Significance of structural variation in thylakoid membranes in maintaining functional photosystems during reproductive growth

Structural variation in the stroma‐grana (SG) arrangement of the thylakoid membranes, such as changes in the thickness of the grana stacks and in the ratio between grana and inter‐grana thylakoid, is often observed. Broadly, such alterations are considered acclimation to changes in growth and the environment. However, the relation of thylakoid morphology to plant growth and photosynthesis remains obscure. Here, we report changes in the thylakoid during leaf development under a fixed light condition. Histological studies on the chloroplasts of fresh green Arabidopsis leaves have shown that characteristically shaped thylakoid membranes lacking the inter‐grana region, referred to hereafter as isolated‐grana (IG), occurred adjacent to highly ordered, large grana layers. This morphology was restored to conventional SG thylakoid membranes with the removal of bolting stems from reproductive plants. Statistical analysis showed a negative correlation between the incidences of IG‐type chloroplasts in mesophyll cells and the rates of leaf growth. Fluorescence parameters calculated from pulse‐amplitude modulated fluorometry measurements and CO₂ assimilation data showed that the IG thylakoids had a photosynthetic ability that was equivalent to that of the SG thylakoids under moderate light. However, clear differences were observed in the chlorophyll a/b ratio. The IG thylakoids were apparently an acclimated phenotype to the internal condition of source leaves. The idea is supported by the fact that the life span of the IG thylakoids increased significantly in the later developing leaves. In conclusion, the heterogeneous state of thylakoid membranes is likely important in maintaining photosynthesis during the reproductive phase of growth.     

Dark-adapted spinach thylakoid protein heterogeneity offers insights into the photosystem II repair cycle

In higher plants, thylakoid membrane protein complexes show lateral heterogeneity in their distribution: photosystem (PS) II complexes are mostly located in grana stacks, whereas PSI and adenosine triphosphate (ATP) synthase are mostly found in the stroma-exposed thylakoids. However, recent research has revealed strong dynamics in distribution of photosystems and their light harvesting antenna along the thylakoid membrane. Here, the dark-adapted spinach (Spinacia oleracea L.) thylakoid network was mechanically fragmented and the composition of distinct PSII-related proteins in various thylakoid subdomains was analyzed in order to get more insights into the composition and localization of various PSII subcomplexes and auxiliary proteins during the PSII repair cycle. Most of the PSII subunits followed rather equal distribution with roughly 70% of the proteins located collectively in the grana thylakoids and grana margins; however, the low molecular mass subunits PsbW and PsbX as well as the PsbS proteins were found to be more exclusively located in grana thylakoids. The auxiliary proteins assisting in repair cycle of PSII were mostly located in stroma-exposed thylakoids, with the exception of THYLAKOID LUMEN PROTEIN OF 18.3 (TLP18.3), which was more evenly distributed between the grana and stroma thylakoids. The TL29 protein was present exclusively in grana thylakoids. Intriguingly, PROTON GRADIENT REGULATION5 (PGR5) was found to be distributed quite evenly between grana and stroma thylakoids, whereas PGR5-LIKE PHOTOSYNTHETIC PHENOTYPE1 (PGRL1) was highly enriched in the stroma thylakoids and practically missing from the grana cores. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: Keys to Produce Clean Energy.     

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.     

Differential scanning calorimetric investigation of pea chloroplast thylakoids and thylakoid fractions.

