Electron and proton transport in chloroplasts taking into account lateral heterogeneity of thylakoids. Mathematical model]

A mathematical model of a chloroplast was constructed, which takes into account the inhomogeneous distribution of complexes of photosystems I and II between granal and intergranal thylakoids. The structural and functional complexes of photosystems I and II, which are localized in intergranal and granal thylakoids, respectively, and the b/f complex, which is uniformly distributed in thylakoid membranes, are assumed to be immobile. The interactions between spatially distant electron transport complexes are provided by plastoquinone and plastocyanine, which diffuse in the thylakoid membrane and intrathylakoid space, respectively. The main stages of proton transport associated with the functioning of photosystem II and oxidation-reduction transformations of plastoquinone are considered. The model takes into account the interactions of protons with membrane-bound buffer groups, the lateral diffusion of hydrogen ions in the intrathylakoid space and in the lumen between adjacent granal thylakoids, and the transmembrane proton transport associated with the function of ATP synthase and passive leakage of protons from thylakoids outside. The numerical integration of two systems of differential equations describing the behavior of some variables in two different regions: granal and intergranal thylakoids was performed. The model describes adequately the kinetics of processes being studied and predicts the occurrence of inhomogeneous lateral profiles of proton potentials and redox state of electron carriers. Modeling the electron and proton transport with allowance for the topological features of chloroplasts (lateral heterogeneity of thylakoids) is important for correct interpretation of "power-flux" interactions and the experimentally measured kinetic parameters averaged over the entire spatially inhomogeneous thylakoid system.     

Thylakoid and grana formation during the development of pea chloroplasts,illuminated by white,red, and blue low intensity light

Summary We analyzed the formation of thylakoids and grana during the development of pea chloroplasts, illuminated by white, red and blue low intensity light. The total length of granal and intergranal thylakoids, and the length of granal thylakoids per unit area of plastid section were measured. Initially the greatest increase in length of granal thylakoids and the highest incidence of grana with large thylakoid content occurred in red light. On the other hand, with illumination times of over 12 hours blue light appeared to be more efficient in stimulating grana formation and thylakoid growth.     

Further studies of the relationship between cation-induced chlorophyll fluorescence and thylakoid membrane stacking changes

Salt-induced changes in thylakoid stacking and chlorophyll fluorescence do not occur with granal membranes obtained by treatment of stacked thylakoids with digitonin. In contrast to normal untreated thylakoids, digitonin prepared granal membranes remain stacked under all ionic conditions and exhibit a constant high level of chlorophyll fluorescence. However, unstacking of these granal membranes is possible if they are pretreated with either acetic anhydride or linolenic acid.Trypsin treatment of the thylakoids inhibits the salt induced chlorophyll fluorescence and stacking changes but stacking of these treated membranes does occur when the pH is lowered, with the optimum being at about pH 4.5. This type of stacking is due to charge neutralization and does not require the presence of the 2000 dalton fragment of the polypeptide associated with the $\text{chlorophyll}\text{a}\text{chlorophyll}\text{b}$ light harvesting complex and known to be lost during treatment with trypsin (Mullet, J.E. and Arntzen, C.J. (1980) Biochim. Biophys. Acta 589, 100–117).Using the method of 9-aminoacridine fluorescence quenching it is argued that the surface charge density, on a chlorophyll basis, of unstacked thylakoid membranes is intermediate between digitonin derived granal and stromal membranes, with granal having the lowest value.The results are discussed in terms of the importance of surface negative charges in controlling salt induced chlorophyll fluorescence and thylakoid stacking changes. In particular, emphasis is placed on a model involving lateral diffusion of different types of chlorophyll protein complex within the thylakoid lipid matrix.     

