter) particles. Approximately 30% of the large particles can be removed under conditions reported to selectively remove carboxydismutase from the membrane surface. The remaining large particles can be removed only under conditions which cause a loss of coupling factor activity. When purified coupling factor is readded to membranes from which all coupling factor activity has been removed, large particles reappear, indicating that they represent coupling factor molecules. Since the number of particles and the amount of ATPase activity in the reconstituted and control membranes were the same, coupling factor molecules may be attached to specific binding sites. Analysis of antibody labeling experiments, enzyme assays, and experiments involving the unstacking and restacking of thylakoid membranes indicate that coupling factor is excluded from regions of membrane stacking (grana) and is present only in unstacked membrane regions. The exclusion of coupling factor from grana, which are known to be centers of intense photosynthetic activity, strongly suggests that the mechanism coupling electron transport to photophosphorylation is indirect. In addition to the large and small particles, in some cases regularly spaced ridges are visible on the outer surface after unstacking. Coupling factor binding sites seem to be excluded from regions where these structures occur.     

Inside-out membrane vesicles isolated from spinach thylakoids.

Inside-out thylakoid vesicles have been separated from right-side-out material after press disruption of chloroplast lamellae. The sepration was obtained by partitionin an aqueous dextran-polyethylene glycol two-phase system, a method which utilizes differences in surface properties for separation of membrane particles. The isolated thylakoid vesicles showed the following inside-out properties: (1) light-induced reversible proton extrusion into the surrounding medium when supplied with the Photosystem II electron acceptor phenyl-p-benzoquinone; (2) a pH rise in the internal phase accompanying the external proton release, (3) sensitivity to trypsin treatment different from that of thylakoid membranes of normal orientation; (4) concave EF and convex PF freeze-fracture faces.     

Spatial relationship of photosystem I, photosystem II, and the light- harvesting complex in chloroplast membranes

We have previously demonstrated (Armond, P. A., C. J. Arntzen, J.-M. Briantais, and C. Vernotte. 1976. Arch. Biochem. Biophys. 175:54-63; and Davis, D. J., P. A. Armond, E. L. Gross, and C. J. Arntzen. 1976. Arch. Biochem. Biophys. 175:64-70) that pea seedlings which were exposed to intermittent illumination contained incompletely developed chloroplasts. These plastids were photosynthetically competent, but did not contain grana. We now demonstrate that the incompletely developed plastids have a smaller photosynthetic unit size; this is primarily due to the absence of a major light-harvesting pigment-protein complex which is present in the mature membranes. Upon exposure of intermittent- light seedlings to continuous white light for periods up to 48 h, a ligh-harvesting chlorophyll-protein complex was inserted into the chloroplast membrane with a concomitant appearance of grana stacks and an increase in photosynthetic unit size. Plastid membranes from plants grown under intermediate light were examined by freeze-fracture electron microscopy. The membrane particles on both the outer (PF) and inner (EF) leaflets of the thylakoid membrane were found to be randomly distributed. The particle density of the PF fracture face was approx. four times that of the EF fracture face. While only small changes in particle density were observed during the greening process under continuous light, major changes in particle size were noted, particularly in the EF particles of stacked regions (EFs) of the chloroplast membrane. Both the changes in particle size and an observed aggregation of the EF particles into the newly stacked regions of the membrane were correlated with the insertion of light-harvesting pigment- protein into the membrane. Evidence is presented for identification of the EF particles as the morphological equivalent of a "complete" photosystem II complex, consisting of a phosochemically active "core" complex surrounded by discrete aggregates of the light-harvesting pigment protein. A model demonstrating the spatial relationships of photosystem I, photosystem II, and the light-harvesting complex in the chloroplast membrane is presented.     