High sensitivity differential scanning calorimetry (DSC) was employed to study the thermal denaturation of components of pea chloroplast thylakoid membranes. In contrast to previous reports utilizing spinach thylakoids, several transitions are reversible, and deconvolution of the calorimetric curves indicates nine transitions in both first and second heating scans, but overlapping transitions obscure at least three transitions in the first heating scans of control thylakoids. Glutaraldehyde fixation increases the denaturation temperature of several transitions which is consistent with a reported increase in thermal stability of thylakoid function due to fixation. Acidic pH treatment has little effect on the DSC curves, although it has been reported to have a significant effect on membrane structure. Separation of grana from stroma thylakoids indicates that components responsible for transitions centered at approximately 56, 73, 77, and 91 degrees C are predominantly or exclusively associated with grana thylakoids, whereas components responsible for transitions centered at approximately 63 and 81 degrees C are predominantly associated with stroma thylakoids. A broad transition centered at 66 degrees C is associated with grana thylakoids, whereas a sharp transition at the same temperature is due to a component associated with stroma thylakoids. Evidence obtained by washing treatments suggests the latter transition originates from the denaturation of the thylakoid ATPase (CF1). Analysis of the calorimetric enthalpy values indicates most components of the grana thylakoids denature irreversibly at high temperature, whereas components associated with the stroma thylakoids have a considerable degree of thermal reversibility.     

New insights in thylakoid membrane organization

High-pressure freezing (HPF) in combination with freeze substitution (FS) was used to analyse changes in the structure of barley chloroplasts during the daily change of light and darkness. In contrast to conventional treatment of samples, HPF-FS revealed substantial differences in chloroplast shape, volume and ultrastructure in the light period and during darkness. While chloroplasts have an ellipsoidal shape in the light, they have an enlarged and round form during the dark period. Samples collected in the light show the typical differentiation of stroma and grana thylakoids as observed by conventional ultrastructural analyses. In chloroplasts of samples collected during the dark period, thylakoids were swollen and grana stacks to a large extent were disintegrated. Similar changes occurred when leaves in the light were treated with the uncoupler gramicidin. The results suggest that the light-dependent changes in thylakoid membrane organization are related to the light-dependent changes in the ionic milieu of the thylakoid lumen and the stroma.     

TLP18.3, a novel thylakoid lumen protein regulating photosystem II repair cycle

A proteome analysis of Arabidopsis thaliana thylakoid-associated polysome nascent chain complexes was performed to find novel proteins involved in the biogenesis, maintenance and turnover of thylakoid protein complexes, in particular the PSII (photosystem II) complex, which exhibits a high turnover rate. Four unknown proteins were identified, of which TLP18.3 (thylakoid lumen protein of 18.3 kDa) was selected for further analysis. The Arabidopsis mutants (SALK_109618 and GABI-Kat 459D12) lacking the TLP18.3 protein showed higher susceptibility of PSII to photoinhibition. The increased susceptibility of DeltaTLP18.3 plants to high light probably originates from an inefficient reassembly of PSII monomers into dimers in the grana stacks, as well as from an impaired turnover of the D1 protein in stroma exposed thylakoids. Such dual function of the TLP18.3 protein is in accordance with its even distribution between the grana and stroma thylakoids. Notably, the lack of the TLP18.3 protein does not lead to a severe collapse of the PSII complexes, suggesting a redundancy of proteins assisting these particular repair steps to assure functional PSII. The DeltaTLP18.3 plants showed no clear visual phenotype under standard growth conditions, but when challenged by fluctuating light during growth, the retarded growth of DeltaTLP18.3 plants was evident.     

Insights into the complex 3-D architecture of thylakoid membranes in the unicellular cyanobacterium Cyanothece sp. ATCC 51142

In cyanobacteria and chloroplasts, thylakoids are the complex internal membrane system where the light reactions of oxygenic photosynthesis occur. In plant chloroplasts, thylakoids are differentiated into a highly interconnected system of stacked grana and unstacked stroma membranes. In contrast, in cyanobacteria, the evolutionary progenitors of chloroplasts, thylakoids do not routinely form stacked and unstacked regions, and the architecture of the thylakoid membrane systems is only now being described in detail in these organisms. We used electron tomography to examine the thylakoid membrane systems in one cyanobacterium, Cyanothece sp. ATCC 51142. Our data showed that thylakoids form a complicated branched network with a rudimentary quasi-helical architecture in this organism. A well accepted helical model of grana-stroma architecture of plant thylakoids describes an organization in which stroma thylakoids wind around stacked granum in right-handed spirals. Here we present data showing that the simplified helical architecture in Cyanothece 51142 is lefthanded in nature. We propose a model comparing the thylakoid membranes in plants and this cyanobacterium in which the system in Cyanothece 51142 is composed of non-stacked membranes linked by fret-like connections to other membrane components of the system in a limited left-handed arrangement.Key words: cyanobacteria, Cyanothece 51142, thylakoid membrane, electron tomography, chloroplast     