珊瑚豆果实成熟过程中叶绿体转化为杂色体的研究

珊瑚豆 (Solanum pseudo- capsicum var.diflorum (Vell.) Bitter)果实成熟过程中 ,果实颜色的变化和叶绿素含量降低及类胡萝卜素含量增长相符合。对果实中叶绿体转化为杂色体进行了电镜观察。早期绿色果实的特点是叶绿体具典型的基粒 -基粒间类囊体结构。在黄绿色果实时期叶绿体类囊体系统解体 ,代之以少数非叶绿素的单个类囊体和积累大的嗜锇的质体小球。质体转变为所谓的原质体。这表明叶绿体在果实成熟中的脱分化过程。当果实达到黄色阶段 ,这些质体所含的质体小球开始从中央形成质体小管的结构。最初质体小球中央变为半透明 ,认为是质体累积胡萝卜素的开始。随着质体小球的延长 ,小管从小球中伸出。这些小管围以电子致密的膜 ,中央是半透明的轴心。与此同时 ,在质体基质中出现一系列发育不同阶段的小泡 ,似乎是形成新的质体小球的过程。在成熟的橙色和橙红色果实中的杂色体中只包含无数小管和小的质体小球。质体小管在数量和长度上增长 ,充满成熟的杂色体。无数质体小球分布在小管之间的空间中。成熟杂色体从脱分化的原质体的重建是真正的再分化过程。可以作出结论 ,珊瑚豆果实叶绿体转化为杂色体实质上是一个脱分化和再分化过程     

Ultrastructural characterization of the reversible differentiation of chloroplasts in cucumber fruit

The changes in plastid ultrastructure in the pericarp of cucumber (Cucumis sativus L) fruit were studied during fruit yellowing (which accompanied maturation) and regreening. In the course of fruit maturation, the thylakoid system was progressively reduced, and only a small number of membranes remained in the plastids of mature fruit. At the same time, the plastoglobules increased in size, often remaining in close proximity to the degrading thylakoids. In pericarp tissue which turned green again, the thylakoid network in the plastids was gradually reconstituted. Morphological similarities between the plastids in mature and regreening fruit indicated that the chloroplasts in regreened tissue were redifferentiated from the plastids of mature fruit. Reconstitution of the thylakoid system appeared to start from two morphologically distinct types of membranes: from double membranes which resembled thylakoids and from membrane-bound bodies (MBBs). The latter appeared to form thylakoids by two mechanisms: by detachment of extensions from their surfaces and by fragmentation. The plastoglobules remained in the plastids during thylakoid system reconstitution and were often observed in close proximity to developing thylakoids. In the course of chloroplast redifferentiation, several types of membraneous structures were found to be associated with the plastid envelope: (i) vesicles which appeared to separate from the envelope and to fuse subsequently with the developing thylakoids, (ii) tubules, and (iii) double-membrane sheets which appeared asde novo forming thylakoids.     

An ATP synthase harboring an atypical γ–subunit is involved in ATP synthesis in tomato fruit chromoplasts

Chromoplasts are non‐photosynthetic plastids specialized in the synthesis and accumulation of carotenoids. During fruit ripening, chloroplasts differentiate into photosynthetically inactive chromoplasts in a process characterized by the degradation of the thylakoid membranes, and by the active synthesis and accumulation of carotenoids. This transition renders chromoplasts unable to photochemically synthesize ATP, and therefore these organelles need to obtain the ATP required for anabolic processes through alternative sources. It is widely accepted that the ATP used for biosynthetic processes in non‐photosynthetic plastids is imported from the cytosol or is obtained through glycolysis. In this work, however, we show that isolated tomato (Solanum lycopersicum) fruit chromoplasts are able to synthesize ATP de novo through a respiratory pathway using NADPH as an electron donor. We also report the involvement of a plastidial ATP synthase harboring an atypical γ–subunit induced during ripening, which lacks the regulatory dithiol domain present in plant and algae chloroplast γ–subunits. Silencing of this atypical γ–subunit during fruit ripening impairs the capacity of isolated chromoplast to synthesize ATP de novo. We propose that the replacement of the γ–subunit present in tomato leaf and green fruit chloroplasts by the atypical γ–subunit lacking the dithiol domain during fruit ripening reflects evolutionary changes, which allow the operation of chromoplast ATP synthase under the particular physiological conditions found in this organelle.     

