The slow rise of the flash-light-induced alkalization by Photosystem II of the suspending medium of thylakoids is reversibly related to thylakoid stacking

We studied the kinetics of flash-induced proton uptake at the reducing site of Photosystem II with Cresol red as indicator for pH transients in the suspending medium. The rise of the alkalization which was observed when Photosystem II was hidden in the stacked regions of the thylakoid membranes was much slower (100 ms) than the reduction of the bound quinones (less than 1 ms). We asked for the delay mechanism. We found that the rise of the alkalization became biphasic if thylakoids were unstacked. This was reversed upon restacking. The portion of the fast phase (half-rise time, 2.7 ms) increased, if the concentration of Mg²⁺ was lowered. After EDTA-treatment we observed solely fast proton uptake. Experiments with dark-adapted chloroplasts showed that the biphasicity was not attributable to the alternating transitions of the bound quinone acceptors through the semiquinone and the hydroquinone stages. The dependence of fast proton uptake on the degree of membrane stacking was on line with our previous proposal (Hong and Junge (1983) Biochim. Biophys. Acta 722, 197–205) that the propagation of a pH pulse in the narrow gaps between stacked membranes was slowed down by multiple reactions of protons with fixed buffering groups. This concept was corroborated by a theory which was given in the subsequent article (Junge, W. and Polle, A. (1986) Biochim. Biophys. Acta 848, 265–273).     

Lateral heterogeneity in the distribution of chlorophyll-protein complexes of the thylakoid membranes of spinach chloroplasts

The lateral distribution of the main chlorophyll-protein complexes between appressed and non-appressed thylakoid membranes has been studied. The reaction centre complexes of Photosystems I and II and the light-harvesting complex have been resolved by an SDS-polyacrylamide gel electrophoretic method which permits most of the chlorophyll to remain protein-bound.

The analyses were applied to subchloroplast fractions shown to be derived from different thylakoid regions. Stroma thylakoids were separated from grana stacks by centrifugation following chloroplast disruption by press treatment or digitonin. Vesicles derived from the grana partitions were isolated by aqueous polymer two-phase partition. A substantial depletion in the amount of Photosystem I chlorophyll-protein complex and an enrichment in the Photosystem II reaction centre complex and the light-harvesting complex occurred in the appressed grana partition region. The high enrichment in this fraction compared to grana stack fractions derived from press or digitonin treatments, suggests that the grana Photosystem I is restricted mainly to the non-appressed grana end membranes and margins, and that the grana partitions possess mainly Photosystem II reaction centre complex and the light-harvesting complex.

In contrast, stroma thylakoids are highly enriched in the Photosystem I reaction centre complex. They possess also some 10–20% of the total Photosystem II reaction centre complex and the light-harvesting complex.

The ratio of light-harvesting complex to Photosystem II reaction centre complex is rather constant in all subchloroplast fractions suggesting a close association between these complexes. This was not so for the ratio of light-harvesting complex and the Photosystem I reaction centre complex.

The lateral heterogeneity in the distribution of the photosystems between appressed and non-appressed membranes must have a profound impact on current understanding of both the distribution of excitation energy and photosynthetic electron transport between the photosystems.     

Functional effects of chemical modification of unstacked and stacked chloroplasts with glutaraldehyde.

Although glutaraldehyde alkylates protein NH₂ groups to the same extent in unstacked and stacked thylakoids, the photosynthetic electron transport of the stacked membranes is always more inhibited. Inhibition of photosystem II electron transport, measured in the presence of lipophilic Hill oxidants, is 20–30% in unstacked and 60–70% in stacked thylakoids. Photosystem I electron transport is nearly completely inhibited in both preparations, but in the case of stacked thylakoids maximal inhibition occurs at a lower glutaraldehyde level than in unstacked thylakoids. In contrast, the photooxidation of the reaction center chromophore of photosystem I (P700) is unaffected by the glutaraldehyde treatment of either stacked or unstacked chloroplasts. The results are discussed with regard to the accessibility of membrane sites to exogenous electron transport cofactors, in view of the observation that N-methylphenazonium methosulfate, a quencher of electronically excited chlorophyll a, partitions more easily into the pigment domains of the glutaraldehyde-fixed unstacked thylakoids.     

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.     