From chloroplasts to photosystems: in situ scanning force microscopy on intact thylakoid membranes

Envelope-free chloroplasts were imaged in situ by contact and tapping mode scanning force microscopy at a lateral resolution of 3-5 nm and vertical resolution of approximately 0.3 nm. The images of the intact thylakoids revealed detailed structural features of their surface, including individual protein complexes over stroma, grana margin and grana-end membrane domains. Structural and immunogold-assisted assignment of two of these complexes, photosystem I (PS I) and ATP synthase, allowed direct determination of their surface density, which, for both, was found to be highest in grana margins. Surface rearrangements and pigment- protein complex redistribution associated with salt-induced membrane unstacking were followed on native, hydrated specimens. Unstacking was accompanied by a substantial increase in grana diameter and, eventually, led to their merging with the stroma lamellae. Concomitantly, PS IIalpha effective antenna size decreased by 21% and the mean size of membrane particles increased substantially, consistent with attachment of mobile light-harvesting complex II to PS I. The ability to image intact photosynthetic membranes at molecular resolution, as demonstrated here, opens up new vistas to investigate thylakoid structure and function.     

The grana margins of plant thylakoid membranes

Plant thylakoid membranes contain three structurally distinct domains: the planar appressed membranes of the grana; the planar non-appressed stroma thylakoids; and the highly curved, non-appressed margins of the grana. Evidence is presented to suggest that the grana margins form a significant structural domain, which has hitherto been neglected. If indeed the grana margins contain some of the cytochrome b/f complex, photosystem (PS) I complex and ATP synthase, they form a third functional domain of the laterally heterogeneous continuous thylakoid membrane network. The consequences of grana margins containing complexes are explored with respect to linear electron transport under light-saturating and light-limiting conditions, non-cyclic vs cyclic photophorylation, and the regulation of light energy distribution to both PS I and PS II.     

Correlation between spatial (3D) structure of pea and bean thylakoid membranes and arrangement of chlorophyll-protein complexes

ABSTRACT: BACKGROUND: The thylakoid system in plant chloroplasts is organized into two distinct domains: granaarranged in stacks of appressed membranes and non-appressed membranes consisting ofstroma thylakoids and margins of granal stacks. It is argued that the reason for thedevelopment of appressed membranes in plants is that their photosynthetic apparatus need tocope with and survive ever-changing environmental conditions. It is not known however,why different plant species have different arrangements of grana within their chloroplasts. Itis important to elucidate whether a different arrangement and distribution of appressed andnon-appressed thylakoids in chloroplasts are linked with different qualitative and/orquantitative organization of chlorophyll-protein (CP) complexes in the thylakoid membranesand whether this arrangement influences the photosynthetic efficiency. RESULTS: Our results from TEM and in situ CLSM strongly indicate the existence of differentarrangements of pea and bean thylakoid membranes. In pea, larger appressed thylakoids areregularly arranged within chloroplasts as uniformly distributed red fluorescent bodies, whileirregular appressed thylakoid membranes within bean chloroplasts correspond to smaller andless distinguished fluorescent areas in CLSM images. 3D models of pea chloroplasts show adistinct spatial separation of stacked thylakoids from stromal spaces whereas spatial divisionof stroma and thylakoid areas in bean chloroplasts are more complex. Structural differencesinfluenced the PSII photochemistry, however without significant changes in photosyntheticefficiency. Qualitative and quantitative analysis of chlorophyll-protein complexes as well asspectroscopic investigations indicated a similar proportion between PSI and PSII corecomplexes in pea and bean thylakoids, but higher abundance of LHCII antenna in pea ones.Furthermore, distinct differences in size and arrangements of LHCII-PSII and LHCI-PSIsupercomplexes between species are suggested. CONCLUSIONS: Based on proteomic and spectroscopic investigations we postulate that the differences in thechloroplast structure between the analyzed species are a consequence of quantitativeproportions between the individual CP complexes and its arrangement inside membranes.Such a structure of membranes induced the formation of large stacked domains in pea, orsmaller heterogeneous regions in bean thylakoids. Presented 3D models of chloroplasts showed that stacked areas are noticeably irregular with variable thickness, merging with eachother and not always parallel to each other.     