The three-dimensional structure of the cyanobacterium Synechocystis sp. PCC 6803

To advance our knowledge of the model cyanobacterium Synechocystis sp. PCC 6803 we investigated the three-dimensional organization of the cytoplasm using standard transmission electron microscopy and electron tomography. Electron tomography allows a resolution of ~5 nm in all three dimensions, superior to the resolution of most traditional electron microscopy, which is often limited in part by the thickness of the section (70 nm). The thylakoid membrane pairs formed layered sheets that followed the periphery of the cell and converged at various sites near the cytoplasmic membrane. At some of these sites, the margins of thylakoid membranes associated closely along the external surface of rod-like structures termed thylakoid centers, which sometimes traversed nearly the entire periphery of the cell. The thylakoid membranes surrounded the central cytoplasm that contained inclusions such as ribosomes and carboxysomes. Lipid bodies were dispersed throughout the peripheral cytoplasm and often juxtaposed with cytoplasmic and thylakoid membranes suggesting involvement in thylakoid maintenance or biogenesis. Ribosomes were numerous and mainly located throughout the central cytoplasm with some associated with thylakoid and cytoplasmic membranes. Some ribosomes were attached along internal unit-membrane-like sheets located in the central cytoplasm and appeared to be continuous with existing thylakoid membranes. These results present a detailed analysis of the structure of Synechocystis sp. PCC 6803 using high-resolution bioimaging techniques and will allow future evaluation and comparison with gene-deletion mutants.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users.     

CHROMOPLASTS OF TOMATO FRUITS. I. ULTRASTRUCTURE OF LOW-PIGMENT AND HIGH-BETA MUTANTS. CAROTENE ANALYSES

Three pigment lines of the tomato cultivar ‘Pearson’ with isogenic backgrounds were studied to determine the relationship between certain carotenoids and the development of chromoplasts during fruit ripening. The lines were normal red (r⁺/r⁺), in which about 90% of the carotenoids in the ripe fruit is lycopene; high-beta (B/B) mutant, in which beta-carotene is the major pigment and the mature fruit color is deep orange ; and low-pigment (r/r) mutant, in which carotenoids are drastically reduced and the mature fruit is pale yellow-orange. This paper reports pigment analyses for the three lines and the ultrastructural changes in plastids of the two mutant lines. Very young, pale green fruits contain proplastids with limited lamellar structure. As the fruits reach the mature green stage, the plastids in all three lines develop into typical chloroplasts. Differences in pigment content and in ultrastructure among the lines are not apparent until ripening commences. In the low-pigment mutant carotenoids are reduced as ripening progresses and no carotenoid crystalloids are formed. As chlorophyll decreases the fruits become pale yellow. The grana become disorganized and the thylakoids appear to separate at the partitions and tend to be arrayed in lines, some still with their ends overlapping. Globules increase slightly in number. In the high-beta mutant the grana break down during ripening and globules increase greatly in size and number. Beta-carotene, presumed to be largely in the globules, crystallizes into elongated or druse type forms which may distort the globules. The crystals may affect the shape of the chromoplasts; long crystals may extend the length of the plastid to over 15 μ. Thylakoid plexes with a regular lattice structure sometimes occur in the chromoplasts of the high-beta mutant. Granules resembling aggregations of phytoferritin particles occur in the chromoplasts of both of these mutants.     

EFFECT OF SHORT-TERM SHADING ON THE CYTOLOGY OF PALISADE TISSUE IN MATURE LEAVES OF THE SUNFLOWER HELIANTHUS ANNUUS

Mature sunflower leaves were exposed to partial shading (35 or 14% of normal sun) or darkness (0% of normal sun) for approximately 8 hr. During this period one-half of each test leaf was shaded; the other half was used as a normal sun control. Palisade cell structure from both halves of each leaf was compared. Shading of leaves had little effect on organelle percent volume values (V_v) with exception of the starch compartment which decreased as shading increased. The surface to volume ratio (S_v) of the chloroplast thylakoids increased while the S_v of the mitochondrial membranes decreased as shading increased. Palisade cell volume did not change in shaded portions of the leaf, except in the fully shaded (dark) tissues where cell volume decreased. Changes in the actual volume of organelle compartments were strongly correlated with changes in cell volume. Thus a general osmotic response may account for some of the volume changes associated with differences in light intensity. Shading increased thylakoid surface areas 10–30% over the full sun controls. The ratio of stromal to granal thylakoid surface area remained constant in both the control and partially shaded samples. However, in darkened samples this ratio decreased as stromal membranes increased more than granal membranes. Changes observed in thylakoid surface areas associated with shading did not support thylakoid models which propose the interconversion of granal membranes to stromal membranes and vice versa.     