Lateral mobility of the light-harvesting complex in chloroplast membranes controls excitation energy distribution in higher plants

Chloroplast thylakoid protein phosphorylation produces changes in light-harvesting properties and in membrane structure as revealed by freeze-fracture electron microscopy. Protein phosphorylation resulted in an increase in the 77 °K fluorescence signal at 735 nm relative to that at 685 nm. In addition, a decrease in connectivity between Photosystem II centers (PS II) and a dynamic quenching of the room temperature variable fluorescence was observed upon phosphorylation. Accompanying these fluorescence changes was a 23% decrease in the amount of stacked membranes. Microscopic analyses indicated that 8.0-nm particles fracturing on the P-face moved from the stacked into the unstacked regions upon phosphorylation. The movement of the 8.0-nm particles was accompanied by the appearance of chlorophyll b and 25 to 29 kD polypeptides in isolated stroma lamellae fractions. We conclude that phosphorylation of a population of the light-harvesting chlorophyll $\text{a}\text{b}$ protein complexes (LHC) in grana partitions causes the migration of these pigment proteins from the PS II-rich appressed membranes into the Photosystem I (PS I) enriched unstacked regions. This increases the absorptive cross section of PS I. In addition, we suggest that the mobile population of LHC functions to interconnect PS II centers in grana partitions; removal of this population of LHC upon phosphorylation limits PS II → PS II energy transfer and thereby favors spillover of energy from PS II to PS I.     

Photosystem II solubilizes as a monomer by mild detergent treatment of unstacked thylakoid membranes*

We studied the aggregation state of Photosystem II in stacked and unstacked thylakoid membranes from spinach after a quick and mild solubilization with the non-ionic detergent n-dodecyl-α,D-maltoside, followed by analysis by diode-array-assisted gel filtration chromatography and electron microscopy. The results suggest that Photosystem II (PS II) isolates either as a paired, appressed membrane fragment or as a dimeric PS II-LHC II supercomplex upon mild solubilization of stacked thylakoid membranes or PS II grana membranes, but predominantly as a core monomer upon mild solubilization of unstacked thylakoid membranes. Analysis of paired grana membrane fragments reveals that the number of PS II dimers is strongly reduced in single membranes at the margins of the grana membrane fragments. We suggest that unstacking of thylakoid membranes results in a spontaneous disintegration of the PS II-LHC II supercomplexes into separated PS II core monomers and peripheral light-harvesting complexes. This revised version was published online in June 2006 with corrections to the Cover Date.     

Interactions between thylakoid electron transfer complexes. II. Modification studies with glutaraldehyde

Photosystem I (PSI) and photosystem II (PSII) complexes have been isolated from stacked spinach thylakoid membranes that had been treated with varying amounts of glutaraldehyde. The concentrations of cytochrome f, Q, and P700 have been determined by spectrophotometric methods. It was found that at low concentrations of glutaraldehyde, the amount of cytochrome f associated with either PSII or PSI increased significantly while the amounts of Q and P700 stayed relatively constant. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting analyses indicated the presence of cytochrome f and other components of the cytochrome b6-f complex in the PSII and PSI preparations after glutaraldehyde treatment, but no intermolecular cross-linked polypeptides could be detected. Solubilization of the cytochrome b6-f complex was also inhibited after thylakoid membranes were treated with low concentrations of glutaraldehyde. These results are discussed in relation to current models for the organization of the membrane complexes, and relate to the location of the cytochrome b6-f complex in appressed and nonappressed membrane regions of thylakoids.     

Immunocytochemical localization of photosystem I and the fucoxanthin-chlorophylla/c light-harvesting complex in the diatomPhaeodactylum tricornutum

Summary iserum against two polypeptides of the major fucoxanthin-chlorophylla/c light-harvesting complex of the diatomPhaeodactylum tricornutum and heterologous antiserum against purified photosystem I particles of maize were used to localize these two complexes on the thylakoid membranes ofP. tricornutum. As in many chromophyte algae, the thylakoids are loosely appressed and organized into extended bands of three, giving a ratio of 21 for appressed versus non-appressed membranes. Immunoelectron microscopy demonstrated that the fucoxanthin-chlorophylla/c light-harvesting complex, which is believed to be associated with photosystem II, was equally distributed on the appressed and non-appressed thylakoid membranes. Photosystem I was also found on both types of membranes, but was slightly more concentrated on the two outer non-appressed membranes of each band. Similarly, photosystem I activity, as measured by the photooxidation of 3,3-diaminobenzidine, was higher in the outer thylakoids than in the central thylakoid of each band. We conclude that the thylakoids of diatoms differ from those of green algae and higher plants in their macromolecular organization as well as in their morphological arrangement.Abbreviations BSA bovine serum albumin - DAB 3,3-diaminobenzidine - FCPC fucoxanthin-chlorophylla/c light-harvesting complex - LHC light-harvesting complex - PBS phosphate-buffered saline - PS photosystem     