Changes of Thylakoid Membrane Stacks and Chl a/b Ratio of Chloroplast from Sacred Lotus (Nelumbo nucifera) Seeds During Their Germination Under Light

Changes of chloroplast thylakoid membrane stacks and Chl a/b ratio in the plumule of sacred lotus (Nelumbo nucifera Gaertn) seeds during their germination under light were as follows: Before germination there were giant grana and very low Chi a/b ratio (0.9) in the chloroplasts. Two days after germination, the thylakoid membranes of the giant grana gradually loosened and even destacked (disintegrated), the Chl a/b ratio was 1.06. Four clays after germination, the newly formed grana thylakoid membranes were 3–5 times shorter than those of the supergrana thylakoid membranes before germination and less grana stacks were seen; the Chl a/b ratio was 1.42. Six days after germination, the stacked thylakoi membranes became more orderly arranged. In addition the grana increased in number, the stroma thylakoid membranes were scarce, the Chl a/b ratio was 2.16. Eiglt days after germination, the thylakoid membranes in each granum decreased, but the total number of grana increased only slightly. In the meantime, some large starch grains and more stroma thylakoid membranes appeared; the Chl a/b ratio was 2.77. Ten days after germination normal thylakoid membrane structure was formed both in grana and stroma lamellae. They were arranged orderly as in the chloroplasts of other higher plants; the Chl a/b ratio was 2.80. The following conclusions could be drawn from the above mentioned results: 1) There was a negative correlation between the degree of stacking of the grana thylakoid membranes and the Chl a/b ratio. This statement further proved that the membranes stacking might mainly be induced by LHCII. 2) Development of the grana thylakoid membranes within chloroplasts from sacred lotus plumule followed that of the stroma thylakoid membranes, and the tendency of changes of their Chl 2/b ratio being from the lowest to the highest and then to normal were quite different from those of other higher plants. The chloroplasts iri the latter plants contain long parallel stacks of nonappressed primary thylakoids at second step, and the changes of their ratio of Chl a/b tend to be from the highest to the lowest and then to normal. There are indications that sacred lotus plumule might employ a distinctive developing pathway. This provides an important basis for Nelumbo to possess an unique position in phylogeny of Angiospermae.     

The constant proportion of grana and stroma lamellae in plant chloroplasts

The relative proportion of stroma lamellae and grana end membranes was determined from electron micrographs of 58 chloroplasts from 21 different plant species. The percentage of grana end membranes varied between 1 and 21% of the total thylakoid membrane indicating a large variation in the size of grana stacks. By contrast the stroma lamellae account for 20.3 ± 2.5 ( sd )% of the total thylakoid membrane. A plot of percentage stroma lamellae against percentage of grana end membranes fits a straight line with a slope of zero showing that the proportion of stroma lamellae is independent of the size of the grana stacks. That stroma lamellae account for about 20% of the thylakoid membrane is in agreement with fragmentation and separation analysis (Gadjieva et al . Biochim. Biophys. Acta 144: 92–100, 1999). Chloroplasts from spinach, grown under high or low light, were fragmented by sonication and separated by countercurrent distribution into two vesicle populations originating from grana and stroma lamellae plus end membranes, respectively. The separation diagrams were very similar lending independent support for the notion that the proportion of stroma lamellae is constant. The results are discussed in relation to the composition and function of the chloroplast in plants grown under different environmental conditions, and in relation to a recent quantitative model for the thylakoid (Albertsson, Trends Plant Sci. 6: 349–354, 2001).     