ULTRASTRUCTURAL CHANGES IN SUNFLOWER CHLOROPLASTS FOLLOWING INOCULATION WITH PSEUDOMONAS SYRINGAE PV. TAGETIS

Severe chlorosis and ultrastructural modifications of chloroplasts occur in sunflower in response to infection by Pseudomonas syringae pv. tagetis. Chlorosis became apparent within 2 days after the cotyledons of 10-day-old sunflower seedlings were inoculated with the bacteria. The first symptoms generally appeared in the center of leaves at the second node above the cotyledons. Leaves above the second node lost essentially all of their pigmentation but remained turgid and continued to expand. Grana thylakoids became dilated and separated from the granal stacks. These thylakoid membranes did not chemically breakdown as in the case in chromoplast formation or normal chloroplast senescence. Both grana and stroma thylakoid membranes coalesced to form a large membrane sheet within the plastid. The ultrastructural changes are unlike those reported to be caused by other chlorosis-inducing bacteria or chlorosis associated with normal senescence.     

Assembly of Newly Imported Oxygen-Evolving Complex Subunits in Isolated Chloroplasts: Sites of Assembly and Mechanism of Binding

We have examined the assembly of the nuclear-encoded subunits of the oxygen-evolving complex (OEC) after their import into isolated intact chloroplasts. We showed that all three subunits examined (OE33, OE23, and OE17) partition between the thylakoid lumen and a site on the inner surface of the thylakoid membrane after import in a homologous system (e.g., pea or spinach subunits into pea or spinach chloroplasts, respectively). Although some interspecies protein import experiments resulted in OEC subunit binding, maize OE17 did not bind thylakoid membranes in chloroplasts isolated from peas. Newly imported OE33 and OE23 were washed from the membranes at the same concentrations of urea and NaCl as the native, indigenous proteins; this observation suggests that the former subunits are bound productively within the OEC. Inhibition of neither chloroplast protein synthesis nor light- or ATP-dependent energization of the thylakoid membrane significantly affected these assembly reactions, and we present evidence suggesting that incoming subunits actively displace those already bound to the thylakoid membrane. Transport of OE33 took place primarily in the stromal-exposed membranes and proceeded through a protease-sensitive, mature intermediate. Initial binding of OE33 to the thylakoid membrane occurred primarily in the stromal-exposed membranes, from where it migrated with measurable kinetics to the granal region. In contrast, OE23 assembly occurred in the granal membrane regions. This information is incorporated into a model of the stepwise assembly of oxygen-evolving photosystem II.     

Thylakoid membrane remodeling during state transitions in Arabidopsis

Adaptability of oxygenic photosynthetic organisms to fluctuations in light spectral composition and intensity is conferred by state transitions, short-term regulatory processes that enable the photosynthetic apparatus to rapidly adjust to variations in light quality. In green algae and higher plants, these processes are accompanied by reversible structural rearrangements in the thylakoid membranes. We studied these structural changes in the thylakoid membranes of Arabidopsis thaliana chloroplasts using atomic force microscopy, scanning and transmission electron microscopy, and confocal imaging. Based on our results and on the recently determined three-dimensional structure of higher-plant thylakoids trapped in one of the two major light-adapted states, we propose a model for the transitions in membrane architecture. The model suggests that reorganization of the membranes involves fission and fusion events that occur at the interface between the appressed (granal) and nonappressed (stroma lamellar) domains of the thylakoid membranes. Vertical and lateral displacements of the grana layers presumably follow these localized events, eventually leading to macroscopic rearrangements of the entire membrane network.     

Red Bell Pepper Chromoplasts Exhibit in Vitro Import Competency and Membrane Targeting of Passenger Proteins from the Thylakoidal Sec and ΔpH Pathways but Not the Chloroplast Signal Recognition Particle Pathway