Immunogold localization of light-harvesting and photosystem I complexes in the thylakoids ofFucus serratus (Phaeophyceae)

Summary The repartition of light-harvesting complex (LHC) and photosystem I (PS I) complex has been examined in isolated plastids ofFucus serratus by immunocytochemical labelling. LHC is distributed equally all along the length of thylakoid membranes, without any special repartition in the appressed membranes of the three associated thylakoids ofFucus. PS I is present on all the thylakoid membranes, but the external membranes of the three associated thylakoids are largely enriched relatively to the inner ones. This specific repartition of PSI on non-appressed membranes can be compared to the localization of PSI on stroma thylakoid membranes of higher plants and green algae. Consequently, although they share some common features with those of higher plants and green algae, the appressions of thylakoids in brown algae has neither the same structure nor the same functional role as typical grana stacked membranes in the repartition of the harvested energy.Abbreviations BSA bovine serum albumin - GAR goat anti-rabbit immunoglobulin G - LHC light-harvesting complex - PBS phosphatebuffered saline - PS I photosystem I - PS II photosystem II     

A mechanism for the formation of inside-out membrane vesicles. Preparation of inside-out vesicles from membrane-paired randomized chloroplast lamellae

Inside-out thylakoid membrane vesicles can be isolated by aqueous polymer two-phase partition of Yeda press-fragmented spinach chloroplasts (Andersson, B. and Åkerlund, H.-E. (1978) Biochim. Biophys. Acta 503, 462–472). The mechanism for their formation has been investigated by studying the yield of inside-out vesicles after various treatments of the chloroplasts prior to fragmentation. No inside-out vesicles were isolated during phase partitioning if the chloroplasts had been destacked in a low-salt medium prior to the fragmentation. Only in those cases where the chloroplast lamellae had been stacked by cations or membrane-paired by acidic treatment did we get any yield of inside-out vesicles. Thus, the intrinsic properties of chloroplast thylakoids seem to be such that they seal into right-side out vesicles after disruption unless they are in an appressed state. This favours the following mechanism for the formation of inside-out thylakoids. After press treatment, a ruptured membrane still remains appressed with an adjacent membrane. Resealing of such an appressed membrane pair would result in an inside-out vesicle.If the compartmentation of chloroplast lamellae into appressed grana and unappressed stroma lamellae is preserved by cations before fragmentation, the inside-out vesicles are highly enriched in photosystem II. This indicates a granal origin which is consistent with the proposed model outlined. Inside-out vesicles possessing photosystem I and II properties in approximately equal proportions could be obtained by acid-induced membrane-pairing of chloroplasts which had been destacked and randomized prior to fragmentation. Since this new preparation of inside-out thylakoid vesicles also exposes components derived from the stroma lamellae it complements the previous preparation.It is suggested that fragmentation of paired membranes followed by phase partitioning should be a general method of obtaining inside-out vesicles from membranes of various biological sources.     

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.     

The stacking of chloroplast thylakoids: Evidence for segregation of charged groups into nonstacked regions

Small particles derived from the digitonin treatment of chloroplast thylakoid membranes in either the stacked (grana-containing) or unstacked condition, as determined by cation concentration, have been used to study the aggregation of thylakoid membranes. At pH values above 5, the small particles from stacked chloroplasts do not aggregate in the presence of Mg²⁺ or other screening cations at concentrations sufficient to cause the restacking of thylakoids from low-salt chloroplasts. However, the small particles from stacked chloroplasts are aggregated either by lowering the pH to 4.6 or adding the binding cation La³⁺. In contrast, the small particles obtained on digitonin treatment of unstacked chloroplasts were aggregated by cations at neutral pH. Large particles (mainly grana) derived from digitonin treatment of stacked chloroplasts could not be unstacked by transfer to media of low cation concentration. It is concluded that the nonappressed regions of the chloroplast thylakoid membranes under stacking conditions carry higher than average negative surface charge densities under physiological pH conditions. Transfer of chloroplasts to media of low cation concentration causes a time-dependent lateral redistribution of charge between the appressed and nonappressed regions, but this redistribution is prevented by prior digitonin treatment of stacked chloroplasts.     