Molecular crowding and order in photosynthetic membranes

The integrity and maintenance of the photosynthetic apparatus in thylakoid membranes of higher plants requires lateral mobility of their components between stacked grana thylakoids and unstacked stroma lamellae. Computer simulations based on realistic protein densities suggest serious problems for lateral protein and plastoquinone diffusion especially in grana membranes, owing to strong retardation by protein complexes. It has been suggested that three structural features of grana thylakoids ensure efficient lateral transport: the organization of protein complexes into supercomplexes; the arrangement of supercomplexes into structured assemblies, which facilitates diffusion process in crowded membranes; the limitation of the diameter of grana discs to less than approximately 500 nm, which keeps diffusion times short enough to support regulation of light harvesting and repair of photodamaged photosystem II.     

Effect of Doubled-CO2 Concentration on the Ultrastructure of Chloroplasts from Medicago sativa and Setaria italica

It has been reported in quite a number of literatures that doubled CO2 concentration increased the photosynthetic rate and dry matter production of C3 plants, but substantially affected C4 plants little. However, why may CO2 enrichment promote growth and either no change or decrease reproductive allocation of the C3 species, but havinag no effects on growth characteristics of the C4 plants? So far, there has been no satisfactory explanation on that mentioned above, except the differences in their CO2 compensatory points. In the past, although some studies on ultrastructure of the chloroplasts under doubled CO2 concentration were limitedly conducted. Almost all the relevant experimental materials were only from C3 plants not from C4 plants, and even though the results were of inconsistancy. Thereby, it needs to verify whether the differences in photosynthesis of C3 and C4 plants at doubled CO2 level is caused by the difference in their chloroplast deterioration. Experiments to this subject were conducted at the Botanical Garden of Institute of Botany, Academia Sinica in 1993 and 1994. Both experimental materials from C3 plant alfalfa (Medicago sativa) and C4 plant foxtail millet (Setaria italica) were cultivated in the cylindrical open-top chambers (2.2 m in diameter × 2.4 m in height) with aluminum frames covered by polyethylene film. Natural air or air with 350× 10-6 CO2 were blown from the bottom of the chamber space with constant temperature between inside and outside of the chamber 〈0.2℃〉. Electron microscopic observation revealed that the ultrastructure of the chloroplasts from C3 plant Medicago sativa and C4 plant Seteria italica growing under the same doubled CO2 concentration were quite different from each other. The differential characteristics in ultrastructure of chloro plasts displayed mainly in the configuration of thylakoid membrances and the accumulation of starch grains. They were as follows: 1. The most striking feature was the building up of starch grains in the chloroplasts of the bundle sheath cells (BSCs) and the mesophyll cells (MCs) at doubled CO2 concentra tion. The starch grains appeared centrifugally first in the BSCs and then in the chloroplast of the other MCs. It was worthy to note that the starch grains in the chloroplasts of C4 plant Setaria ira/ica were much more than those of the C3 plant Medicago sativa . The decline of photosynthesis in the doubled CO2-grown C4 plants might be caused by an over accumulation of starch grains, that deformed the chloroplast even demaged the stroma thylakoids and grana. There might exsist a correlation between the comformation of thylakoid system and starch grain accumulation, namely conversion and transfer of starch need energy from ATP, and coupling factor (CF) for ATP formation distributed mainly on protoplastic surface (PSu) of stroma thylakoid membranes, as well as end and margin membranes of grana thylakoids. Thereby, these results could provide a conclusive evidence for the reason of non effectiveness on growth characteristics of C4 plant. 2. Under normal condition , the mature chlolroplats of higher plants usually develop complete and regularly arranged photosynthetic membrane systems . Chloroplasts from the C4 plant Setaria italica, however, exerted significant changes on stacking degree, grana width and stroma thylakoid length under doubled CO2 concentration; In these changes, the grana stacks were smaller and more numerous, and the number of thylakoids per granum was greatly increased, and the stroma thylakoid was greatly lengthened as compared to those of the control chloroplasts. But the grana were mutually intertwined by stroma thylakoid. The integrity of some of the grana were damaged due to the augmentation of the intrathylakoid space . Similarly, the stroma thylakoids were also expanded. In case. the plant was seriously effected by doubled CO2 concentration as observed in C4 plant Setaria italica , its chloroplasts contained merely the stroma (matrix) with abundant starch grains, while grana and stroma thylakoid membranes were unrecognizable, or occasionally a few residuous pieces of thylakoid membranes could be visualized, leaving a situation which appeared likely to be chloroplast deterioration. However, under the same condition the C3 plant Medicago sativa possessed normally developed chloroplasts, with intact grana and stroma thylakoid membranes. Its chloroplasts contained grana intertwined with stroma thylakoid membranes, and increased in stacking degree and granum width, in spite of more accumulated starch grains within the chloroplasts. These configuration changes of the thylakoid system were in consistant with the results of the authors another study on chloroplast function, viz. the increased capacity of chloroplasts for light absorption and efficiency of PSⅡ.     