Chloroplast to chromoplast development involves new synthesis and plastid localization of nuclear-encoded proteins, as well as changes in the organization of internal plastid membrane compartments. We have demonstrated that isolated red bell pepper (Capsicum annuum) chromoplasts contain the 75-kD component of the chloroplast outer envelope translocon (Toc75) and are capable of importing chloroplast precursors in an ATP-dependent fashion, indicating a functional general import apparatus. The isolated chromoplasts were able to further localize the 33- and 17-kD subunits of the photosystem II O₂-evolution complex (OE33 and OE17, respectively), lumen-targeted precursors that utilize the thylakoidal Sec and ΔpH pathways, respectively, to the lumen of an internal membrane compartment. Chromoplasts contained the thylakoid Sec component protein, cpSecA, at levels comparable to chloroplasts. Routing of OE17 to the lumen was abolished by ionophores, suggesting that routing is dependent on a transmembrane ΔpH. The chloroplast signal recognition particle pathway precursor major photosystem II light-harvesting chlorophyll a/b protein failed to associate with chromoplast membranes and instead accumulated in the stroma following import. The Pftf (plastid fusion/translocation factor), a chromoplast protein, integrated into the internal membranes of chromoplasts during in vitro assays, and immunoblot analysis indicated that endogenous plastid fusion/translocation factor was also an integral membrane protein of chromoplasts. These data demonstrate that the internal membranes of chromoplasts are functional with respect to protein translocation on the thylakoid Sec and ΔpH pathways.Plastids are developmentally related organelles capable of interconversion among a variety of structurally and biochemically distinct forms in response to both environmental and tissue-specific cues (Whatley, 1978; Thomson and Whatley, 1980). Formation of chromoplasts in many fruits is one striking example of this plasticity. Heavily pigmented, photosynthetically inactive chromoplasts frequently develop from chloroplasts during ripening. This conversion involves dramatic changes in the organization and composition of the internal plastid compartment, which include the loss of proteins involved in carbon fixation in the stroma and replacement with chromoplast-specific proteins, the breakdown of the photosynthetic thylakoid membranes and loss of proteins involved in light capture and electron transfer, and, in some cases, the formation of new membranes (Spurr and Harris, 1968; Camara and Brangeon, 1981; Piechulla et al., 1987; Kuntz et al., 1989).Chromoplast formation is an active rather than simply a degradative process. New proteins, specific to or enhanced in chromoplasts, are synthesized and compartmentalized in the plastid (Camara et al., 1995; Price et al., 1995). Most chromoplast proteins are predicted to be nuclear encoded, translated on cytoplasmic ribosomes, and posttranslationally imported into the plastid, as are nuclear-encoded chloroplast proteins. Import of chloroplast proteins occurs via a general import machinery that appears to mediate translocation of most or all proteins that are delivered to the chloroplast stroma, either as a final destination or as an intermediate location (Cline and Henry, 1996; Robinson and Mant, 1997; Schnell, 1998). Proteins are targeted to the general import pathway by an N-terminal extension that is cleaved upon import, resulting in the appearance of a processed protein of reduced M_r. Presumably, the import of proteins into chromoplasts is accomplished by the same machinery that is responsible for import of proteins into chloroplasts, although this has never been directly examined.In some chromoplasts an extensive set of internal membranes accumulates, replacing the thylakoids. For example, in the fibrillar-type chromoplast of bell pepper (Capsicum annuum), the photosynthetic membranes are replaced by membranous sheets and vesicles in addition to the carotenoid-rich plastoglobules and fibrils (Spurr and Harris, 1968; Laborde and Spurr, 1973; Camara and Brangeon, 1981; Deruere et al., 1994). The often extensive internal membranes are the site of synthesis of keto-xanthophylls, which constitute the major carotenoids of red fruit (Bouvier et al., 1994).Our interests are in the biogenesis of the internal membranes of plastids, in particular the proteins that are integral to the bilayer, as well as those located in the luminal compartment formed by the bilayer. In chloroplasts, proteins destined for the thylakoid membrane or lumen are routed from the stroma into the thylakoid membrane and lumen by one of at least four distinct mechanisms: the ΔpH, chloroplast SRP, thylakoid Sec pathways, and an apparently spontaneous insertion mechanism (for review, see Cline and Henry, 1996; Robinson and Mant, 1997; Schnell, 1998). In view of the extensive internal membrane system of bell pepper chromoplasts, one would expect the presence of proteins and accompanying translocation machinery in these membranes. However, no chromoplast-specific proteins have been conclusively demonstrated to be either integral or luminal to these membranes.One protein, Pftf (plastid fusion/translocation factor), predicted to be membrane anchored by sequence analysis, has been purified from the stromal compartment of pepper chromoplasts (Hugueney et al., 1995). This raised the possibility that mature chromoplasts lack the ability to localize proteins into/across internal membranes. To address this question we developed a method for isolating protein import-competent chromoplasts from bell peppers. Immunoblotting confirmed that these chromoplasts contain known translocation machinery components. Chromoplasts were assayed in vitro for their ability to import and localize passenger proteins from the three known protein-machinery-dependent thylakoid-targeting pathways. We found mature chromoplasts to be capable of membrane targeting of proteins that utilize the thylakoidal Sec and ΔpH pathways but not capable of inserting a membrane protein, LHCP, which utilizes the chloroplast SRP pathway. Pftf was inserted into the membranes of these chromoplasts in a manner similar to that observed in chloroplasts, and resident Pftf was also found to be integrally associated with chromoplast membranes. The precise role of these pathways in the formation of bell pepper chromoplasts remains to be fully elucidated.     