Cation-mediated regulation of excitation energy distribution in chloroplasts lacking organized Photosystem II complexes

Despite the total loss of Photosystem II activity, thylakoids isolated from the green nuclear maize mutant hcf1-3 contain normal amounts of the light-harvesting chlorophyll $\text{a}\text{b}$ pigment-protein complex (LHC). We interpret the spectroscopic and ultrastructural characteristics of these thylakoids to indicate that the LHC present in these membranes is not associated with Photosystem II reaction centers and thus exists in a ‘free’ state within the thylakoid membrane. In contrast, the LHC found in wild-type maize thylakoids shows the usual functional association with Photosystem II reaction centers. Several lines of evidence suggest that the free LHC found in thylakoids isolated from hcf1-3 is able to mediate cation-dependent changes in both thylakoid appression and energy distribution between the photosystems: (1) Thylakoids isolated from hcf1-3 and wild-type seedlings exhibit a similar Mg²⁺-dependent increase in the short/long wavelength fluorescence emission peak ratio at 77 K. This Mg²⁺ effect is lost following incubation of thylakoids isolated from either source with low concentrations of trypsin. Such treatment results in the partial proteolysis of the LHC in both membrane types. (2) Thylakoids isolated from both hcf1-3 and wild-type seedlings show a similar Mg²⁺ dependence for the enhancement of the maximal yield of room temperature fluorescence and light scattering; both Mg²⁺ effects are abolished by brief incubation of the thylakoids with low concentrations of trypsin (3) Mg²⁺ acts to reduce the relative quantum efficiency of Photosystem I-dependent electron transport at limiting 650 nm light in thylakoids isolated from hcf1-3. (4) The pattern of digitonin fractionation of thylakoid membranes, which is dependent upon structural membrane interactions and upon LHC in the thylakoids, is similar in thylakoids isolated from both hcf1-3 and wild-type seedlings. We conclude that the surface-exposed segment of the LHC, but not the LHC-Photosystem II core association, is necessary for the cation-dependent changes in both thylakoid appression and energy distribution between the two photosystems, and that the LHC itself is able to transfer excitation energy directly to Photosystem I in a Mg²⁺-dependent fashion in the absence of Photosystem II reaction centers. The latter phenomenon is equivalent to a cation-induced change in the absorptive cross-section of Photosystem I.     

Immunogold localization of LHC II proteins in chloroplasts with different degrees of grana stacking induced by SAN-9789.

The amount and distribution of proteins of the light-harvesting complex associated with photosystem II (PS II) were investigated using immunogold labelling of chloroplasts of wheat ( Triticum aestivum L. cv. Walde). The seedlings were grown in weak red light (16 mW m⁻²) after imbibition of grains with SAN-9789 (Norflurazon, 0.028 to 28 mg I⁻¹). Chloroplasts of these plants exhibited thylakoids with different degrees of stacking. Thylakoids of untreated plants grown in a greenhouse had most gold particles per unit membrane length in both appressed and non-appressed regions compared to red light grown plants. The ratios of labelling between appressed and non-appressed membranes were fairly constant in red light- and greenhouse-grown plants. The labelling densities were 2.5–3 times higher in the appressed thylakoids compared to the non-appressed thylakoids. However, at a SAN concentration of 2.8 mg I⁻¹ there was a sharp decrease in thylakoid appressions and in labelling density of both appressed and non-appressed membranes. The total amount of particles per chloroplast was also much lower as compared to that at lower SAN concentrations. Plants treated with the highest concentration of SAN (28 mg I⁻¹) contained chloroplasts devoid of normal grana structures. In these plastids, the thylakoids were elongated and single. The labelling density in these membranes was ca 50% of that observed at 2.8 mg I⁻¹. This paper thus supports earlier observations that proteins of the light-harvesting complex of PS II (LHC II) are mainly localized in the appressed regions of the grana membranes, and may be involved in the formation of grana.     

Different degrees of phosphorylation and lateral mobility of two polypeptides belonging to the light-harvesting complex of Photosystem II