Chloroplast Function in Guard Cells of Vicia faba L. : Measurement of the Electrochromic Absorbance Change at 518 nm

Stomatal conductance is coupled to leaf photosynthetic rate over a broad range of environmental conditions. We have investigated the extent to which chloroplasts in guard cells may contribute to this coupling through their photosynthetic activity. Guard cells were isolated by sonication of abaxial epidermal peels of Vicia faba. The electrochromic band shift of isolated guard cells was probed in vivo as a means of studying the electric field that is generated across the thylakoid membranes by photosynthetic electron transport and dissipated by photophosphorylation. Both guard cells and mesophyll cells exhibited fast and slow components in the formation of the flash-induced electrochromic change. The spectrum of electrochromic absorbance changes in guard cells was the same as in the leaf mesophyll and was typical of that observed in isolated chloroplasts. This observation indicates that electron transport and photophosphorylation occur in guard cell chloroplasts. Neither the fast nor the slow component of the absorbance change was observed in the presence of the uncoupler carbonylcyanide p-trifluoromethoxy-phenylhydrazone which confirms that the absorbance change was caused by the electric field across the thylakoid membranes. The magnitude of the fast rise was reduced by half in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea. Therefore, photosystem II is functional and roughly equal in concentration to photosystem I in guard cell chloroplasts. The slow rise was abolished by 2,5-dibromo-3-methyl-6-isopropyl-1,4-benzoquinone indicating the involvement of the cytochrome b₆/f complex in electron transport between the two photosystems. Relaxation of the absorbance change was irreversibly retarded in cells treated with the energy transfer inhibitor, N,N′-dicyclohexylcarbodiimide. The slowing of the rapid decay kinetics by N,N′-dicyclohexylcarbodiimide confirms that the electrical potential across the thyalkoid membrane is dissipated by photophosphorylation. These results show that guard cell chloroplasts conduct photosynthetic electron transport in a manner similar to that in mesophyll cells and provide the first evidence that photophosphorylation occurs in guard cells in vivo.     

Thylakoid Membrane Maturation and PSII Activation Are Linked in Greening Synechocystis sp. PCC 6803 Cells

Thylakoid membranes are typical and essential features of both chloroplasts and cyanobacteria. While they are crucial for phototrophic growth of cyanobacterial cells, biogenesis of thylakoid membranes is not well understood yet. Dark-grown Synechocystis sp. PCC 6803 cells contain only rudimentary thylakoid membranes but still a relatively high amount of phycobilisomes, inactive photosystem II and active photosystem I centers. After shifting dark-grown Synechocystis sp. PCC 6803 cells into the light, “greening” of Synechocystis sp. PCC 6803 cells, i.e. thylakoid membrane formation and recovery of photosynthetic electron transport reactions, was monitored. Complete restoration of a typical thylakoid membrane system was observed within 24 hours after an initial lag phase of 6 to 8 hours. Furthermore, activation of photosystem II complexes and restoration of a functional photosynthetic electron transport chain appears to be linked to the biogenesis of organized thylakoid membrane pairs.Thylakoid membranes are typical and essential features of both chloroplasts and cyanobacteria. The intracellular thylakoid membranes of cyanobacteria harbor the protein complexes of the photosynthetic electron transport chain (Nowaczyk et al., 2010; Bernat and Rögner, 2011). The photosynthetic electron transport chain is composed of three large membrane protein complexes, i.e. PSII, the cytochrome b₆f complex, and PSI. Excitation energy trapping by PSII results in water splitting at the PSII donor side within the thylakoid lumen and transport of electrons to the primary and secondary electron accepting quinone molecules Q_A and Q_B, respectively. Following double reduction and protonation, Q_B is released from PSII into the plastoquinone (PQ) pool and delivers electrons to the cytochrome b₆f complex. The cytochrome b₆f complex transfers the electrons to the soluble electron carrier plastocyanin or cytochrome c₆, which subsequently reduces PSI. For efficient light harvesting, cyanobacteria contain soluble light-harvesting antenna proteins, the phycobilisomes (PBSs), which transfer light energy to the photosynthetic reaction centers. In cyanobacteria, the PSI-to-PSII ratio is controlled by light and by the redox state of the PQ/PQH₂-pool (Fujita et al., 1987), and under high-light growth conditions, typically less PSI is present in cyanobacterial thylakoid membranes compared with low-light conditions (Fujita et al., 1994).Thylakoid membranes and photosynthetic electron transport are essential for phototrophic growth of cyanobacterial cells. Despite their importance for survival of cyanobacteria, biogenesis of thylakoid membranes is yet not well understood. It still is an ongoing debate whether the internal membrane systems (cytoplasmic and thylakoid membranes) are connected in cyanobacteria or not, and thus whether thylakoids represent a completely separated membrane entity (Liberton et al., 2006; van de Meene et al., 2006, 2012; Schneider et al., 2007). Up to now, only few proteins have been described to be involved in thylakoid membrane biogenesis. Among them the Vipp1 protein (vesicle inducing protein in plastids1) seems to play an important role in thylakoid membrane biogenesis, as in chloroplasts of Arabidopsis (Arabidopsis thaliana) and in the cyanobacterium Synechocystis sp. PCC 6803 (hereafter referred to as Synechocystis), depletion of Vipp1 results in a reduced thylakoid membrane system (Kroll et al., 2001; Westphal et al., 2001). While the exact physiological function of the protein is not yet known (Vothknecht et al., 2012), depletion of Vipp1 in Synechocystis not only results in reduced thylakoid membrane formation, but also affects the activity and structure of components of the photosynthetic electron transport chain (Fuhrmann et al., 2009; Gao and Xu, 2009).As complexes of the respiratory electron transport chain are also localized in cyanobacterial thylakoids, the photosynthetic and respiratory electron transport pathways are highly interconnected and both contribute to formation of an electrochemical gradient across the thylakoid membrane and energy production. Due to this, Synechocystis is able to grow completely heterotrophically under light-activated photoheterotrophic growth (LAHG) conditions in the presence of high Glc concentrations (Anderson and McIntosh, 1991; Smart et al., 1991).In this study, we have used dark-grown Synechocystis cells to investigate “greening” of Synechocystis cells, i.e. thylakoid membrane formation and recovery of photosynthetic electron transport reactions. Following transfer of Synechocystis cells into the light, complete restoration of a typical thylakoid membrane system was observed within 24 h. While dark-grown Synechocystis cells contained only rudimentary thylakoid membranes, they still contained a high concentration of PBSs, active PSI as well as inactive PSII complexes. Activation of PSII complexes appears to be linked to the biogenesis of organized thylakoid membrane pairs.     