Dynamic flexibility in the structure and function of photosystem II in higher plant thylakoid membranes: the grana enigma

Grana are not essential for photosynthesis, yet they are ubiquitous in higher plants and in the recently evolved Charaphyta algae; hence grana role and its need is still an intriguing enigma. This article discusses how the grana provide integrated and multifaceted functional advantages, by facilitating mechanisms that fine-tune the dynamics of the photosynthetic apparatus, with particular implications for photosystem II (PSII). This dynamic flexibility of photosynthetic membranes is advantageous in plants responding to ever-changing environmental conditions, from darkness or limiting light to saturating light and sustained or intermittent high light. The thylakoid dynamics are brought about by structural and organizational changes at the level of the overall height and number of granal stacks per chloroplast, molecular dynamics within the membrane itself, the partition gap between appressed membranes within stacks, the aqueous lumen encased by the continuous thylakoid membrane network, and even the stroma bathing the thylakoids. The structural and organizational changes of grana stacks in turn are driven by physicochemical forces, including entropy, at work in the chloroplast. In response to light, attractive van der Waals interactions and screening of electrostatic repulsion between appressed grana thylakoids across the partition gap and most probably direct protein interactions across the granal lumen (PSII extrinsic proteins OEEp-OEEp, particularly PsbQ-PsbQ) contribute to the integrity of grana stacks. We propose that both the light-induced contraction of the partition gap and the granal lumen elicit maximisation of entropy in the chloroplast stroma, thereby enhancing carbon fixation and chloroplast protein synthesizing capacity. This spatiotemporal dynamic flexibility in the structure and function of active and inactive PSIIs within grana stacks in higher plant chloroplasts is vital for the optimization of photosynthesis under a wide range of environmental and developmental conditions.     

Studies on the Conversion of Chloroplast to Chromoplast During Fruit Ripening in Solanum pseudo-capsicum var. diflorum

Determination of chlorophyll and carotenoid contents in the ectocarp during fruit ripening in Solanum pseudo-capsicum var. diflorurn (Veil.) Bitter revealed that the changes of fruit colour coincided with the decline of chlorophyll and the increase of carotenoid contents. The conversion of chloroplasts to chromoplasts in the fruit was studied by electron microscopy. The early green fruit was characterized by chloroplasts with a typical grana-intergranal thylakoid structure. At yellow-green fruit stage the thylakoid system was disintegrated and replaced by few non-chlorophyllous single thylakoids, with accumulation of large osmiophilic plastoglobules. The plastids developed as the so-called proplastids. These indicated dedifferentiation of chloroplasts in a ripening fruit. When the fruit reached its yellow stage, numerous large plastoglobules contained in the young chromoplasts frequently showed transitional changes to plastid tubule structure. At first, the center of plastoglobules became semi-translucent. It was believed that the young chromoplast were in an initial state of carotenoid deposition, followed by plastoglobules elongation and tubule protrution from the globules. These tubules were surrounded with an electron dense membranous sheath leaving the core semi-translucent. Concurrently a series of vesicles in different developmental stages appeared from the stroma of the plastid, likely representing a process of formation of numerous small new plastoglobules. In the chromoplasts of a ripe orange-or orange red-colored fruit only numerous tubules and small plastoglobules were present. The plastid tubules increased in number and elongated in length filling the mature chromoplast. Numerous small plastoglobules also increased and distributed in the spaces between tubules. These results indicated that the reconstruction of a mature chromoplast from a dedifferentiated plastid was really a form of redifferentiation, and it might be concluded that the conversion of chloroplast to chromoplast in the fruit of S. pseudo-capsicum var. diflorum, in fact, was a processes of dedifferentiation and redifferentiation.     