Several studies have shown that a subpopulation of the light-harvesting chlorophyll a/b-protein complex of Photosystem II (LHC-II) migrates from the appressed to the stroma-exposed thylakoids upon its phosphorylation. In this study we have analyzed the 27 and 25 kDa apopolypeptides of LHC-II, resolved by two-dimensional electrophoresis, with respect to their relative abundance and phosphorylation in thylakoids and subfractions derived from appressed or stroma-exposed thylakoid regions. The results show that the two polypeptides are heterogeneous with respect to both phosphate incorporation and degree of lateral migration. In intact thylakoids, the specific phosphorylation of the 25 kDa polypeptide exceeded that of the 27 kDa polypeptide by a factor of 3. Following phosphorylation, the 25 kDa polypeptide of the stroma lamellae showed as much as 4–5-times higher specific phosphorylation compared to the 27 kDa polypeptide. Moreover, there was a time-dependent increase in the amount of the 25 kDa polypeptide relative to the 27 kDa polypeptide in the stroma-exposed thylakoids. These results demonstrate a different polypeptide composition of the LHC-II tightly bound to Photosystem II and the free pool of LHC-II able to migrate laterally upon phosphorylation. The mobile pool of LHC-II is estimated to have two 27 kDa polypeptides for every 25 kDa polypeptide, while the ratio in the immobile pool is 4:1.     

Plastocyanin redox kinetics in spinach chloroplasts: evidence for disequilibrium in the high potential chain

Reduction kinetics of cytochrome f, plastocyanin (PC) and P(700) ('high-potential chain') in thylakoids from spinach were followed after pre-oxidation by a saturating light pulse. We describe a novel approach to follow PC redox kinetics from deconvolution of 810-860 nm absorption changes. The equilibration between the redox-components was analyzed by plotting the redox state of cytochrome f and PC against that of P(700). In thylakoids with (1) diminished electron transport rate (adjusted with a cytochrome bf inhibitor) or (2) de-stacked grana, cytochrome f and PC relaxed close to their thermodynamic equilibriums with P(700). In stacked thylakoids with non-inhibited electron transport, the equilibration plots were complex and non-hyperbolic, suggesting that during fast electron flux, the 'high-potential chain' does not homogeneously equilibrate throughout the membrane. Apparent equilibrium constants <5 were calculated, which are below the thermodynamic equilibrium known for the 'high potential chain'. The disequilibrium found in stacked thylakoids with high electron fluxes is explained by restricted long-range PC diffusion. We develop a model assuming that about 30% of Photosystem I mainly located in grana end-membranes and margins rapidly equilibrate with cytochrome f via short-distance transluminal PC diffusion, while long-range lateral PC migration between grana cores and distant stroma lamellae is restricted. Implications for the electron flux control are discussed.     

Further investigations on structural and catalytic properties of O2 evolving preparations from tobacco and two chlorophyll deficient tobacco mutants

Previous investigations (Specht, S., Pistorius, E.K. and Schmid, G.H.: Photosynthesis Res. 13, 47–56, 1987) of Photosystem II membranes from tobacco (Nicotiana tabacum L. cv. John William's Broadleaf) which contain normally stacked thylakoid membranes and from two chlorophyll deficient tobacco mutants (Su/su and Su/su var. Aurea) which have low stacked or essentially unstacked thylakoids with occasional membrane doublings, have been extended by using monospecific antisera raised against the three extrinsic polypeptides of 33,21 and 16 kDa. The results show that all three peptides are synthesized as well in wild type tobacco as in the two mutants to about the same level and that they are present in thylakoid membranes of all three plants. However, in the mutants the 16 and 21 kDa peptides (but not the 33 kDa peptide) are easily lost during solubilization of Photosystem II membranes. In the absence of the 16 and 21 kDa peptide Photosystem II membranes from the mutants have a higher O₂ evolving activity without addition of CaCl₂ than the wild type Photosystem II membranes. On the other hand, after removal of the 33 kDa peptide no significant differences in the binding of Mn could be detected among the three plants. The results also show that reaction center complexes from wild type tobacco and the mutant Su/su are almost identical to the Triton-solubilized Photosystem II membranes from the mutant Su/su var. Aurea.Abbreviations PS photosystem - chl chlorophyll - LHCP light harvesting chlorophyll a/b protein complex - WT wild type - OEE1, OEE2 and OEE3 oxygen evolution enhancing complex of 29–36 kDa, 21–24 kDa and 16–18 kDa, respectively     

Quality control of photosystem II: FtsH hexamers are localized near photosystem II at grana for the swift repair of damage