Further identification of the exoplasmic face particles on the freeze-fractured thylakoid membranes: a study using double and triple mutants from Chlamydomonas reinhardtii lacking various photosystem II subunits and the cytochrome b6/f complex.

About 20% of the exoplasmic face (EF) particles present in the freeze-fractured thylakoid membranes of the wild type strain of Chlamydomonas reinhardtii remain in mutants lacking photosystem II (PSII) because of the absence of either one of the two PSII subcomplexes CP43 or D1/D2/CP47. We show that about half of these residual EF particles can be accounted for by PSII subcomplexes still present in such mutants, and by cytochrome (cyt) b6/f complexes. Analysis of double mutants lacking both types of protein complexes points to an association of cyt b6/f complexes with PSII subcomplexes in some of these EF particles and to a requirement in cyt b6/f complexes for the translocation of each of the two PSII subcomplexes (the CP43 subunit and the D1/D2/CP47 subcomplex) from the unstacked to the stacked regions of the thylakoid membranes.     

Unique thylakoid membrane architecture of a unicellular N2-fixing cyanobacterium revealed by electron tomography

Cyanobacteria, descendants of the endosymbiont that gave rise to modern-day chloroplasts, are vital contributors to global biological energy conversion processes. A thorough understanding of the physiology of cyanobacteria requires detailed knowledge of these organisms at the level of cellular architecture and organization. In these prokaryotes, the large membrane protein complexes of the photosynthetic and respiratory electron transport chains function in the intracellular thylakoid membranes. Like plants, the architecture of the thylakoid membranes in cyanobacteria has direct impact on cellular bioenergetics, protein transport, and molecular trafficking. However, whole-cell thylakoid organization in cyanobacteria is not well understood. Here we present, by using electron tomography, an in-depth analysis of the architecture of the thylakoid membranes in a unicellular cyanobacterium, Cyanothece sp. ATCC 51142. Based on the results of three-dimensional tomographic reconstructions of near-entire cells, we determined that the thylakoids in Cyanothece 51142 form a dense and complex network that extends throughout the entire cell. This thylakoid membrane network is formed from the branching and splitting of membranes and encloses a single lumenal space. The entire thylakoid network spirals as a peripheral ring of membranes around the cell, an organization that has not previously been described in a cyanobacterium. Within the thylakoid membrane network are areas of quasi-helical arrangement with similarities to the thylakoid membrane system in chloroplasts. This cyanobacterial thylakoid arrangement is an efficient means of packing a large volume of membranes in the cell while optimizing intracellular transport and trafficking.