Subdiffraction‐resolution live‐cell imaging for visualizing thylakoid membranes

The chloroplast is the chlorophyll‐containing organelle that produces energy through photosynthesis. Within the chloroplast is an intricate network of thylakoid membranes containing photosynthetic membrane proteins that mediate electron transport and generate chemical energy. Historically, electron microscopy (EM) has been a powerful tool for visualizing the macromolecular structure and organization of thylakoid membranes. However, an understanding of thylakoid membrane dynamics remains elusive because EM requires fixation and sectioning. To improve our knowledge of thylakoid membrane dynamics we need to consider at least two issues: (i) the live‐cell imaging conditions needed to visualize active processes in vivo; and (ii) the spatial resolution required to differentiate the characteristics of thylakoid membranes. Here, we utilize three‐dimensional structured illumination microscopy (3D‐SIM) to explore the optimal imaging conditions for investigating the dynamics of thylakoid membranes in living plant and algal cells. We show that 3D‐SIM is capable of examining broad characteristics of thylakoid structures in chloroplasts of the vascular plant Arabidopsis thaliana and distinguishing the structural differences between wild‐type and mutant strains. Using 3D‐SIM, we also visualize thylakoid organization in whole cells of the green alga Chlamydomonas reinhardtii. These data reveal that high light intensity changes thylakoid membrane structure in C. reinhardtii. Moreover, we observed the green alga Chromochloris zofingiensis and the moss Physcomitrella patens to show the applicability of 3D‐SIM. This study demonstrates that 3D‐SIM is a promising approach for studying the dynamics of thylakoid membranes in photoautotrophic organisms during photoacclimation processes.     

Diffusion of a membrane protein, Tat subunit Hcf106, is highly restricted within the chloroplast thylakoid network

The thylakoid membrane forms stacked thylakoids interconnected by ‘stromal’ lamellae. Little is known about the mobility of proteins within this system. We studied a stromal lamellae protein, Hcf106, by targeting an Hcf106-GFP fusion protein to the thylakoids and photobleaching. We find that even small regions fail to recover Hcf106-GFP fluorescence over periods of up to 3 min after photobleaching. The protein is thus either immobile within the thylakoid membrane, or its diffusion is tightly restricted within distinct regions. Autofluorescence from the photosystem II light-harvesting complex in the granal stacks likewise fails to recover. Integral membrane proteins within both the stromal and granal membranes are therefore highly constrained, possibly forming ‘microdomains’ that are sharply separated.     

The role of chlorophyll-protein complexes in the function and structure of chloroplast thylakoids

Summary The photosynthetic pigments of chloroplast thylakoid membranes are complexed with specific intrinsic polypeptides which are included in three supramolecular complexes, photosystem I complex, photosystem II complex and the light-harvesting complex. There is a marked lateral heterogeneity in the distribution of these complexes along the membrane with photosystem II complex and its associated light-harvesting complex being located mainly in the stacked membranes of the grana partitions, while photosystem I complex is found mainly in unstacked thylakoids together with ATP synthetase. In contrast, the intermediate electron transport complex, the cylochrome b-f complex, is rather uniformly distributed in these two membrane regions. The consequences of this lateral heterogeneity in the location of the thylakoid complexes are considered in relation to the function and structure of chloroplasts of higher plants.     

Characteristics of Photosystem I Complexes in the End Membranes of Pea Granal Thylakoids

Two fractions of the light fragments enriched in the photosystem I (PSI) complexes were obtained from pea (Pisum sativum L.) thylakoids by digitonin treatment and subsequent differential centrifugation. The ratio of chlorophyll a to chlorophyll b, chlorophyll/P700 spectra of low-temperature fluorescence, and excitation spectra of long-wave fluorescence were measured. These characteristics were shown to be different due to variation in the size and composition of the light-harvesting antenna of PSI complexes present in the particles obtained. The larger antenna size of one of the fractions was related to the incorporation of the pool of light-harvesting complex II (LHCII). A comparison with the data available allowed us to identify these particles as fragments of intergranal thylakoids and end membranes of granal thylakoids. The suggestion that an increase in the PSI light-harvesting antenna in intergranal thylakoids is related to the attachment of phosphorylated LHCII is discussed.