Light regulation of photosynthetic membrane structure,organization, and function

The light environment during plant growth determines the structural and functional properties of higher plant chloroplasts, thus revealing a dynamically regulated developmental system. Pisum sativum plants growing under intermittent illumination showed chloroplasts with fully functional photosystem (PS) II and PSI reaction centers that lacked the peripheral chlorophyll (Chi) a/b and Chl a light-harvesting complexes (LHC), respectively. The results suggest a light flux differential threshold regulation in the biosynthesis of the photosystem core and peripheral antenna complexes. Sun-adapted species and plants growing under far-red-depleted illumination showed grana stacks composed of few (3–5) thylakoids connected with long intergrana (stroma) thylakoids. They had a PSII/PSI reaction center ratio in the range 1.3–1.9. Shade-adapted species and plants growing under far-red-enrichcd illumination showed large grana stacks composed of several thylakoids, often extending across the entire chloroplast body, and short intergrana stroma thylakoids. They had a higher PSII/PSI reaction center ratio, in the range of 2.2–4.0. Thus, the relative extent of grana and stroma thylakoid formation corresponds with the relative amounts of PSII and PSI in the chloroplast, respectively. The structural and functional adaptation of the photosynthetic membrane system in response to the quality of illumination involves mainly a control on the rate of PSII and PSI complex biosynthesis.     

Distribution of the early light-inducible protein in the thylakoids of developing pea chloroplasts

The distribution of the early light-inducible protein (ELIP) of pea (Pisum sativum) between grana and stroma thylakoids was studied. An antibody raised against a bacterial-expressed fusion protein containing ELIP sequences was used. Illumination of dark-grown pea seedlings causes an accumulation of the ELIP in the thylakoid membranes with a maximum level at 16 h. During continuous illumination exceeding 16 h the level decreases again. The fractionation of thylakoid membranes of 48-h-illuminated pea seedlings in grana and stroma thylakoids reveals that there is no uniform distribution of ELIP in the thylakoids. Rather 60-70% of ELIP was found in the stroma thylakoids and 30-40% in the grana thylakoids. This distribution is in accordance with that of photosystem I but not with that of photosystem II. After Triton-X-100 solubilization almost all ELIP is found in the photosystem-I-containing fraction. This also supports an association of ELIP with photosystem I.     

Arrangement of Photosystem II and ATP Synthase in Chloroplast Membranes of Spinach and Pea

We used cryoelectron tomography to reveal the arrangements of photosystem II (PSII) and ATP synthase in vitreous sections of intact chloroplasts and plunge-frozen suspensions of isolated thylakoid membranes. We found that stroma and grana thylakoids are connected at the grana margins by staggered lamellar membrane protrusions. The stacking repeat of grana membranes in frozen-hydrated chloroplasts is 15.7 nm, with a 4.5-nm lumenal space and a 3.2-nm distance between the flat stromal surfaces. The chloroplast ATP synthase is confined to minimally curved regions at the grana end membranes and stroma lamellae, where it covers 20% of the surface area. In total, 85% of the ATP synthases are monomers and the remainder form random assemblies of two or more copies. Supercomplexes of PSII and light-harvesting complex II (LHCII) occasionally form ordered arrays in appressed grana thylakoids, whereas this order is lost in destacked membranes. In the ordered arrays, each membrane on either side of the stromal gap contains a two-dimensional crystal of supercomplexes, with the two lattices arranged such that PSII cores, LHCII trimers, and minor LHCs each face a complex of the same kind in the opposite membrane. Grana formation is likely to result from electrostatic interactions between these complexes across the stromal gap.     