The reaction center-binding D1 protein of Photosystem II is oxidatively damaged by excessive visible light or moderate heat stress. The metalloprotease FtsH has been suggested as responsible for the degradation of the D1 protein. We have analyzed the distribution and subunit structures of FtsH in spinach thylakoids and various membrane fractions derived from the thylakoids using clear native polyacrylamide gel electrophoresis and Western blot analysis. FtsH was found not only in the stroma thylakoids but also in the Photosystem II-enriched grana membranes. Monomeric, dimeric, and hexameric FtsH proteases were present as major subunit structures in thylakoids, whereas only hexameric FtsH proteases were detected in Triton X-100-solubilized Photosystem II membranes. Importantly, among the membrane fractions examined, hexameric FtsH proteases were most abundant in the Photosystem II membranes. In accordance with this finding, D1 degradation took place in the Photosystem II membranes under light stress. Sucrose density gradient centrifugation analysis of thylakoids and the Photosystem II membranes solubilized with n-dodecyl-β-d-maltoside and a chemical cross-linking study of thylakoids showed localization of FtsH near the Photosystem II light-harvesting chlorophyll-protein supercomplexes in the grana. These results suggest that part of the FtsH hexamers are juxtapositioned to PSII complexes in the grana in darkness, carrying out immediate degradation of the photodamaged D1 protein under light stress.     

Possible effects of the detachment of stromal lamellae from granal stacks on salt-induced changes in spillover. A study by sonication of chloroplasts

Salt-induced chlorophyll fluorescence and spillover changes in control and briefly sonicated chloroplasts have been studied under conditions where Photosystem II traps are closed. In a low-salt medium containing 10 mM KCl, control envelope-free chloroplasts exhibited good spillover, as measured by low chlorophyll fluorescence yield at room temperature, a high ratio of the fluorescence peaks $\text{F}{}_{735}\text{F}{}_{685}$ at 77 K, and increased Photosystem I activity in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea and Photosystem II light. In contrast, when stacked chloroplasts were briefly sonicated and subsequently diluted into a low-salt medium, a high fluorescence yield at room temperature and a low ratio of $\text{F}{}_{735}\text{F}{}_{685}$ at 77 K persisted. When unstacked chloroplasts were sonicated and then diluted into a high-salt medium, the room temperature fluorescence yield remained low. The results are interpreted in terms of a model relating the changes in chlorophyll fluoresecence with the lateral diffusion of Photosystem I and Photosystem II chlorophyll-protein complexes in the plane of the thylakoid membrane creating randomized or segregated domains, depending on the degree of electrostatic screening of surface charges (Barber, J. (1980) FEBS Lett. 188, 1–10). It is argued that brief sonication of stacked chloroplasts separates stromal membranes from granal stacks, thus limiting the inter-mixing of the photosystems via lateral diffusion even when the ionic composition of the medium is varied. Consequently energy transfer from Photosystem II to Photosystem I is relatively poor and chlorophyll fluorescence from Photosystem II is enhanced. The loss of the salt effect on sonicated unstacked membranes can also be accommodated by the model. In this case it seems that the generation of small membrane fragments does not allow the normal salt-induced phase separation of the pigment-protein complexes to occur.     

Exposure to low levels of photosynthetically active radiation induces rapid increases in palisade cell chloroplast volume and thylakoid surface area in sunflower (Helianthus annuus L.)

Summary Sudden changes in photoactive radiation (PAR) (wavelength, 400–700 nm) induces rapid surface area changes in chloroplast thylakoid membranes. Although this response may have important photo-acclimative functions for the plant, little is known about the mechanisms by which changes in irradiance are detected or how thylakoid membranes actually increase or decrease surface area. Knowledge of the time required for significant changes in thylakoid area would help eliminate or support several possible mechanisms that may be involved in this aspect of photo-acclimation in plants. Leaf tissues were acclimated to a PAR of 500 mol quanta per m² per s then exposed to low irradiance (PAR, 50 mol quanta per m² per s) and sampled at 5, 15, 30, and 60 min post exposure. Tissue and cell structure were quantified and results showed a significant increase in the surface-to-volume ratio and surface area per unit of standard leaf volume for both appressed and nonappressed thylakoids within 5 min of exposure to low irradiance. On the basis of the ratios of appressed to nonappressed thylakoids, the surface area of the nonappressed thylakoids was found to increase faster than that of the appressed thylakoids throughout the sample period. The portion of the appressed thylakoids in contact with the stroma was defined as margin thylakoids. Margin thylakoid surface-to-volume ratio did not change relative to the high-irradiance control during the sample period but did remain significantly lower than the low-irradiance control during the sample period. The ratio of appressed to margin thylakoids indicated a broadening and shortening of the appressed thylakoid stack within the first 5 min of low-irradiance exposure. The rapidity of the shade response indicates that the early events in this response probably do not directly involve gene activation pathways.Abbreviations PAR photosynthetically active radiation - Sv surface to volume density - Vv volume density - UV-B ultraviolet B radiation