Lateral heterogeneity of plant thylakoid protein complexes: early reminiscences

The concept that the two photosystems of photosynthesis cooperate in series, immortalized in Hill and Bendall''s Z scheme, was still a black box that defined neither the structural nor the molecular organization of the thylakoid membrane network into grana and stroma thylakoids. The differentiation of the continuous thylakoid membrane into stacked grana thylakoids interconnected by single stroma thylakoids is a morphological reflection of the non-random distribution of photosystem II/light-harvesting complex of photosystem II, photosystem I and ATP synthase, which became known as lateral heterogeneity.     

Light-induced structural changes of thylakoids in normal and carotenoid deficient chloroplasts of maize

Summary Changes of membrane thickness and loculi were studied after red (650 nm) and far-red (707 nm) light in thylakoids of maize with different stacking and pigment compositions.The most intensive shrinkage of thylakoid membranes occurred in grana and under red light. Membranes of stroma thylakoids responded more to far-red light. Bundle sheath thylakoid membranes did not change in thickness. Loculi decreased in all types of thylakoids under both, red and far-red light. Thylakoids obtained from a -carotenic mutant exhibited a contrasting response: swelling under red light followed by photodestruction. Changes under far-red light were similar to that of normal stroma thylakoids.The data on normal chloroplasts show that the light induced shrinkage of membranes and the decrease of loculi are coupled to a different degree in various kinds of thylakoids; that the thylakoid flattening can be correlated with the Photosystem content of the membranes; and that two kinds of single thylakoids (stroma lamellae and bundle sheath lamellae) are different in molecular structure and function.Data on carotenoid deficient chloroplasts indicate a photooxidative destruction of the thylakoids by Photosystem 2 that occurs in the absence of normal carotenoids.     

Quantification of photosystem I and II in different parts of the thylakoid membrane from spinach

Electron paramagnetic resonance (EPR) was used to quantify Photosystem I (PSI) and PSII in vesicles originating from a series of well-defined but different domains of the thylakoid membrane in spinach prepared by non-detergent techniques. Thylakoids from spinach were fragmented by sonication and separated by aqueous polymer two-phase partitioning into vesicles originating from grana and stroma lamellae. The grana vesicles were further sonicated and separated into two vesicle preparations originating from the grana margins and the appressed domains of grana (the grana core), respectively. PSI and PSII were determined in the same samples from the maximal size of the EPR signal from P700(+) and Y(D)( .-), respectively. The following PSI/PSII ratios were found: thylakoids, 1.13; grana vesicles, 0.43; grana core, 0.25; grana margins, 1.28; stroma lamellae 3.10. In a sub-fraction of the stroma lamellae, denoted Y-100, PSI was highly enriched and the PSI/PSII ratio was 13. The antenna size of the respective photosystems was calculated from the experimental data and the assumption that a PSII center in the stroma lamellae (PSIIbeta) has an antenna size of 100 Chl. This gave the following results: PSI in grana margins (PSIalpha) 300, PSI (PSIbeta) in stroma lamellae 214, PSII in grana core (PSIIalpha) 280. The results suggest that PSI in grana margins have two additional light-harvesting complex II (LHCII) trimers per reaction center compared to PSI in stroma lamellae, and that PSII in grana has four LHCII trimers per monomer compared to PSII in stroma lamellae. Calculation of the total chlorophyll associated with PSI and PSII, respectively, suggests that more chlorophyll (about 10%) is associated with PSI than with PSII.